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_Phoenix_Code.h
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_Phoenix_Code.h
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//Project Lynxmotion Phoenix
//Description: Phoenix software
//Software version: V2.0
//Date: 29-10-2009
//Programmer: Jeroen Janssen [aka Xan]
// Kurt Eckhardt(KurtE) converted to C and Arduino
// Kåre Halvorsen aka Zenta - Makes everything work correctly!
//
// This version of the Phoenix code was ported over to the Arduino Environement
// and is specifically configured for the Lynxmotion BotBoarduino
//
// Phoenix_Code.h
//
// This contains the main code for the Phoenix project. It is included in
// all of the different configurations of the phoenix code.
//
//NEW IN V2.X
//=============================================================================
//
//KNOWN BUGS:
// - Lots ;)
//
//=============================================================================
// Header Files
//=============================================================================
#define DEFINE_HEX_GLOBALS
#if ARDUINO>99
#include <Arduino.h>
#else
#endif
//#include <EEPROM.h>
//#include <PS2X_lib.h>
#include <pins_arduino.h>
//#include <SoftwareSerial.h>
#define BalanceDivFactor CNT_LEGS //;Other values than 6 can be used, testing...CAUTION!! At your own risk ;)
//#include <Wire.h>
//#include <I2CEEProm.h>
// Only compile in Debug code if we have something to output to
#ifdef DBGSerial
#define DEBUG
//#define DEBUG_X
#endif
//--------------------------------------------------------------------
//[TABLES]
//ArcCosinus Table
//Table build in to 3 part to get higher accuracy near cos = 1.
//The biggest error is near cos = 1 and has a biggest value of 3*0.012098rad = 0.521 deg.
//- Cos 0 to 0.9 is done by steps of 0.0079 rad. [1/127]
//- Cos 0.9 to 0.99 is done by steps of 0.0008 rad [0.1/127]
//- Cos 0.99 to 1 is done by step of 0.0002 rad [0.01/64]
//Since the tables are overlapping the full range of 127+127+64 is not necessary. Total bytes: 277
static const byte GetACos[] PROGMEM = {
255,254,252,251,250,249,247,246,245,243,242,241,240,238,237,236,234,233,232,231,229,228,227,225,
224,223,221,220,219,217,216,215,214,212,211,210,208,207,206,204,203,201,200,199,197,196,195,193,
192,190,189,188,186,185,183,182,181,179,178,176,175,173,172,170,169,167,166,164,163,161,160,158,
157,155,154,152,150,149,147,146,144,142,141,139,137,135,134,132,130,128,127,125,123,121,119,117,
115,113,111,109,107,105,103,101,98,96,94,92,89,87,84,81,79,76,73,73,73,72,72,72,71,71,71,70,70,
70,70,69,69,69,68,68,68,67,67,67,66,66,66,65,65,65,64,64,64,63,63,63,62,62,62,61,61,61,60,60,59,
59,59,58,58,58,57,57,57,56,56,55,55,55,54,54,53,53,53,52,52,51,51,51,50,50,49,49,48,48,47,47,47,
46,46,45,45,44,44,43,43,42,42,41,41,40,40,39,39,38,37,37,36,36,35,34,34,33,33,32,31,31,30,29,28,
28,27,26,25,24,23,23,23,23,22,22,22,22,21,21,21,21,20,20,20,19,19,19,19,18,18,18,17,17,17,17,16,
16,16,15,15,15,14,14,13,13,13,12,12,11,11,10,10,9,9,8,7,6,6,5,3,0 };//
//Sin table 90 deg, persision 0.5 deg [180 values]
static const word GetSin[] PROGMEM = {
0, 87, 174, 261, 348, 436, 523, 610, 697, 784, 871, 958, 1045, 1132, 1218, 1305, 1391, 1478, 1564,
1650, 1736, 1822, 1908, 1993, 2079, 2164, 2249, 2334, 2419, 2503, 2588, 2672, 2756, 2840, 2923, 3007,
3090, 3173, 3255, 3338, 3420, 3502, 3583, 3665, 3746, 3826, 3907, 3987, 4067, 4146, 4226, 4305, 4383,
4461, 4539, 4617, 4694, 4771, 4848, 4924, 4999, 5075, 5150, 5224, 5299, 5372, 5446, 5519, 5591, 5664,
5735, 5807, 5877, 5948, 6018, 6087, 6156, 6225, 6293, 6360, 6427, 6494, 6560, 6626, 6691, 6755, 6819,
6883, 6946, 7009, 7071, 7132, 7193, 7253, 7313, 7372, 7431, 7489, 7547, 7604, 7660, 7716, 7771, 7826,
7880, 7933, 7986, 8038, 8090, 8141, 8191, 8241, 8290, 8338, 8386, 8433, 8480, 8526, 8571, 8616, 8660,
8703, 8746, 8788, 8829, 8870, 8910, 8949, 8987, 9025, 9063, 9099, 9135, 9170, 9205, 9238, 9271, 9304,
9335, 9366, 9396, 9426, 9455, 9483, 9510, 9537, 9563, 9588, 9612, 9636, 9659, 9681, 9702, 9723, 9743,
9762, 9781, 9799, 9816, 9832, 9848, 9862, 9876, 9890, 9902, 9914, 9925, 9935, 9945, 9953, 9961, 9969,
9975, 9981, 9986, 9990, 9993, 9996, 9998, 9999, 10000 };//
//Build tables for Leg configuration like I/O and MIN/ Max values to easy access values using a FOR loop
//Constants are still defined as single values in the cfg file to make it easy to read/configure
// BUGBUG: Need a cleaner way to define...
// Lets allow for which legs servos to be inverted to be defined by the robot
// This is used by the Lynxmotion Symetrical Quad.
