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</head>
<body>

  

  <section id="abstract">
  <p>
  This document describes a formal information model and a common representation 
  for a Web of Things (WoT) Thing Description 1.1. 
  A Thing Description describes the metadata and interfaces of <a>Things</a>,
  where a <a>Thing</a> is an abstraction of a physical or virtual entity that
  provides interactions to and participates in the Web of Things. 
  Thing Descriptions provide a set of interactions based on a small vocabulary 
  that makes it possible both to integrate diverse devices and 
  to allow diverse applications to interoperate. 
  Thing Descriptions, by default, are encoded in a JSON format that also allows
  JSON-LD processing. The latter provides a powerful foundation to represent
  knowledge about <a>Things</a> in a machine-understandable way.
  A Thing Description instance can be hosted by the <a>Thing</a> itself or hosted
  externally when a <a>Thing</a> has resource restrictions (e.g., limited memory space)
  or when a Web of Things-compatible legacy device is retrofitted 
  with a Thing Description.
  Furthermore, this document introduces the Thing Model, which allows authors to describe
  only the model or class of an Internet of Thing (IoT) entity. Thing Models can be seen as a template for Thing 
  Description instances, but with reduced constraints such as no or few requirements for specific 
  communication metadata. 
  </p>

  <p>
    This specification describes a superset of the features defined in Thing Description 1.0 [[WOT-THING-DESCRIPTION]]. 
    Unless otherwise specified, documents created with version 1.0 of this specification remain
    compatible with Thing Description 1.1.
  </p>
  </section>

  <section id="sotd">
<!-- AT-RISK
    <p>
      The following <span class="at-risk">at-risk features</span> (marked in yellow throughout this specification)
      may be removed due to insufficient implementation experience
      <a href="https://w3c.github.io/wot-thing-description/testing/report.html">reported</a>
      and/or comments received during the CR period:
    </p>
    <ul>
      <li>
        Whole sections related to the security schemes described in
        <a href="#certsecurityscheme"></a>,
        <a href="#publicsecurityscheme"></a>, and
        <a href="#popsecurityscheme"></a>.
      </li>
      <li>
        Vocabulary terms and assertions related to the
        <code>implicit</code>, <code>password</code>, and <code>client</code> flows in <a href="#oauth2securityscheme"></a>.
      </li>
      <li>All default values related to the above in <a href="#sec-default-values"></a>.</li>
      <li>A <a href="#td-writeall-consumer">behavioral assertion</a> for <code>writeallproperties</code> that allows rejection of incomplete writes.</li>
    </ul>
-->
  </section>

  <section id="introduction" class="informative">
  <h1>Introduction</h1>
  <section id="introduction-td">
    <h2>Thing Description</h2>
  <p>
  The WoT Thing Description (TD) is a central building block in the W3C Web of
  Things (WoT) and can be considered as the entry point of a <a>Thing</a>
  (much like the <i>index.html</i> of a Web site). A TD instance has five main
  components: textual metadata about the <a href="#thing">Thing</a> itself,
  a set of <a href="#interactionaffordance">Interaction Affordances</a>
  that indicate how the <a>Thing</a> can be used,
  <a href="#sec-data-schema-vocabulary-definition">schemas</a> for the data
  exchanged with the <a>Thing</a> for machine-understandability, <a href="#sec-security-vocabulary-definition">Security Definitions</a>
  to provide metadata about the security mechanisms that must be used for interactions, and, finally, <a href="#sec-hypermedia-vocabulary-definition">Web links</a> to 
  express any formal or informal relation to other <a>Things</a> or documents on the Web.
  </p>
  <p>
  The <a>Interaction Model</a> of W3C WoT defines three types of <a>Interaction Affordances</a>:
  Properties (<a href="#propertyaffordance"><code>PropertyAffordance</code></a> class)
  can be used for sensing and controlling parameters, such as getting the current value or 
  setting an operation state.
  Actions (<a href="#actionaffordance"><code>ActionAffordance</code></a> class) model
  invocation of physical (and hence time-consuming) processes, but can also be used to 
  abstract RPC-like calls of existing platforms. 
  Events (<a href="#eventaffordance"><code>EventAffordance</code></a> class) are used
  for the push model of communication where notifications,
  discrete events, or streams of values are sent asynchronously to the receiver.
  See [[?WOT-ARCHITECTURE]] for details.
  </p>
  <p>
  In general, the TD provides metadata for different <a>Protocol Bindings</a>
  identified by URI schemes [[RFC3986]] (e.g., <code>http</code>, <code>coap</code>, etc. [[?IANA-URI-SCHEMES]]),
  content types based on media types [[RFC2046]]
  (e.g., <code>application/json</code>, <code>application/xml</code>, <code>application/cbor</code>, <code>application/exi</code>, etc. [[?IANA-MEDIA-TYPES]]),
  and security mechanisms (for authentication, authorization, confidentiality, etc.).
  Serialization of TD instances is based on JSON [[RFC8259]], where JSON names refer to terms of
  the TD vocabulary, as defined in this specification document. In addition the JSON serialization of TDs
  follows the syntax of JSON-LD 1.1 [[?JSON-LD11]] to enable extensions and rich semantic processing.
  </p>
  <p>
  <a href="#simple-thing-description-sample">Example 1</a> shows a TD instance and
  illustrates the <a>Interaction Model</a> with Properties, Actions, and Events
  by describing a lamp <a>Thing</a> with the title <i>MyLampThing</i>.
  </p>
<aside class="example" id="simple-thing-description-sample" title="Thing Description sample">
    <pre>{
    "@context": "https://www.w3.org/2022/wot/td/v1.1",
    "id": "urn:dev:ops:32473-WoTLamp-1234",
    "title": "MyLampThing",
    "securityDefinitions": {
        "basic_sc": {"scheme": "basic", "in": "header"}
    },
    "security": "basic_sc",
    "properties": {
        "status": {
            "type": "string",
            "forms": [{"href": "https://mylamp.example.com/status"}]
        }
    },
    "actions": {
        "toggle": {
            "forms": [{"href": "https://mylamp.example.com/toggle"}]
        }
    },
    "events":{
        "overheating":{
            "data": {"type": "string"},
            "forms": [{
                "href": "https://mylamp.example.com/oh",
                "subprotocol": "longpoll"
            }]
        }
    }
}</pre>
</aside>


  <p>
  From this TD example, 
  we know there exists one <a href="#propertyaffordance">Property affordance</a>
  with the title <i>status</i>. 
  In addition, 
  information is provided to indicate that this Property is accessible via 
  (the secure form of) the HTTP protocol with a GET method 
  at the URI <code>https://mylamp.example.com/status</code> 
  (announced within the <code>forms</code> structure by the 
  <code>href</code> member), and will return a string-based status value.
  The use of the GET method is not stated explicitly,
  but is one of the default assumptions defined by this document.
  </p>
  <p>
  In a similar manner, an <a href="#actionaffordance">Action affordance</a> is specified to toggle the
  switch status using the POST method on the
  <code>https://mylamp.example.com/toggle</code> resource,
  where POST is again a default assumption for invoking Actions.
  </p>
  <p>
  The <a href="#eventaffordance">Event affordance</a> enables a mechanism for asynchronous messages
  to be sent by a <a>Thing</a>.
  Here, a subscription to be notified upon a possible overheating event 
  of the lamp can be obtained by using HTTP with its long polling
  subprotocol on <code>https://mylamp.example.com/oh</code>.
  </p>
 
  <p>
  This example also specifies the <code>basic</code> security scheme, 
  requiring a username and password for access.
  Note that a security scheme is first given a name in 
  <code>securityDefinitions</code> and then activated by specifying
  that name in a <code>security</code> section.
  In combination with the use of the HTTP protocol this example
  demonstrates the use of HTTP Basic Authentication.
  Specification of at least one security scheme at the top level is mandatory,
  and gives the default access requirements for every resource.
  However, security schemes can also be specified per-form,
  with configurations given at the form level overriding configurations given at the <code>Thing</code> level,
  allowing for the specification of fine-grained access control.
  It is also possible to use a special <code>nosec</code> security scheme to
  indicate that no access control mechanisms are used.
  Additional examples will be provided later.
  </p>

  <p>
        The Thing Description offers the possibility to add contextual definitions
        in some namespace. This mechanism can be used to integrate additional semantics
        to the content of the Thing Description instance, provided that formal knowledge,
        e.g., logic rules for a specific domain of application, can be found under the
        given namespace. Contextual information can also help specify some configurations and 
        behavior of the underlying communication protocols declared in the <code>forms</code> field.
        <a href="#thing-description-full-serialization">Example 2</a> extends the TD sample from
        Example 1 by introducing a second definition in the <code>@context</code> to declare the
        prefix <code>saref</code> as referring to <a href="https://w3id.org/saref">SAREF</a>, the
        Smart Appliance Reference Ontology [[SMARTM2M]]. This IoT ontology includes terms interpreted
        as semantic labels that can be set as values of the
        <code>@type</code> field, giving the semantics of <a>Things</a> and their
        <a>Interaction Affordances</a>. In the example below, the <a>Thing</a> is labelled with
        <code>saref:LightSwitch</code>, the <code>status</code> <a>Property</a> is labelled with
        <code>saref:OnOffState</code> and the <code>toggle</code> <a>Action</a> with
        <code>saref:ToggleCommand</code>.
  </p>


 
 <aside class="example" id="thing-description-full-serialization" title="Thing Description with TD Context Extension for semantic annotations">
              <pre>
    {
        "@context": [
            "https://www.w3.org/2022/wot/td/v1.1",
            { "saref": "https://w3id.org/saref#" }
        ],
        "id": "urn:dev:ops:32473-WoTLamp-1234",
        "title": "MyLampThing",
        "@type": "saref:LightSwitch",
        "securityDefinitions": {
            "basic_sc": {"scheme": "basic", "in": "header"}
        },
        "security": "basic_sc",
        "properties": {
            "status": {
                "@type": "saref:OnOffState",
                "type": "string",
                "forms": [{
                    "href": "https://mylamp.example.com/status"
                }]
            }
        },
        "actions": {
            "toggle": {
                "@type": "saref:ToggleCommand",
                "forms": [{
                    "href": "https://mylamp.example.com/toggle"
                }]
            }
        },
        "events": {
            "overheating": {
                "data": {"type": "string"},
                "forms": [{
                    "href": "https://mylamp.example.com/oh"
                }]
            }
        }
    }</pre>
</aside>

<p>
    The declaration mechanism inside some
    <code>@context</code> is specified by JSON-LD. A TD instance complies to version 1.1 of
    that specification [[?json-ld11]]. Hence, a TD instance can be also processed as an RDF
    document (for details about semantic processing, please refer to Appendix
    <a href="#json-ld-ctx-usage"></a> and the documentation under the namespace IRIs, e.g.,
    <a href="https://www.w3.org/2019/wot/td">https://www.w3.org/2019/wot/td</a>).
</p>
</section>
<section id="introduction-tm">
    <h2>Thing Model</h2>
    
    <p>One of the main intentions of a <a>Thing Description</a> is to provide a <a>Consumer</a> 
        with all the details necessary to successfully interact with a <a>Thing</a>.  
        In some IoT application scenarios, a fully detailed <a>Thing Description</a>, e.g., with 
        communication metadata is not necessary (e.g., IoT ecosystems may implicitly handle communication separately),
        or may not be available because a new entity has not yet been deployed (e.g., IP address is not yet known). 
        Sometimes, also a kind of class definition is required that forces capability definitions that should be 
        available for all created instances (e.g., large-scale production of new devices).
    </p> 
        
    <p>In order to address the above-mentioned scenarios or others, the <a>Thing Model</a> can be used that mainly provides the data model 
        definitions within <a>Things</a>' <a>Properties</a>, <a>Actions</a>, and/or <a>Events</a> and can be potentially used 
        as template for creating <a>Thing Description</a> instances. In the following a sample 
        <a>Thing Model</a> is presented that can be seen as a model for the <a>Thing Description</a>
        instance in <a href="#simple-thing-description-sample"></a>. 
    </p>

    <pre class="example" title="Thing Model sample" id="td-model-example-lamp">
        {
            "@context": ["https://www.w3.org/2022/wot/td/v1.1"], 
            "@type" : "tm:ThingModel",
            "title": "Lamp Thing Model",
            "properties": {
                "status": {
                    "description": "current status of the lamp (on|off)",
                    "type": "string",
                    "readOnly": true
                }
            },
            "actions": {
                "toggle": {
                    "description": "Turn the lamp on or off"
                }
            },
            "events": {
                "overheating": {
                    "description": "Lamp reaches a critical temperature (overheating)",
                    "data": {"type": "string"}
                }
            }
        }
        </pre>
        <p>
            <a>Thing Model</a> definitions are identified by the <code>"@type": "tm:ThingModel"</code>. 
            As the example shows, it does not provide details about a single <a>Thing</a> instance due to the 
            lack of communication and security metadata.        
            This specification presents a mechanism for deriving valid <a>Thing Description</a> instances from 
            such <a>Thing Model</a> definitions. In addition, other design concepts are specified, including how 
            to override, extend, and reuse existing <a>Thing Model</a> definitions.
        </p>

</section>
</section>

<section id="conformance">
<p>
A Thing Description instance complies with this specification if it follows 
the normative statements in
<a href="#sec-vocabulary-definition"></a>
and
<a href="#sec-td-serialization"></a> 
regarding Thing Description serialization.
</p>
<p>
A JSON Schema [[?JSON-SCHEMA]] to validate Thing Description instances
is provided in Appendix <a href="#json-schema-for-validation"></a>.
</p>

</section>

<section id="terminology" class="informative"> 
<h2>Terminology</h2>

  <p>The fundamental WoT terminology such as
  <dfn>Thing</dfn>,
  <dfn>Consumer</dfn>,
  <dfn>Thing Description</dfn> (<dfn class="lint-ignore">TD</dfn>),
  <dfn>Partial TD</dfn>,
  <dfn>Thing Model</dfn> (<dfn class="lint-ignore">TM</dfn>),
  <dfn>Interaction Model</dfn>,
  <dfn>Interaction Affordance</dfn>,
  <dfn>Property</dfn>,
  <dfn>Action</dfn>,
  <dfn>Event</dfn>,
  <dfn>Protocol Binding</dfn>,
  <dfn>Servient</dfn>,
  <dfn>Vocabulary</dfn>,
  <dfn>Term</dfn>,
  <dfn id="dfn-vocab-term">Vocabulary Term</dfn>,
  <dfn>WoT Interface</dfn>, and
  <dfn>WoT Runtime</dfn>
  are defined in <a href="https://www.w3.org/TR/wot-architecture/#terminology">Section 3</a>
  of the WoT Architecture specification [[?WOT-ARCHITECTURE]].
  </p>

  <p>
      In addition, this specification introduces the following definitions:
  </p>

  <dl>
    <dt>
        <dfn id="dfn-context-ext">TD Context Extension</dfn>
    </dt>
    <dd>
        A mechanism to extend <a>Thing Descriptions</a> with additional <a>Vocabulary
        Terms</a>. It is the basis for semantic annotations and extensions to core
        mechanisms such as Protocol Bindings, Security Schemes, and Data Schemas.
    </dd>
    <dt>
        <dfn id="dfn-inf-model">TD Information Model</dfn>
    </dt>
    <dd>
        Set of <a>Class</a> definitions constructed from pre-defined <a>Vocabularies</a>
        on which constraints apply, thus defining the semantics of these <a>Vocabularies</a>.
        Class definitions are typically expressed in terms of a <a>Signature</a> (a set of
        <a>Vocabulary Terms</a>) and functions over that <a>Signature</a>. The <a>TD
        Information Model</a> also includes <a>Default Values</a>, defined as a global
        function over <a>Classes</a>.
    </dd>
    <dt>
    <dfn id="dfn-td-processor">TD Processor</dfn>
    </dt>
    <dd>
        A system that can serialize some internal representation of a <a>Thing Description</a>
        in a given format and/or deserialize it from that format. A <a>TD Processor</a> must detect
        semantically inconsistent <a>Thing Descriptions</a>, that is, <a>Thing Descriptions</a>
        that cannot satisfy constraints on the <a>Instance Relation</a> of the <code>Thing</code>
        class. For that purpose, a <a>TD Processor</a> may compute forms of <a>Thing
        Descriptions</a> in which all possible <a>Default Values</a> are assigned. A <a>TD Processor</a>
        is typically a sub-system of a <a>WoT Runtime</a>.
        Implementations of a TD Processor may be a TD producer only (able to serialize to TD Documents)
        or a TD consumer only (able to deserialize from TD Documents).
    </dd>
    <dt>
        <dfn id="dfn-td-serialization">TD Serialization</dfn>
        or
        <dfn id="dfn-td-document">TD Document</dfn>
    </dt>
    <dd>
        Textual or binary representation of <a>Thing Descriptions</a> that can be stored and
        exchanged between <a>Servients</a>. A <a>TD Serialization</a> follows a given representation
        format,  identified by a media type when exchanged over the network.
        The default representation format for <a>Thing Descriptions</a> is JSON-based as defined by
        this specification.
    </dd>
  </dl>

  <p>
      These definitions are further developed in <a href="#preliminary-definitions"></a>.
  </p>
</section>

<section class="normative">
  <h1>Namespaces</h1>

  <p>
      The version of the <a>TD Information Model</a>
      defined in <a href="#sec-vocabulary-definition"></a> of this specification
      is identified by the following IRI:
  </p>
  <p>
    <code>https://www.w3.org/2022/wot/td/v1.1</code>
  </p>
  <p>
      This IRI [[RFC3987]], which is also a URI [[!RFC3986]], can be dereferenced to obtain a
      <a href="https://www.w3.org/2022/wot/td/v1.1">JSON-LD context file</a> [[?json-ld11]],
      allowing the compact strings in <a>TD Documents</a> to be expanded to full IRI-based
      <a>Vocabulary Terms</a>. However, this processing is only required when transforming
      JSON-based <a>TD Documents</a> to RDF, an optional feature of <a>TD Processor</a>
      implementations.
  </p>



    <p>
        In the present specification, <a>Vocabulary Terms</a> are always presented in their compact form.
        Their expanded form can be accessed under the namespace IRI of the <a>Vocabulary</a> they
        belong to. These namespaces follow the structure of <a href="#class-definitions"></a>.
        Each <a>Vocabulary</a> used in the <a>TD Information Model</a> has its own namespace IRI,
        as follows:
    </p>
  
    <table class="def">
    <thead>
        <tr>
            <th>Vocabulary</th>
            <th>Namespace IRI</th>
        </tr>
    </thead>
    <tbody>
        <tr>
            <td>Core</td>
            <td><code>https://www.w3.org/2019/wot/td#</code></td>
        </tr>
        <tr>
            <td>Data Schema</td>
            <td><code> 	https://www.w3.org/2019/wot/json-schema#</code></td>
        </tr>
        <tr>
            <td>Security</td>
            <td><code>https://www.w3.org/2019/wot/security#</code></td>
        </tr>
        <tr>
            <td>Hypermedia Controls</td>
            <td><code>https://www.w3.org/2019/wot/hypermedia#</code></td>
        </tr>
    </tbody>
    </table>
    <p>
        All vocabularies that are additionally used for <a>Thing Model</a> definitions have the following namespace IRI:
    </p>


    <table class="def">
        <thead>
            <tr>
                <th>Vocabulary</th>
                <th>Namespace IRI</th>
            </tr>
        </thead>
        <tbody>
            <tr>
                <td>Thing Model</td>
                <td><code>https://www.w3.org/2022/wot/tm#</code></td>
            </tr>
        </tbody>
        </table>
  
    <p>
        The <a>Vocabularies</a> are independent from each other.
        They may be reused and extended in other W3C specifications.
        Every breaking change in the design of a <a>Vocabulary</a>
        will require the assignment of a new year-based namespace URI.
        Note that to maintain the general coherence of the <a>TD Information Model</a>,
        the associated JSON-LD context file is versioned such that every version has its own URI
        (<code>v1</code>, <code>v1.1</code>, <code>v2</code>, ...)
        to also identify non-breaking changes, in particular the addition of new <a>Terms</a>.
    </p>

    <p>
        Because a <a>Vocabulary</a> under some namespace IRI can only undergo non-breaking
        changes, its content can be safely cached or embedded in applications. One 
        advantage of exposing relatively static content under a namespace IRI is to
        optimize payload sizes of messages exchanged between constrained devices. It
        also avoids any privacy leakage resulting from devices accessing publicly
        available vocabularies from private networks (see also
        <a href="#sec-security-consideration-context"></a>).
    </p>

  </section>
  

  <section id="sec-vocabulary-definition" class="normative">
    <h1>TD Information Model</h1>

    <p>
      This section introduces the <a>TD Information Model</a>.
      The <a>TD Information Model</a> serves as the conceptual basis
      for the processing of Thing Descriptions and their serialization,
      which is described separately in <a href="#sec-td-serialization"></a>.
    <p>

      <section>
      <h2>Overview</h2>
    
      <p>
        The <a>TD Information Model</a> is built upon the following, independent <a>Vocabularies</a>:
        <ul>
            <li>
                the <em>core</em> TD <a>Vocabulary</a>, which reflects the
                <a>Interaction Model</a> with the <a>Properties</a>, <a>Actions</a>, and <a>Events</a>
                <a>Interaction Affordances</a> [[?WOT-ARCHITECTURE]]
            </li>
            <li>
                the <em>Data Schema</em> <a>Vocabulary</a>, including (a subset of)
                the terms defined by JSON Schema [[?JSON-SCHEMA]]
            </li>
            <li>
                the <em>WoT Security</em> <a>Vocabulary</a>, identifying security mechanisms
                and requirements for their configuration
            </li>
            <li>
                the <em>Hypermedia Controls</em> <a>Vocabulary</a>, encoding the main principles of RESTful
                communication using Web links and forms
            </li>
        </ul>
      </p>

      <p>
          Each of these <a>Vocabularies</a> is essentially a set of <a>Terms</a> that can
          be used to build data structures, interpreted as objects in the
          traditional object-oriented sense. Objects are instances of classes
          and have properties. In the context of W3C WoT, they denote <a>Things</a> and
          their <a>Interaction Affordances</a>. A formal definition of objects is given in
          <a href="#preliminary-definitions"></a>. The main elements of
          the <a>TD Information Model</a> are then presented in
          <a href="#class-definitions"></a>. Certain object properties may be
          omitted in a TD when <a>Default Values</a> exist. A list of defaults
          is given in <a href="#sec-default-values"></a>.
      </p>

      <p>
          The UML diagram shown next gives an overview of the <a>TD Information Model</a>.
          It represents all classes as tables and the associations that exist between
          classes, starting from the class <a href="#thing"><code>Thing</code></a>,
          as directed arrows. For the sake of readability, the diagram was split in
          four parts, one for each of the four base <a>Vocabularies</a>.
      </p>
      
      <!--<p><a href="http://visualdataweb.de/webvowl/#iri=https://rawgit.com/w3c/wot-thing-description/TD-JSON-LD-1.1/ontology/td.ttl">Click here for the visualization</a></p>-->

      <p class="note">
        The following figures are automatically generated based on the underlying ontology definitions. 
      </p>

    <figure id="td-core-model">
      <img src="visualization/td.svg" alt="UML diagram of the TD information model for the TD core vocabulary"/>
      <figcaption>TD core vocabulary (<a href="visualization/td.svg">SVG file</a>)</figcaption>
    </figure>
    
    <hr>

    <figure id="td-data-schema-model">
      <img src="visualization/jsonschema.svg" alt="UML diagram of the TD information model for the Data schema vocabulary"/>
      <figcaption>Data schema vocabulary (<a href="visualization/jsonschema.svg">SVG file</a>)</figcaption>
    </figure>
    
    <hr>
    
    <figure id="td-security-model">
      <img src="visualization/wotsec.svg" alt="UML diagram of the TD information model for the WoT security vocabulary"/>
      <figcaption>WoT security vocabulary (<a href="visualization/wotsec.svg">SVG file</a>)</figcaption>
    </figure>
    
    <hr>
    
    <figure id="hypermedia-model">
      <img src="visualization/hctl.svg" alt="UML diagram of the TD information model for the hypermedia controls vocabulary"/>
      <figcaption>Hypermedia controls vocabulary (<a href="visualization/hctl.svg">SVG file</a>)</figcaption>
    </figure>

    </section>

    <section id="preliminary-definitions">

        <h2>Preliminaries</h2>

        <p>
            To provide a model that can be easily processed by both,
            simple rules on a tree-based document (i.e., raw JSON processing)
            and rich Semantic Web tooling (i.e., JSON-LD processing),
            this document defines the following formal preliminaries
            to construct the <a>TD Information Model</a> accordingly.
        </p>

        <p>
            All definitions in this section refer to <em>sets</em>, which
            intuitively are collections of elements that can themselves be sets.
            All arbitrarily complex data structures can be defined in terms
            of sets. In particular, an <dfn>Object</dfn> is a data structure
            recursively defined as follows:
        </p>

        <ul>
            <li>
                a <a>Term</a>, which may or may not belong to a <a>Vocabulary</a>,
                is an <a>Object</a>.
            </li>
            <li>
                a set of name-value pairs where the name is a <a>Term</a> and the
                value is another <a>Object</a>, is also an <a>Object</a>.
            </li>
        </ul>

        <p>
            Though this definition does not prevent <a>Objects</a> to include multiple
            name-value pairs with the same name, they are generally not considered
            in this specification. An <a>Object</a> whose elements only have numbers
            as names is called an <dfn>Array</dfn>. Similarly, an <a>Object</a> whose
            elements only have <a>Term</a>s (that do not belong to any <a>Vocabulary</a>)
            as names is called a <dfn>Map</dfn>. All names appearing in some name-value pair
            in a <a>Map</a> are assumed to be <em>unique</em> within the scope of the
            <a>Map</a>.
        </p>

        <p>
            Moreover, <a>Object</a>s can be instances of some <dfn>Class</dfn>.
            A <a>Class</a>, which is denoted by a <a>Vocabulary Term</a>, is
            first defined by a set of <a>Vocabulary Terms</a> called a <dfn>Signature</dfn>. A
            <a>Class</a> whose <a>Signature</a> is empty is called a <dfn>Simple Type</dfn>.
        </p>