#ifndef cRRCoxaInv
#define cRRCoxaInv 1
#endif
#ifndef cRMCoxaInv
#define cRMCoxaInv 1
#endif
#ifndef cRFCoxaInv
#define cRFCoxaInv 1
#endif
#ifndef cLRCoxaInv
#define cLRCoxaInv 0
#endif
#ifndef cLMCoxaInv
#define cLMCoxaInv 0
#endif
#ifndef cLFCoxaInv
#define cLFCoxaInv 0
#endif
#ifndef cRRFemurInv
#define cRRFemurInv 1
#endif
#ifndef cRMFemurInv
#define cRMFemurInv 1
#endif
#ifndef cRFFemurInv
#define cRFFemurInv 1
#endif
#ifndef cLRFemurInv
#define cLRFemurInv 0
#endif
#ifndef cLMFemurInv
#define cLMFemurInv 0
#endif
#ifndef cLFFemurInv
#define cLFFemurInv 0
#endif
#ifndef cRRTibiaInv
#define cRRTibiaInv 1
#endif
#ifndef cRMTibiaInv
#define cRMTibiaInv 1
#endif
#ifndef cRFTibiaInv
#define cRFTibiaInv 1
#endif
#ifndef cLRTibiaInv
#define cLRTibiaInv 0
#endif
#ifndef cLMTibiaInv
#define cLMTibiaInv 0
#endif
#ifndef cLFTibiaInv
#define cLFTibiaInv 0
#endif
#ifndef cRRTarsInv
#define cRRTarsInv 1
#endif
#ifndef cRMTarsInv
#define cRMTarsInv 1
#endif
#ifndef cRFTarsInv
#define cRFTarsInv 1
#endif
#ifndef cLRTarsInv
#define cLRTarsInv 0
#endif
#ifndef cLMTarsInv
#define cLMTarsInv 0
#endif
#ifndef cLFTarsInv
#define cLFTarsInv 0
#endif
// Also define default BalanceDelay
#ifndef BALANCE_DELAY
#define BALANCE_DELAY 100
#endif
#ifdef HEXMODE
// Standard Hexapod...
// Servo Horn offsets
#ifdef cRRFemurHornOffset1 // per leg configuration
static const short cFemurHornOffset1[] PROGMEM = {
cRRFemurHornOffset1, cRMFemurHornOffset1, cRFFemurHornOffset1, cLRFemurHornOffset1, cLMFemurHornOffset1, cLFFemurHornOffset1};
#define CFEMURHORNOFFSET1(LEGI) ((short)pgm_read_word(&cFemurHornOffset1[LEGI]))
#else // Fixed per leg, if not defined 0
#ifndef cFemurHornOffset1
#define cFemurHornOffset1 0
#endif
#define CFEMURHORNOFFSET1(LEGI) (cFemurHornOffset1)
#endif
#ifdef cRRTibiaHornOffset1 // per leg configuration
static const short cTibiaHornOffset1[] PROGMEM = {
cRRTibiaHornOffset1, cRMTibiaHornOffset1, cRFTibiaHornOffset1, cLRTibiaHornOffset1, cLMTibiaHornOffset1, cLFTibiaHornOffset1};
#define CTIBIAHORNOFFSET1(LEGI) ((short)pgm_read_word(&cTibiaHornOffset1[LEGI]))
#else // Fixed per leg, if not defined 0
#ifndef cTibiaHornOffset1
#define cTibiaHornOffset1 0
#endif
#define CTIBIAHORNOFFSET1(LEGI) (cTibiaHornOffset1)
#endif
#ifdef c4DOF
#ifdef cRRTarsHornOffset1 // per leg configuration
static const short cTarsHornOffset1[] PROGMEM = {
cRRTarsHornOffset1, cRMTarsHornOffset1, cRFTarsHornOffset1, cLRTarsHornOffset1, cLMTarsHornOffset1, cLFTarsHornOffset1};
#define CTARSHORNOFFSET1(LEGI) ((short)pgm_read_word(&cTarsHornOffset1[LEGI]))
#else // Fixed per leg, if not defined 0
#ifndef cTarsHornOffset1
#define cTarsHornOffset1 0
#endif
#define CTARSHORNOFFSET1(LEGI) cTarsHornOffset1
#endif
#endif
//Min / Max values
#ifndef SERVOS_DO_MINMAX
const short cCoxaMin1[] PROGMEM = {
cRRCoxaMin1, cRMCoxaMin1, cRFCoxaMin1, cLRCoxaMin1, cLMCoxaMin1, cLFCoxaMin1};
const short cCoxaMax1[] PROGMEM = {
cRRCoxaMax1, cRMCoxaMax1, cRFCoxaMax1, cLRCoxaMax1, cLMCoxaMax1, cLFCoxaMax1};
const short cFemurMin1[] PROGMEM ={
cRRFemurMin1, cRMFemurMin1, cRFFemurMin1, cLRFemurMin1, cLMFemurMin1, cLFFemurMin1};
const short cFemurMax1[] PROGMEM ={
cRRFemurMax1, cRMFemurMax1, cRFFemurMax1, cLRFemurMax1, cLMFemurMax1, cLFFemurMax1};
const short cTibiaMin1[] PROGMEM ={
cRRTibiaMin1, cRMTibiaMin1, cRFTibiaMin1, cLRTibiaMin1, cLMTibiaMin1, cLFTibiaMin1};
const short cTibiaMax1[] PROGMEM = {
cRRTibiaMax1, cRMTibiaMax1, cRFTibiaMax1, cLRTibiaMax1, cLMTibiaMax1, cLFTibiaMax1};
#ifdef c4DOF
const short cTarsMin1[] PROGMEM = {
cRRTarsMin1, cRMTarsMin1, cRFTarsMin1, cLRTarsMin1, cLMTarsMin1, cLFTarsMin1};