        <p>
            The <a>Signature</a> of a <a>Class</a> allows to construct two functions that further
            define <a>Classes</a>: an <dfn>Assignment Function</dfn> and a <dfn>Type Function</dfn>.
            The <a>Assignment Function</a> of a <a>Class</a> takes a <a>Vocabulary Term</a> of the
            <a>Class</a>'s <a>Signature</a> as input and returns either <code>true</code> or
            <code>false</code> as output. Intuitively, the <a>Assignment Function</a> indicates
            whether an element of the <a>Signature</a> is mandatory or optional when instantiating
            the <a>Class</a>. The <a>Type Function</a> of a <a>Class</a> also takes a <a>Vocabulary
            Term</a> of the <a>Class</a>'s <a>Signature</a> as input and returns another <a>Class</a>
            as output. These functions are <em>partial</em>: their domain is limited to the
            <a>Signature</a> of the <a>Class</a> being defined.
        </p>

        <p>
            On the basis of these two functions, an <dfn>Instance Relation</dfn> can be defined
            for a pair composed of an <a>Object</a> and a <a>Class</a>. This relation is defined as
            constraints to be satisfied. That is, an <a>Object</a> is an instance of a <a>Class</a>
            if the two following constraints are <em>both</em> satisfied:
            <ul>
                <li>
                    if for every <a>Term</a> for which the <a>Assignment Function</a> of the <a>Class</a>
                    returns <code>true</code>, the <a>Object</a> includes a name-value pair with the
                    <a>Vocabulary Term</a> as name.
                </li>
                <li>
                    if for every <a>Vocabulary Term</a> in the <a>Signature</a> of the <a>Class</a>
                    used as name in some name-value pair of the <a>Object</a>, the value of that pair
                    is an instance of the <a>Class</a> returned by the <a>Type Function</a> of the
                    <a>Class</a> for the given <a>Vocabulary Term</a>.
                </li>
            </ul>
        </p>

        <p>
            According to the definition above, an <a>Object</a> would be an instance of every <a>Simple
            Type</a>, regardless of its structure. Instead, another definition for the <a>Instance
            Relation</a> is introduced for <a>Simple Types</a>: an <a>Object</a> is an instance
            of a <a>Simple Type</a> if it is a <a>Term</a> with a given lexical form (e.g., <code>true</code>,
            <code>false</code> for the <code>boolean</code> type, <code>1</code>, <code>2</code>,
            <code>3</code>, ... for the <code>unsignedInt</code> type, etc.).
        </p>

        <p>
            Moreover, additional <a>Classes</a>, called <dfn class="lint-ignore">Parameterized Classes</dfn>, can be derived
            from the generic <a>Map</a> and <a>Array</a> structures. An <a>Object</a> is a <a>Map</a> of some
            <a>Class</a>, that is, an instance of the <a>Map</a> type <em>parameterized</em> with some
            <a>Class</a>, if it is a <a>Map</a> such that the value in all the name-value pairs it contains is
            an instance of this <a>Class</a>. The same applies to <a>Arrays</a>.
        </p>

        <p>
            Finally, a <a>Class</a> is a <dfn>Subclass</dfn> of some other <a>Class</a> if every instance of
            the former is also an instance of the latter.
        </p>

        <p>
            Given all definitions above, the <a>TD Information Model</a> is to be understood
            as a set of <a>Class</a> definitions,
            which include a <a>Class</a> name (a <a>Vocabulary Term</a>),
            a <a>Signature</a> (a set of <a>Vocabulary Terms</a>),
            an <a>Assignment Function</a>,
            and a <a>Type Function</a>.
            These <a>Class</a> definitions are provided as tables in <a href="#class-definitions"></a>.
            For each table, the values "mandatory" (respectively, "optional") in the assignment column
            indicates that the <a>Assignment Function</a> returns <code>true</code>
            (respectively, <code>false</code>) for the corresponding <a>Vocabulary Term</a>.
        </p>

        <p>
            By convention, <a>Simple Types</a> are denoted by names starting with lowercase.
            The <a>TD Information Model</a> references the following <a>Simple Types</a> 
            defined in XML Schema [[XMLSCHEMA11-2-20120405]]:
            <code>string</code>,
            <code>anyURI</code>,
            <code>dateTime</code>,
            <code>integer</code>,
            <code>unsignedInt</code>,
            <code>double</code>, and
            <code>boolean</code>.
            Their definition (i.e., the specification of their lexical form) is outside of the
            scope of the <a>TD Information Model</a>.</p>
        <p>
            In addition, the <a>TD Information Model</a> defines a global function on
            pairs of <a>Vocabulary Terms</a>. The function takes a <a>Class</a> name and
            another <a>Vocabulary Term</a> as input and
            returns an <a>Object</a>. If the returned <a>Object</a> is different from
            <code>null</code>, it represents the <dfn>Default Value</dfn> for some
            assignment on the input <a>Vocabulary Term</a> in an instance of the input
            <a>Class</a>. This function allows to relax the constraint
            defined above on the <a>Assignment Function</a>:
            an <a>Object</a> is an instance of a <a>Class</a> if it includes all mandatory
            assignments <em>or</em> if <a>Default Value</a> exist for the missing
            assignments. All <a>Default Values</a> are given in the table of
            <a href="#sec-default-values"></a>. In each table of
            <a href="#class-definitions"></a>, the assignment column contains the value
            "with default" if a <a>Default Value</a> is available for the corresponding
            combination of <a>Class</a> and <a>Vocabulary Term</a> in the <a>TD
            Information Model</a>.
        </p>

        <p>
            The formalization introduced here does not consider the possible relation
            between <a>Objects</a> as abstract data structures and physical world objects
            such as <a>Things</a>. However, care was given to the possibility of re-interpreting
            all <a>Vocabulary Terms</a> involved in the <a>TD Information Model</a> as RDF
            resources, so as to integrate them in a larger model of the physical world
            (an ontology).
            For details about semantic processing, please refer to 
            <a href="#json-ld-ctx-usage"></a> and the documentation under the namespace IRIs, e.g.,
            <a href="https://www.w3.org/2019/wot/td">https://www.w3.org/2019/wot/td</a>.
        </p>

        
    </section>
    
      <section>

        <h2>Class Definitions</h2>

        <p>
            <span class="rfc2119-assertion" id="td-processor">
                A <a>TD Processor</a> MUST satisfy the
                <a>Class</a> instantiation constraints on all <a>Classes</a> defined in
                <a href="#sec-core-vocabulary-definition"></a>,
                <a href="#sec-data-schema-vocabulary-definition"></a>,
                <a href="#sec-security-vocabulary-definition"></a>,
                and <a href="#sec-hypermedia-vocabulary-definition"></a>.
            </span>
        </p>

      <section id="sec-core-vocabulary-definition">
      <h2>Core Vocabulary Definitions</h2>

      <!-- rendered from RDF definitions -->
      %s


    <!--
        <section><h3><code>MultiLanguage</code></h3><p>A <a>Map</a> providing a set of human-readable texts in different languages identified by language tags described in [[BCP47]]. See <a href="#titles-descriptions-serialization-json"></a> for example usages of this container in a Thing Description instance.</p>
        <p>
        <span class="rfc2119-assertion" id="td-multilanguage-language-tag"> 
            Each name of the <code>MultiLanguage</code> <a>Map</a>
            MUST be a language tag as defined in [[!BCP47]].
        </span>
        <span class="rfc2119-assertion" id="td-multilanguage-value"> 
            Each value of the <code>MultiLanguage</code> <a>Map</a>
            MUST be of type <code>string</code>.
        </span>
        </p>
        </section>
    -->
      </section>
    
      <section id="sec-data-schema-vocabulary-definition">
      <h2>Data Schema Vocabulary Definitions</h2>
	  <p>A data schema is an abstract notation for data contained in data formats.</p>
      <p>
        The data schema vocabulary definition reflects a very common subset of the terms defined by JSON Schema [[?JSON-SCHEMA]]. It is noted
        that data schema definitions within Thing Description instances are not limited to this defined subset and may use additional terms
        found in JSON Schema using a <a>TD Context Extension</a> for the additional terms as described in
        <a href="#sec-context-extensions"></a>, otherwise these terms are semantically ignored by <a>TD Processors</a>
        (for details about semantic processing, please refer to 
        <a href="#json-ld-ctx-usage"></a> and the documentation under the namespace IRIs, e.g.,
        <a href="https://www.w3.org/2019/wot/td">https://www.w3.org/2019/wot/td</a>).
      </p>
      <p>In a TD, concrete data formats are specified in Forms (see <a href="#form"></a>) using content types.
         When the value of a content type in an instance of the Form is <code>application/json</code>, 
         the data schema can be processed directly by JSON Schema processors.
         Otherwise, Web of Things (WoT) Binding Templates [[?WOT-BINDING-TEMPLATES]] defines data schema's 
         available mappings to other content types such as XML [[?xml]]. 
         If the content type in an instance of the Form is not <code>application/json</code> and 
         if no mapping is defined for the content type, specifying a data schema does not make sense 
         for the content type.
      </p>
	  <p><span class="at-risk">The following table is at risk but contains content types which MAY use data schema.</span></p>
	  <p>
         <table class="def">
            <thead>
               <tr>
                  <th>Format</th>
                  <th>Content Type</th>
               </tr>
            </thead>
            <tbody>
               <tr>
                  <td>JSON</td>
                  <td>
                     <code>application/json</code> <br />
                     <code>application/ld+json</code> <br />
                     <code>application/senml+json</code> <br />
                     <code>application/cbor</code> <br />
                     <code>application/senml+cbor</code> <br />
                  </td>
               </tr>
               <tr>
                  <td>XML</td>
                  <td>
                     <code>application/xml</code> <br />
                     <code>application/senml+xml</code> <br />
                     <code>application/exi</code> <br />
                  </td>
               </tr>
            </tbody>
         </table>
      </p>

      <!-- rendered from RDF definitions -->
      %s
        
      </section>
    
      <section id="sec-security-vocabulary-definition">
      <h2>Security Vocabulary Definitions</h2>

      <p>
      This specification provides a selection of well-established security mechanisms
      that are directly built into protocols eligible as <a>Protocol Bindings</a> for W3C WoT
      or are widely in use with those protocols.
      The current set of HTTP security schemes is partly based on 
      <a href="https://github.com/OAI/OpenAPI-Specification/blob/main/versions/3.0.1.md#securitySchemeObject">OpenAPI 3.0.1</a> (see also [[?OPENAPI]]). 
      However while the HTTP security schemes, <a>Vocabulary</a>, and syntax
      given in this specification share many similarities with OpenAPI, they are not compatible.
      </p>

      <!-- rendered from RDF definitions -->
      %s
      
      </section>

      <section id="sec-hypermedia-vocabulary-definition">
      <h2>Hypermedia Controls Vocabulary Definitions</h2>

      <p>
        The present model provides a representation for (typed) Web links and Web forms exposed by
        a <a>Thing</a>. The <code>Link</code> class definition reflects a very common subset of the terms defined in
        Web Linking [[!RFC8288]]. The defined terms can be used, e.g., to describe the relation to another <a>Thing</a> such
        as a <i>Lamp Thing</i> is controlled by a <i>Switch Thing</i>. The <code>Form</code> class corresponds to a newly
        introduced form of hypermedia control to manipulate the state of <a>Things</a> (and other Web resources).
      </p>

      <!-- rendered from RDF definitions -->
      %s


    </section>

   </section>
   <section id="sec-default-values">
      <h3>Default Value Definitions</h3>
      <p><span class="rfc2119-assertion" id=
      "td-vocabulary-defaults">When assignments in a TD are
      missing, a <a href="#dfn-td-processor" class="internalDFN"
      data-link-type="dfn">TD Processor</a> <em class="rfc2119"
      title="MUST">MUST</em> follow the <a href=
      "#dfn-default-value" class="internalDFN" data-link-type=
      "dfn">Default Value</a> assignments expressed in the table of
      <a href="#sec-default-values" class=
      "sec-ref">Default Value
      Definitions</a>.</span></p>
      <p>The following table gives all <a href="#dfn-default-value"
      class="internalDFN" data-link-type="dfn">Default Values</a>
      defined in the <a href="#dfn-inf-model" class="internalDFN"
      data-link-type="dfn">TD Information Model</a>.</p>
      <table class="def">
        <thead>
          <tr>
            <th>
              <a href="#dfn-class" class="internalDFN"
              data-link-type="dfn">Class</a>
            </th>
            <th>
              <a href="#dfn-vocab-term" class="internalDFN"
              data-link-type="dfn">Vocabulary Term</a>
            </th>
            <th>
              <a href="#dfn-default-value" class="internalDFN"
              data-link-type="dfn">Default Value</a>
            </th>
            <th>Comment</th>
          </tr>
        </thead>
        <tbody>
          <tr class="rfc2119-default-assertion" id=
          "td-default-readOnly">
            <td><code>DataSchema</code></td>
            <td><code>readOnly</code></td>
            <td><code>false</code></td>
            <td></td>
          </tr>
          <tr class="rfc2119-default-assertion" id=
          "td-default-writeOnly">
            <td><code>DataSchema</code></td>
            <td><code>writeOnly</code></td>
            <td><code>false</code></td>
            <td></td>
          </tr>
          <tr class="rfc2119-default-assertion" id=
          "td-default-observable">
            <td><code>PropertyAffordance</code></td>
            <td><code>observable</code></td>
            <td><code>false</code></td>
            <td></td>
          </tr>
          <tr class="rfc2119-default-assertion" id=
          "td-default-safe">
            <td><code>ActionAffordance</code></td>
            <td><code>safe</code></td>
            <td><code>false</code></td>
            <td></td>
          </tr>
          <tr class="rfc2119-default-assertion" id=
          "td-default-idempotent">
            <td><code>ActionAffordance</code></td>
            <td><code>idempotent</code></td>
            <td><code>false</code></td>
            <td></td>
          </tr>
          <tr class="rfc2119-default-assertion" id=
          "td-default-success">
            <td><code>AdditionalExpectedResponse</code></td>
            <td><code>success</code></td>
            <td><code>false</code></td>
            <td></td>
          </tr>
          <tr class="rfc2119-default-assertion" id=
          "td-default-AdditionalResponseContentType">
            <td><code>AdditionalExpectedResponse</code></td>
            <td><code>contentType</code></td>
            <td>value of the <code>contentType</code> of the <code>Form</code> element it belongs to.</td>
            <td></td>
          </tr>
          <tr class="rfc2119-default-assertion" id=
          "td-default-contentType">
            <td><code>Form</code></td>
            <td><code>contentType</code></td>
            <td><code>application/json</code></td>
            <td></td>
          </tr>
          <tr class="rfc2119-default-assertion" id=
          "td-default-op-properties">
            <td><code>Form</code></td>
            <td><code>op</code></td>
            <td>
              <a href="#dfn-array" class="internalDFN"
              data-link-type="dfn">Array</a> of <code>string</code>
              with the elements <code>readproperty</code> and
              <code>writeproperty</code> when <code>readOnly</code> and <code>writeOnly</code> are set to <code>false</code> or
              <a href="#dfn-array" class="internalDFN"
              data-link-type="dfn">Array</a> of <code>string</code>
              with the element <code>readproperty</code> when <code>readOnly</code> is set to <code>true</code> or
              <a href="#dfn-array" class="internalDFN"
              data-link-type="dfn">Array</a> of <code>string</code>
              with the element <code>writeproperty</code> when <code>writeOnly</code> is set to <code>true</code>.
              <br>
            </td>
            <td>If defined within an instance of
            <code>PropertyAffordance</code></td>
          </tr>
          <tr class="rfc2119-default-assertion" id=
          "td-default-op-actions">
            <td><code>Form</code></td>
            <td><code>op</code></td>
            <td><code>invokeaction</code></td>
            <td>If defined within an instance of
            <code>ActionAffordance</code></td>
          </tr>
          <tr class="rfc2119-default-assertion" id=
          "td-default-op-events">
            <td><code>Form</code></td>
            <td><code>op</code></td>
            <td><a>Array</a> of <code>string</code> with the elements <code>subscribeevent</code> and <code>unsubscribeevent</code></td>
            <td>If defined within an instance of
            <code>EventAffordance</code></td>
          </tr>
          <tr class="rfc2119-default-assertion" id=
          "td-default-in-basic">
            <td><code>BasicSecurityScheme</code></td>
            <td><code>in</code></td>
            <td><code>header</code></td>
            <td></td>
          </tr>
          <tr class="rfc2119-default-assertion" id=
          "td-default-in-digest">
            <td><code>DigestSecurityScheme</code></td>
            <td><code>in</code></td>
            <td><code>header</code></td>
            <td></td>
          </tr>
          <tr class="rfc2119-default-assertion" id=
          "td-default-qop">
            <td><code>DigestSecurityScheme</code></td>
            <td><code>qop</code></td>
            <td><code>auth</code></td>
            <td></td>
          </tr>
          <tr class="rfc2119-default-assertion" id=
          "td-default-in-apikey">
            <td><code>APIKeySecurityScheme</code></td>
            <td><code>in</code></td>
            <td><code>query</code></td>
            <td></td>
          </tr>
          <tr class="rfc2119-default-assertion" id=
          "td-default-in-bearer">
            <td><code>BearerSecurityScheme</code></td>
            <td><code>in</code></td>
            <td><code>header</code></td>
            <td></td>
          </tr>
          <tr class="rfc2119-default-assertion" id=
          "td-default-alg">
            <td><code>BearerSecurityScheme</code></td>
            <td><code>alg</code></td>
            <td><code>ES256</code></td>
            <td></td>
          </tr>
          <tr class="rfc2119-default-assertion" id=
          "td-default-format">
            <td><code>BearerSecurityScheme</code></td>
            <td><code>format</code></td>
            <td><code>jwt</code></td>
            <td></td>
          </tr>
        </tbody>
      </table>
    </section>
  </section>

  <section id="sec-td-serialization" class="normative">
  <h1>TD Representation Format</h1>

  <p>
    WoT Thing Descriptions represent Things and are modeled and structured based on
  <a href="#sec-vocabulary-definition"></a>.
  This section defines a JSON-based representation format for <a>Things</a>,
  a serialization of instances of the <a>Class</a> <code>Thing</code> defined by the <a>TD Information Model</a>.
  </p>

  <p>
    <span class="rfc2119-assertion" id="td-processor-serialization">
        A <a>TD Processor</a> MUST be able to serialize <a>Thing Descriptions</a>
        into the JSON format [[!RFC8259]] and/or deserialize <a>Thing Descriptions</a>
        from that format, according to the rules noted in
        <a href="#td-basic-types-mapping"></a> and
        <a href="#td-class-serialization"></a>.
    </span>
  </p>

  <p>
  The JSON serialization of the <a>TD Information Model</a> is aligned with
  the syntax of JSON-LD 1.1 [[?json-ld11]]
  in order to streamline semantic evaluation.
  Hence, the TD representation format can be processed either as raw JSON
  or with a JSON-LD 1.1 processor
  (for details about semantic processing, please refer to 
  <a href="#json-ld-ctx-usage"></a> and the documentation under the namespace IRIs, e.g.,
  <a href="https://www.w3.org/2019/wot/td">https://www.w3.org/2019/wot/td</a>).
  </p>

<p>
In order to support interoperable internationalization,
<span class="rfc2119-assertion" id="td-json-open">TDs MUST be serialized according to the 
requirements defined in Section 8.1 of RFC8259 [[!RFC8259]] for open ecosystems.</span>
In summary, this requires the following:
<ul>
<li><span class="rfc2119-assertion" id="td-json-open_utf-8">TDs MUST be encoded using UTF-8 [[!RFC3629]].</span></li>
<li><span class="rfc2119-assertion" id="td-json-open_no-byte-order">Implementations MUST NOT 
  add a byte order mark (U+FEFF) to the beginning of a TD document.</span></li>
<li><span class="rfc2119-assertion" id="td-json-open_accept-byte-order"><a>TD Processors</a> MAY ignore
  the presence of a byte order mark rather than treating it as an error.</span></li>
</ul>
</p>

<section id="td-basic-types-mapping">
<h2>Mapping to JSON Types</h2>

  <p>
    The <a>TD Information Model</a> is constructed,
    so that there is an easy mapping between model <a>Objects</a> and JSON types.
    Every <a>Class</a> instances maps to a JSON object,
    where each name-value pair of the <a>Class</a> instance
    is a member of the JSON object.
  </p>

  <p>
    Every <a>Simple Type</a> mentioned in
    <a href="#class-definitions"></a> (i.e., <code>string</code>, <code>anyURI</code>,
    <code>dateTime</code>, <code>integer</code>, <code>unsignedInt</code>,
    <code>double</code>, and <code>boolean</code>) maps to a primitive JSON 
    type (string, number, boolean), as per the rules listed below. These
    rules apply to values in name-value pairs:
  </p>
  <ul>
  <li><span class="rfc2119-assertion" id="td-string-type">
        Values that are of type <code>string</code> or
        <code>anyURI</code> MUST be serialized as JSON strings.
  </span></li>
  <li><span class="rfc2119-assertion" id="td-datetime-type">
        Values that are of type <code>dateTime</code>
        MUST be serialized as JSON strings  following the "date-time" format
        specified by [[RFC3339]].
    </span>
        Examples would include <code>2019-05-24T13:12:45Z</code> and
        <code>2015-07-11T09:32:26+08:00</code>.
    <span class="rfc2119-assertion" id="td-datetime-recommended-type">
        Values that are of type <code>dateTime</code>
        SHOULD use the literal <code>Z</code> 
        representing the UTC time zone instead 
        of an offset.
    </span>
  </li>
  <li><span class="rfc2119-assertion" id="td-integer-type">
        Values that are of type <code>integer</code> or <code>unsignedInt</code>
        MUST be serialized as JSON numbers without a fraction or exponent part.
  </span></li>
  <li><span class="rfc2119-assertion" id="td-number-type">
        Values that are of type <code>double</code>
        MUST be serialized as JSON number.
  </span></li>
  <li><span class="rfc2119-assertion" id="td-boolean-type">
        Values that are of type <code>boolean</code>
        MUST be serialized as JSON boolean.
  </span></li>
  </ul>
  
  <p>
    Every complex type of the <a>TD Information Model</a> (i.e., <a>Arrays</a>, <a>Maps</a>, and <a>Class</a> instances)
    maps to a structured JSON type (array and object), as per the rules listed below:
  </p>
  <ul>
  <li><span class="rfc2119-assertion" id="td-array-type">
        A value of type <a>Array</a> MUST be serialized as JSON array,
        with each value of the name-value pairs as element of the JSON array
        ordered by the numeric name of the pair.
  </span></li>
  <li><span class="rfc2119-assertion" id="td-map-type">
        A value of type <a>Map</a> MUST be serialized as JSON object,
        with each name-value pair as member of the JSON object.
  </span></li>
  <li><span class="rfc2119-assertion" id="td-class-type">
        A <a>Class</a> instance MUST be serialized as JSON object,
        following the detailed rules given individually in <a href="#td-class-serialization"></a>.
  </span></li>
  </ul>

</section>
  
<section id="omitting-default-values">
<h2>Omitting Default Values</h2>

  <p>
  A Thing Description serialization may omit <a>Vocabulary Term</a>
  for which <a>Default Values</a> are defined,
  as listed in the table given in <a href="#sec-default-values"></a>.
  </p>

  <p>
  The following example shows the TD instance from
  <a href="#simple-thing-description-sample">Example 1</a>
  with a checkbox to also include the members with <a>Default Values</a> (=checkbox checked).
  These members can be omitted (=checkbox unchecked) to simplify the TD serialization.
  Note that a <a>TD Processor</a> interprets these omitted members identically
  as if they were explicitly present with a given <a>Default Value</a>.
  </p>

  <aside class="example with-default">
    <div class="with-default-control">
      <input type="checkbox"/>
      <span><i>with Default Values</i></span>
    </div>
<pre>{
    "@context": "https://www.w3.org/2022/wot/td/v1.1",
    "id": "urn:dev:ops:32473-WoTLamp-1234",
    "title": "MyLampThing",
    "securityDefinitions": {
        "basic_sc": {
            "scheme": "basic"
        }
    },
    "security": "basic_sc",
    "properties": {
        "status": {
            "type": "string",
            "forms": [{
                "href": "https://mylamp.example.com/status"
            }]
        }
    },
    "actions": {
        "toggle": {
            "forms": [{
                "href": "https://mylamp.example.com/toggle"
            }]
        }
    },
    "events": {
        "overheating": {
            "data": {
                "type": "string"
            },
            "forms": [{
                "href": "https://mylamp.example.com/oh",
                "subprotocol": "longpoll"
            }]
        }
    }
}
</pre>
<pre>{
    "@context": "https://www.w3.org/2022/wot/td/v1.1",
    "id": "urn:dev:ops:32473-WoTLamp-1234",
    "title": "MyLampThing",
    "securityDefinitions": {
        "basic_sc": {
            "scheme": "basic",
            "in": "header"
        }
    },
    "security": "basic_sc",
    "properties": {
        "status": {
            "type": "string",
            "readOnly": false,
            "writeOnly": false,
            "observable": false,
            "forms": [{
                "op": [
                    "readproperty",
                    "writeproperty"
                ],
                "href": "https://mylamp.example.com/status",
                "contentType": "application/json"
            }]
        }
    },
    "actions": {
        "toggle": {
            "safe": false,
            "idempotent": false,
            "forms": [{
                "op": "invokeaction",
                "href": "https://mylamp.example.com/toggle",
                "contentType": "application/json"
            }]
        }
    },
    "events": {
        "overheating": {
            "data": {
                "type": "string",
                "readOnly": false,
                "writeOnly": false
            },
            "forms": [{
                "op": "subscribeevent",
                "href": "https://mylamp.example.com/oh",
                "contentType": "application/json",
                "subprotocol": "longpoll"
            }]
        }
    }
}
</pre>
    </aside>

    <p>
    Please note that, depending on the <a>Protocol Binding</a> used,
    additional protocol-specific <a>Vocabulary Terms</a> may apply.
    They may also have associated <a>Default Values</a>,
    and hence can also be omitted as explained in this subsection.
    Further information can be found in <a href="#protocol-bindings"></a>.
    </p>
  </section>

<section id="td-class-serialization">
<h2>Information Model Serialization</h2>

<section id="sec-thing-as-a-whole-json">
<h3>Thing Root Object</h3>

  <p>
    A Thing Description is a data structure rooted at an <a>Object</a>
    of type <a href="#thing"><code>Thing</code></a>.
    In turn, a JSON serialization of the Thing Description
    is a JSON object, which is the root of a syntax tree constructed
    from the <a>TD Information Model</a>.
  </p>

  <p><span class="rfc2119-assertion" id="td-context">
  The root element of a <a>TD Serialization</a> MUST be a JSON object that
  includes a member with the name <code>@context</code> and a value of type
  string or array that equals or respectively contains <code>https://www.w3.org/2022/wot/td/v1.1</code>.
  </span></p>
  