const short cTarsMax1[] PROGMEM = {
cRRTarsMax1, cRMTarsMax1, cRFTarsMax1, cLRTarsMax1, cLMTarsMax1, cLFTarsMax1};
#endif
#endif
// Servo inverse direction
const bool cCoxaInv[] = {cRRCoxaInv, cRMCoxaInv, cRFCoxaInv, cLRCoxaInv, cLMCoxaInv, cLFCoxaInv};
bool cFemurInv[] = {cRRFemurInv, cRMFemurInv, cRFFemurInv, cLRFemurInv, cLMFemurInv, cLFFemurInv};
const bool cTibiaInv[] = {cRRTibiaInv, cRMTibiaInv, cRFTibiaInv, cLRTibiaInv, cLMTibiaInv, cLFTibiaInv};
#ifdef c4DOF
const boolean cTarsInv[] = {cRRTarsInv, cRMTarsInv, cRFTarsInv, cLRTarsInv, cLMTarsInv, cLFTarsInv};
#endif
//Leg Lengths
const byte cCoxaLength[] PROGMEM = {
cRRCoxaLength, cRMCoxaLength, cRFCoxaLength, cLRCoxaLength, cLMCoxaLength, cLFCoxaLength};
const byte cFemurLength[] PROGMEM = {
cRRFemurLength, cRMFemurLength, cRFFemurLength, cLRFemurLength, cLMFemurLength, cLFFemurLength};
const byte cTibiaLength[] PROGMEM = {
cRRTibiaLength, cRMTibiaLength, cRFTibiaLength, cLRTibiaLength, cLMTibiaLength, cLFTibiaLength};
#ifdef c4DOF
const byte cTarsLength[] PROGMEM = {
cRRTarsLength, cRMTarsLength, cRFTarsLength, cLRTarsLength, cLMTarsLength, cLFTarsLength};
#endif
//Body Offsets [distance between the center of the body and the center of the coxa]
const short cOffsetX[] PROGMEM = {
cRROffsetX, cRMOffsetX, cRFOffsetX, cLROffsetX, cLMOffsetX, cLFOffsetX};
const short cOffsetZ[] PROGMEM = {
cRROffsetZ, cRMOffsetZ, cRFOffsetZ, cLROffsetZ, cLMOffsetZ, cLFOffsetZ};
//Default leg angle
const short cCoxaAngle1[] PROGMEM = {
cRRCoxaAngle1, cRMCoxaAngle1, cRFCoxaAngle1, cLRCoxaAngle1, cLMCoxaAngle1, cLFCoxaAngle1};
#ifdef cRRInitCoxaAngle1 // We can set different angles for the legs than just where they servo horns are set...
const short cCoxaInitAngle1[] PROGMEM = {
cRRInitCoxaAngle1, cRMInitCoxaAngle1, cRFInitCoxaAngle1, cLRInitCoxaAngle1, cLMInitCoxaAngle1, cLFInitCoxaAngle1};
#endif
//Start positions for the leg
const short cInitPosX[] PROGMEM = {
cRRInitPosX, cRMInitPosX, cRFInitPosX, cLRInitPosX, cLMInitPosX, cLFInitPosX};
const short cInitPosY[] PROGMEM = {
cRRInitPosY, cRMInitPosY, cRFInitPosY, cLRInitPosY, cLMInitPosY, cLFInitPosY};
const short cInitPosZ[] PROGMEM = {
cRRInitPosZ, cRMInitPosZ, cRFInitPosZ, cLRInitPosZ, cLMInitPosZ, cLFInitPosZ};
//=============================================================================
#elif defined(OCTOMODE)
// Octopods
// Servo Horn offsets
#ifdef cRRFemurHornOffset1 // per leg configuration
static const short cFemurHornOffset1[] PROGMEM = {
cRRFemurHornOffset1, cRMRFemurHornOffset1, cRMFFemurHornOffset1, cRFFemurHornOffset1, cLRFemurHornOffset1, cLMRFemurHornOffset1, cLMFFemurHornOffset1, cLFFemurHornOffset1};
#define CFEMURHORNOFFSET1(LEGI) ((short)pgm_read_word(&cFemurHornOffset1[LEGI]))
#else // Fixed per leg, if not defined 0
#ifndef cFemurHornOffset1
#define cFemurHornOffset1 0
#endif
#define CFEMURHORNOFFSET1(LEGI) (cFemurHornOffset1)
#endif
#ifdef cRRTibiaHornOffset1 // per leg configuration
static const short cTibiaHornOffset1[] PROGMEM = {
cRRTibiaHornOffset1, cRMRTibiaHornOffset1, cRMFTibiaHornOffset1, cRFTibiaHornOffset1, cLRTibiaHornOffset1, cLMRTibiaHornOffset1, cLMFTibiaHornOffset1, cLFTibiaHornOffset1};
#define CTIBIAHORNOFFSET1(LEGI) ((short)pgm_read_word(&cTibiaHornOffset1[LEGI]))
#else // Fixed per leg, if not defined 0
#ifndef cTibiaHornOffset1
#define cTibiaHornOffset1 0
#endif
#define CTIBIAHORNOFFSET1(LEGI) (cTibiaHornOffset1)
#endif
#ifdef c4DOF
#ifdef cRRTarsHornOffset1 // per leg configuration
static const short cTarsHornOffset1[] PROGMEM = {
cRRTarsHornOffset1, cRMRTarsHornOffset1, cRMFTarsHornOffset1, cRFTarsHornOffset1, cLRTarsHornOffset1, cLMRTarsHornOffset1, cLMFTarsHornOffset1, cLFTarsHornOffset1};
#define CTARSHORNOFFSET1(LEGI) ((short)pgm_read_word(&cTarsHornOffset1[LEGI]))
#else // Fixed per leg, if not defined 0
#ifndef cTarsHornOffset1
#define cTarsHornOffset1 0
#endif
#define CTARSHORNOFFSET1(LEGI) cTarsHornOffset1
#endif
#endif
//Min / Max values
#ifndef SERVOS_DO_MINMAX
const short cCoxaMin1[] PROGMEM = {
cRRCoxaMin1, cRMRCoxaMin1, cRMFCoxaMin1, cRFCoxaMin1, cLRCoxaMin1, cLMRCoxaMin1, cLMFCoxaMin1, cLFCoxaMin1};
const short cCoxaMax1[] PROGMEM = {
cRRCoxaMax1, cRMRCoxaMax1, cRMFCoxaMax1, cRFCoxaMax1, cLRCoxaMax1, cLMRCoxaMax1, cLMFCoxaMax1, cLFCoxaMax1};
const short cFemurMin1[] PROGMEM ={
cRRFemurMin1, cRMRFemurMin1, cRMFFemurMin1, cRFFemurMin1, cLRFemurMin1, cLMRFemurMin1, cLMFFemurMin1, cLFFemurMin1};
const short cFemurMax1[] PROGMEM ={
cRRFemurMax1, cRMRFemurMax1, cRMFFemurMax1, cRFFemurMax1, cLRFemurMax1, cLMRFemurMax1, cLMFFemurMax1, cLFFemurMax1};
const short cTibiaMin1[] PROGMEM ={
cRRTibiaMin1, cRMRTibiaMin1, cRMFTibiaMin1, cRFTibiaMin1, cLRTibiaMin1, cLMRTibiaMin1, cLMFTibiaMin1, cLFTibiaMin1};
const short cTibiaMax1[] PROGMEM = {
cRRTibiaMax1, cRMRTibiaMax1, cRMFTibiaMax1, cRFTibiaMax1, cLRTibiaMax1, cLMRTibiaMax1, cLMFTibiaMax1, cLFTibiaMax1};
#ifdef c4DOF
const short cTarsMin1[] PROGMEM = {
cRRTarsMin1, cRMRTarsMin1, cRMFTarsMin1, cRFTarsMin1, cLRTarsMin1, cLMRTarsMin1, cLMFTarsMin1, cLFTarsMin1};
const short cTarsMax1[] PROGMEM = {
cRRTarsMax1, cRMRTarsMax1, cRMFTarsMax1, cRFTarsMax1, cLRTarsMax1, cLMRTarsMax1, cLMFTarsMax1, cLFTarsMax1};
#endif
#endif
// Servo inverse direction
const bool cCoxaInv[] = {cRRCoxaInv, cRMRCoxaInv, cRMFCoxaInv, cRFCoxaInv, cLRCoxaInv, cLMRCoxaInv, cLMFCoxaInv, cLFCoxaInv};
bool cFemurInv[] = {cRRFemurInv, cRMRFemurInv, cRMFFemurInv, cRFFemurInv, cLRFemurInv, cLMRFemurInv, cLMFFemurInv, cLFFemurInv};
const bool cTibiaInv[] = {cRRTibiaInv, cRMRTibiaInv, cRMFTibiaInv, cRFTibiaInv, cLRTibiaInv, cLMRTibiaInv, cLMFTibiaInv, cLFTibiaInv};
#ifdef c4DOF
const boolean cTarsInv[] = {cRRTarsInv, cRMRTarsInv, cRMFTarsInv, cRFTarsInv, cLRTarsInv, cLMRTarsInv, cLMFTarsInv, cLFTarsInv};
#endif
//Leg Lengths
const byte cCoxaLength[] PROGMEM = {
cRRCoxaLength, cRMRCoxaLength, cRMFCoxaLength, cRFCoxaLength, cLRCoxaLength, cLMRCoxaLength, cLMFCoxaLength, cLFCoxaLength};
const byte cFemurLength[] PROGMEM = {
cRRFemurLength, cRMRFemurLength, cRMFFemurLength, cRFFemurLength, cLRFemurLength, cLMRFemurLength, cLMFFemurLength, cLFFemurLength};
const byte cTibiaLength[] PROGMEM = {
cRRTibiaLength, cRMRTibiaLength, cRMFTibiaLength, cRFTibiaLength, cLRTibiaLength, cLMRTibiaLength, cLMFTibiaLength, cLFTibiaLength};
#ifdef c4DOF
const byte cTarsLength[] PROGMEM = {
cRRTarsLength, cRMRTarsLength, cRMFTarsLength, cRFTarsLength, cLRTarsLength, cLMRTarsLength, cLMFTarsLength, cLFTarsLength};
#endif
//Body Offsets [distance between the center of the body and the center of the coxa]
const short cOffsetX[] PROGMEM = {
cRROffsetX, cRMROffsetX, cRMFOffsetX, cRFOffsetX, cLROffsetX, cLMROffsetX, cLMFOffsetX, cLFOffsetX};
const short cOffsetZ[] PROGMEM = {
cRROffsetZ, cRMROffsetZ, cRMFOffsetZ, cRFOffsetZ, cLROffsetZ, cLMROffsetZ, cLMFOffsetZ, cLFOffsetZ};
//Default leg angle
const short cCoxaAngle1[] PROGMEM = {
cRRCoxaAngle1, cRMRCoxaAngle1, cRMFCoxaAngle1, cRFCoxaAngle1, cLRCoxaAngle1, cLMRCoxaAngle1, cLMFCoxaAngle1, cLFCoxaAngle1};
#ifdef cRRInitCoxaAngle1 // We can set different angles for the legs than just where they servo horns are set...