  <p>
  In general, this URI is used to identify the
  TD representation format version defined by this specification.
  For JSON-LD processing [[?json-ld11]], this URI specifies the Thing Description context file.
  An <code>@context</code> of type array indicates <a>TD Context Extensions</a> (see <a href="#sec-context-extensions"></a> for details).
  </p>

<pre class="example">
{  
    "@context": "https://www.w3.org/2022/wot/td/v1.1",
    ...
}
</pre>

  <p><span class="rfc2119-assertion" id="td-context-toplevel">
    All name-value pairs of an instance of <code>Thing</code>,
    where the name is a <a>Vocabulary Term</a> in the <a>Signature</a> of <code>Thing</code>,
    MUST be serialized as JSON members of the root object.
  </span></p>

  <p>
    A TD snippet for a serialized root object including all mandatory and optional members is given below:
  </p>

<pre class="example" id="thing-serialization-sample" title="Sample of Thing serializations">
{
    "@context": "https://www.w3.org/2022/wot/td/v1.1",
    "@type": "Thing",
    "id": "urn:dev:ops:32473-Thing-1234",
    "title": "MyThing",
    "titles": {...},
    "description": "Human readable information.",
    "descriptions": {...},
    "support": "mailto:support@example.com",
    "version": {...},
    "created": "2018-11-14T19:10:23.824Z",
    "modified": "2019-06-01T09:12:43.124Z",
    "securityDefinitions": {...},
    "security": ...,
    "base": "https://servient.example.com/",
    "properties": {...},
    "actions": {...},
    "events": {...},
    "links": [...],
    "forms": [...]
}
</pre>

  <p><span class="rfc2119-assertion" id="td-objects">
  All values assigned to
  <code>version</code>,
  <code>securityDefinitions</code>,
  <code>properties</code>,
  <code>actions</code>, and
  <code>events</code>
  in an instance of the <a>Class</a> <code>Thing</code>
  MUST be serialized as JSON objects.
  </span></p>

  <p><span class="rfc2119-assertion" id="td-arrays">
  All values assigned to
  <code>links</code>, and
  <code>forms</code>
  in an instance of the <a>Class</a> <code>Thing</code>
  MUST be serialized as JSON arrays containing JSON objects
  as defined in <a href="#link-serialization-json"></a>
  and <a href="#form-serialization-json"></a>, respectively.
  </span></p>

  <p>
  <span class="rfc2119-assertion" id="td-security-activation">
  The value assigned to
  <code>security</code>
  in an instance of <a>Class</a> <code>Thing</code>
  MUST be serialized as JSON string or as JSON array whose elements are JSON strings.
  </span>
  </p>

</section> <!-- end of id="sec-thing-as-a-whole-json"-->

<section id="titles-descriptions-serialization-json">
<h3>Human-Readable Metadata</h3>

  <p>
    JSON members named <code>title</code> and <code>description</code> are 
    used within a TD document to provide human-readable metadata.
    They can be used as comments for developers inspecting a TD document
    or as display texts for user interface.
  </p>

  <p>
    As defined in <a href="#thing"></a>, the base text direction used to display human-readable metadata
    can either be estimated using heuristics such as the first-strong rule or inferred from language information.
    In TD documents the default language is defined by a value assigned to <code>@language</code> in the <code>@context</code>,
    and this, along with a script subtag if necessary, can be used to determine a base text direction.
    <span class="rfc2119-assertion" id="td-context-default-language-direction-independence">
      However, when interpreting human-readable text,
      each human-readable string value MUST be processed independently.
    </span>
    In other words, a <a>TD Processor</a> cannot carry forward changes in direction from one string to another,
    or infer direction for one string from another one elsewhere in the TD.
  </p>

  <p class="note">
    Strings on the Web [[?STRING-META]] suggests 
    both strong-first and language-based inferencing as means
    to determine the base text direction.
    Given that the Thing Description format is based on JSON-LD 1.1 
    [[?json-ld11]], which currently lacks explicit direction metadata,
    these approaches are currently considered appropriate 
    at the time of this publication. 
    However, if JSON-LD 1.1 adopts support for explicit
    base direction metadata as recommended by [[?STRING-META]],
    the Thing Description format should be updated to take advantage of 
    that feature.
  </p>
  
  <p>
  A TD snippet using <code>title</code> and <code>description</code> is 
  shown below. The default language is set to <code>en</code> through the
  definition of the <code>@language</code> member within a JSON object in the <code>@context</code> array.
  </p>

<pre class="example">
{
    "@context": [
        "https://www.w3.org/2022/wot/td/v1.1",
        { "@language" : "en" }
    ],
    "title": "MyThing",
    "description": "Human readable information.",
    ...
    "properties": {
        "on": {
            "title": "On/Off",
            "type": "boolean",
            "forms": [...]
        },
        "status": {
            "title": "Status",
            "type": "object",
            ...
            "forms": [...]
        }
    },
    ...
}
</pre>

  <p>
  The JSON members named <code>titles</code> and <code>descriptions</code> are 
  used within the TD document to provide human-readable metadata
  in multiple languages within a single TD document.
  <span class="rfc2119-assertion" id="td-multi-languages">
    All name-value pairs of a <code>MultiLanguage</code> <a>Map</a>
    MUST be serialized as members of a JSON object,
    where the name is a well-formed language tag as defined by [[!BCP47]]
    and the value is a human-readable string in the language indicated by the tag.
  </span>
  See <a href="#multilanguage"></a> for details.
  <span class="rfc2119-assertion" id="td-multi-languages-consistent">
    All <code>MultiLanguage</code> object within a TD document
    SHOULD contain the same set of language members.
  </span>
  </p>

  <p>A TD snippet using <code>titles</code> and <code>descriptions</code> at different levels is given below:</p>
    
<pre class="example">
{
    "@context": "https://www.w3.org/2022/wot/td/v1.1",
    "title": "MyThing",
    "titles": {
        "en":"MyThing",
        "de": "MeinDing",
        "ja": "私の物",
        "zh-Hans": "我的东西", 
        "zh-Hant": "我的東西"
    },
    "descriptions": {
        "en":"Human readable information.",
        "de": "Menschenlesbare Informationen.",
        "ja": "人間が読むことができる情報",
        "zh-Hans": "人们可阅读的信息", 
        "zh-Hant": "人們可閱讀的資訊"
    },
    ...
    "properties": {
        "on": {
            "titles": {
                "en": "On/Off",
                "de": "An/Aus",
                "ja": "オンオフ",
                "zh-Hans": "开关",
                "zh-Hant": "開關" },
            "type": "boolean",
            "forms": [...]
        },
        "status": {
            "titles": {
                "en": "Status",
                "de": "Zustand",
                "ja": "状態",
                "zh-Hans": "状态",
                "zh-Hant": "狀態" },
            "type": "object",
            ...
            "forms": [...]
        }
    },
    ...
}
</pre>
    
  <p>
  TD instances may also combine the use of <code>title</code> and <code>description</code>
  with <code>titles</code> and <code>descriptions</code>.
  <span class="rfc2119-assertion" id="td-title-description">
    When <code>title</code> and <code>titles</code> or
    <code>description</code> and <code>descriptions</code>
    are present within the same JSON object,
    the values of <code>title</code> and <code>description</code> MAY be seen as the default text.
  </span>
  <span class="rfc2119-assertion" id="td-titles-descriptions">
    When <code>title</code> and <code>titles</code> or
    <code>description</code> and <code>descriptions</code>
    are present in a TD document,
    each <code>title</code> and <code>description</code> member
    SHOULD have a corresponding <code>titles</code> and <code>descriptions</code> member, respectively.
  </span>
  The language of the default text is indicated by the default language,
  which is usually set by the creator of the Thing Description instance.
  </p>
    
<pre class="example">
{
    "@context": [
        "https://www.w3.org/2022/wot/td/v1.1",
        { "@language" : "de" }
    ],
    "title": "MeinDing",
    "titles": {
        "en": "MyThing",
        "de": "MeinDing",
        "ja": "私の物",
        "zh-Hans": "我的东西", 
        "zh-Hant": "我的東西"
    },
    "description": "Menschenlesbare Informationen.",
    "descriptions": {
        "en": "Human readable information.",
        "de": "Menschenlesbare Informationen.",
        "ja": "人間が読むことができる情報",
        "zh-Hans": "人们可阅读的信息", 
        "zh-Hant": "人們可閱讀的資訊"
    },
    ...
    "properties": {
        "on": {
            "title": "An/Aus",
            "titles": {
                "en": "On/Off",
                "de": "An/Aus",
                "ja": "オンオフ",
                "zh-Hans": "开关",
                "zh-Hant": "開關" },
            "type": "boolean",
            "forms": [...]
        },
        "status": {
            "title": "Zustand",
            "titles": {
                "en": "Status",
                "de": "Zustand",
                "ja": "状態",
                "zh-Hans": "状态",
                "zh-Hant": "狀態" },
            "type": "object",
            ...
            "forms": [...]
        }
    },
    ...
}
</pre>

<p>
  Another possibility to set the default language is through a language negotiation mechanism,
  such as the <code>Accept-Language</code> header field of HTTP.
  <span class="rfc2119-assertion" id="td-ns-multilanguage-content-negotiation">
    In cases where the default language has been negotiated,
    an <code>@language</code> member MUST be present to indicate the result of the negotiation and the corresponding default language of the returned content.
  </span>
  <span class="rfc2119-assertion" id="td-ns-multilanguage-content-negotiation-no-multi">
    When the default language has been negotiated successfully,
    TD documents SHOULD include the appropriate matching values for the members <code>title</code> and <code>description</code>
    in preference to <code>MultiLanguage</code> objects in <code>titles</code> and <code>descriptions</code> members.
  </span>
  <span class="rfc2119-assertion" id="td-ns-multilanguage-content-negotiation-optional">
    Note however that Things MAY choose to not support such dynamically-generated TDs
    nor to support language negotiation (e.g., because of resource constraints).
  </span>
  </p>

</section> <!-- end of id="human-readable-serialization-json"-->

<section id="version-serialization-json">
<h3><code>version</code></h3>

  <p><span class="rfc2119-assertion" id="td-version">
    All name-value pairs of an instance of <code>VersionInfo</code>,
    where the name is a <a>Vocabulary Term</a> included in the <a>Signature</a> of <code>VersionInfo</code>,
    MUST be serialized as JSON members with the <a>Vocabulary Term</a> as name.
  </span></p>

  
  <p>A TD snippet of a version information object is given below:</p>

<pre class="example">
{
    ...
    "version": { "instance": "1.2.1" },
    ...
}
</pre>

  <p>
        The <code>version</code> member is intended as container for additional application- and/or device-specific version information based 
        on <a>TD Context Extensions</a>. See <a href="#semantic-annotations"></a> for details.
  </p>

</section> <!-- end of id="version-json"-->

<section id="security-serialization-json">
<h3><code>securityDefinitions</code> and <code>security</code></h3>

  <p>
    In a <code>Thing</code> instance, the value assigned to
    <code>securityDefinitions</code> is a <a>Map</a> of instances of
    <code>SecurityScheme</code>.
    <span class="rfc2119-assertion" id="td-security">
    All name-value pairs of a <a>Map</a> of <code>SecurityScheme</code> instances
    MUST be serialized as members of the JSON object that results from serializing the <a>Map</a>;
    the name of a pair MUST be serialized as a JSON string and the value of the pair, an
    instance of <code>SecurityScheme</code>, MUST be serialized as a JSON object.
  </span></p>

  <p><span class="rfc2119-assertion" id="td-security-schemes">
    All name-value pairs of an instance of one of the <a>Subclasses</a> of
    <code>SecurityScheme</code>,
    where the name is a <a>Vocabulary Term</a> included in the
    <a>Signature</a> of that <a>Subclass</a> or in the <a>Signature</a> of
    <code>SecurityScheme</code>, MUST be serialized as members of the JSON object
    that results from serializing the <code>SecurityScheme</code> <a>Subclass</a>'s
    instance, with the <a>Vocabulary Term</a> as name.
  </span></p>

  <p>
  The following TD snippet shows a simple security configuration specifying
  basic username/password authentication in the header.
  The value given for <code>in</code> is actually the <a>Default Value</a> (<code>header</code>)
  and could be omitted.
  A named security configuration must be given
  in the <code>securityDefinitions</code> map.
  That definition must be activated by including its JSON name in the
  <code>security</code> member, which can and should be of type string when only one definition is activated.
  </p>

<pre class="example" id="security-basic-example">
    ...
    "securityDefinitions": {
        "basic_sc": {
            "scheme": "basic",
            "in": "header"
        }
    },
    "security": "basic_sc",
    ...
</pre>

<p>
    Security configuration in the TD is mandatory.
    <span class="rfc2119-assertion" id="td-security-mandatory">
    At least one security definition MUST be activated through the
    <code>security</code> member at the Thing level (i.e., in the TD root object).
    </span>
    This configuration can be seen as the default security mechanism required to interact with the <a>Thing</a>.
    <span class="rfc2119-assertion" id="td-security-overrides">
    Security definitions MAY also be activated at the form level by including a
    <code>security</code> member in form objects,
    which overrides (i.e., completely replace) all definitions activated at the Thing level.
    </span>
    </p>
  
    <p>
    The <code>nosec</code> security scheme is provided for the case that 
    no security is needed.
    The minimal security configuration for a <a>Thing</a> is activation
    of the <code>nosec</code> security scheme 
    at the Thing level, as shown in the following example:
    </p>
  
  <pre class="example">
  {
      "@context": "https://www.w3.org/2022/wot/td/v1.1",
      "id": "urn:dev:ops:32473-Thing-1234",
      "title": "MyThing",
      "description": "Human readable information.",
      "support": "https://servient.example.com/contact",
      "securityDefinitions": { "nosec_sc": { "scheme": "nosec" }},
      "security": "nosec_sc",
      "properties": {...},
      "actions": {...},
      "events": {...},
      "links": [...]
  }
  </pre> 
  
  <section id="security-multiple">
    <h3>Multiple Security Definitions</h3>

    <p>
    To give a more complex example, 
    suppose we have a <a>Thing</a> where all <a>Interaction Affordances</a>
    require basic authentication except for one, for which
    no authentication is required.
    For the <code>status</code> Property and the <code>toggle</code> Action,
    <code>basic</code> authentication is required and defined at the Thing level.
    For the <code>overheating</code> Event, however,
    no authentication is required, and hence the security configuration is
    overridden at the form level.
    </p>
  
  <pre class="example">
  {
      ...
      "securityDefinitions": {
          "basic_sc": {"scheme": "basic"},
          "nosec_sc": {"scheme": "nosec"}
      },
      "security": "basic_sc",
      ...
      "properties": {
          "status": {
              ...
              "forms": [{
                  "href": "https://mylamp.example.com/status"
              }]
          }
      },
      "actions": {
          "toggle": {
              ...
              "forms": [{
                  "href": "https://mylamp.example.com/toggle"
              }]
          }
      },
      "events": {
          "overheating": {
              ...
              "forms": [{
                  "href": "https://mylamp.example.com/oh",
                  "security": "nosec_sc"
              }]
          }
      }
  }
  </pre>

  <p>
  TDs can specify a combination of security schemes as well.
  Below is a TD snippet showing digest authentication
  on a proxy combined with bearer token authentication on the <a>Thing</a>.
  In the <code>digest</code> scheme, the <a>Default Value</a> of <code>in</code>
  (i.e., <code>header</code>) is omitted, but still applies.
  Note that the corresponding private security configuration
  such as username/password and tokens must be configured in the <a>Consumer</a>
  to interact successfully.
  When activating multiple security definitions, 
  the <code>security</code> member becomes an array.
  </p>

<pre class="example" id="security-digest-example">
    ...
    "securityDefinitions": {
        "proxy_sc": {
            "scheme": "digest",
            "proxy": "https://portal.example.com/"
        },
        "bearer_sc": {
            "scheme": "bearer",
            "in":"header",
            "format": "jwt",
            "alg": "ES256",
            "authorization": "https://servient.example.com:8443/"
        }
    },
    "security": ["proxy_sc", "bearer_sc"],
    ...
</pre>
 
  <p>However, the use of an array with multiple elements to combine security schemes
  in a <code>security</code> element is now deprecated.
  A <a href="#combosecurityscheme"><code>ComboSecurityScheme</code></a> 
  should be used instead as in the following example, which is exactly equivalent to the one above:
  </p>

<pre class="example" id="security-digest-example2">
    ...
    "securityDefinitions": {
        "proxy_sc": {
            "scheme": "digest",
            "proxy": "https://portal.example.com/"
        },
        "bearer_sc": {
            "scheme": "bearer",
            "in":"header",
            "format": "jwt",
            "alg": "ES256",
            "authorization": "https://servient.example.com:8443/"
        },
        "combo_sc": {
            "scheme": "combo",
            "allOf": ["proxy_sc", "bearer_sc"]
        }
    },
    "security": "combo_sc",
    ...
</pre>
</section>
<section id="security-security-forms">
    <h3><code>security</code> in Forms</h3>

  <p>
  Security configurations can also be specified for different forms
  within the same <a>Interaction Affordance</a>. This may be required for devices that support
  multiple protocols, for example HTTP and CoAP [[?RFC7252]], which support different
  security mechanisms.  This is also useful when alternative authentication
  mechanisms are allowed.  Here is a TD snippet demonstrating three possible
  ways to activate a Property affordance: via HTTPS with basic authentication,
  with digest authentication, with bearer token authentication.
  In other words, 
  the use of different security configurations within multiple forms
  provides a way to combine security mechanisms in an "OR" fashion.
  In contrast, putting multiple security configurations in the same
  <code>security</code> member combines them in an "AND" fashion, 
  since in that case they would all need to be satisfied to allow activation of the <a>Interaction Affordance</a>.
  Note that activating one (default) configuration at the Thing level is still mandatory.
  </p>

<pre class="example">
{
    ...
    "securityDefinitions": {
        "basic_sc": { "scheme": "basic" },
        "digest_sc": { "scheme": "digest" },
        "bearer_sc": { "scheme": "bearer" }
    },
    "security": "basic_sc",
    ...
    "properties": {
        "status": {
            ...
            "forms": [{
                "href": "https://mylamp.example.com/status"
            }, {
                "href": "https://mylamp.example.com/status",
                "security": "digest_sc"
            }, {
                "href": "https://mylamp.example.com/status",
                "security": "bearer_sc"
            }]
        }
    },
    ...
}
</pre>
</section>
<section id="security-comboSecurityScheme">
    <h3><code>ComboSecurityScheme</code></h3>

  <p>To avoid redundancy in this case, e.g. repeating the details of the <code>form</code>
  elements, a <a href="#combosecurityscheme"><code>ComboSecurityScheme</code></a>
  with <code>oneOf</code> can be used instead.  
  </p>
<pre class="example">
{
    ...
    "securityDefinitions": {
        "basic_sc": { "scheme": "basic" },
        "digest_sc": { "scheme": "digest" },
        "bearer_sc": { "scheme": "bearer" },
        "combo_sc": { 
            "scheme": "combo", 
            "oneOf": [ "basic_sc", "digest_sc", "bearer_sc" ] 
        }
    },
    "security": "combo_sc",
    ...
    "properties": {
        "status": {
            ...
            "forms": [{
                "href": "https://mylamp.example.com/status"
            }]
        }
    },
    ...
}
</pre>
</section>
<section id="security-oauth2">
    <h3>OAuth 2.0 usage</h3>
  <p>
  As another more complex example, OAuth 2.0 makes use of scopes. 
  These are identifiers that 
  may appear in tokens and must match with corresponding identifiers in a resource to allow 
  access to that resource (or <a>Interaction Affordance</a> in the case of W3C WoT).
  For example, in the following, the <code>status</code> Property can be
  read by <a>Consumers</a> using bearer tokens containing the scope <code>limited</code>,
  but the <code>configure</code> Action can only be invoked
  with a token containing the <code>special</code> scope.
  Scopes are not identical to roles, but are often associated with them;
  for example, perhaps only those in an administrative role are authorized to perform "special" interactions.
  Tokens can have more than one scope and are issued by dedicated web services to users.
  In this example, an administrator could be issued tokens with both the <code>limited</code> and <code>special</code> scopes,
  while ordinary users could be provided with tokens with the <code>limited</code> scope.
  </p>
  
<pre class="example">
{
    ...
    "securityDefinitions": {
        "oauth2_sc": {
            "scheme": "oauth2",
            "flow": "client",
            "token": "https://example.com/token",
            "scopes": ["limited", "special"]
        }
    },
    "security": "oauth2_sc",
    ...
    "properties": {
        "status": {
            ...
            "forms": [{
                "href": "https://scopes.example.com/status",
                "scopes": ["limited"]
            }]
        }
    },
    "actions": {
        "configure": {
            ...
            "forms": [{
                "href": "https://scopes.example.com/configure",
                "scopes": ["special"]
            }]
        }
    },
    ...
}
</pre>

</section>
<section id="security-apikey">
    <h3>API key usage</h3>

<p>A Thing can require an onboarding process that results in the Consumer requiring an API key
    to interact with the Thing. This API key can be included in the request to the Thing in different ways 
    as the API key scheme specifies. Below is an example of how it can be used as a URI template where the API key 
    should be replaced in the URI by the Consumer when sending an HTTPS request.
</p>


<pre class="example">
    {
        ...
        "securityDefinitions": {
            "apikey_key": {
                "scheme": "apikey",
                "in": "uri",
                "name": "adminKey"
            }
        },
        "security": "apikey_key",
        "properties": {
            "status": {
                ...
                "forms": [{
                    "href": "https://example.com/{adminKey}/status",
                    ...
                }]
            }
        },
        ...
    }
    </pre>

  <p>To give another example of the use of
  the <a href="#combosecurityscheme"><code>ComboSecurityScheme</code></a> in addition to the
  use of URI templates example shown above, suppose there is a security scheme
  where a client ID and a "secret" key provided by a cloud service provider must both be
  embedded in the URL.  Technically, only the key is actually secret and must be handled
  out-of-band, and the client ID, which is not secret, could be embedded in the TD.
  However, if the client ID cannot be easily rotated we may want to avoid embedding it in
  the TD to enhance privacy.
  In this case we can combine two instances of 
  <a href="#apikeysecurityscheme"><code>APIKeySecurityScheme</code></a>, both
  using the <code>uri</code> value for the <code>in</code> location specifier, to 
  declare two URI variables.  These can then (in fact, they must) be used in the 
  <code>href</code> in a <code>Form</code> where the security scheme is active.
  An example follows:
  </p>
<pre class="example">
{
    ...
    "securityDefinitions": {
        "apikey_key": {
            "scheme": "apikey",
            "in": "uri",
            "name": "secKey"
        },
        "apikey_id": {
            "scheme": "apikey",
            "in": "uri",
            "name": "secClientID"
        },
        "apikey_combo": {
            "scheme": "combo",
            "allOf": ["apikey_key","apikey_id"]
        }
    },
    "security": "apikey_combo",
    ...
    "properties": {
        "status": {
            ...
            "forms": [{
                "href": "https://example.com/{secClientID}/status/{secKey}",
                ...
            }]
        }
    },
    ...
}
</pre>
<p>While not shown in this example, it is legal to declare additional URI template
variables using <code>uriVariables</code> and include them in the same URI template,
although the names cannot conflict with those declared in security schemes.  
Using a specific prefix as in the above example
for URI variables declared in security schemes can make it easier to avoid name conflicts.
</p>
<p> <b>API Key in Body:</b> Security parameters might also be included along with the payload in some
systems.  For example, suppose a system requires every payload to be a JSON
object including a member named <code>auth</code> whose value is an object
containing a member called <code>key</code> containing an access key.
Depending on the interaction, however, other elements of the JSON object might 
vary.  This situation can be dealt with using the <code>body</code> security
information location.
Note that for this location, the <code>name</code> parameter is actually a JSON pointer
evaluated relative to the root of the <code>DataSchema</code> for each interaction
it is bound with, which allows it to be used with payloads that vary in other respects.
As an example, here is a light that has a property to set its brightness and color
and two separate actions to turn it on and off.  Although the JSON payloads
are different for these actions the <code>/auth/key</code> element occurs in the same 
relative location so single JSON pointer can be used.
Note: if the security key occurs in different inconsistent locations, it will be
necessary to use multiple security scheme definitions.
<pre class="example">
{
    ...
    "securityDefinitions": {
        "apikey_body": {
            "scheme": "apikey",
            "in": "body",
            "name": "/auth/key"
        }
    },
    "security": "apikey_body",
    ...
    "properties": {
        "color": {
            ...
            "type": "object",
            "properties": {
                "brightness": {
                    "type": "number",
                    ...
                },
                "rgb": {
                    "type": "array",
                    ...
                },
                "auth": {
                    "type": "object",
                    "properties": {
                        "key": {
                           "type": "string"
                        }
                    },
                    "required": ["key"]
                }
            },
            "required": ["brightness", "rgb", "auth"],
            "forms": [{
                "href": "https://example.com/color",
                ...
            }]
        }
    },
    "action": {
        "on": {
            ...
            "input": {
                "auth": {
                    "type": "object",
                    "properties": {
                        "key": {
                           "type": "string"
                        }
                    },
                    "required": ["key"]
                }
            },
            "required": ["auth"],
            "forms": [{
                "href": "https://example.com/on",
                ...
            }]
        },
        "off": {
            ...
            "input": {
                "auth": {
                    "type": "object",
                    "properties": {
                        "key": {
                           "type": "string"
                        }
                    },
                    "required": ["key"]
                }
            },
            "required": ["auth"],
            "forms": [{
                "href": "https://example.com/off",
                ...
            }]
        }
    },
    ...
}
</pre>
However, it is rather annoying and redundant to add the security information
to every data schema.  It is possible to simplify this example by using
the feature that the location referenced by a JSON pointer in a <code>body</code>
location will be automatically inserted if it does not exist.  In this
case the above example can be simplified to the following.  Note that in fact
a data schema will effectively be <em>created</em> for the actions <code>on</code> and
<code>off</code> to hold just the security information.
<pre class="example">
{
    ...
    "securityDefinitions": {
        "apikey_body": {
            "scheme": "apikey",
            "in": "body",
            "name": "/auth/key"
        }
    },
    "security": "apikey_body",
    ...
    "properties": {
        "color": {
            ...
            "type": "object",
            "properties": {
                "brightness": {
                    "type": "number",
                    ...
                },
                "rgb": {
                    "type": "array",
                    ...
                }
            },
            "required": ["brightness", "rgb"],
            "forms": [{
                "href": "https://example.com/color",
                ...
            }]
        }
    },
    "action": {
        "on": {
            ...
            "required": ["auth"],
            "forms": [{
                "href": "https://example.com/on",
                ...
            }]
        },
        "off": {
            ...
            "forms": [{
                "href": "https://example.com/off",
                ...
            }]
        }
    },
    ...
}
</pre>