const short cCoxaInitAngle1[] PROGMEM = {
cRRInitCoxaAngle1, cRMRInitCoxaAngle1, cRMFInitCoxaAngle1, cRFInitCoxaAngle1, cLRInitCoxaAngle1, cLMRInitCoxaAngle1, cLMFInitCoxaAngle1, cLFInitCoxaAngle1};
#endif
//Start positions for the leg
const short cInitPosX[] PROGMEM = {
cRRInitPosX, cRMRInitPosX, cRMFInitPosX, cRFInitPosX, cLRInitPosX, cLMRInitPosX, cLMFInitPosX, cLFInitPosX};
const short cInitPosY[] PROGMEM = {
cRRInitPosY, cRMRInitPosY, cRMFInitPosY, cRFInitPosY, cLRInitPosY, cLMRInitPosY, cLMFInitPosY, cLFInitPosY};
const short cInitPosZ[] PROGMEM = {
cRRInitPosZ, cRMRInitPosZ, cRMFInitPosZ, cRFInitPosZ, cLRInitPosZ, cLMRInitPosZ, cLMFInitPosZ, cLFInitPosZ};
//=============================================================================
#else
// Quads...
// Servo Horn offsets
#ifdef cRRFemurHornOffset1 // per leg configuration
static const short cFemurHornOffset1[] PROGMEM = {
cRRFemurHornOffset1, cRFFemurHornOffset1, cLRFemurHornOffset1, cLFFemurHornOffset1};
#define CFEMURHORNOFFSET1(LEGI) ((short)pgm_read_word(&cFemurHornOffset1[LEGI]))
#else // Fixed per leg, if not defined 0
#ifndef cFemurHornOffset1
#define cFemurHornOffset1 0
#endif
#define CFEMURHORNOFFSET1(LEGI) (cFemurHornOffset1)
#endif
#ifdef cRRTibiaHornOffset1 // per leg configuration
static const short cTibiaHornOffset1[] PROGMEM = {
cRRTibiaHornOffset1, cRFTibiaHornOffset1, cLRTibiaHornOffset1, cLFTibiaHornOffset1};
#define CTIBIAHORNOFFSET1(LEGI) ((short)pgm_read_word(&cTibiaHornOffset1[LEGI]))
#else // Fixed per leg, if not defined 0
#ifndef cTibiaHornOffset1
#define cTibiaHornOffset1 0
#endif
#define CTIBIAHORNOFFSET1(LEGI) (cTibiaHornOffset1)
#endif
#ifdef c4DOF
#ifdef cRRTarsHornOffset1 // per leg configuration
static const short cTarsHornOffset1[] PROGMEM = {
cRRTarsHornOffset1, cRFTarsHornOffset1, cLRTarsHornOffset1, cLFTarsHornOffset1};
#define CTARSHORNOFFSET1(LEGI) ((short)pgm_read_word(&cTarsHornOffset1[LEGI]))
#else // Fixed per leg, if not defined 0
#ifndef cTarsHornOffset1
#define cTarsHornOffset1 0
#endif
#define CTARSHORNOFFSET1(LEGI) cTarsHornOffset1
#endif
#endif
//Min / Max values
#ifndef SERVOS_DO_MINMAX
const short cCoxaMin1[] PROGMEM = {
cRRCoxaMin1, cRFCoxaMin1, cLRCoxaMin1, cLFCoxaMin1};
const short cCoxaMax1[] PROGMEM = {
cRRCoxaMax1, cRFCoxaMax1, cLRCoxaMax1, cLFCoxaMax1};
const short cFemurMin1[] PROGMEM ={
cRRFemurMin1, cRFFemurMin1, cLRFemurMin1, cLFFemurMin1};
const short cFemurMax1[] PROGMEM ={
cRRFemurMax1, cRFFemurMax1, cLRFemurMax1, cLFFemurMax1};
const short cTibiaMin1[] PROGMEM ={
cRRTibiaMin1, cRFTibiaMin1, cLRTibiaMin1, cLFTibiaMin1};
const short cTibiaMax1[] PROGMEM = {
cRRTibiaMax1, cRFTibiaMax1, cLRTibiaMax1, cLFTibiaMax1};
#ifdef c4DOF
const short cTarsMin1[] PROGMEM = {
cRRTarsMin1, cRFTarsMin1, cLRTarsMin1, cLFTarsMin1};
const short cTarsMax1[] PROGMEM = {
cRRTarsMax1, cRFTarsMax1, cLRTarsMax1, cLFTarsMax1};
#endif
#endif
// Servo inverse direction
const bool cCoxaInv[] = {cRRCoxaInv, cRFCoxaInv, cLRCoxaInv, cLFCoxaInv};
bool cFemurInv[] = {cRRFemurInv, cRFFemurInv, cLRFemurInv, cLFFemurInv};
const bool cTibiaInv[] = {cRRTibiaInv, cRFTibiaInv, cLRTibiaInv, cLFTibiaInv};
#ifdef c4DOF
const boolean cTarsInv[] = {
cRRTarsInv, cRFTarsInv, cLRTarsInv, cLFTarsInv};
#endif
//Leg Lengths
const byte cCoxaLength[] PROGMEM = {
cRRCoxaLength, cRFCoxaLength, cLRCoxaLength, cLFCoxaLength};
const byte cFemurLength[] PROGMEM = {
cRRFemurLength, cRFFemurLength, cLRFemurLength, cLFFemurLength};
const byte cTibiaLength[] PROGMEM = {
cRRTibiaLength, cRFTibiaLength, cLRTibiaLength, cLFTibiaLength};
#ifdef c4DOF
const byte cTarsLength[] PROGMEM = {
cRRTarsLength, cRFTarsLength, cLRTarsLength, cLFTarsLength};
#endif
//Body Offsets [distance between the center of the body and the center of the coxa]
const short cOffsetX[] PROGMEM = {
cRROffsetX, cRFOffsetX, cLROffsetX, cLFOffsetX};
const short cOffsetZ[] PROGMEM = {
cRROffsetZ, cRFOffsetZ, cLROffsetZ, cLFOffsetZ};
//Default leg angle
const short cCoxaAngle1[] PROGMEM = {
cRRCoxaAngle1, cRFCoxaAngle1, cLRCoxaAngle1, cLFCoxaAngle1};
#ifdef cRRInitCoxaAngle1 // We can set different angles for the legs than just where they servo horns are set...
const short cCoxaInitAngle1[] PROGMEM = {
cRRInitCoxaAngle1, cRFInitCoxaAngle1, cLRInitCoxaAngle1, cLFInitCoxaAngle1};
#endif
//Start positions for the leg
const short cInitPosX[] PROGMEM = {
cRRInitPosX, cRFInitPosX, cLRInitPosX, cLFInitPosX};
const short cInitPosY[] PROGMEM = {
cRRInitPosY, cRFInitPosY, cLRInitPosY, cLFInitPosY};
const short cInitPosZ[] PROGMEM = {
cRRInitPosZ, cRFInitPosZ, cLRInitPosZ, cLFInitPosZ};
#endif
// Define some globals for debug information
boolean g_fShowDebugPrompt;
boolean g_fDebugOutput;
boolean g_fEnableServos = true;
//--------------------------------------------------------------------
//[REMOTE]
#ifndef cTravelDeadZone
#define cTravelDeadZone 4 //The deadzone for the analog input from the remote
#endif
//====================================================================
//[ANGLES]
short CoxaAngle1[CNT_LEGS]; //Actual Angle of the horizontal hip, decimals = 1
short FemurAngle1[CNT_LEGS]; //Actual Angle of the vertical hip, decimals = 1
short TibiaAngle1[CNT_LEGS]; //Actual Angle of the knee, decimals = 1
#ifdef c4DOF
short TarsAngle1[CNT_LEGS]; //Actual Angle of the knee, decimals = 1
#endif
//--------------------------------------------------------------------
//[POSITIONS SINGLE LEG CONTROL]
short LegPosX[CNT_LEGS]; //Actual X Posion of the Leg
short LegPosY[CNT_LEGS]; //Actual Y Posion of the Leg
short LegPosZ[CNT_LEGS]; //Actual Z Posion of the Leg
//--------------------------------------------------------------------
//[INPUTS]
//--------------------------------------------------------------------
//[GP PLAYER]
//--------------------------------------------------------------------
//[OUTPUTS]
boolean LedA; //Red
boolean LedB; //Green
boolean LedC; //Orange
boolean Eyes; //Eyes output
//--------------------------------------------------------------------
//[VARIABLES]
byte Index; //Index universal used
byte LegIndex; //Index used for leg Index Number
//GetSinCos / ArcCos
short AngleDeg1; //Input Angle in degrees, decimals = 1
short sin4; //Output Sinus of the given Angle, decimals = 4
short cos4; //Output Cosinus of the given Angle, decimals = 4
short AngleRad4; //Output Angle in radials, decimals = 4
//GetAtan2
short AtanX; //Input X
short AtanY; //Input Y
short Atan4; //ArcTan2 output
long XYhyp2; //Output presenting Hypotenuse of X and Y
//Body Inverse Kinematics
short PosX; //Input position of the feet X
short PosZ; //Input position of the feet Z
short PosY; //Input position of the feet Y
long BodyFKPosX; //Output Position X of feet with Rotation
long BodyFKPosY; //Output Position Y of feet with Rotation
long BodyFKPosZ; //Output Position Z of feet with Rotation
//Leg Inverse Kinematics
long IKFeetPosX; //Input position of the Feet X
long IKFeetPosY; //Input position of the Feet Y
long IKFeetPosZ; //Input Position of the Feet Z
boolean IKSolution; //Output true if the solution is possible
boolean IKSolutionWarning; //Output true if the solution is NEARLY possible
boolean IKSolutionError; //Output true if the solution is NOT possible
//--------------------------------------------------------------------
//[TIMING]
unsigned long lTimerStart; //Start time of the calculation cycles
unsigned long lTimerEnd; //End time of the calculation cycles
byte CycleTime; //Total Cycle time
word ServoMoveTime; //Time for servo updates
word PrevServoMoveTime; //Previous time for the servo updates
//--------------------------------------------------------------------
//[GLOABAL]
//--------------------------------------------------------------------
// Define our global Input Control State object
INCONTROLSTATE g_InControlState; // This is our global Input control state object...
// Define our ServoWriter class
ServoDriver g_ServoDriver; // our global servo driver class
boolean g_fLowVoltageShutdown; // If set the bot shuts down because the input voltage is to low
word Voltage;
//--boolean g_InControlState.fRobotOn; //Switch to turn on Phoenix
//--boolean g_InControlState.fPrev_RobotOn; //Previous loop state
//--------------------------------------------------------------------
//[Balance]
long TotalTransX;
long TotalTransZ;
long TotalTransY;
long TotalYBal1;
long TotalXBal1;
long TotalZBal1;
//[Single Leg Control]
boolean AllDown;
//[gait - State]
// Note: Information about the current gait is now part of the g_InControlState...
boolean TravelRequest; //Temp to check if the gait is in motion
long GaitPosX[CNT_LEGS]; //Array containing Relative X position corresponding to the Gait
long GaitPosY[CNT_LEGS]; //Array containing Relative Y position corresponding to the Gait
long GaitPosZ[CNT_LEGS]; //Array containing Relative Z position corresponding to the Gait
long GaitRotY[CNT_LEGS]; //Array containing Relative Y rotation corresponding to the Gait
//boolean GaitLegInAir[CNT_LEGS]; // True if leg is in the air
//byte GaitNextLeg; // The next leg which will be lifted
boolean fWalking; // True if the robot are walking
byte bExtraCycle; // Forcing some extra timed cycles for avoiding "end of gait bug"
#define cGPlimit 2 // GP=GaitPos testing different limits
boolean g_fRobotUpsideDown; // Is the robot upside down?