</section>

</section> <!-- end of id="security-serialization-json"-->    

<section id="property-serialization-json">
<h3><code>properties</code></h3>
  
  <p>
  The value assigned to <code>properties</code> in a <code>Thing</code> instance
  is a <a>Map</a> of instances of <code>PropertyAffordance</code>.
  <span class="rfc2119-assertion" id="td-properties">
    All name-value pairs of a <a>Map</a> of <code>PropertyAffordance</code> instances
    MUST be serialized as members of the JSON object that results from serializing the <a>Map</a>;
    the name of a pair MUST be serialized as a JSON string and the value of the pair, an
    instance of <code>PropertyAffordance</code>, MUST be serialized as a JSON object.
  </span></p>

  <p>
  <span class="rfc2119-assertion" id="td-property-names">
    All name-value pairs of an instance of <code>PropertyAffordance</code>,
    where the name is a <a>Vocabulary Term</a> included in (one of) the <a>Signatures</a> of
    <code>PropertyAffordance</code>, <code>InteractionAffordance</code>, or <code>DataSchema</code>,
    MUST be serialized as members of the JSON object that results from
    serializing the <code>PropertyAffordance</code> instance, with the
    <a>Vocabulary Term</a> as name.
  </span>
  See <a href="#data-schema-serialization-json" class="sec-ref"></a> for
  details on serializing <a href="#dataschema" class="sec-ref"><code>DataSchema</code></a> instances.
  </p>

  <p><span class="rfc2119-assertion" id="td-property-arrays">
    The value assigned to <code>forms</code> in an instance of <code>PropertyAffordance</code>
    MUST be serialized as a JSON array
    containing one or more JSON object serializations as defined in <a href="#form-serialization-json"></a>.
  </span></p>

  <p>
  A snippet for two <a>Property</a> affordances is given below:
  </p>

<aside class="example" id="property-serialization-sample" title="Sample of Property serializations">
<pre>
    ...
    "properties": {
        "on": {
            "type": "boolean",
            "forms": [...]
        },
        "status": {
            "type": "object",
            "properties": {
                "brightness": {
                    "type": "number",
                    "minimum": 0.0,
                    "maximum": 100.0
                },
                "rgb": {
                    "type": "array",
                    "items": {
                        "type": "number",
                        "minimum": 0,
                        "maximum": 255
                    },
                    "minItems": 3,
                    "maxItems": 3
                }
            },
            "required": ["brightness", "rgb"],
            "forms": [...]
        }
    },
    ...
</pre>
</aside>

</section> <!-- end of id="property-serialization-json"-->

<section id="action-serialization-json">
<h3><code>actions</code></h3>

  <p>
    In a <code>Thing</code> instance, the value assigned to <code>actions</code>
    is a <a>Map</a> of instances of <code>ActionAffordance</code>.
    <span class="rfc2119-assertion" id="td-actions">
    All name-value pairs of a <a>Map</a> of <code>ActionAffordance</code> instances
    MUST be serialized as members of the JSON object that results from serializing the <a>Map</a>;
    the name of a pair MUST be serialized as a JSON string and the value of the pair, an
    instance of <code>ActionAffordance</code>, MUST be serialized as a JSON object.
  </span></p>

  <p><span class="rfc2119-assertion" id="td-action-names">
    All name-value pairs of an instance of <code>ActionAffordance</code>,
    where the name is a <a>Vocabulary Term</a> included in (one of) the <a>Signatures</a> of
    <code>ActionAffordance</code> or <code>InteractionAffordance</code>,
    MUST be serialized as members of the JSON object that results from
    serializing the <code>ActionAffordance</code> instance, with the
    <a>Vocabulary Term</a> as name.
  </span></p>

  <p>
  <span class="rfc2119-assertion" id="td-action-objects">
    The values assigned to <code>input</code> and <code>output</code> in an instance of
    <code>ActionAffordance</code>
    MUST be serialized as JSON objects.
  </span>
  They rely on the <a>Class</a> <a href="#dataschema" class="sec-ref"><code>DataSchema</code></a>,
  whose serialization is defined in <a href="#data-schema-serialization-json"></a>.
  </p>

  <p><span class="rfc2119-assertion" id="td-action-arrays">
    The value assigned to <code>forms</code> in an instance of <code>ActionAffordance</code>
    MUST be serialized as a JSON array
    containing one or more JSON object serializations as defined in <a href="#form-serialization-json"></a>.
  </span></p>

  <p>
  A TD snippet of an Action affordance is given below:
  </p>

<aside class="example" id="action-serialization-sample" title="Sample of an Action serialization">
<pre>
    ...
    "actions": {
        "fade": {
            "title": "Fade in/out",
            "description": "Smooth fade in and out animation.",
            "input": {
                "type": "object",
                "properties": {
                    "from": {
                        "type": "integer",
                        "minimum": 0,
                        "maximum": 100
                    },
                    "to": {
                        "type": "integer",
                        "minimum": 0,
                        "maximum": 100
                    },
                    "duration": {"type": "number"}
                },
                "required": ["to","duration"]
            },
            "output": {"type": "string"},
            "forms": [...]
        }
    },
    ...
</pre>
</aside>
 

</section> <!-- end of id="action-serialization-json"-->

<section id="event-serialization-json">
<h3><code>events</code></h3>

  <p>
    In a <code>Thing</code> instance, the value assigned to <code>events</code>
    is a map of instances of <code>EventAffordance</code>.
    <span class="rfc2119-assertion" id="td-events">
    All name-value pairs of a <a>Map</a> of <code>EventAffordance</code> instances
    MUST be serialized as members of the JSON object that results from serializing the <a>Map</a>;
    the name of a pair MUST be serialized as a JSON string and the value of the pair, an
    instance of <code>EventAffordance</code>, MUST be serialized as a JSON object.
  </span></p>

  <p><span class="rfc2119-assertion" id="td-event-names">
    All name-value pairs of an instance of <code>EventAffordance</code>,
    where the name is a <a>Vocabulary Term</a> included in (one of) the <a>Signatures</a> of
    <code>EventAffordance</code> or <code>InteractionAffordance</code>,
    MUST be serialized as members of the JSON object that results from
    serializing the <code>EventAffordance</code> instance, with the
    <a>Vocabulary Term</a> as name.
  </span></p>

  <p>
  <span class="rfc2119-assertion" id="td-event-objects">
    The values assigned to <code>subscription</code>,
    <code>data</code>, and <code>cancellation</code>
    in an instance of <code>EventAffordance</code>
    MUST be serialized as JSON objects.
  </span>
  They rely on the <a>Class</a> <a href="#dataschema" class="sec-ref"><code>DataSchema</code></a>,
  whose serialization is defined in <a href="#data-schema-serialization-json"></a>.
  </p>

  <p><span class="rfc2119-assertion" id="td-event-arrays">
  The value assigned to <code>forms</code> in an instance of <code>EventAffordance</code>
  MUST be serialized as a JSON array
  containing one or more JSON object serializations as defined in <a href="#form-serialization-json"></a>.
  </span></p>

  <p>
  A TD snippet of an Event object is given below:
  </p>

<aside class="example" id="event-serialization-sample" title="Sample of an Event serialization">
<pre>
    ...
    "events": {
        "overheated": {
            "data": {
                "type": "string"
            },
            "forms": [...]
        }
    },
    ...
</pre>
</aside>

<p>
Event affordances have been defined in a flexible manner, 
in order to adopt existing (e.g., WebSub [[websub]]) or customer-oriented event mechanisms (e.g., Webhooks).
For this reason, <code>subscription</code> and <code>cancellation</code> can be defined according to the desired mechanism. Please find further details in [[?WOT-BINDING-TEMPLATES]].
Example <a href="#webhook-example-serialization"></a> illustrates how Events can use <code>subscription</code> and <code>cancellation</code> to describe Webhooks.
</p>

</section> <!-- end of id="event-serialization-json"-->

<section id="link-serialization-json">
<h3><code>links</code></h3>

  <p><span class="rfc2119-assertion" id="td-links">
    All name-value pairs of an instance of <code>Link</code>,
    where the name is a <a>Vocabulary Term</a> included in the <a>Signature</a> of <code>Link</code>,
    MUST be serialized as members of the JSON object that results from
    serializing the <code>Link</code> instance, with the
    <a>Vocabulary Term</a> as name.
  </span></p>


  <p>It is recommended to follow the link relation values as provided in Section <a href="#link"></a>.
 The examples provided below demonstrate the use of different link relation types.</p>


 <p>A reference can be provided that points to a <a>Thing</a> (e.g., a controller) that controls the underlying
    unit (e.g., a lamp). For this <code>controlledBy</code> can be used:</p>
 

<aside class="example" id="link-serialization-sample" title="Sample of a Link serialization">
<pre>
    ...
    "links": [{
        "rel": "controlledBy",
        "href": "https://servient.example.com/things/lampController",
        "type": "application/td+json"
    }]
    ...
</pre>
</aside>

<p>To point to a developer documentation of a <a>Thing</a> the value <code>service-doc</code> can be used:</p>

    <pre class="example" title="Link to developer documentation">
        ...
        "links": [{
            "rel": "service-doc",
            "href": "https://example.com/howTo",
            "type": "application/pdf"
        }]
        ...
    </pre>

    <p>A superordinate Thing can collect a group of Things and refer to them by using the <code>item</code> value:</p>

    <pre class="example" title="An electric drive includes two motors.">
        "title" : "Electric Drive",
        ...
        "links": [{
            "rel": "item",
            "href": "coaps://motor1.example.com",
            "type": " application/td+json"
        },
        {
            "rel": "item",
            "href": "coaps://motor2.example.com",
            "type": " application/td+json"
        }
        ]
        ...
    </pre>

    <p>A Thing refers to a group in which it is collected with the <code>collection</code> value:</p>

    <pre class="example" title="An electric motor is member of the electric drive collection.">
        "title" : "Electric Motor 1",
        "base": "coaps://motor1.example.com",
        ...
        "links": [{
            "rel": "collection",
            "href": "coaps://drive.example.com",
            "type": " application/td+json"
        }]
        ...
    </pre>





</p>

</section> <!-- end of id="link-serialization-json"-->

<section id="form-serialization-json">
<h3><code>forms</code></h3>

  <p><span class="rfc2119-assertion" id="td-forms">
    All name-value pairs of an instance of <code>Form</code>,
    where the name is a <a>Vocabulary Term</a> included in the <a>Signature</a> of <code>Form</code>,
    MUST be serialized as members of the JSON object that results from
    serializing the <code>Form</code> instance, with the
    <a>Vocabulary Term</a> as name.
  </span></p>

  <p><span class="rfc2119-assertion" id="td-form-protocolbindings">
  If required, form objects
  MAY be supplemented with protocol-specific <a>Vocabulary Terms</a>
  identified with a prefix.
  </span>
  See also <a href="#protocol-bindings"></a>.
  </p>

  <p>A TD snippet of a form object in the <code>forms</code> array is given below:</p>

<aside class="example" id="form-serialization-sample" title="Sample of a Form serialization">
<pre>
    ...
    "forms": [{
        "op": "writeproperty",
        "href": "http://mytemp.example.com:5683/temp",
        "contentType": "application/json",
        "htv:methodName": "POST"
    }]
    ...
</pre>
</aside>

<section id="form-uriVariables">
    <h3><code>uriVariables</code></h3>

  <p>
  <code>href</code> may also carry a URI that contains dynamic variables
  such as <code>lat</code> and <code>lon</code> in <code>http://example.org/weather/?lat=35&amp;lon=139</code>.
  In that case the URI can be defined as template as defined in [[RFC6570]]:
  <code>http://example.org/weather/{?lat,long}</code>.
  </p>

  <p><span class="rfc2119-assertion" id="td-uriVariables-names">
  In such a case, the URI Template variables MUST be collected
  in the JSON-object based <code>uriVariables</code> member
  with the associated (unique) variable names as JSON names.
  </span></p>

  <p><span class="rfc2119-assertion" id="td-uriVariables-dataschema">
  The serialization of each value in the map assigned to <code>uriVariables</code>
  in an instance of <code>Form</code> MUST
  rely on the <a>Class</a> <a href="#dataschema" class="sec-ref"><code>DataSchema</code></a>,
  whose serialization is defined in <a href="#data-schema-serialization-json"></a>.
  </span></p>

  <p>A TD snippet using a URI Template for query parameters and <code>uriVariables</code> is given below:</p>

<pre class="example">
{
    "@context": "https://www.w3.org/2022/wot/td/v1.1",
    ...
    "properties": {
        "weather": {
            ...
            "uriVariables": {
                "lat": { 
                    "type": "number", 
                    "minimum": 0, 
                    "maximum": 90, 
                    "description": "Latitude for the desired location in the world" },
                "long": { 
                    "type": "number", 
                    "minimum": -180, 
                    "maximum": 180, 
                    "description": "Longitude for the desired location in the world" }
            },
            "forms": [{
              "href": "http://example.org/weather/{?lat,long}",
              "htv:methodName": "GET"
            }]
        },
        ...
    },
    ...
}
</pre>

<p>
    Alternatively, as defined in [[RFC6570]], <code>uriVariables</code> can be used for replacing the <code>href</code> structure.
    An example TD is provided below where a valid request to get the forecast of Bogota, Colombia would be an HTTP GET
    request to <code>http://example.org/weather/bogota</code>:
    <pre class="example">
        {
            "@context": "http://www.w3.org/ns/td",
            ...
            "properties": {
                "weather": {
                    ...
                    "uriVariables": {
                        "city": {
                            "type": "string",
                            "description": "City name to find the weather information for" 
                        }
                    },
                    "forms": [{
                        "href": "http://example.org/weather/{city}",
                        "htv:methodName": "GET"
                    }]
                },
            ...
            },
            ...
        }
    </pre>
</p>

<p>
    The two examples below can be also combined, while using the same <code>uriVariables</code> feature.
    An HTTP GET request to <code>http://example.org/weather/bogota/?unit=Celsius</code> can be described as follows:
    <pre class="example">
        {
            "@context": "http://www.w3.org/ns/td",
            ...
            "properties": {
                "weather": {
                    ...
                    "uriVariables": {
                        "city": {
                            "type": "string",
                            "description": "City name to find the weather information for" 
                        },
                        "unit": {
                            "type": "string",
                            "enum":["Fahrenheit","Celsius"],
                            "description": "Desired unit for the temperature value"
                        }
                    },
                    "forms": [{
                        "href": "http://example.org/weather/{city}/{?unit}",
                        "htv:methodName": "GET"
                    }]
                },
            ...
            },
            ...
        }
    </pre>
</p>

<p>
    <code>uriVariables</code> are mainly for properties and events. When retrofitting an existing system, it may be necessary to use
    <code>uriVariables</code> for actions. In general, it is recommended to avoid <code>uriVariables</code> as much as possible when a 
    new WoT-based system is designed.
</p>
</section>
<section id="form-contentType">
    <h3><code>contentType</code></h3>

  <p>
  The <code>contentType</code> member is used to assign a media type [[!RFC2046]]
  including media type parameters as attribute-value pairs separated by a <code>;</code> character.
  Example:
  </p>

<pre class="example">
    ...
    "contentType": "text/plain; charset=utf-8",
    ...
</pre>
</section>
<section id="form-response">
    <h3><code>response</code></h3>

  <p>
  In some use cases, the form metadata of the <a>Interaction Affordance</a> not only
  describes the request, but also provides metadata for the expected response.
  For instance, an Action <code>takePhoto</code> defines an <code>input</code> schema
  to submit parameter settings of a camera (aperture priority, timer, etc.) using
  JSON for the request payload (i.e., <code>"contentType": "application/json"</code>).
  The output of this action is the photo taken, which is available in JPEG format, for example.
  In such cases, the <code>response</code> member is used to indicate the representation format
  of the response payload (e.g., <code>"contentType": "image/jpeg"</code>).
  Here no <code>output</code> schema is required, as the content type fully specifies
  the representation format.
  </p>

  <p>
  <span class="rfc2119-assertion" id="td-form-response-object">
  If present, the value assigned to <code>response</code> in an instance of
  <code>Form</code> MUST be a JSON object.
  </span>
  <span class="rfc2119-assertion" id="td-forms-response">
  If present, the response object MUST contain a <code>contentType</code> member as
  defined in the <a>Class</a> definition of
  <a href="#expectedresponse" class="sec-ref"><code>ExpectedResponse</code></a>.
  </span>
  </p>

  <p>
  A <code>form</code> snippet with the <code>response</code> member is shown
  below based on the <code>takePhoto</code> Action described above:
  </p>

<pre class="example">
{
    ...
    "actions": {
        "takePhoto": {
            ...
            "forms": [{
                "op": "invokeaction",
                "href": "http://camera.example.com/api/snapshot",
                "contentType": "application/json",
                "response": {
                    "contentType": "image/jpeg"
                }
            }]
        }
    },
    ...
}
</pre>
</section>
<section id="form-contentMediaType-contentEncoding">
    <h3><code>contentMediaType</code> and <code>contentEncoding </code></h3>


<p>
In some cases binary data is embedded in text-based values, e.g., a JSON string-based value embeds a base64 encoded image.
The terms <code>contentMediaType</code> and <code>contentEncoding</code> can be used to clarify the context and encoding 
format of such name-value pairs. A sample usage of <code>contentMediaType</code> and <code>contentEncoding</code>
is shown below:
</p>

<pre class="example">
{
    ...
    "properties": {
        "image": { 
	        "description": "Provides latest image", 
	        "type": "string",
	        "contentMediaType": "image/png",
	        "contentEncoding": "base64",
	        "forms": [{ 
			    "op": "readproperty", 
			    "href": "coaps://mylamp.example.com/lastPicture", 
			    "cov:methodName": "GET",
			    "contentType": "application/json" 
		    }] 
        }
    },
    ...
}
</pre>
</section>

<section id="form-top-level">
    <h3>Top level <code>forms</code></h3>

  <p>
  When <code>forms</code> is present at the top level, it can be used to describe meta interactions offered by a <a>Thing</a>.
  For example, the operation types <code>readallproperties</code> and <code>writeallproperties</code> are for meta
  interactions with a <a>Thing</a> by which <a>Consumers</a> can read and write all properties at once.
  In the example below, a <code>forms</code> member is included in the TD root object
  and the <a>Consumer</a> can use the submission target
  <code>https://mylamp.example.com/allproperties</code> both to read or write all
  Properties (i.e., <code>on</code>, <code>brightness</code>, and <code>timer</code>)
  of the <a>Thing</a> in a single protocol transaction.
  </p>

<pre class="example" id="td-forms-readall-example">
{
    ...
    "properties": {
        "on": {
            "type": "boolean",
            "forms": [...]
        },
        "brightness": {
            "type": "number",
            "forms": [...]
        },
        "timer": {
            "type": "integer",
            "forms": [...]
        }
    },
    ...
    "forms": [{
        "op": "readallproperties",
        "href": "https://mylamp.example.com/allproperties",
        "contentType": "application/json",
        "htv:methodName": "GET"
    }, {
        "op": "writeallproperties",
        "href": "https://mylamp.example.com/allproperties",
        "contentType": "application/json",
        "htv:methodName": "PUT"
    }]
}
</pre>

<p>
In the case of operation type <code>writeallproperties</code>, it is expected that the <a>Consumer</a> provides all writable (non <code>readOnly</code>) properties and the (new) assigned values (e.g., within payload).
Similarly, for the <code>writemultipleproperties</code> operation type, it is expected that the <a>Consumer</a> provides writable (non <code>readOnly</code>) properties.
On the <a>Thing</a> side, <a>Thing</a> is expected to return readable (non <code>writeOnly</code>) properties in the case of <code>readmultipleproperties</code> and <code>readallproperties</code> operation types.
</p>

</section>
</section> <!-- end of id="form-serialization-json"-->

<section id="data-schema-serialization-json">
<h3>Data Schemas</h3>

  <p>
  The data schemas of the WoT Thing Description defined through the
  <a href="#dataschema" class="sec-ref"><code>DataSchema</code></a> <a>Class</a>
  are based on a subset of the JSON Schema terms [[?JSON-SCHEMA]].
  Thus, serializations of the TD data schemas can be fed directly into JSON Schema
  validator implementations to validate the data exchanged with <a>Things</a>.
  </p>

  <p>
  Data schema serialization applies to <code>PropertyAffordance</code> instances,
  the values assigned to <code>input</code> and <code>output</code> in
  <code>ActionAffordance</code> instances,
  the values assigned to <code>subscription</code>, <code>data</code>, and <code>cancellation</code> in
  <code>EventAffordance</code> instances,
  and the value assigned to <code>uriVariables</code> in instances of <a>Subclasses</a> of <code>InteractionAffordance</code>
  (when a <a href="#form-serialization-json">form object</a> uses a URI Template).
  </p>

  <p><span class="rfc2119-assertion" id="td-data-schema">
    All name-value pairs of an instance of one of the <a>Subclasses</a> of
    <code>DataSchema</code>, where the name is a <a>Vocabulary Term</a> included in the
    <a>Signature</a> of that <a>Subclass</a> or in the <a>Signature</a> of
    <code>DataSchema</code>, MUST be serialized as members of the JSON object
    that results from serializing the <code>DataSchema</code> <a>Subclass</a>'s
    instance, with the <a>Vocabulary Term</a> as name.
  </span></p>

  <p><span class="rfc2119-assertion" id="td-data-schema-objects">
  The value assigned to <code>properties</code> in an instance of
  <code>ObjectSchema</code> MUST be serialized as a JSON object.
  </span></p>

  <p><span class="rfc2119-assertion" id="td-data-schema-arrays">
  The values assigned to <code>enum</code>,
  <code>required</code>,
  and <code>oneOf</code> in an instance of <code>DataSchema</code>
  MUST be serialized as a JSON array.
  </span></p>

  <p><span class="rfc2119-assertion" id="td-data-schema-objects-arrays">
  The value assigned to <code>items</code> in an instance of
  <code>ArraySchema</code> MUST be serialized as a JSON object or a JSON array containing JSON objects.
  </span></p>

  <p>
  A TD snippet data schema members is given below.
  Note that the surrounding object may be a data schema object
  (e.g., for <code>input</code> and <code>output</code>)
  or a Property object, which would contain additional members.
  </p>

<aside class="example" id="dataschema-serialization-sample" title="Sample of a DataSchema serialization">
<pre>
    ...
    "type": "object",
    "properties": {
        "status": {
            "title": "Status",
            "type": "string",
            "enum": ["On", "Off", "Error"]
        },
        "brightness": {
            "title": "Brightness value",
            "type": "number",
            "minimum": 0.0,
            "maximum": 100.0
        },
        "rgb": {
            "title": "RGB color value",
            "type": "array",
            "items": {
                "type": "number",
                "minimum": 0,
                "maximum": 255
            },
            "minItems": 3,
            "maxItems": 3
        }
    },
    ...
</pre>
</aside>

  <p>
  The terms <code>readOnly</code> and <code>writeOnly</code> can be used to signal
  which data items are exchanged in read interactions (i.e., when reading a Property)
  and which in write interactions (i.e., when writing a Property).
  This can be used as a workaround when Properties of an unconventional <a>Thing</a>
  exhibit different data for reading and writing, which can be the case when
  augmenting an existing device or service with a Thing Description.
  </p>

  <p>A TD snippet with the usage of <code>readOnly</code> and <code>writeOnly</code> is given below:</p>

<pre class="example">
    ...
    "properties": {
        "status": {
            "description": "Read or write On/Off status.",
            "type": "object",
            "properties": {
                "latestStatus": {
                    "type": "string",
                    "enum": ["On", "Off"],
                    "readOnly": true
                },
                "newStatusValue": {
                    "type": "string",
                    "enum": ["On", "Off"],
                    "writeOnly": true
                }
            },
            forms: [...]
        }
    }
    ...
</pre>

  <p>
  When the <code>status</code> Property is read,
  the status data is returned using a <code>latestStatus</code> member in the payload.
  To update the <code>status</code> Property,
  the new value must be provided through a <code>newStatusValue</code> member in the payload.
  </p>

  <p>
  As an additional feature,
  a Thing Description instance allows the usage of a <code>unit</code> member within data schemas.
  This can be used to associate a unit of measure to a data item.
  Its string value can be selected freely. However, it is recommended to select units defined in
  well-known <a>Vocabularies</a>. See <a href="#sec-context-extensions"></a> for an example.
</p>

</section> <!-- end of id="data-schema-serialization-json"-->

</section> <!-- end of id="serialization-json"-->

<section id="identification-serialization-json">
<h2>Identification</h2>

  <p>
  The JSON-based serialization of Thing Descriptions is identified by 
  the media type <code>application/td+json</code> or the
  CoAP Content-Format ID <code>432</code> (see <a href="#iana-section"></a>).
  </p>

</section>

<section id="validation-serialization-json">
<h2>Validation</h2>
  <p class="ednote" title="No Tag Yet">
  This section refers to
  tagging of assertions into different categories for the purposes of 
  validation.  This has not yet been done but will be done prior to CR
  transition.
  </p>
  <!--
  <p class="ednote" title="Extensions">
  Validation of extensions is difficult for various reasons 
  so we may extend this with variants
  that support extensions or not e.g. "Basic Validation with/without Extensions".
  </p>
  -->