boolean fRobotUpsideDownPrev;
//=============================================================================
// Define our default standard Gaits
//=============================================================================
#ifndef DEFAULT_GAIT_SPEED
#define DEFAULT_GAIT_SPEED 50
#define DEFAULT_SLOW_GAIT 70
#endif
//cRR=0, cRF, cLR, cLF, CNT_LEGS};
#ifndef OVERWRITE_GAITS
#ifdef HEXMODE
// Hex Gaits
// Speed, Steps, Lifted, Front Down, Lifted Factor, Half Height, On Ground,
// Quad extra: COGAngleStart, COGAngleStep, CogRadius, COGCCW
// { RR, <RM> RF, LR, <LM>, LF}
#ifdef DISPLAY_GAIT_NAMES
extern "C" {
// Move the Gait Names to program space...
const char s_szGN1[] PROGMEM = "Ripple 12";
const char s_szGN2[] PROGMEM = "Tripod 8";
const char s_szGN3[] PROGMEM = "Tripple 12";
const char s_szGN4[] PROGMEM = "Tripple 16";
const char s_szGN5[] PROGMEM = "Wave 24";
const char s_szGN6[] PROGMEM = "Tripod 6";
};
#endif
PHOENIXGAIT APG[] = {
{DEFAULT_SLOW_GAIT, 12, 3, 2, 2, 8, 3, {7, 11, 3, 1, 5, 9} GATENAME(s_szGN1)}, // Ripple 12
{DEFAULT_SLOW_GAIT, 8, 3, 2, 2, 4, 3, {1, 5, 1, 5, 1, 5} GATENAME(s_szGN2)}, //Tripod 8 steps
{DEFAULT_GAIT_SPEED, 12, 3, 2, 2, 8, 3, {5, 10, 3, 11, 4, 9} GATENAME(s_szGN3) }, //Triple Tripod 12 step
{DEFAULT_GAIT_SPEED, 16, 5, 3, 4, 10, 1, {6, 13, 4, 14, 5, 12} GATENAME(s_szGN4)}, // Triple Tripod 16 steps, use 5 lifted positions
{DEFAULT_SLOW_GAIT, 24, 3, 2, 2, 20, 3, {13, 17, 21, 1, 5, 9} GATENAME(s_szGN5)}, //Wave 24 steps
{DEFAULT_GAIT_SPEED, 6, 2, 1, 2, 4, 1, {1, 4, 1, 4, 1, 4} GATENAME(s_szGN6)} //Tripod 6 steps
};
#elif defined(OCTOMODE)
// Octopod Gaits
// Speed, Steps, Lifted, Front Down, Lifted Factor, Half Height, On Ground,
// { RR, RMR, RMF, RF, LR, LMR, LMF, LF}
#ifdef DISPLAY_GAIT_NAMES
extern "C" {
// Move the Gait Names to program space...
const char s_szGN1[] PROGMEM = "Tripod 6";
};
#endif
PHOENIXGAIT APG[] = {
{DEFAULT_GAIT_SPEED, 6, 2, 1, 2, 4, 1, {1, 4, 1, 4, 4, 1, 4, 1} GATENAME(s_szGN1)} //Tripod 6 steps
};
#else
// Quad Gaits
#ifdef DISPLAY_GAIT_NAMES
extern "C" {
// Move the Gait Names to program space...
const char s_szGN1[] PROGMEM = "Ripple 12";
const char s_szGN2[] PROGMEM = "Tripod 8";
}
#endif
PHOENIXGAIT APG[] = {
{DEFAULT_GAIT_SPEED, 16, 3, 2, 2, 12, 3, 2250, 3600/16, 30, true, {5, 9, 1, 13} GATENAME(s_szGN1)}, // Wave 16
{1, 28, 3, 2, 2, 24, 3, 2250, 3600/28, 30, true, {8, 15, 1, 22} GATENAME(s_szGN2)} // Wave 28?
};
#endif
#endif
//--------------------------------------------------------------------
#ifdef ADD_GAITS
byte NUM_GAITS = sizeof(APG)/sizeof(APG[0]) + sizeof(APG_EXTRA)/sizeof(APG_EXTRA[0]);
#else
byte NUM_GAITS = sizeof(APG)/sizeof(APG[0]);
#endif
//=============================================================================
// Function prototypes
//=============================================================================
extern void GaitSelect(void);
extern void WriteOutputs(void);
extern void SingleLegControl(void);
extern void GaitSeq(void);
extern void BalanceBody(void);
extern void CheckAngles();
extern void PrintSystemStuff(void); // Try to see why we fault...
//extern void GaitGetNextLeg(byte GaitStep);
extern void BalCalcOneLeg (long PosX, long PosZ, long PosY, byte BalLegNr);
extern void BodyFK (short PosX, short PosZ, short PosY, short RotationY, byte BodyIKLeg) ;
extern void LegIK (short IKFeetPosX, short IKFeetPosY, short IKFeetPosZ, byte LegIKLegNr);
extern void Gait (byte GaitCurrentLegNr);
extern void GetSinCos(short AngleDeg1);
extern short GetATan2 (short AtanX, short AtanY);
extern unsigned long isqrt32 (unsigned long n);
extern void StartUpdateServos(void);
extern boolean TerminalMonitor(void);
//--------------------------------------------------------------------------
// SETUP: the main arduino setup function.