  <p>
  In several contexts automatic validation of a JSON-based serialization 
  of a Thing Description is useful.  Formally, a valid TD must satisfy all
  the assertions in this specification, but not all assertions can be 
  validated given only the JSON serialization, for instance, the assertions
  listed under <a href="#behavior"></a> that relate a TD to the
  behavior of a Thing that it describes.  Extensions are also problematic,
  in that even if formal metadata is given for validating an extension,
  dynamically fetching this metadata in a deployment might pose a privacy
  risk.  In this section, therefore, we name and define various levels of
  validation appropriate for different contexts.
  </p>
  <section id="minimal-validation-serialization-json">
  <h3>Minimal Validation</h3>
  <p>Minimal Validation is appropriate where validation needs to be 
  self-contained (e.g. devices on isolated networks).
  It does not attempt to validate context extensions and vocabularies.
  </p><p> 
  In practice, these assertions can be validated using a JSON Schema 
  in combination with a few spot checks, for example to check that 
  security schema names have matching definitions.
  </p><p> 
  This level of validation includes all assertions implied by 
  normative tables in this document as well as all assertions marked
  with the "Minimal" tag.
  </p>
  </section>
  <section id="basic-validation-serialization-json">
  <h3>Basic Validation</h3>
  <p>Basic validation is appropriate in situations where
  network access is possible and does not pose a privacy risk, and
  for relatively unconstrained computing requirements.  It is suitable
  for gateways, for example, but not for endpoints, since semantic
  processing is required.  It can validate extensions.
  </p><p>
  In this case, context definition files and 
  SHACL definitions can be used to validate additional
  assertions and check TDs for semantic consistency.  In addition, if
  context definitions and SHACL constraints for extension vocabularies 
  can be fetched, then these
  can be used to validate extensions.
  </p><p> 
  This level of validation includes all those covered by 
  <a href="#minimal-validation-serialization-json"></a>
  as well as all assertions marked with the "Basic" tag.
  </p>
  </section>
  <section id="full-validation-serialization-json">
  <h3>Full Validation</h3>
  <p>Full validation confirms that all the assertions in this document
  are satisfied, 
  including the assertions given in <a href="#behavior"></a> that
  confirm the TD is consistent with the Thing it describes.
  This level of validation is appropriate during development, before
  release, and possibly after installation.
  Validation during development would have to be on test Things.
  Actual installation of instances of such Things requires updating the
  TD with appropriate per-instance identifiers and URLs and so for
  maximum assurance, in-field validation would have to take place after
  installation.
  </p>
  </section>
  
</section>

</section> <!-- end of id="sec-td-serialization"-->

<section id="sec-context-extensions" class="informative">
<h1>TD Context Extensions</h1>

  <p>
  In addition to the standard <a>Vocabulary</a> definitions in
  <a href="#sec-vocabulary-definition"></a>,
  the WoT Thing Description offers the possibility to add context knowledge
  from additional namespaces.
  This mechanism can be used to enrich the Thing Description
  instances with additional (e.g., domain-specific) semantics.
  It can also be used to import additional <a>Protocol Bindings</a>
  or new security schemes in the future.
  </p>

  <p>
  For such <a>TD Context Extensions</a>, the Thing Descriptions use the <code>@context</code>
  mechanism known from JSON-LD [[?json-ld11]].
  When using <a>TD Context Extensions</a>,
  the value of <code>@context</code> of the <a>Class</a> <code>Thing</code>
  is an Array with additional elements of type <code>anyURI</code> identifying JSON-LD context files
  or <a>Map</a> containing namespace IRIs as defined in <a href="#thing"></a>.
  </p>

  <p>
    The serialization rules for complex types in <a href="#td-basic-types-mapping"></a>
    define the serialization of an extended <code>@context</code> name-value pair.
    A snippet with <a>TD Context Extensions</a> is given below:
  </p>

<pre class="example">
{
    "@context": [
        "https://www.w3.org/2022/wot/td/v1.1",
        {
            "eg": "http://example.org/iot#",
            "cov": "http://www.example.org/coap-binding#"
        },
        "https://schema.org/"
    ],
    ...
}
</pre>

<section>
<h3>Semantic Annotations</h3>

    <p>
    <a>TD Context Extensions</a> allow for the use of additional <a>Vocabulary Terms</a> in a Thing Description instance.
    If the included namespaces are based on <a>Class</a> definitions
    such as those provided by the RDF Schema or OWL,
    they can be used to annotate any <a>Class</a> instance of a Thing Description semantically
    by associating the instance to a such an external <a>Class</a> definition.
    This is done by assigning a <a>Class</a> name to the <code>@type</code> name-value pair or
    including <a>Class</a> name in its <a>Array</a> value for multiple associations/annotations.
    Following the serialization rules in <a href="#td-basic-types-mapping"></a>,
    <code>@type</code> is either serialized as a JSON string or as a JSON array.
    <code>@type</code> is the JSON-LD keyword [[?json-ld11]] used to set the type of a node.
    </p>

    <p>
    <a>TD Context Extensions</a> also allow the inclusion of additional name-value pairs
    and well-defined values within any <a>Class</a> instance of a Thing Description.
    These pairs and values are defined through the included <a>Vocabulary Terms</a>
    and are serialized as additional members in the corresponding JSON objects
    or values of existing members, respectively.
    Examples are additional version metadata for the <a>Thing</a>
    or units of measure for data items.
    </p>

    <p>
    The next subsections show some sample usage of different kind of ontologies in Thing Descriptions.
    </p>

    <section id="semantic-annotations-example-version-units">
    <h3>Example I: Additional Basic Metadata</h3>

    <p>
      The sample TD snippet below provides additional metadata terms from different 
      external context files as provided in <code>@context</code>. The version information 
      container is extended by adding additional version information about the used software (<code>s:softwareVersion</code>). 
      <a href="http://schema.org">schema.org</a> is used for providing serial number and organisation information such as the company name of the <a>Thing</a>. 
      The <a href="https://w3id.org/saref">SAREF</a> ontology is used to provide a semantic context of the 
      <a>Thing</a> (<code>saref:TemperatureSensor</code>), and for the unit assignment for the temperature property 
      the  <a href="http://www.ontology-of-units-of-measure.org/resource/om-2/">Ontology of Units of Measure (OM)</a>
      is used. 
    </p>

    <p class="note">
        Please note that these <a>Vocabularies</a> and ontologies are used as examples. Others can be used based on application domain and use case.
    </p>
<pre class="example">
{
    "@context": [
        "https://www.w3.org/2022/wot/td/v1.1",
        {
            "saref": "https://w3id.org/saref#",
            "om": "http://www.ontology-of-units-of-measure.org/resource/om-2/",
            "schema": "http://schema.org" 
        }
    ],
    "version": {
        "instance": "1.2.1",
        "schema:softwareVersion" : "1.0.1"
    },
    "schema:serialNumber": "4CE0460D0G",
    "schema:manufacturer": {"name": "CompanyName"},
    ...
    "@type": "saref:TemperatureSensor",
    "properties": {
        "temperature": {
            "description": "Temperature value of the weather station",
            "type": "number",
            "minimum": -32.5,
            "maximum": 55.2,
            "unit": "om:degree_Celsius",
            "forms": [...]
        },
        ...
    },
    ...
}
</pre>

</section>
<section id="semantic-annotations-example-state">
    <h3>Example II: State Annotations</h3>

    <p>
        In many cases, <a>TD Context Extensions</a> may be used to annotate pieces of a data schema,
        to be able to semantically process the state information of the physical world object,
        which is represented by the data exchanged during an interaction (e.g., in the payload of a response).
        For example, a semantic description of this state information in RDF
        can be embedded in the <a>TD Document</a> and pieces of a data schema can be individually annotated
        as referring to specific parts of that RDF-modeled state of the physical world object.
    </p>

    <p>
        The TD snippet below uses SAREF to describe the state of a lamp. The external <a>Vocabulary
        Term</a> <code>ssn:forProperty</code>, taken from <a href="https://www.w3.org/TR/vocab-ssn/">SSN</a>,
        the Semantic Sensor Network Ontology [[VOCAB-SSN]], is being used to link the data schema of
        the <code>status</code> <a>Property</a> with the actual on/off state of the physical
        world object.
    </p>

<pre class="example" id="saref-state-annotation-example">
{
    "@context": [
        "https://www.w3.org/2022/wot/td/v1.1",
        {
            "saref": "https://w3id.org/saref#",
            "ssn": "http://www.w3.org/ns/ssn/"
        }
    ],
    "id": "urn:dev:ops:32473-WoTLamp-1234",
    "@type": "saref:LightSwitch",
    "saref:hasState": {
        "@id": "urn:dev:ops:32473-WoTLamp-1234/state",
        "@type": "saref:OnOffState"
    },
    ...
    "properties": {
        "status": {
            "ssn:forProperty": "urn:dev:ops:32473-WoTLamp-1234/state",
            "type": "string",
            "forms": [{"href": "https://mylamp.example.com/status"}]
        },
        "fullStatus": {
            "ssn:forProperty": "urn:dev:ops:32473-WoTLamp-1234/state",
            "type": "object",
            "properties": {
                "statusString": { "type": "string" },
                "statusCode": { "type": "number" },
                "statusDescription": { "type": "string" }
            },
            "forms": [{"href": "https://mylamp.example.com/status?full=true"}]
        },
        ...
    },
    ...
}
</pre>

    <p>
        In <a href="#thing-description-full-serialization"></a>, the state of the <a>Thing</a>
        is given by the <code>status</code> affordance itself
        and possible state changes are given by the <code>toggle</code> affordance.
        In other words, the state of the physical world object directly provides the
        <a>Interaction Affordances</a> of the <a>Thing</a>. This design is satisfactory for
        simple cases. In more elaborate cases, however, several affordances may be available
        for the same physical state. In the example above, the <code>fullStatus</code>
        <a>Property</a> provides an alternative, more verbose representation for the state
        of the lamp.
    </p>

</section>
<section id="semantic-annotations-example-geoloc">
    <h3>Example III: Geolocation Annotations</h3>

    <p class="issue">
        This new subsection is in work in progress. Examples will be updated based on experience
        of the next PlugFests.
    </p>


    <p>
    For many use cases like in building, agriculture, or smart city location based data is required. This
    information can be provided in the Thing Description in different ways and can be relied on
    different kind of location ontologies (e.g.,[[w3c-basic-geo]], schema.org) depending on purpose (e.g., indoor, outdoor).  
    Also see [[sdw-bp]].
    </p>
    
    <p>
        The TD snippet below uses <code>lat</code> and <code>long</code> from the [[w3c-basic-geo]] ontology to 
        provide static latitude and longitude metadata at Thing's top level. 
    </p>

    <pre class="example" id="saref-geolocation-annotation-example">
{
    "@context": [
        "https://www.w3.org/2022/wot/td/v1.1",
        {
            "geo": "http://www.w3.org/2003/01/geo/wgs84_pos#"        
        }
    ],
    "@type": "Thing",
    "geo:lat": "26.58",
    "geo:long": "297.83",
    ...
    "properties": {
        ...
    
}
</pre>


<p>
        In some use cases location based metadata have to be provided at the interaction level, e.g., 
        as provided as a <a>Property</a> that returns the latest <code>longitude</code>, <code>latitude</code>, and <code>elevation</code> values
        based on schema.org:
</p>

<pre class="example" id="saref-geolocation-annotation-example-2">
{
    "@context": [
        "https://www.w3.org/2022/wot/td/v1.1",
        {
            "schema": "http://schema.org#"
        }
    ],
    ...
    "properties": {
        "position": {
            "type": "object",
            "@type": "schema:GeoCoordinates",
            "properties": {
                    "longitude": { "type": "number" },
                    "latitude":  { "type": "number" },
                    "elevation": { "type": "number" }
            },
            "forms": [{"href": "https://robot.example.com/position"}]
        },
        ...
    },
    ...
}
</pre>

<p>
        In case a different name is desired for, e.g., <code>longitude</code>, <code>latitude</code>, 
        and <code>elevation</code> in the data model, the <code>jsonld:context</code> can be used to link 
        terms to specific vocabulary from an ontology (also see [[JSON-SCHEMA-ONTOLOGY]], Section 3.3 Defining a JSON-LD context for data instances):
</p>

<pre class="example" id="saref-geolocation-annotation-example-3">
{
    "@context": [
        "https://www.w3.org/2022/wot/td/v1.1",
        {
            "schema": "http://schema.org#"
        }
    ],
    ...
    "properties": {
        "position": {
        "jsonld:context": {
            "schema": "http://schema.org/"
            "long": "schema:longitude",
            "lat": "schema:latitude",
            "height": "schema:elevation"
        },
        "type": "object",
        "properties": {
            "long": { "type": "number" },
            "lat": { "type": "number" },
            "height": { "type": "number" }
        }
        }
  },
    ...
}
</pre>

</section>
</section>

<section>
<h3>Adding Protocol Bindings</h3>

  <p>
  With the <a>TD Context Extensions</a> in a Thing Description,
  the communication metadata can be supplemented or new <a>Protocol Bindings</a> added
  through additional <a>Vocabulary Terms</a> serialized into JSON objects representing a <code>Form</code> instance.
  (see also <a href="#protocol-bindings"></a>).
  </p>
    
  <p>
  The following TD example uses a fictional CoAP <a>Protocol Binding</a>,
  as no such <a>Protocol Binding</a> is available at the time of writing this specification.
  This <a>TD Context Extension</a> assumes that there is a <em>CoAP in RDF vocabulary</em> similar to <em>HTTP Vocabulary in RDF 1.0</em> [[?HTTP-in-RDF10]]
  that is accessible via an example namespace <code>http://www.example.org/coap-binding#</code>.
  The supplemented <code>cov:methodName</code> member instructs the <a>Consumer</a>
  which CoAP method has to be applied
  (e.g., <code>GET</code> for the CoAP Method Code 0.01,
  <code>POST</code> for the CoAP Method Code 0.02,
  or <code>iPATCH</code> for CoAP Method Code 0.07).
  </p>
    
<aside class="example" id="context-extension-for-forms" title="Specialization of forms through TD Context Extension">
<pre>
{
    "@context": [
        "https://www.w3.org/2022/wot/td/v1.1",
        { "cov": "http://www.example.org/coap-binding#" }
    ],
    ...
    "properties": {
        "brightness": {
            "description": "The current brightness setting",
            "type": "integer",
            "minimum": -64,
            "maximum": 64,
            "forms": [{
                "op": "readproperty",
                "href": "coap://example.org:61616/api/brightness",
                "cov:methodName": "GET"
            }, {
                "op": "writeproperty",
                "href": "coap://example.org:61616/api/brightness",
                "cov:methodName": "POST"
            }]
        },
        ...
    },
    ...
}
</pre>
</aside>
    
</section>
    
<section>
<h2>Adding Security Schemes</h2>
    
  <p>
  Finally, new security schemes that are not included in <a href="#sec-security-vocabulary-definition"></a>
  can be imported using the <a>TD Context Extension</a> mechanism.
  This example uses a fictional ACE security scheme
  based on [[?ACE]] that is, for this example,
  defined by the namespace at <code>http://www.example.org/ace-security#</code>.
  Note that such additional security schemes must be <a>Subclasses</a> of the
  <a>Class</a> <a href="#securityscheme" class="sec-ref"><code>SecurityScheme</code></a>.
  </p>
    
<pre class="example">
{
    @context: [
        "https://www.w3.org/2022/wot/td/v1.1",
        {
            "cov": "http://www.example.org/coap-binding#",
            "ace": "http://www.example.org/ace-security#"
        }
    ],
    ...
    "securityDefinitions": {
        "ace_sc": {
            "scheme": "ace:ACESecurityScheme",
            ...
            "ace:as": "coaps://as.example.com/token",
            "ace:audience": "coaps://rs.example.com",
            "ace:scopes": ["limited", "special"],
            "ace:cnonce": true
        }
    },
    "security": ["ace_sc"],
    "properties": {
        "status": {
            ...
            "forms": [{
                "op": "readproperty",
                "href": "coaps://rs.example.com/status",
                "contentType": "application/cbor",
                "cov:methodName": "GET",
                "ace:scopes": ["limited"]
            }]
        }
    },
    "actions": {
        "configure": {
            ...
            "forms": [{
                "op": "invokeaction",
                "href": "coaps://rs.example.com/configure",
                "contentType": "application/cbor",
                "cov:methodName": "POST",
                "ace:scopes": ["special"]
            }]
        }
    },
    ...
}
</pre>

  <p>
  Note that all security schemes defined in <a href="#sec-security-vocabulary-definition"></a>
  are already part of the TD context and need not to be included through a <a>TD Context Extension</a>.
  </p>
    
</section>
</section>

<section id="behavior" class="normative">
<h2>Behavioral Assertions</h2>
 <p>
 The following assertions relate to the behavior of components of a 
 WoT system, as opposed to the representation or information model of the TD. 
 However, note that TDs are descriptive, and may in particular be used to
 describe pre-existing network interfaces. In these cases, assertions cannot
 be made that constrain the behavior of such pre-existing interfaces.  Instead,
 the assertions must be interpreted as constraints on the TD to accurately
 represent such interfaces. 
 </p> 
<section id="behavior-security">
<h3>Security Configurations</h3>
 <p>
 To enable secure interoperation, 
 security configurations must accurately reflect the requirements of the <a>Thing</a>:
<ul>
<li>
 <span class="rfc2119-assertion" id="td-security-binding">
 If a <a>Thing</a> requires a specific access mechanism for an interaction, that
 mechanism MUST be specified in the security configuration of the Thing Description.
 </span>  
</li>
<li>
 <span class="rfc2119-assertion" id="td-security-no-extras">
 If a <a>Thing</a> does not require a specific access mechanism for an interaction, that
 mechanism MUST NOT be specified in the security configuration of the Thing Description.
 </span>  
</li>
</ul>
 Some security protocols may ask for authentication 
 information dynamically, including required encoding or encryption schemes. 
 One consequence of the above is that if a protocol asks for
 a form of security credentials or an encoding or encryption scheme 
 not declared in the Thing Description 
 then the Thing Description is to be considered invalid.
 </p>
</section> <!-- end of id="behavior-security"-->
<section id="behavior-data">
<h3>Data Schemas</h3>
<p>The data schemas provided in the TD should accurately represent the 
data payloads returned and accepted by the described <a>Thing</a>
in the interactions specified in the TD.  In general, <a>Consumers</a> should
follow the data schemas strictly, not generating anything not given
in the WoT Thing Description, but should accept additional data from
the <a>Thing</a> not given explicitly in the WoT Thing Description.  In general, <a>Things</a> are <em>described</em> by WoT Thing Descriptions,
but <a>Consumers</a> are <em>constrained</em> to follow WoT Thing Descriptions when
interacting with <a>Things</a>.
<ul>
<li>
<span class="rfc2119-assertion" 
      id="client-data-schema">
A <a>Thing</a> acting as a <a>Consumer</a> when interacting with another target <a>Thing</a>
described in a WoT Thing Description MUST generate data  
organized according to the data schemas given in the corresponding
interactions.
</span>
</li>
<li>
<span class="rfc2119-assertion" 
      id="server-data-schema">
A WoT Thing Description MUST accurately describe the 
data returned and accepted by each interaction.
</span>
</li>
<li>
<span class="rfc2119-assertion" 
      id="server-data-schema-extras">
A <a>Thing</a> MAY return additional data from an interaction
even when such data is 
not described in the data schemas given in its WoT Thing Description.
</span>
This applies to <code>ObjectSchema</code> and <code>ArraySchema</code> (when <code>items</code> is an Array of
<code>DataSchema</code>) where there can be additional properties or items in the data returned. This behaves as if
<code>"additionalProperties":true</code> or <code>"additionalItems":true</code> as defined in [[?JSON-SCHEMA]].
</li>
<li>
<span class="rfc2119-assertion" 
      id="client-data-schema-accept-extras">
A <a>Thing</a> acting as a <a>Consumer</a> when interacting with another <a>Thing</a> MUST accept without
error any additional data  
not described in the data schemas given in the Thing Description of the target <a>Thing</a>.
</span>
This applies to <code>ObjectSchema</code> and <code>ArraySchema</code> (when <code>items</code> is an Array of
<code>DataSchema</code>) where there can be additional properties or items in the data returned. This behaves as if
<code>"additionalProperties":true</code> or <code>"additionalItems":true</code> as defined in [[?JSON-SCHEMA]].
</li>
<li>
<span class="rfc2119-assertion" 
      id="client-data-schema-no-extras">
A <a>Thing</a> acting as a <a>Consumer</a> when interacting with another <a>Thing</a> MUST NOT generate data
not described in the data schemas given in the Thing Description of that <a>Thing</a>.
</span>
</li>
<li>
<span class="rfc2119-assertion" 
      id="client-uri-template">
A <a>Thing</a> acting as a <a>Consumer</a> when interacting with another <a>Thing</a> MUST generate URIs
according to the URI Templates, base URIs, and form href parameters
given in the Thing Description of the target <a>Thing</a>.
</span>
</li>
<li>
<span class="rfc2119-assertion" 
      id="server-uri-template">
URI Templates, base URIs, and href members
in a WoT Thing Description MUST accurately describe the <a>WoT Interface</a> of the <a>Thing</a>.
</span>
</li>
</ul>
</p>
</section> <!-- end of id="behavior-data"-->

<section id="protocol-bindings">
  <h3>Protocol Bindings</h3>

  <p>
    A <a>Protocol Binding</a> is the mapping from an <a>Interaction Affordance</a> to concrete messages of a
    specific protocol such as HTTP [[?RFC7231]], CoAP [[?RFC7252]], or MQTT [[?MQTT]]. <a>Protocol Bindings</a> of
    <a>Interaction Affordances</a> are serialized as <code>forms</code> as defined in <a href="#form-serialization-json"></a>.
  </p>

  <p>
    Every form in a WoT Thing Description must have a submission target,
    given by the <code>href</code> member. The URI scheme [[!RFC3986]] of this
    submission target indicates what <a>Protocol Binding</a> the <a>Thing</a> implements
    [[?WOT-ARCHITECTURE]].
    For instance, if the target starts with <code>http</code> or
    <code>https</code>, a <a>Consumer</a> can then infer the <a>Thing</a> implements the
    <a>Protocol Binding</a> based on HTTP and it should expect HTTP-specific terms in the
    form instance (see next section, <a href="#http-binding-assertions"></a>).
    <ul>
        <li>
            <span class="rfc2119-assertion" id="bindings-requirements-scheme">
                Every form in a WoT Thing Description MUST follow the requirements
                of the <a>Protocol Binding</a> Template indicated by the URI scheme [[!RFC3986]] of its
                <code>href</code> member as indicated by the Binding Templates specification at <a href="https://w3c.github.io/wot-binding-templates/#creating-a-new-protocol-binding">Creating a New Protocol Binding</a>.

            </span>
        </li>
        <li>
            <span class="rfc2119-assertion" id="bindings-server-accept">
                Every form in a WoT Thing Description MUST accurately describe requests
                (including request headers, if present) accepted by the <a>Thing</a> in an
                interaction.
            </span>
        </li>
    </ul>


    <p class="note">
        Optimally, the protocols used are listed as a scheme in the IANA registry [[?IANA-URI-SCHEMES]]). 
        This guarantees a unique <a>Protocol Binding</a> assignment. In case the desired protocol is not yet 
        registered with IANA, it is recommended to follow the scheme value of the protocol specifications, if available.
        In principle, to avoid ambiguity in the identification of the protocol via the scheme, the <a>Protocol Binding</a> document will provide 
        a recommended scheme value to enable unique protocol identification in the context of WoT.
    </p>

  </p>

  <section id="http-binding-assertions">
    <h4>Protocol Binding based on HTTP</h4>

    <p>
        Per default the Thing Description supports the <a>Protocol Binding</a> based on HTTP 
        by including the HTTP RDF vocabulary definitions from <em>HTTP Vocabulary in RDF 1.0</em> [[?HTTP-in-RDF10]].
        This vocabulary can be 
        directly used within TD instances by the usage of the prefix <code>htv</code>, which 
        points to <code>http://www.w3.org/2011/http#</code>. 
        Further details of <a>Protocol Binding</a> based on HTTP can be found in [[?WOT-BINDING-TEMPLATES]].
    </p>
    <p>
        To interact with a <a>Thing</a> that implements the <a>Protocol Binding</a> based on HTTP, a <a>Consumer</a>
        needs to know what HTTP method to use when submitting a form. In the general case,
        a Thing Description can explicitly include a term indicating the method, i.e.,
        <code>htv:methodName</code>. For the
        sake of conciseness, the <a>Protocol Binding</a> based on HTTP defines <a>Default Values</a> for the operation types listed below,
        which also aims at convergence of the methods expected by <a>Things</a> (e.g., GET to read, PUT to write).
        <span class="rfc2119-assertion" id="td-default-http-method">
            When no method is indicated in a form representing an <a>Protocol Binding</a> based on HTTP, 
            a <a>Default Value</a> MUST be assumed as shown in
            the following table.
        </span>
    </p>

    <table class="def">
        <thead>
            <tr>
                <th><a>Vocabulary term</a></th>
                <th>Default value</th>
                <th>Context</th>
            </tr>
        </thead>
        <tbody>
            <tr class="rfc2119-default-assertion" id="td-default-http-method_get">
                <td>
                    <code>htv:methodName</code>
                </td>
                <td><code>GET</code></td>
                <td>
                    <code>Form</code> with operation type <code>readproperty</code>, <code>readallproperties</code>, <code>readmultipleproperties</code>
                </td>
            </tr>
            <tr class="rfc2119-default-assertion" id="td-default-http-method_put">
                <td>
                    <code>htv:methodName</code>
                </td>
                <td><code>PUT</code></td>
                <td>
                    <code>Form</code> with operation type <code>writeproperty</code>, <code>writeallproperties</code>, <code>writemultipleproperties</code>
                </td>
            </tr>
            <tr class="rfc2119-default-assertion" id="td-default-http-method_post">
                <td>
                    <code>htv:methodName</code>
                </td>
                <td><code>POST</code></td>
                <td>
                    <code>Form</code> with operation type <code>invokeaction</code>
                </td>
            </tr>
        </tbody>
    </table>

    <p>
        For example, the <a href="#simple-thing-description-sample">Example 1</a> in <a href="#introduction"></a>
        does not contain operation types and HTTP methods in the forms. 
        The following <a>Default Values</a> should be assumed for the forms in the <a href="#simple-thing-description-sample">Example 1</a>:
    </p>

    <aside class="example with-default">
            <div class="with-default-control">
                <input type="checkbox">
                <span><i>with default values for Protocol Binding based on HTTP</i></span>
            </div>
            <pre>{
    "@context": "https://www.w3.org/2022/wot/td/v1.1",
    "id": "urn:dev:ops:32473-WoTLamp-1234",
    "title": "MyLampThing",
    "securityDefinitions": {
        "basic_sc": {
            "scheme": "basic",
            "in": "header"
        }
    },
    "security": [
        "basic_sc"
    ],
    "properties": {
        "status": {
            "type": "string",
            "readOnly": true,
            "forms": [
                {
                    "op": "readproperty",
                    "href": "https://mylamp.example.com/status"
                }
            ]
        }
    },
    "actions": {
        "toggle": {
            "forms": [
                {
                    "href": "https://mylamp.example.com/toggle"
                }
            ]
        }
    },
    "events": {
        "overheating": {
            "data": {
                "type": "string"
            },
            "forms": [
                {
                    "href": "https://mylamp.example.com/oh",
                    "subprotocol": "longpoll"
                }
            ]
        }
    }
}</pre>
        <pre>{
    "@context": "https://www.w3.org/2022/wot/td/v1.1",
    "id": "urn:dev:ops:32473-WoTLamp-1234",
    "title": "MyLampThing",
    "securityDefinitions": {
        "basic_sc": {
            "scheme": "basic",
            "in": "header"
        }
    },
    "security": [
        "basic_sc"
    ],
    "properties": {
        "status": {
            "type": "string",
            "readOnly": true,
            "forms": [
                {
                    "op": "readproperty",
                    "href": "https://mylamp.example.com/status",
                    "htv:methodName": "GET"
                }
            ]
        }
    },
    "actions": {
        "toggle": {
            "forms": [
                {
                    "op": "invokeaction",
                    "href": "https://mylamp.example.com/toggle",
                    "htv:methodName": "POST"
                }
            ]
        }
    },
    "events": {
        "overheating": {
            "data": {
                "type": "string"
            },
            "forms": [
                {
                    "op": "subscribeevent",
                    "href": "https://mylamp.example.com/oh",
                    "subprotocol": "longpoll"
                }
            ]
        }
    }
}</pre>
    </aside>

    <p>In the case of a <code>forms</code> entry that has multiple <code>op</code> values the usage 
        of the <code>htv:methodName</code> is not permitted. A <a>TD Processor</a> will extend
        the multiple <code>op</code> values to separate <code>forms</code> entries and associates 
        a single operation with the default assumption. The address information (e.g. <code>href</code>) and 
        other metadata are taken over in the extended version.
    </p>
    
        <aside class="example with-default">
            <div class="with-default-control">
                <input type="checkbox">
                <span><i>extended <code>forms</code> in case of multiple values in <code>op</code></i></span>
            </div>
            <pre>{
    "@context": "https://www.w3.org/2022/wot/td/v1.1",
    "id": "urn:dev:ops:32473-WoTLamp-1234",
    "title": "MyLampThing",
    "securityDefinitions": {
        "basic_sc": {
            "scheme": "basic",
            "in": "header"
        }
    },
    "security": [
        "basic_sc"
    ],
    "properties": {
        "status": {
            "type": "string",
            "forms": [
                {
                    "op" : ["readproperty", "writeproperty"],
                    "href": "https://mylamp.example.com/status"
                }
            ]
        }
    }
}</pre>
        <pre>{
    "@context": "https://www.w3.org/2022/wot/td/v1.1",
    "id": "urn:dev:ops:32473-WoTLamp-1234",
    "title": "MyLampThing",
    "securityDefinitions": {
        "basic_sc": {
            "scheme": "basic",
            "in": "header"
        }
    },
    "security": [
        "basic_sc"
    ],
    "properties": {
        "status": {
            "type": "string",
            "forms": [
                {
                    "op": "readproperty",
                    "href": "https://mylamp.example.com/status",
                    "htv:methodName": "GET"
                },
                {
                    "op": "writeproperty",
                    "href": "https://mylamp.example.com/status",
                    "htv:methodName": "PUT"
                }
            ]
        }
    }
}</pre>
    </aside>

  </section>

  <section>
      <h4>Other Protocol Bindings</h4>

      <p>
          The number of <a>Protocol Bindings</a> a <a>Thing</a> can implement
          is not restricted. Other <a>Protocol Bindings</a> (e.g., for CoAP, MQTT, or OPC UA)
          are intended to be standardized in separate documents such as a protocol <a>Vocabulary</a> similar to <em>HTTP Vocabulary in RDF 1.0</em> [[?HTTP-in-RDF10]]
          or specifications including <a>Default Value</a> definitions. Such protocols can be simply integrated into the TD by the
          usage of the <a>TD Context Extension</a> mechanism (see <a href="#sec-context-extensions"></a>).
      </p>
      <p>
          Please refer to [[?WOT-BINDING-TEMPLATES]] for information on how to describe IoT platforms and ecosystems.
      </p>
  </section>
</section>

</section> <!-- end of id="behavior"-->

<section id="sec-security-consideration" class="informative">
  <h4>Security and Privacy Considerations</h4>
  
  <p>
  In general the security measures taken to protect a WoT 
  system will depend on the threats and attackers that system
  may face and the value of the assets needs to protect.
  In addition privacy risks will depend on the association of 
  Things with identifiable people and both the direct information and 
  the inferred information available from such an association.
  A detailed discussion of security and privacy considerations for the Web of Things,
  including a threat model that can be adapted to various circumstances, is
  presented in the informative document [[WOT-SECURITY-GUIDELINES]].  
  This section discusses only security and privacy risks
  and possible mitigations directly relevant to the WoT Thing Description.
  </p>
  <p>A WoT Thing Description can describe both secure and 
  insecure network interfaces.  When a Thing Description is 
  retro-fitted to an existing network interface, no change in the 
  security status of the network interface is to be expected.
  </p>
  <p>The use of a WoT Thing Description introduces  
  the security and privacy risks given in the following sections.
  After each risk, we suggest some possible mitigations.
  </p>
  <section id="sec-security-consideration-context">
  <h5>Context Fetching Privacy Risk</h5>
      <p>Fetching the vocabulary files given in the <code>@context</code>
          member of any JSON-LD [[?json-ld11]] document can be a privacy risk.
          In the case of the WoT, an attacker can observe the network
          traffic produced by such fetches and can use the metadata
          of the fetch, such as the destination IP address,
          to infer information about the device especially if domain-specific
          vocabularies are used.  This is a risk even if the connection
          is encrypted, and is related to DNS privacy leaks.
      </p>
      <dl><dt>Mitigation:</dt><dd>
          Avoid actual fetching of vocabulary files.
          Vocabulary files should be cached whenever possible.
          Ideally they would be made immutable, built into the interpreting device,
          and not fetched at all,
          with the URI in the <code>@context</code> member serving only as 
          an identifier of the (known) vocabulary. 
          This requires the use of strict version control, as updates
          should use a new URI to ensure that existing URIs can refer to 
          immutable data.
          Use well-known standard vocabulary files whenever possible to
          improve the chances that the context file will be available locally
          to systems interpreting the metadata in a Thing Description.
      </dd></dl>
   </section>
   <section id="sec-security-consideration-id">
   <h5>Immutable Identifiers Privacy Risk</h5>
      <p>A Thing Description containing an identifier (<code>id</code>) may
         describe a Thing that is associated with an identifiable
         person.  Such identifiers pose various risks including tracking.
         However, if the identifier is also immutable, then the 
         tracking risk is amplified, since a device
         may be sold or given to another person and the known ID used to 
         track that person.
      </p>
      <dl><dt>Mitigation:</dt><dd>
          All identifiers should be mutable,
          and there should be a mechanism to update the <code>id</code>
          of a <a>Thing</a>.
          Specifically,
          the <code>id</code> of a <a>Thing</a> should not be fixed in hardware.
          This does, however, conflict with the Linked Data ideal that
          identifiers are fixed URIs.  In many circumstances it
          will be acceptable to only allow updates to identifiers if
          a <a>Thing</a> is reinitialized.  In this case as a software entity the
          old <a>Thing</a> ceases to exist and a new <a>Thing</a> is created.
          This can be sufficient to break a tracking chain when, for
          example, a device is sold to a new owner.
          Alternatively, if more frequent changes are desired during 
          the operational phase of a device,
          a mechanism can be put into place to notify only authorized users
          of the change in identifier when a change is made.
          Note however that some classes of devices, e.g., medical devices,
          may require immutable IDs by law in some jurisdictions.
          In this case extra attention should be paid to secure 
          access to files, such as Thing Descriptions, containing such
          immutable identifiers.  It may also be desirable to not share
          the "true" immutable identifier in such a case in the TD whenever possible.
          </dd></dl>
      </p>
   </section>
   <section id="sec-security-consideration-fingerprint">
   <h5>Fingerprinting Privacy Risk</h5>
      <p>As noted above, the <code>id</code> member in a TD can pose a privacy risk.  
      However, even if the <code>id</code> is updated as described to mitigate its
      tracking risk, it may still be possible to associate
      a TD with a particular physical device, and from there to an identifiable person, 
      through fingerprinting.
      </p>
      <p>Even if a specific device instance cannot be identified through fingerprinting,
      it may be possible to infer the type of a device from the information in the TD, such
      as the set of interactions, and use this type to infer private information about an
      identifiable person, such as a medical condition.
      </p>
      <dl><dt>Mitigation:</dt><dd>
          Only authorized users should be provided access
          to the Thing Description for a <a>Thing</a>, and only the amount of
          information needed for the level of authorization and the use case should be provided.
          If the TD is only distributed to authorized users 
          through secure and confidential channels, for
          example through a directory service that requires authentication,
          then external unauthorized parties will not have access to the TD to fingerprint it.
          To further mitigate this risk, information not necessary for a particular
          use case of a TD should be omitted whenever possible.  For example,
          for an ad-hoc connection to a device where the Consumer does 
          not store state about the Thing, the <code>id</code> can be omitted.
          If the Consumer does not need certain interactions for its use case, they can be omitted.
          If the Consumer is not authorized to use certain interactions, they can likewise be omitted.
          If the Consumer does not have any capability to display human-readable information
          such as titles or descriptions, they can be omitted or replaced with zero-length strings.
      </dd></dl>
   </section>
   <section id="sec-security-consideration-global-id-risk">
   <h5>Globally Unique Identifier Privacy Risk</h5>
      <p>Globally unique identifiers pose a privacy risk if a centralized authority is needed to
      create and distribute them, since then a third party has knowledge of the identifiers.
      </p>
      <dl><dt>Mitigation:</dt><dd>
          The <code>id</code> field in TDs are intentionally not required to be globally unique.
          There are several cryptographic mechanisms available to generate suitable IDs in a 
          distributed fashion that do
          not require a central registry.  These mechanisms typically have a very low probability
          of generating duplicate identifiers, and this needs to be taken into account in the system
          design; for example, by detecting duplicates and regenerating IDs when necessary.
          The scope of IDs also does not need to be global: it is acceptable to use identifiers
          that only distinguish Things in a certain context, such as within a home or factory.
      </dd></dl>
   </section>
   <section id="sec-security-consideration-TD-tampering">
   <h5>TD Interception and Tampering Security Risk</h5>
      <p>Intercepting and tampering with TDs can be used to launch man-in-the-middle attacks,
      for example by rewriting URLs in TDs to redirect accesses to a malicious 
      intermediary that can capture or manipulate data.
      </p>
      <dl><dt>Mitigation:</dt><dd>
          Obtain Thing Descriptions only through
          mutually authenticated channels.
          This ensures that the <a>Consumer</a> and the server are both sure of the
          identity of the other party to the communication.
          This is also necessary in order to deliver TDs only to authorized users.
      </dd></dl>
   </section>
   <section id="sec-security-consideration-context-tampering">
   <h5>Context Interception and Tampering Security Risk</h5>
      <p>Intercepting and tampering with context files can be used to facilitate attacks
      by modifying the interpretation of vocabulary. 
      </p>
      <dl><dt>Mitigation:</dt><dd>
	      Ideally context files would only be obtained through authenticated channels
	      but it is notable (and unfortunate) that many contexts are indicated using
	      HTTP URLs, which are vulnerable to interception and modification if 
	      dereferenced.  However, if context files are immutable and cached, 
	      and dereferencing is avoided whenever possible, then this risk can be reduced.
      </dd></dl>
   </section>
   <section id="sec-security-consideration-inferencing">
   <h5>Inferencing of Personally Identifiable Information Privacy Risk</h5>
      <p>In many locales, in order to protect the privacy of users,
      there are legal requirements for the handling of
      personally identifiable information,
      that is,
      information that can be associated with a particular person.
      Such information can of course be generated by IoT devices directly.
      However,
      the existence and metadata of IoT devices
      (the kind of data stored in a Thing Description)
      can also contain or be used to infer personally identifiable information.
      This information can be as simple as the fact that a certain person owns a certain
      type of device,
      which can lead to additional inferences about that person.
      </p>
      <dl><dt>Mitigation:</dt><dd>
          Treat a Thing Description associated with a 
	      personal device as if it contained
	      personally identifiable information.
          As an example application of this principle,
          consider how to obtain user consent.  
          Consent for usage of personally identifiable data
          generated by a <a>Thing</a> is often obtained when a <a>Thing</a> is paired with system
          consuming the data,
          which is frequently also when the Thing Description
          is registered with a local directory or the system consuming the 
          Thing Description in order to access the device.
          In this case, consent for using data from a <a>Thing</a> can be combined with
          consent for accessing the Thing Description of the <a>Thing</a>.
          As a second example, if we consider a TD to contain personally
          identifiable information, then it should not be retained indefinitely
          or used for purposes other than those for which consent was given.
      </dd></dl>
  </section>

  </section>

  <section id="thing-model" class="normative">
  <h1>Thing Model</h1>
      
  <p class="note">
    The following section has its origin in [[wot-thing-description]], Annex C. Here Thing Description 
    Template is renamed to <a>Thing Model</a>, but keeps the same intention.
    For this version of the specification, <a>Thing Model</a> and its model features (e.g., extensions, referencing, obligations, placeholder) are formal 
    introduced. For Thing Model, an own content type is under discussion. Please note this section is in work in progress.
  </p>

  <section id="thing-model-concept" class="normative">
    <h2>Basic Concept</h2>

    <p>
    The figure below illustrates the relation of the <a>Thing Model</a> and <a>Thing Description</a>. A <a>Thing Model</a> mainly describes 
    interaction affordances such as the <a>Properties</a>, <a>Actions</a>, and <a>Events</a> and common metadata. This kind of template should 
    be valid and followed for all instantiated <a>Thing Descriptions</a> that are relied on this <a>Thing Model</a>. This paradigm can be compared 
    with abstract class or interface definition (~Thing Model) in object-oriented programming to create objects (~Thing Descriptions).
    </p>

  <figure id="thing-model-td">
    <img src="visualization/thing_model_td.png" alt="Thing Model and its relation to the Thing Description">
        <figcaption>
            Thing Model and its relation to the Thing Description.
        </figcaption>
    </figure>

    <p>
    The <a>Thing Model</a> is a logical description of the interface and possible interaction with <a>Thing</a>'s
    <a>Properties</a>, <a>Actions</a>, and <a>Events</a>, however it does not contain <a>Thing</a> instance-specific
    information, such as concrete protocol usage (e.g., IP address), or even a serial number and GPS location.
    However, Thing Models allows to include, e.g., security schemes if they apply to the entire class of instances the 
    model describes. They might have URLs (e.g., like token servers) that might need to be omitted or parameterized 
    (with templates) although in a lot of cases these might also be given. 
    </p>


    <p>
        <a>Thing Model</a> can be serialized in the same JSON-based format as a Thing Description which also allows JSON-LD processing. 
        Note that a <a>Thing Model</a> cannot be validated in the same way as <a>Thing Description</a> instances due to some missing 
        mandatory terms.
    </p>
  </section>
    <section id="thing-model-declaration" class="normative">
        <h2>Thing Model Declaration</h2>

    <p>
    A <a>Thing Model</a> is recognized by the top level <em>@type</em>.
    <span class="rfc2119-assertion" id="tm-identification">
        <a>Thing Model</a> definitions MUST use the keyword <em>@type</em> at top level 
        and a value of type string or array that equals or respectively contains <code>tm:ThingModel</code>.
    </span>
    The prefix <code>tm</code> is defined within <a>Thing Descriptions</a>' context and points to the <a>Thing Model</a> namespace as 
    defined in <a href="#namespaces"></a>. It is intended that vocabulary from the <code>tm</code> context only be used in <a>Thing Model</a>
    definitions and are removed or replaced when <a>Thing Descriptions</a> are generated (also see <a href="#thing-model-td-generation"></a>).
    </p>
    <p>
        <span class="rfc2119-assertion" id="tm-protocol-security-restriction">
    A <a>Thing Model</a> MAY NOT contain instance specific <a>Protocol Binding</a> and security information such as endpoint addresses.
    </span>

    Consequently, <a>Thing Model</a> definitions will also be valid if there are no JSON members like <em>forms</em>, <em>base</em>, 
    <em>securityDefinitions</em>, and <em>security</em>. <a>Thing Models</a> are also valid even if these JSON members are used (e.g., as template), however,
    the nested mandatory members like <em>href</em> are omitted.
    </p>

    <p>    
    <a href="#td-model-example-lamp"></a> shows a valid sample lamp <a>Thing Model</a> without any protocol and security information.
    </p>
    

    </section>

    <section id="thing-model-tools" class="normative">
        <h2>Modeling Tools</h2>

        <p>In the context of <a>Thing Model</a> definitions specific features are introduced that can be used for <a>Thing</a> modelling.</p>

    <section id="thing-model-versioning" class="normative">
        <h3>Versioning</h3>
    
    <p>
        Over time, <a>Thing Model</a> definitions may change and must be made identifiable through versioning.  
        In that case the string-based term <code>model</code> can be used within the <code>version</code> container to 
        provide a version pattern like [[SEMVER]]. The following snippet shows the usage of <code>model</code> in a
        Thing Model instance. 
    </p>

    <pre class="example" title="Thing Model versioning">
        {
            ...
            "@type" : "tm:ThingModel",
            "title": "Lamp Thing Model",
            "description": "Lamp Thing Description Model",
            "version" : {"model" : "1.0.0" },
            ...
        }
        </pre>

        <p>
         Due to the definition of <a>Thing Model</a> the term <code>instance</code> can be omitted within the <code>version</code> container. 
        </p>

        <p>

            When <a>Thing Models</a> are updated and have a new version, this may affect 
            other <a>Thing Models</a> that use the extension and import features (see Section <a href="#thing-model-extension-import"></a>). 
            In some cases it is also useful to reflect a new version in the file name and/or in a corresponding URL to identify the version.

          </p>

    </section>
    <section id="thing-model-extension-import" class="normative">
        <h3>Extension and Import</h3>

    <p>
        A <a>Thing Model</a> can extend an existing <a>Thing Model</a> by using the <code>tm:extends</code> mechanism announced in the <code>links</code> definition: 
     <span class="rfc2119-assertion" id="tm-extend">
        A <a>Thing Model</a> MUST use at least one <code>links</code> entry with <code>"rel":"tm:extends"</code> 
        that targets a <a>Thing Model</a> that is be extended.
    </span>
    The <a>Thing Model</a> will inherit all definitions from the extended <a>Thing Model</a>. There is the opportunity 

    to extend the existing definition with further metadata by providing further JSON name-value pairs from the existing 
    TD information model (<a href="#sec-vocabulary-definition"></a>) or using the context extension concept 
    (<a href="#sec-context-extensions"></a>). A <a>Thing Model</a> can also overwrite existing definitions such as <code>title(s)</code> 
    and <code>maximum</code> etc.. For this there exist two limitations: 

    <span class="rfc2119-assertion" id="tm-overwrite-interaction">
        A <a>Thing Model</a> SHOULD NOT overwrite the JSON names defined within the  
        <code>properties</code>, <code>actions</code>, and/or <code>events</code> <a>Map</a> of the extended <a>Thing Model</a>.
    </span>
    <span class="rfc2119-assertion" id="tm-overwrite-types">
        Definitions SHOULD NOT be overwritten in such a way that possible instance values are no longer valid compared to the origin extended definitions.
    </span>
    Those assertions preserve the semantics throughout of the extended <a>Thing Model</a>. 
    E.g., it is not allowed that a <code>"minimum":2 </code>  from a extended <a>Thing Model</a> can be overwritten with <code>"minimum":0</code>. 
    Meanwhile, overwriting with <code>"minimum":5 </code> would work since all instances values will always fulfill the restrictions of the extended <a>Thing Model</a> 
    (also see Figure <a href="#thing-model-overwriting"></a> for further explanation).

    </p>

    <p>
       Lets assume we have a basic model description as provided in the following example:
    </p>

    <pre class="example" title="Basic On/Off Thing Model Definition" id="td-model-example-basic-on-off">
        {
            "@context": ["https://www.w3.org/2022/wot/td/v1.1"], 
            "@type" : "tm:ThingModel",
            "title": "Basic On/Off Thing Model",
            "properties": {
                "onOff": {
                    "type": "boolean"
                }
            }
        }
    </pre>

    <p>Now it is designed a new device class model called 'Smart Lamp Control' that should be used as template 
        for creating TD instances. This model will reuse the existing definition of the 'Basic On/Off Thing Model'
        and extend it with a <code>dim</code> property:
    </p>

    <pre class="example" title="Smart Lamp Control Thing Model Definition" id="td-model-example-smart-lamp-control">
        {
            "@context": ["https://www.w3.org/2022/wot/td/v1.1"], 
            "@type" : "tm:ThingModel",
            "title": "Smart Lamp Control with Dimming",
            "links" : [{
                "rel": "tm:extends",
                "href": "http://example.com/BasicOnOffTM",
                "type": "application/td+json"
             }],
            "properties" : {
                "dim" : {
                    "title": "Dimming level"
                    "type": "integer",
                    "minimum": 0,
                    "maximum": 100
                }
           }
        }
    </pre>
    <p>
    Please note that the <code>title</code> is overwritten and will be used when TD instances are created (also see in the next subsection <a href="#thing-model-td-generation"></a>).
    </p>

    <p>
    The <code>tm:extends</code> feature only permits inheriting all definitions of one <a>Thing Model</a>. In many use cases, however,
     it is desired only to import pieces of definitions of one or more existing <a>Thing Models</a>. 
     For doing this, the <code>tm:ref</code> term is introduced that provides the location of an existing (sub-)definition that should be reused.
     <span class="rfc2119-assertion" id="tm-tmRef1">
     The <code>tm:ref</code> value MUST follow the pattern
     <ul>
        <li>file location as URI [[RFC3986]](Section 4.1)), followed by</li>
        <li><code>#</code> character, and followed by</li>
        <li>JSON Pointer [[RFC6901]] definition.</li>
     </ul>
    </span>
    <span class="rfc2119-assertion" id="tm-tmRef2">
        Every time <code>tm:ref</code> is used, the referenced pre-definition and its dependencies 
        (e.g., by context extension) MUST be assumed at the new defined definition.
    </span>
    </p>

    <p>
        The following example shows a new TM definition that imports the existing definition of the property 
        <code>onOff</code> from <a href="#td-model-example-basic-on-off"></a> into the new property definition 
        <code>switch</code>.
    </p>
    <pre class="example" title="Smart Lamp Control imports existing definition" id="td-model-example-tmRef">
        {
            "@context": ["https://www.w3.org/2022/wot/td/v1.1"], 
            "@type" : "tm:ThingModel",
            "title": "Smart Lamp Control",
            "properties" : {
                "switch" : {
                    "tm:ref" :"http://example.com/BasicOnOffTM.tm.jsonld#/properties/onOff"
                }
           }
        }
    </pre>



    <p>
      At the place the "tm:ref" is defined, additional name-value pairs can be added. 
      It is also permitted to override name-value pairs from the referenced definition.  
      <span class="rfc2119-assertion" id="tm-tmRef-overwrite">
        If the intention is to override an existing JSON name-value pair definition from <code>tm:ref</code>, the same JSON name MUST be used
        at the same level of the <code>tm:ref</code> declaration that provides a new value. This process MUST follow the 
        JSON Merge Patch algorithm as defined in [RFC7396] where the content of the referenced definition is patched with the new provided JSON name-value 
        pairs.
       </span>
    </p>
    <p>
       It is noted that the values can also be based on a JSON <code>object</code> or <code>array</code>, or simply be a <code>null</code> value. <code>null</code> would result 
       to a removal of existing JSON name-value pair in the target.
    </p>
    <p>
       <span class="rfc2119-assertion" id="tm-tmRef-overwrite-semantic-meaning">
        Similar to <code>tm:extends</code> and to keep the semantic meaning, definitions SHOULD NOT be overwritten in such a way that possible 
        instance values are no longer valid compared to the origin referenced definition.
       </span>
    </p>

    <p>
        The following example shows a new TM definition that overwrites (<code>maximum</code>), enhances (<code>unit</code>), and removes (<code>title</code>) existing definitions from
         <a href="#td-model-example-smart-lamp-control"></a>. 
    </p>

    <pre class="example" title="Smart Lamp Control extend and overwrite existing definitions" id="td-model-example-tmRef2">
        {
            "@context": ["https://www.w3.org/2022/wot/td/v1.1"], 
            "@type" : "tm:ThingModel",
            "title": "Smart Lamp Control",
            "properties" : {
                "dimming" : {
                    "tm:ref" :"http://example.com/SmartLampControlwithDimming.tm.jsonld#/properties/dim",
                    "title": null,
                    "maximum": 80,
                    "unit" : "%"
                }
           }
        }
    </pre>

    <p>
        Based on the JSON Merge Patch algorithm the <code>{"title": null,"maximum": 80,"unit" : "%"}</code> would act as a patch for the referenced origin content <code>{"title": "Dimming level",  "type": "integer", "minimum": 0, "maximum": 100}</code>.
    </p>
 
    <p>
        The <code>tm:extends</code> and the import mechanism based on <code>tm:ref</code> can also be used at the same time in 
        a TM definition. The following example extends the TM from <a href="#td-model-example-basic-on-off"></a> and imports
        the <code>status</code> and <code>dim</code> definitions from <a href="#td-model-example-lamp"></a> and 
        <a href="#td-model-example-smart-lamp-control"></a> respectively.
    </p>

    <pre class="example" title="Smart Lamp Control Thing Model with extend and import mechanism" id="td-model-example-smart-lamp-control-extend-import">
        {
            "@context": ["https://www.w3.org/2022/wot/td/v1.1"], 
            "@type" : "tm:ThingModel",
            "title": "Smart Lamp Control",
            "links" : [{
                "rel": "extends",
                "href": "http://example.com/BasicOnOffTM",
                "type": "application/td+json"
             }],
            "properties" : {
                "status" : {
                    "tm:ref" :"http://example.com/LampTM.tm.jsonld#/properties/status"
                },
                "dimming" : {
                    "tm:ref" :"http://example.com/LampWithDimmingTM.tm.jsonld#/properties/dim"
                }
           }
        }
    </pre>

    <p>


    The following figure summarizes the allowable override behaviour of the extension and imports TM functions presented in this section.
    Three <a>Thing Models</a> use the <code>tm:ref</code> or <code>tm:extends</code> feature to reuse TM definitions of the Smart Lamp Control <a>Thing Model</a>.
    The first <a>Thing Model</a> imports and overwrites the <code>maximum</code> value to <code>120</code> within the <code>dimmer</code> property. However, this results 
    in possible instance values (at runtime) that may not be in the range of the original <code>dim</code> definition between <code>0</code> and <code>100</code> of the dim definition of the Smart Lamp Control 
    Thing Model. Thus, such a <a>Thing Model</a> definition is not allowed.  
     
     The second model overwrites the property <code>type</code> value by <code>number</code>. Again, this will potentially result in numeric <code>dim</code> values that are not
     accepted by the definition of the origin <code>dim</code> type definition (integer) of the Smart Lamp Control <a>Thing Model</a>.  

     The last model is defined in a correct way. The new ranges of <code>dim</code> produce potential instance values that are also fulfilled by the 
     original <code>dim</code> definition. 
    </p>

    <figure id="thing-model-overwriting">
        <img src="visualization/tm_overwriting.png" alt="Overwriting behavior">
            <figcaption>
                Overwriting behavior of <a>Thing Models</a>.
            </figcaption>
        </figure>

</section>

<section id="thing-model-composition" class="normative">
    <h3>Composition</h3>
<p>
In some applications, it is beneficial to reuse existing <a>Thing Model</a> definitions and compose them into a new IoT system. 
An example would be that a new Smart Ventilator is designed to consist of two sub/child <a>Thing Model</a> definitions such as 
a Ventilation <a>Thing Model</a> that provides <code>on/off</code> and <code>adjustRpm</code> capabilities, and an LED <a>Thing Model</a> that 
provides <code>dimmable</code> and <code>RGB</code> capabilities. 
</p>

<aside class="example ds-selector-tabs" ><div class="marker">
    <span class="example-title">Top level/parent Smart Ventilator Thing Model </span>
     </div>
       <div class="selectors">
         <button class="selected exampleTab1 SmartVentilator" onclick="openTab('exampleTab1', 'SmartVentilator')">Smart Ventilator TM</button>
         <button class="exampleTab1 Ventilation"         onclick="openTab('exampleTab1', 'Ventilation')">Ventilation TM</button>
         <button class="exampleTab1 LED"    onclick="openTab('exampleTab1', 'LED')">LED TM</button>
       </div>
       <pre class="SmartVentilator exampleTab1 selected ">
        {
            "@context": "https://www.w3.org/2022/wot/td/v1.1",
            "@type": "tm:ThingModel",
            "title": "Smart Ventilator Thing Model",
            "version" : { "model" : "1.0.0" },
            "links": [
              {
                "rel": "tm:submodel",
                "href": "./Ventilation.tm.jsonld",
                "type": "application/tm+json",
                "instanceName": "ventilation"
              },
              {
                "rel": "tm:submodel",
                "href": "./LED.tm.jsonld",
                "type": "application/tm+json",
                "instanceName": "led"
              }
            ],
            "properties" : {
                "status" : {"type": "string", "enum": ["On", "Off", "Error"]}
            }
          }
       </pre>
       <pre class="Ventilation exampleTab1">
        {
            "@context": "https://www.w3.org/2022/wot/td/v1.1",
            "@type": "tm:ThingModel",
            "title": "Ventilator Thing Model",
            "version": {
                "model": "1.0.0"
            },
            "properties": {
                "switch": {
                    "type": "boolean",
                    "description": "True=On; False=Off"
                },
                "adjustRpm": {
                    "type": "number",
                    "minimum": 200,
                    "maximum": 1200
                }
            }
        }
       </pre>
       <pre class="LED exampleTab1">
        {
            "@context": "https://www.w3.org/2022/wot/td/v1.1",
            "@type": "tm:ThingModel",
            "title": "LED Thing Model",
            "version": {
                "model": "1.0.0"
            },
            "properties": {
                "R": {
                    "type": "number",
                    "description": "Red color"
                },
                "G": {
                    "type": "number",
                    "description": "Green color"
                },
                "B": {
                    "type": "number",
                    "description": "Blue color"
                }
            },
            "actions": {
                "fadeIn": {
                    "title": "fadeIn",
                    "input": {
                        "type": "number",
                        "description": "fadeIn in ms"
                    }
                },
                "fadeOut": {
                    "title": "fadeIn",
                    "input": {
                        "type": "number",
                        "description": "fadeOut in ms"
                    }
                }
            }
        }
       </pre>
     </aside>


<p>
    Such composition can be introduced by the usage of the <code>links</code> container. 
    <span class="rfc2119-assertion" id="tm-compose-submodel">
        If it is desired to provide information that a <a>Thing Model</a> consists of one or more (sub-)<a>Thing Models</a>, the <code>links</code> entries MUST use the <code>"rel":"tm:submodel"</code> 
        that targets to the (sub-) <a>Thing Models</a>.
    </span>
    <span class="rfc2119-assertion" id="tm-compose-instanceName">
        Optionally an <code>instanceName</code> can be provided to associate an individual name to the composed (sub-) <a>Thing Model</a>.
    </span> 
    This is useful when multiple similar <a>Thing Model</a> definitions are composed and needs to be distinguished. 
</p>


<p>
    Different strategies can be followed to generate <a>Thing Descriptions</a> from composed <a>Thing Model</a> definitions. The default recommendation is to generate from each
     parent and sub/child <a>Thing Model</a> a corresponding <a>Thing Descriptions</a> (also see <a href="#thing-model-td-generation"></a>). 
   The composition relation can be reflected by the <code>collection</code> and <code>item</code> relation types in the links container of the 
   <a>Thing Descriptions</a>. An example based on Smart Ventilation is given here:   
</p>


<aside class="example ds-selector-tabs" ><div class="marker">
    <span class="example-title">Thing Descriptions of the Smart Ventilator</span>
     </div>
       <div class="selectors">
         <button class="selected exampleTab1 SmartVentilator" onclick="openTab('exampleTab1', 'SmartVentilator')">Top level Smart Ventilator TD</button>
         <button class="exampleTab1 Ventilation"         onclick="openTab('exampleTab1', 'Ventilation')">Ventilation TD</button>
         <button class="exampleTab1 LED"    onclick="openTab('exampleTab1', 'LED')">LED TD</button>
       </div>
       <pre class="SmartVentilator exampleTab1 selected ">
        {
            "@context": "https://www.w3.org/2022/wot/td/v1.1",
            "title": "Smart Ventilator",
            "securityDefinitions": {
                "basic_sc": {
                    "scheme": "basic",
                    "in": "header"
                }
            },
            "security": "basic_sc",
            "links": [
                {
                    "rel": "item",
                    "href": "./Ventilation.td.jsonld",
                    "type": "application/td+json"
                },
                {
                    "rel": "item",
                    "href": "./LED.td.jsonld",
                    "type": "application/td+json"
                },
                {
                    "rel": "type",
                    "href": "./SmartVentilator.tm.jsonld",
                    "type": "application/tm+json"
                }
            ],
            "properties": {
                "status": {
                    "type": "string",
                    "enum": [
                        "On",
                        "Off",
                        "Error"
                    ],
                    "forms": [
                        {
                            "href": "http://127.0.13.232:4563/status"
                        }
                    ]
                }
            }
        }
       </pre>
       <pre class="Ventilation exampleTab1">
        {
            "@context": "https://www.w3.org/2022/wot/td/v1.1",
            "title": "Ventilator",
            "securityDefinitions": {
                "basic_sc": {
                    "scheme": "basic",
                    "in": "header"
                }
            },
            "security": "basic_sc",
            "links": [
                {
                    "rel": "collection",
                    "href": "./SmartVentilation.td.jsonld",
                    "type": "application/td+json"
                },
                {
                    "rel": "type",
                    "href": "./Ventilation.tm.jsonld",
                    "type": "application/tm+json"
                }
            ],
            "security": "basic_sc",
            "properties": {
                "switch": {
                    "type": "boolean",
                    "description": "True=On; False=Off",
                    "forms": [
                        {
                            "href": "http://127.0.13.212:4563/switch"
                        }
                    ]
                },
                "adjustRpm": {
                    "type": "number",
                    "minimum": 200,
                    "maximum": 1200,
                    "forms": [
                        {
                            "href": "http://127.0.13.212:4563/adjustRpm"
                        }
                    ]
                }
            }
        }
       </pre>
       <pre class="LED exampleTab1">
        {
            "@context": "https://www.w3.org/2022/wot/td/v1.1",
            "title": "LED Thing Model",
            "securityDefinitions": {
                "basic_sc": {
                    "scheme": "basic",
                    "in": "header"
                }
            },
            "security": "basic_sc",
            "links": [
                {
                    "rel": "collection",
                    "href": "./SmartVentilation.td.jsonld",
                    "type": "application/td+json"
                },
                {
                    "rel": "type",
                    "href": "./LED.tm.jsonld",
                    "type": "application/tm+json"
                }
            ],
            "properties": {
                "R": {
                    "type": "number",
                    "description": "Red color",
                    "forms": [
                        {
                            "href": "http://127.0.13.211:4563/R"
                        }
                    ]
                },
                "G": {
                    "type": "number",
                    "description": "Green color",
                    "forms": [
                        {
                            "href": "http://127.0.13.211:4563/G"
                        }
                    ]
                },
                "B": {
                    "type": "number",
                    "description": "Blue color",
                    "forms": [
                        {
                            "href": "http://127.0.13.211:4563/B"
                        }
                    ]
                }
            },
            "actions": {
                "fadeIn": {
                    "title": "fadeIn",
                    "input": {
                        "type": "number",
                        "description": "fadeIn in ms"
                    },
                    "forms": [
                        {
                            "href": "http://127.0.13.211:4563/fadeIn"
                        }
                    ]
                },
                "fadeOut": {
                    "title": "fadeOut",
                    "input": {
                        "type": "number",
                        "description": "fadeOut in ms"
                    },
                    "forms": [
                        {
                            "href": "http://127.0.13.211:4563/fadeOut"
                        }
                    ]
                }
            }
        }
       </pre>
     </aside>



<p>
    A single TD can also be generated which contains the interaction definitions of the top level/parent
    <a>Thing Model</a> and all interaction definitions of all sub/child <a>Thing Models</a>. 
    <span class="rfc2119-assertion" id="tm-compose-name-collision">
       To avoid name collisions of the sub/child interaction names it is recommended to rename the JSON name to the <code>instanceName</code> followed with <code>'_'</code> and the interaction name of the sub/child <a>Thing Model</a>.
    </span> 
    The following example shows a generated (self-contained) <a>Thing Description</a> of the Smart Ventilator Thing Model.
</p>

<pre class="example" title="Self-contained TD of the Smart Ventilator TM">
    {
        "@context": "https://www.w3.org/2022/wot/td/v1.1",
        "title": "Smart Ventilator",
        "securityDefinitions": {
            "basic_sc": {
                "scheme": "basic",
                "in": "header"
            }
        },
        "security": "basic_sc",
        "links": [
            {
                "rel": "type",
                "href": "./SmartVentilator.tm.jsonld",
                "type": "application/tm+json"
            }
        ],
        "properties": {
            "status": {
                "type": "string",
                "enum": [
                    "On",
                    "Off",
                    "Error"
                ],
                "forms": [
                    {
                        "href": "http://127.0.13.232:4563/status"
                    }
                ]
            },
            "ventilation_switch": {
                "type": "boolean",
                "description": "True=On; False=Off",
                "forms": [
                    {
                        "href": "http://127.0.13.212:4563/switch"
                    }
                ]
            },
            "ventilation_adjustRpm": {
                "type": "number",
                "minimum": 200,
                "maximum": 1200,
                "forms": [
                    {
                        "href": "http://127.0.13.212:4563/adjustRpm"
                    }
                ]
            },
            "led_R": {
                "type": "number",
                "description": "Red color",
                "forms": [
                    {
                        "href": "http://127.0.13.211:4563/R"
                    }
                ]
            },
            "led_G": {
                "type": "number",
                "description": "Green color",
                "forms": [
                    {
                        "href": "http://127.0.13.211:4563/G"
                    }
                ]
            },
            "led_B": {
                "type": "number",
                "description": "Blue color",
                "forms": [
                    {
                        "href": "http://127.0.13.211:4563/B"
                    }
                ]
            }
        },
        "actions": {
            "led_fadeIn": {
                "title": "fadeIn",
                "input": {
                    "type": "number",
                    "description": "fadeIn in ms"
                },
                "forms": [
                    {
                        "href": "http://127.0.13.211:4563/fadeIn"
                    }
                ]
            },
            "led_fadeOut": {
                "title": "fadeOut",
                "input": {
                    "type": "number",
                    "description": "fadeOut in ms"
                },
                "forms": [
                    {
                        "href": "http://127.0.13.211:4563/fadeOut"
                    }
                ]
            }
        }
    }
    </pre>

</section>

  <section id="thing-model-td-required" class="normative">
    <h2>Required</h2>


  <p>    
    In some cases it is desirable to enforce which interaction affordances are mandatory and have to be implemented in a <a>Thing Description</a> instance or can be always expected 
    by the <a>Thing Model</a>.
    <span class="rfc2119-assertion" id="tm-tmRequired">
        To guarantee the implementation of particular kinds of interaction models, Thing Model definitions MUST use 
        the JSON member name <code>tm:required</code>. 
    </span>
    <span class="rfc2119-assertion" id="tm-tmRequired-array">
        <code>tm:required</code> MUST be a JSON array at the top level. 
    </span>
    <span class="rfc2119-assertion" id="tm-tmRequired-JSONPointer">
        The value of <code>tm:required</code> MUST provide JSON Pointer [[RFC6901]] references to the required interaction model 
        definitions. 
    </span>
    <span class="rfc2119-assertion" id="tm-tmRequired-resolver">
        The JSON Pointers of <code>tm:required</code> MUST resolve to an entire interaction affordance Map 
        definition.
    </span>
</p>

<p>    
The following sample shows the usage of <code>tm:required</code> for the <a>Property</a> interaction <code>status</code>
and <a>Action</a> interaction <code>toggle</code>. 
</p>

<pre class="example" title="Thing Model with the tm:required term for interaction affordances.">
{
    "@context": ["https://www.w3.org/2022/wot/td/v1.1"], 
    "@type" : "tm:ThingModel",
    "title": "Lamp Thing Model",
    "description": "Lamp Thing Description Model",
    "tm:required": [
        "#/properties/status",
        "#/actions/toggle"
    ],
    "properties": {
        "status": {
            "description": "current status of the lamp (on|off)",
            "type": "string",
            "readOnly": true
        }
    },
    "actions": {
        "toggle": {
            "description": "Turn the lamp on or off"
        }
    },
    "events": {
        "overheating": {
            "description": "Lamp reaches a critical temperature (overheating)",
            "data": {"type": "string"}
        }
    }
}
</pre>
    
<p>
Since the <a>Event</a> <code>overheating</code> is not mandatory it may not be available in a <a>Thing Description</a> 
instance.
</p>

</section>

<section id="thing-model-td-placeholder" class="normative">
    <h3>Placeholder</h3>

<p>
    A <a>Thing Model</a> can specify which terms should be used in a TD instance, but their values are unspecific and are first known during TD instantiation. 
    In such a case the placeholder labeling MAY be used in Thing Model that MUST be substituted with a concrete value when TD instance is created 
    from the Thing Model. 
    <span class="rfc2119-assertion" id="tm-placeholder">
        The string-based pattern of the placeholder MUST follow a valid pattern based on the regular expression <code>{{2}[ -~]+}{2}</code> (e.g., <code>{{</code><code>PLACEHOLDER_IDENTIFIER</code><code>}}</code>). 
        The characters between <code>{{</code> and <code>}}</code> are used as identifier name of the placeholder. The identifier name can be used to identify the placeholder for the substitution process.
    </span>
    <span class="rfc2119-assertion" id="tm-placeholder-value">
        A placeholder can only be applied within the value of the JSON name-value pair and the value has to be a JSON string. 
    </span>  
    <span class="rfc2119-assertion" id="tm-placeholder-retyping">
    In the case that a non string-based value of a JSON name-value pair should have a placeholder, the value must be (temporarily) typed as string. After replacing the placeholder, e.g. when creating a Thing Description instance, the original type can be applied with the 
    corresponding replaced value.  
    </span>
          
</p>

<p>
    The following Thing Model example defines different placeholders. The placeholder map is used to apply the replacement and to
    transform the intended value type.    
</p>

<aside class="example ds-selector-tabs" ><div class="marker">
 <span class="example-title">Thing Description generation from Thing Model</span>
  </div>
    <div class="selectors">
      <button class="selected exampleTab1 thingmodel" onclick="openTab('exampleTab1', 'thingmodel')">Thing Model</button>
      <button class="exampleTab1 placeholder"         onclick="openTab('exampleTab1', 'placeholder')">Placeholder Map</button>
      <button class="exampleTab1 thingdescription"    onclick="openTab('exampleTab1', 'thingdescription')">Thing Description</button>
    </div>
    <pre class="thingmodel exampleTab1 selected ">
{
	"@context": ["https://www.w3.org/2022/wot/td/v1.1"], 
	"@type" : "tm:ThingModel",
	"title": "Thermostate No. {{THERMOSTATE_NUMBER}}",
	"base": "mqtt://{{MQTT_BROKER_ADDRESS}}",
	"properties": {
		"temperature": {
			"description": "Shows the current temperature value",
			"type": "number",
			"minimum": -20,
			"maximum": "{{THERMOSTATE_TEMPERATURE_MAXIMUM}}",
			"observable" : "{{THERMOSTATE_TEMPERATURE_OBSERVABLE}}"
		}
	}
	...
}
	</pre>
    <pre class="placeholder exampleTab1">
{
	"THERMOSTATE_NUMBER": 4, 
	"MQTT_BROKER_ADDRESS" : "192.168.178.72:1883",
	"THERMOSTATE_TEMPERATURE_MAXIMUM": 47.7, 
	"THERMOSTATE_TEMPERATURE_OBSERVABLE" : true
}
	</pre>
    <pre class="thingdescription exampleTab1">
{
	"@context": ["https://www.w3.org/2022/wot/td/v1.1"], 
	"@type" : "Thing",
	"title": "Thermostate No. 4",
	"base": "mqtt://192.168.178.72:1883",
	"properties": {
		"temperature": {
			"description": "Shows the current temperature value",
			"type": "number",
			"minimum": -20.0,
			"maximum": 47.7,
			"observable" : true
		}
	}
	...
}
	</pre>
  </aside>

  </section>



  
  </section>

  <section id="thing-model-td-generation" class="normative">
    <h2>Derivation of Thing Description Instances</h2>

    <p>
        <a>Thing Models</a> can be used as templates to generate a <a>Thing Description</a> based on the restrictions defined in 
        Sections <a href="#sec-vocabulary-definition"></a> and <a href="#sec-td-serialization"></a>. During this process 
        missing data such as communication and security metadata have to be complemented to create valid <a>Thing Description</a> instances.
        <span class="rfc2119-assertion" id="tm-td-generation-inconsistencies">
            A <a>Thing Model</a> MUST be defined in such a way that there are no inconsistencies that would result in a <a>Thing Description</a> not 
            being able to meet the requirements as described in Section <a href="#sec-vocabulary-definition"></a> and <a href="#sec-td-serialization"></a>.
        </span>
            A TM-to-TD generator to derive a <a>Thing Description</a> instance from a <a>Thing Model</a> transforms it to a <a>Partial TD</a> using the
            following steps:
         <ul>
            <li class="rfc2119-assertion" id="thing-model-td-generation-processor-imports">Copy all definitions from the input <a>Thing Model</a> to the resulting <a>Partial TD</a> instance. If used, the extension and imports
            feature MUST be resolved and represented in the <a>Partial TD</a> instance according to <a href="#thing-model-extension-import"></a>.</li>
            <li class="rfc2119-assertion" id="thing-model-td-generation-processor-extends"> If used, <code>links</code> element entry with <code>"rel":"tm:extends"</code> MUST be removed from the current <a>Partial TD</a></li>
            <li class="rfc2119-assertion" id="thing-model-td-generation-processor-type">The <code>tm:ThingModel</code> value of the top-level <code>@type</code> MUST to be replaced by the value <code>Thing</code> in the <a>Partial TD</a> instance.</li>
            <li class="rfc2119-assertion" id="thing-model-td-generation-processor-required">If the <code>tm:required</code> feature is used based on Section <a href="#thing-model-td-required"></a>, the required interactions MUST be taken over to the <a>Partial TD</a> instance.</li>
            <li class="rfc2119-assertion" id="thing-model-td-generation-processor-placeholder">If used, all placeholders (see Section <a href="#thing-model-td-placeholder"></a>) in the <a>Thing Model</a> MUST be replaced with a valid corresponding value in the <a>Partial TD</a>.</li>
        </ul>
        Finally, a TM-to-TD generator will take the resulting <a>Partial TD</a> and transform it into a <a>Thing Description</a> with this last step
        <ul>
            <li class="rfc2119-assertion" id="thing-model-td-generation-processor-forms">Missing communication and/or security metadata details MUST be completed in the <a>Thing Description</a> instance based on Section <a href="#security-serialization-json"></a> and/or <a href="#form-serialization-json"></a>.</li>

        </ul>
    </p>
  

      <p>Thing description instances that follow a Thing Model can carry the information regarding which type of Thing Model is derived. In this context, the linking concept can be used with <code>"rel" : "type"</code> (also see
          Section <a href="#link"></a>), as shown in the following example: 
      </p>

      <aside class="example ds-selector-tabs" ><div class="marker">
        <span class="example-title">Linking Thing Description to a Thing Model Definition</span>
         </div>
           <div class="selectors">
             <button class="selected exampleTab2 thingmodel" onclick="openTab('exampleTab2', 'thingmodel')">Thing Model</button>
             <button class="exampleTab2 thingdescription"    onclick="openTab('exampleTab2', 'thingdescription')">Thing Description</button>
           </div>
           <pre class="selected exampleTab2 thingmodel">
{
	...
	"@type": "tm:ThingModel",
	"title": "Smart Pump",
	"description": "Smart Pump live plant and simulator",
	"id": "urn:smart:device:wot:pump",
	"version" : {"model" : "1.0.0" },
	...
}
		</pre>
        <pre class="exampleTab2 thingdescription">
{
	...
	"@type": "Thing",
	"title": "Smart Pump",
	"description": "Smart Pump live plant and simulator",
	"id": "urn:smart:device:wot:pump:instance:1",
	"version" : {"instance": "1.0.0",
				 "model" : "1.0.0" },
	"links" : [{
		"rel" : "type",
		"href" : "http://example.com/ThingModelPool/Pump",
		"type": "application/td+json"
	}],
	...
}
		</pre>
        </aside>

         <p>Please note that a TD can only be an instance of one TM at a time. 
             That means for Thing Descriptions:
         <span class="rfc2119-assertion" id="tm-rel-type-maximum">
            The <code>links</code> array can use the entry with <code>"rel" : "type"</code> a maximum of once.
        </span> 
    </p>

    

</section>


<section id="thing-model-td-generation-examples" class="normative">
    <h2>Examples</h2>

    <p>
        The following <a>Thing Model</a> extends the model as shown in <a href="#td-model-example-smart-lamp-control"></a> and 
        overwrites the <code>maximum</code> value of the <code>dim</code> property  
    </p>

    <pre class="example" title="Extending Smart Control Lamp with a modified dim constrained">
    {
        "@context": ["https://www.w3.org/2022/wot/td/v1.1"], 
        "@type" : "tm:ThingModel",
        "links" : [{
            "rel": "tm:extends",
            "href": "http://example.com/SmartControlLampTM",
            "type": "application/td+json"
         }],
        "properties" : {
            "dim" : {
                "maximum": 200
            }
       }
    }
    </pre>

    <p>The expected <a>Thing Description</a> that is derived from this <a>Thing Model</a> would be (with HTTP Binding and basic security applied):</p>

    <pre class="example" title="Thing Description">
        {
            "@context": ["https://www.w3.org/2022/wot/td/v1.1"], 
            "@type" : "Thing",
            "title": "Smart Lamp Control",
            "securityDefinitions": {
                "basic_sc": {"scheme": "basic", "in": "header"}
            },
            "security": "basic_sc",
            "links" : [{
                "rel": "type",
                "href": "url/to/SmartLampControlModifiedDimTM",
                "type": "application/td+json"
             }
           ],
           "properties" : {
                "onOff : {
                    "type: "boolean",
                    "forms": [{"href": "https://smartlamp.example.com/onoff"}]
                },
                "dim" : {
                    "type": "integer",
                    "minimum": 0,
                    "maximum": 200,
                    "forms": [{"href": "https://smartlamp.example.com/dim"}]
                }
           }
        }
    </pre>

    


</section>

 
</section>
  <section id="iana-section" class="normative">
 
  <h1>IANA Considerations</h1>
    <section id="media-type-section">
    <h2><code>application/td+json</code> Media Type Registration</h2>
    <dl>
      <dt>Type name:</dt>
      <dd>application</dd>
      <dt>Subtype name:</dt>
      <dd>td+json</dd>
      <dt>Required parameters:</dt>
      <dd>None</dd>
      <dt>Optional parameters:</dt>
      <dd>None</dd>
      <dt>Encoding considerations:</dt>
      <dd>See <a href="https://tools.ietf.org/html/rfc6839#section-3.1">RFC&nbsp;6839, section 3.1</a>.</dd>
      <dt>Security considerations:</dt>
      <dd>See <a href="https://tools.ietf.org/html/rfc8259#section-12">RFC&nbsp;8259, section 12</a>.
        <p>
          <span class="rfc2119-assertion" id="iana-security-execution">
            Since WoT Thing Description is intended to be a pure data exchange format for
            <a>Thing</a> metadata, the serialization SHOULD NOT be passed through a
            code execution mechanism such as JavaScript's <code>eval()</code>
            function to be parsed.
          </span>
          An (invalid) document may contain code that,
          when executed, could lead to unexpected side effects compromising
          the security of a system.
        </p>
        <p>
          WoT Thing Descriptions can be evaluated with a JSON-LD 1.1 processor,
          which typically follows links to remote contexts (i.e., TD context
          extensions, see <a href="https://www.w3.org/TR/wot-thing-description/#sec-context-extensions">W3C WoT Thing Description, section 7</a>)
          automatically, resulting in the transfer of files
          without the explicit request of the <a>Consumer</a> for each one. If remote
          contexts are served by third parties, it may allow them to gather
          usage patterns or similar information leading to privacy concerns.
          <span class="rfc2119-assertion" id="iana-security-remote">
          While implementations on resource-constrained devices are expected
          to perform raw JSON processing (as opposed to JSON-LD processing),
          implementations in general SHOULD statically cache vetted
          versions of their supported context extensions and not to follow links
          to remote contexts.
          </span>
          Supported context extensions can be managed
          through a secure software update mechanism instead.
        </p>
        <p>
          Context Extensions (see <a href="https://www.w3.org/TR/wot-thing-description/#sec-context-extensions">W3C WoT Thing Description, section 7</a>)
          that are loaded from the Web over non-secure connections,
          such as HTTP, run the risk of being altered by an attacker such that
          they may modify the <a>TD Information Model</a> in a way that could
          compromise security.
          <span class="rfc2119-assertion" id="iana-security-alter">
          For this reason, <a>Consumer</a> again
          SHOULD vet and cache remote contexts before allowing the system
          to use it.
          </span>
        </p>
        <p>
          Given that JSON-LD processing usually includes the substitution of
          long IRIs [[RFC3987]] with short terms,
          WoT Thing Descriptions may expand considerably when processed using
          a JSON-LD 1.1 processor and, in the worst case, the resulting data
          might consume all of the recipient's resources.
          <span class="rfc2119-assertion" id="iana-security-expansion">
          <a>Consumers</a> SHOULD treat any TD metadata with due skepticism.
          </span>
        </p>
      </dd>
      <dt>Interoperability considerations:</dt>
      <dd>See <a href="https://tools.ietf.org/html/rfc8259">RFC&nbsp;8259</a>.
        <p>
        Rules for processing both conforming and non-conforming content are
        defined in this specification.
        </p>
      </dd>
      <dt>Published specification:</dt>
      <dd><a href="https://w3c.github.io/wot-thing-description/">https://w3c.github.io/wot-thing-description/</a></dd>
      <dt>Applications that use this media type:</dt>
      <dd>
        All participating entities in the W3C Web of Things, that is,
        <a>Things</a>, <a>Consumers</a>, and Intermediaries as defined in the
        <a href="https://www.w3.org/TR/wot-architecture/">Web of Things (WoT) Architecture</a>.</dd>
      <dt>Fragment identifier considerations:</dt>
      <dd>See <a href="https://tools.ietf.org/html/rfc6839#section-3.1">RFC&nbsp;6839, section 3.1</a>.</dd>
      <dt>Additional information:</dt>
      <dd>
        <dl>
          <dt>Magic number(s):</dt>
          <dd>Not Applicable</dd>
          <dt>File extension(s):</dt>
          <dd>.jsontd</dd>
          <dt>Macintosh file type code(s):</dt>
          <dd>TEXT</dd>
        </dl>
      </dd>
      <dt>Person &amp; email address to contact for further information:</dt>
      <dd>Matthias Kovatsch &lt;w3c@kovatsch.net&gt;</dd>
      <dt>Intended usage:</dt>
      <dd>COMMON</dd>
      <dt>Restrictions on usage:</dt>
      <dd>None</dd>
      <dt>Author(s):</dt>
      <dd>The WoT Thing Description specification is a product of the Web of Things Working Group.</dd>
      <dt>Change controller:</dt>
      <dd><abbr title="World Wide Web Consortium">W3C</abbr></dd>
    </dl>

    </section>
    <section id="content-format-section">
    <h2>CoAP Content-Format Registration</h2>
    <p>
      IANA assigns compact CoAP Content-Format IDs for media types in the
      <a href="https://www.iana.org/assignments/core-parameters/core-parameters.xhtml#content-formats">CoAP Content-Formats</a>
      subregistry within the
      <a href="https://www.iana.org/assignments/core-parameters/core-parameters.xhtml">Constrained RESTful Environments (CoRE) Parameters</a>
      registry [[RFC7252]].
      The Content-Format ID for WoT Thing Description is 432.
    </p>
    <dl>
      <dt>Media Type:</dt>
      <dd>application/td+json</dd>
      <dt>Encoding:</dt>
      <dd>-</dd>
      <dt>ID:</dt>
      <dd>432</dd>
      <dt>Reference:</dt>
      <dd>[<a href="https://w3c.github.io/wot-thing-description/">"Web of Things (WoT) Thing Description", May 2019</a>]</dd>
    </dl>
    </section>
  </section>

  <section id="example-serialization" class="appendix informative">
    <h2>Example Thing Description Instances</h2>
  
    <section id="myLampThing-example-serialization">
    <h3>MyLampThing Example with CoAP Protocol Binding</h3>
  
    <p>Feature list of the <a>Thing</a>:</p>
  
    <ul>
        <li>Title: MyLampThing</li>
        <li>Context Extensions: none</li>
        <li>Offered affordances: 1 Property, 1 Action, 1 Event</li>
        <li>Security: PSKSecurityScheme</li>
        <li>Protocol Binding: CoAP [[?RFC7252]] over TLS</li>
        <li>Comment: Also see <a href="#adding-protocol-bindings"></a>.</li>
    </ul>
  
  <pre class="example" title="MyLampThing with CoAP Protocol Binding">
  {
     "@context": [
        "https://www.w3.org/2022/wot/td/v1.1",
        {
        "cov": "http://www.example.org/coap-binding#"
        }
      ],
      "id": "urn:dev:ops:32473-WoTLamp-1234",
      "title": "MyLampThing",
      "description": "MyLampThing uses JSON serialization",
      "securityDefinitions": {"psk_sc":{"scheme": "psk"}},
      "security": ["psk_sc"],
      "properties": {
          "status": {
              "description": "Shows the current status of the lamp",
              "type": "string",
              "forms": [{
                  "op": "readproperty",
                  "href": "coaps://mylamp.example.com/status",
                  "cov:methodName": "GET" 
              }]
          }
      },
      "actions": {
          "toggle": {
              "description": "Turn on or off the lamp",
              "forms": [{
                  "href": "coaps://mylamp.example.com/toggle",
                  "cov:methodName": "POST" 
              }]
          }
      },
      "events": {
          "overheating": {
              "description": "Lamp reaches a critical temperature (overheating)",
              "data": {"type": "string"},
              "forms": [{
                  "href": "coaps://mylamp.example.com/oh",
                  "cov:methodName": "GET",
                  "subprotocol": "cov:observe" 
              }]
          }
      }
  }
  </pre>
  </section>
  
    <section id="myLightSensor-example-serialization">
    <h3>MyIlluminanceSensor Example with MQTT Protocol Binding</h3>
  
    <p>Feature list of the <a>Thing</a>:</p>
  
    <ul>
        <li>Title: MyIlluminanceSensor</li>
        <li>Context Extensions: none</li>
        <li>Offered affordances: 1 Event</li>
        <li>Security: none</li>
        <li>Protocol Binding: MQTT [[?MQTT]]</li>
        <li>Comment: An MQTT client frequently publishes the illuminance data (number is serialized in text format) to 
            the topic <code>/illuminance</code> by the MQTT broker running behind the address 192.168.1.187:1883.</li>
    </ul>
  
  <pre class="example" title="MyIlluminanceSensor with MQTT Protocol Binding">
          {   
              "@context": "https://www.w3.org/2022/wot/td/v1.1",
              "title": "MyIlluminanceSensor",
              "id": "urn:dev:ops:32473-WoTIlluminanceSensor-1234",
              "securityDefinitions": {"nosec_sc": {"scheme": "nosec"}},
              "security": ["nosec_sc"],
              "events": {
                  "illuminance": {
                      "data":{"type": "integer"},
                      "forms": [
                          {
                              "href": "mqtt://192.168.1.187:1883/illuminance",
                              "contentType": "text/plain",
                              "op": "subscribeevent"
                          }
                      ]
                  }
              } 
          }
  </pre>
    </section>
  
  
    <section id="webhook-example-serialization">
      <h3>Webhook Event Example</h3>
    
      <p>Feature list of the <a>Thing</a>:</p>
    
      <ul>
          <li>Title: WebhookThing</li>
          <li>Context Extensions: use HTTP <a>Protocol Binding</a> supplements (htv prefix already included in TD context)</li>
          <li>Offered affordances: 1 Event</li>
          <li>Security: none</li>
          <li>Protocol Binding: HTTP</li>
          <li>Comment: <i>WebhookThing</i> provides an Event affordance <code>temperature</code>
              which periodically pushes the latest temperature value to the <a>Consumer</a> using a Webhook mechanism,
              where the <a>Thing</a> sends POST requests to a callback URI provided by the <a>Consumer</a>.
              To describe this, the <code>subscription</code> member defines a write-only parameter <code>callbackURL</code>,
              which must be submitted through the <code>subscribeevent</code> form.
              The read-only parameter <code>subscriptionID</code> is returned by the subscription.
              The <i>WebhookThing</i> will then periodically POST to this callback URI with a payload defined by <code>data</code>.
              To unsubscribe, the <a>Consumer</a> has to submit the <code>unsubscribeevent</code> form with the <code>subscriptionID</code> as described in <code>cancellation</code>.
              Alternatively, <code>uriVariables</code> approache can be used that informs the <a>Consumer</a> to include the <code>subscriptionID</code> string 
              into the URI that have to be called with the delete method (see tab 'With uriVariables'). In such setup, the <code>cancellation</code> container can be obmitted.
              In general, this example can be further automated by using a <a>TD Context Extension</a> to include proper semantic annotations.
          </li>
      </ul>



<aside class="example ds-selector-tabs" ><div class="marker">
    <span class="example-title">Temperature Event with subscription and cancellation</span>
     </div>
       <div class="selectors">
         <button class="selected exampleTab1 without" onclick="openTab('exampleTab1', 'without')">Without uriVariables</button>
         <button class="exampleTab1 with"         onclick="openTab('exampleTab1', 'with')">With uriVariables</button>
       </div>
       <pre class="without exampleTab1 selected ">
        {
            "@context": "http://www.w3.org/ns/td",
            "id": "urn:dev:ops:32473-Thing-1234",
            "title": "WebhookThing",
            "description": "Webhook-based Event with subscription and unsubscribe form.",
            "securityDefinitions": {"nosec_sc": {"scheme": "nosec"}},
            "security": ["nosec_sc"],
            "events": {
                "temperature": {
                    "description": "Provides periodic temperature value updates.",
                    "subscription": {
                        "type": "object",
                        "properties": {
                            "callbackURL": {
                                "type": "string",
                                "format": "uri",
                                "description": "Callback URL provided by subscriber for Webhook notifications.",
                                "writeOnly": true
                            },
                            "subscriptionID": {
                                "type": "string",
                                "description": "Unique subscription ID for cancellation provided by WebhookThing.",
                                "readOnly": true
                            }
                        }
                    },
                    "data": {
                        "type": "number",
                        "description": "Latest temperature value that is sent to the callback URL."
                    },
                    "cancellation": {
                        "type": "object",
                        "properties": {
                            "subscriptionID": {
                                "type": "integer",
                                "description": "Required subscription ID to cancel subscription.",
                                "writeOnly": true
                            }
                        }
                    },
                    "forms": [
                        {
                            "op": "subscribeevent",
                            "href": "http://192.168.0.124:8080/events/temp/subscribe",
                            "contentType": "application/json",
                            "htv:methodName": "POST"
                        },
                        {
                            "op": "unsubscribeevent",
                            "href": "http://192.168.0.124:8080/events/temp/cancel",
                            "htv:methodName": "POST"
                        }
                    ]
                }
            }
        }
       </pre>
       <pre class="with exampleTab1">
        {
            "@context": "http://www.w3.org/ns/td",
            "id": "urn:dev:ops:32473-Thing-1234",
            "title": "WebhookThing",
            "description": "Webhook-based Event with subscription and unsubscribe form.",
            "securityDefinitions": {"nosec_sc": {"scheme": "nosec"}},
            "security": ["nosec_sc"],
            "events": {
                "temperature": {
                    "description": "Provides periodic temperature value updates.",
                    "subscription": {
                        "type": "object",
                        "properties": {
                            "callbackURL": {
                                "type": "string",
                                "format": "uri",
                                "description": "Callback URL provided by subscriber for Webhook notifications.",
                                "writeOnly": true
                            },
                            "subscriptionID": {
                                "type": "string",
                                "description": "Unique subscription ID for cancellation provided by WebhookThing.",
                                "readOnly": true
                            }
                        }
                    },
                    "data": {
                        "type": "number",
                        "description": "Latest temperature value that is sent to the callback URL."
                    },
                    "uriVariables": {
                        "subscriptionID": { "type": "string" }
                    },
                    "forms": [
                        {
                            "op": "subscribeevent",
                            "href": "http://192.168.0.124:8080/events/temp/subscribe",
                            "contentType": "application/json",
                            "htv:methodName": "POST"
                        },
                        {
                            "op": "unsubscribeevent",
                            "href": "http://192.168.0.124:8080/events/temp/{subscriptionID}",
                            "htv:methodName": "DELETE"
                        }
                    ]
                }
            }
        }
       </pre>
     </aside>

     <p class="ednote">
        Instead of a periodically POST call of the Thing the consumer may provide a response data with information when the next POST should be 
        provided by the Thing. The WoT WG is currently working on a definition that covers this scenario for the next update of the TD document (W3C TD 1.1 CR).   
      </p>
    





    </section>
  </section>

  <section id="json-schema-for-validation" class="appendix informative">
  <h1>JSON Schema for TD Instance Validation</h1>
    <p>
        Below is a JSON Schema [[?JSON-SCHEMA]] document for syntactically validating Thing Description instances serialized in JSON based format.
    </p>
    <p class="note">The Thing Description defined by this document allows for 
        adding external vocabularies by using <code>@context</code> mechanism 
        known from JSON-LD [[?json-ld11]], and the terms in those external vocabularies can be
        used in addition to the terms defined in <a href="#sec-vocabulary-definition"></a>. 
        For this reason, the below JSON schema is intentionally non-strict in that 
        regard. You can replace the value of <code>additionalProperties</code> schema 
        property <code>true</code> with <code>false</code> in different scopes/levels in 
        order to perform a stricter validation in case no external vocabularies are used.
    </p>

    <p class="note"> Please note that some JSON Schema validation tools do not support the <code>iri-reference</code> string format. 
	    It can be replaced with <code>uri-reference</code> or the term <code>format</code> can removed from the definition of <code>anyUri</code>.
    </p>

    <p>
        The following JSON Schema for validating TD instances does not require the terms with <a>Default Values</a> to be present. Thus the terms with <a>Default Values</a> are optional. (see also <a href="#sec-default-values"></a>)
    </p>
    <pre class="advisement">
    {td.json-schema.validation}
    </pre>

  </section>



<section id="json-ld-ctx-usage" class="appendix informative">
    <h1>JSON-LD Context Usage</h1>

    <p>
        The present specification introduces the <a>TD Information Model</a>
        as a set of constraints over different <a>Vocabularies</a>, i.e. sets of
        <a>Vocabulary Terms</a>. This section briefly explains how a machine-readable
        definition of these constraints can be integrated into client applications,
        by making use of the mandatory <code>@context</code> of a TD document.
    </p>

    <p>
        Accessing the <a>TD Information Model</a> from a TD document is done in
        two steps. First, clients must retrieve a mapping from JSON strings to IRIs.
        This mapping is defined as a JSON-LD context, as explained later. Second, clients
        can access the constraints defined on these IRIs by dereferencing them.
        Constraints are defined as logical axioms in the RDF format, readily interpretable
        by client programs.
    </p>

    <p>
        All <a>Vocabulary Terms</a> referenced in <a href="#sec-vocabulary-definition"></a>
        are serialized as (compact) JSON strings in a TD document. However, each of these
        terms is unambiguously identified by a full IRI, as per the first Linked Data
        principle [[LINKED-DATA]]. The mappings from JSON keys to IRIs is what the
        <code>@context</code> value of a TD points to. For instance, the file at
    </p>

    <p>
        <code>https://www.w3.org/2022/wot/td/v1.1</code>
    </p>

    <p>
        includes the following mappings (among others):
        <table>
            <tbody>
                <tr>
                    <td><code>properties</code></td>
                    <td>→</td>
                    <td><code>https://www.w3.org/2019/wot/td#hasPropertyAffordance</code></td>
                </tr>
                <tr>
                    <td><code>object</code></td>
                    <td>→</td>
                    <td><code>https://www.w3.org/2019/wot/json-schema#ObjectSchema</code></td>
                </tr>
                <tr>
                    <td><code>basic</code></td>
                    <td>→</td>
                    <td><code>https://www.w3.org/2019/wot/security#BasicSecurityScheme</code></td>
                </tr>
                <tr>
                    <td><code>href</code></td>
                    <td>→</td>
                    <td><code>https://www.w3.org/2019/wot/hypermedia#hasTarget</code></td>
                </tr>
                <tr>
                    <td colspan="3">...</td>
                </tr>
            </tbody>
        </table>
    </p>

    <p>
        This JSON file follows the JSON-LD 1.1 syntax [[JSON-LD11]].
        Numerous JSON-LD libraries can automatically process the <code>@context</code> of a TD
        and expand all the JSON strings it includes.
    </p>

    <p>
        Once every <a>Vocabulary Term</a> of a TD is expanded to a IRI, the second step
        consists in dereferencing this IRI to get fragments of the <a>TD Information Model</a>
        that refer to that <a>Vocabulary Term</a>. For instance, dereferencing the IRI
    </p>

    <p>
        <code>https://www.w3.org/2019/wot/json-schema#ObjectSchema</code>
    </p>

    <p>
        results in an RDF document stating that the term <code>ObjectSchema</code> is a
        <a>Class</a> and more precisely, a sub-class of <code>DataSchema</code>. Such
        logical axioms are represented in RDF using formalisms of various complexity:
        here, sub-class relations are expressed as RDF Schema axioms [[RDF-SCHEMA]].
        Moreover, these axioms may be serialized in various formats. Here, they are
        serialized in the Turtle format [[TURTLE]]:
    </p>

    <p>
<pre class="nohighlight">
<code>&lt;https://www.w3.org/2019/wot/json-schema#ObjectSchema&gt;
    a rdfs:Class .
&lt;https://www.w3.org/2019/wot/json-schema#ObjectSchema&gt;
    rdfs:subClassOf &lt;https://www.w3.org/2019/wot/json-schema#DataSchema&gt; .</code>
</pre>
    </p>

    <p>
        By default, if a user agent does not perform any content negotiation, a human-readable
        HTML documentation is returned instead of the RDF document. To negotiate content,
        clients must include the HTTP header <code>Accept: text/turtle</code> in their request.
    </p>
</section>

<section id="changes" class="appendix">
  <h1>Recent Specification Changes</h1>
  <section>
  <h2 id="changes-from-june-2021">Changes from Second Public Working Draft 7 June 2021</h2>
    <ul>
      <!-- section 4. Namespaces -->
      <li>In section <a href="#namespaces"></a>, new namespace IRI is provided for Thing Description 1.1.</li>
      <!-- section 5.3 Class Definitions -->
      <li>In section <a href="#class-definitions"></a>:
        <ul>
          <li>The type definition of <code>titles</code> and <code>descriptions</code> members that appear in sub-sections <a href="#thing"></a>, <a href="#interactionaffordance"></a>, <a href="#dataschema"></a> and <a href="#securityscheme"></a> were clarified.
          </li>
          <!-- section 5.3.1 Core Vocabulary Definitions -->
          <li>In section <a href="#sec-core-vocabulary-definition"></a>: 
            <ul>
              <!-- section 5.3.1.1 Thing -->
              <li>In section <a href="#thing"></a>:
                <ul>
                  <li>The allowed values for the <code>op</code> member of a <code>Form</code> were expanded.</li>
                  <li>The description of the <code>forms</code> term was clarified.</li>
                  <li>The value used for <code>@context</code> has changed in Thing Description 1.1.</li>
                  <li>The rule in the use of <code>@context</code> for Thing Description 1.1 to be able to be consumed by TD 1.0 consumers are specified.</li>
                </ul>
              </li>
              <!-- section 5.3.1.3 PropertyAffordance -->
              <li>In section <a href="#propertyaffordance"></a>:
                <ul>
                  <li>Clarifed that property can be retrieved and/or updated.</li>
                  <li>An additional note was appended for clarification.</li>
                </ul>
              </li>
              </li>
              <!-- section 5.3.1.4 ActionAffordance -->
              <li>In section <a href="#actionaffordance"></a>:
                <ul>
                  <li>The allowed values of the <code>op</code> member of a <code>Form</code> were expanded.
                  </li>
                </ul>
              </li>
            </ul>
          </li>
          <!-- section 5.3.2.1 DataSchema -->
          <li>In section <a href="#dataschema"></a>:
            <ul>
              <li>The description of the <code>unit</code> term was clarified.</li>
              <li>The vocabulary terms <code>contentEncoding</code> and <code>contentMediaType</code> were moved to 
section <a href="#stringschema"></a>.
              </li>
            </ul>
          </li>
          <!-- section 5.3.3 Security Vocabulary Definitions -->
          <li>In section <a href="#sec-security-vocabulary-definition"></a>:
            <ul>
              <!-- section 5.3.3.4 BasicSecurityScheme -->
              <li>In section <a href="#basicsecurityscheme"></a>, the assignment of the <code>in</code> member was clarified.</li>
              <!-- section 5.3.3.5 DigestSecurityScheme -->
              <li>In section <a href="#digestsecurityscheme"></a>, the assignment of the <code>in</code> and <code>qop</code> member was clarified.</li>
              <!-- section 5.3.3.6 APIKeySecurityScheme -->
              <li>In section <a href="#apikeysecurityscheme"></a>, the assignment of the <code>in</code> member was clarified.</li>
              <!-- section 5.3.3.7 BearerSecurityScheme -->
              <li>In section <a href="#bearersecurityscheme"></a>, the assignment of the <code>alg</code>, <code>format</code> and <code>in</code> member was clarified.</li>
            </ul>
          </li>
          <!-- section 5.3.4.1 Link -->
          <li>In section <a href="#link"></a>, a new value <code>tm:submodel</code> was added to the table describing the values used for relation types.
          </li>
          <!-- section 5.3.4.2. Form -->
          <li>In section <a href="#form"></a>:
            <ul>
              <li>The assignment of the <code>op</code> term was clarified.</li>
              <li><code>Values subscribeallevents</code>, <code>unsubscribeallevents</code>, <code>queryallactions</code>, <code>queryaction</code> and <code>cancelaction</code> were added to the type definition of <code>op</code> term.</li>
              <li>A <a href="#table-operation-types">table</a> was added to describe the values of <code>op</code> term.
              </li>
            </ul>
          </li>
        </ul>
      </li>
      <!-- section 5.4 Default Value Definitions -->
      <li>In section <a href="#sec-default-values"></a>, default assignments were added to <code>PropertyAffordance</code> class's <code>observable</code> member and <code>AdditionalExpectedResponse</code> class's <code>contentType</code> member.</li>
      <!-- section 6. TD Representation Format -->
      <li>In section <a href="#sec-td-serialization"></a>:
        <ul>
          <!-- section 6.3.1 Thing Root Object -->
          <li>In section <a href="#sec-thing-as-a-whole-json"></a>, the value used for <code>@context</code> has changed in Thing Description 1.1.</li>
          <!-- section 6.3.4 securityDefinitions and security -->
          <li>In section <a href="#security-serialization-json"></a>:
            <ul>
              <li>Examples were reordered, then the section was partitioned into sub-sections to make the section easier to read.
              </li>
              <!-- section 6.3.4.4 OAuth 2.0 usage -->
              <li>In section <a href="#security-oauth2"></a>, the <code>flow</code> that appears in <a href="#example-18"></a> now uses <code>client</code> as a value.
              </li>
            </ul>
          </li>
          <!-- section 6.3.9.1 uriVariables -->
          <li>In section <a href="#form-uriVariables"></a>, more examples were added.</li>
          <!-- section 6.6 -->
          <li>A sub-section describing canonicalization was removed.</li>
        </ul>
      </li>
      <!-- 7.1.1 Example I: Additional Basic Metadata -->
      <li>In section <a href="#semantic-annotations-example-version-units"></a>, additional terms are used in the example.
      </li>
      <!-- 8.3 Protocol Bindings -->
      <li>In section <a href="#protocol-bindings"></a>:
        <ul>
          <li>Added a reference to the Binding Templates specification to clarify <code>href</code> semantics.</li>
          <li>A note was appended for clarification.</li>
        </ul>
      </li>
      <!-- 10.3 Modeling Tools -->
      <li>In section <a href="#thing-model-tools"></a>:
        <ul>
          <!-- section 10.3.1 Versioning -->
          <li>In section <a href="#thing-model-versioning"></a>, a paragraph was added to describe a consideration in the use of versioning.</li>
          <!-- section 10.3.2 Extension and Import -->
          <li>In section <a href="#thing-model-extension-import"></a>:
            <ul>
              <li>The syntax and processing rule of <code>tm:ref</code> was clarified.</li>
              <li><a href="#thing-model-overwriting"></a> was added.</li>
            </ul>
          </li>
          <!-- section 10.3.3 Composition -->
          <li>Section <a href="#thing-model-composition"></a> was added.</li>
          <li>Section <a href="#thing-model-td-placeholder"></a> is now after section <a href="#thing-model-td-required"></a>. (order reversed)</li>
        </ul>
      </li>
      <!-- appendix A.3 Webhook Event Example -->
      <li>In appendix <a href="#webhook-example-serialization"></a>, the example and its description were updated.</li>
      <!-- appendix B. JSON Schema for TD Instance Validation -->
      <li>In appendix <a href="#json-schema-for-validation"></a>, the text of the second note was updated for clarification.</li>
    </ul>
  </section>
  <section>
  <h2 id="changes-from-fpwd">Changes from First Public Working Draft 24 November 2020</h2>
    <p>Changes from First Public Working Draft 24 November 2020 are described in the 
        <a href="https://www.w3.org/TR/2021/WD-wot-thing-description11-20210607/">Second Public Working Draft</a>.
    </p>
  </section>
</section>

<section id="acknowledgements" class="appendix normative">
  <h1>Acknowledgements</h1>
  <p>The editors would like to special thank Matthias Kovatsch (co-editor of TD 1.0), Michael Koster, Michael Lagally, Kazuyuki Ashimura, Ege Korkan, Daniel Peintner, Toru Kawaguchi, María Poveda, Dave Raggett, Kunihiko Toumura, Takeshi Yamada, Ben Francis, Manu Sporny, Klaus Hartke, Addison Phillips, Jose M. Cantera, Tomoaki Mizushima, Soumya Kanti Datta and Benjamin Klotz for providing contributions, guidance and expertise.</p>
  <p>Also, many thanks to the W3C staff and all other current and former active Participants of the W3C Web of Things Interest Group (WoT IG) and Working Group (WoT WG) for their support, technical input and suggestions that led to improvements to this document.</p>
  <p>Finally, special thanks to Joerg Heuer for leading the WoT IG for 2 years from its inception and guiding the group to come up with the concept of WoT building blocks including the Thing Description.</p>
</section>

<p class="note">
    Temporary ReSpec fix regarding non-listed references: [[RFC6068]], [[RFC3966]], [[html]], [[RFC6750]],  [[RFC7519]],  [[RFC7797]],  [[RFC8392]],  [[RFC7516]], [[LDML]],  [[SEMVER]], [[RFC7617]], [[RFC7616]] 
</p>

</body>
</html>