//--------------------------------------------------------------------------
void setup(){
#ifdef OPT_SKETCHSETUP
SketchSetup();
#endif
g_fShowDebugPrompt = true;
g_fDebugOutput = false;
#ifdef DBGSerial
DBGSerial.begin(38400);
#endif
// Init our ServoDriver
g_ServoDriver.Init();
//Checks to see if our Servo Driver support a GP Player
// DBGSerial.write("Program Start\n\r");
// debug stuff
delay(10);
//Turning off all the leds
LedA = 0;
LedB = 0;
LedC = 0;
Eyes = 0;
// Setup Init Positions
for (LegIndex= 0; LegIndex < CNT_LEGS; LegIndex++ )
{
LegPosX[LegIndex] = (short)pgm_read_word(&cInitPosX[LegIndex]); //Set start positions for each leg
LegPosY[LegIndex] = (short)pgm_read_word(&cInitPosY[LegIndex]);
LegPosZ[LegIndex] = (short)pgm_read_word(&cInitPosZ[LegIndex]);
}
ResetLegInitAngles();
//Single leg control. Make sure no leg is selected
#ifdef OPT_SINGLELEG
g_InControlState.SelectedLeg = 255; // No Leg selected
g_InControlState.PrevSelectedLeg = 255;
#endif
//Body Positions
g_InControlState.BodyPos.x = 0;
g_InControlState.BodyPos.y = 0;
g_InControlState.BodyPos.z = 0;
//Body Rotations
g_InControlState.BodyRot1.x = 0;
g_InControlState.BodyRot1.y = 0;
g_InControlState.BodyRot1.z = 0;
g_InControlState.BodyRotOffset.x = 0;
g_InControlState.BodyRotOffset.y = 0; //Input Y offset value to adjust centerpoint of rotation
g_InControlState.BodyRotOffset.z = 0;
//Gait
g_InControlState.GaitType = 0;
g_InControlState.BalanceMode = 0;
g_InControlState.LegLiftHeight = 50;
g_InControlState.ForceGaitStepCnt = 0; // added to try to adjust starting positions depending on height...
g_InControlState.GaitStep = 1;
GaitSelect();
#ifdef cTurretRotPin
g_InControlState.TurretRotAngle1 = cTurretRotInit; // Rotation of turrent in 10ths of degree
g_InControlState.TurretTiltAngle1 = cTurretTiltInit; // the tile for the turret
#endif
g_InputController.Init();
// Servo Driver
ServoMoveTime = 150;
g_InControlState.fRobotOn = 0;
g_fLowVoltageShutdown = false;
#ifdef DEBUG_IOPINS
// pinMode(A0, OUTPUT);
pinMode(A1, OUTPUT);
pinMode(A2, OUTPUT);
pinMode(A3, OUTPUT);
pinMode(A4, OUTPUT);
#endif
#ifdef OPT_WALK_UPSIDE_DOWN
g_fRobotUpsideDown = false; //Assume off...
#ifdef DBGSerial
DBGSerial.println(IsRobotUpsideDown, DEC);
#endif
#endif
}
//=============================================================================
// Loop: the main arduino main Loop function
//=============================================================================
void loop(void)
{
//Start time
unsigned long lTimeWaitEnd;
lTimerStart = millis();
DoBackgroundProcess();
//Read input
CheckVoltage(); // check our voltages...
if (!g_fLowVoltageShutdown) {
// DebugWrite(A0, HIGH);
g_InputController.ControlInput();
// DebugWrite(A0, LOW);
}
WriteOutputs(); // Write Outputs
#ifdef IsRobotUpsideDown
if (!fWalking){// dont do this while walking
g_fRobotUpsideDown = IsRobotUpsideDown; // Grab the current state of the robot...
if (g_fRobotUpsideDown != fRobotUpsideDownPrev) {
// Double check to make sure that it was not a one shot error
g_fRobotUpsideDown = IsRobotUpsideDown; // Grab the current state of the robot...
if (g_fRobotUpsideDown != fRobotUpsideDownPrev) {
fRobotUpsideDownPrev = g_fRobotUpsideDown;
#ifdef DGBSerial
DBGSerial.println(fRobotUpsideDownPrev, DEC);
#endif
}
}
}
// DBGSerial.println(analogRead(0), DEC);
#endif
#ifdef OPT_WALK_UPSIDE_DOWN
if (g_fRobotUpsideDown){
g_InControlState.TravelLength.x = -g_InControlState.TravelLength.x;
g_InControlState.BodyPos.x = -g_InControlState.BodyPos.x;
g_InControlState.SLLeg.x = -g_InControlState.SLLeg.x;
g_InControlState.BodyRot1.z = -g_InControlState.BodyRot1.z;
}
#endif
#ifdef OPT_GPPLAYER
//GP Player
g_ServoDriver.GPPlayer();
if (g_ServoDriver.FIsGPSeqActive())
return; // go back to process the next message
#endif
//Single leg control
SingleLegControl ();
DoBackgroundProcess();
//Gait
GaitSeq();
DoBackgroundProcess();
//Balance calculations
TotalTransX = 0; //reset values used for calculation of balance
TotalTransZ = 0;
TotalTransY = 0;
TotalXBal1 = 0;
TotalYBal1 = 0;
TotalZBal1 = 0;
if (g_InControlState.BalanceMode) {
#ifdef DEBUG
if (g_fDebugOutput) {
TravelRequest = (abs(g_InControlState.TravelLength.x)>cTravelDeadZone) || (abs(g_InControlState.TravelLength.z)>cTravelDeadZone)
|| (abs(g_InControlState.TravelLength.y)>cTravelDeadZone) || (g_InControlState.ForceGaitStepCnt != 0) || fWalking;
DBGSerial.print("T(");
DBGSerial.print(fWalking, DEC);
DBGSerial.print(" ");
DBGSerial.print(g_InControlState.TravelLength.x,DEC);
DBGSerial.print(",");
DBGSerial.print(g_InControlState.TravelLength.y,DEC);
DBGSerial.print(",");
DBGSerial.print(g_InControlState.TravelLength.z,DEC);
DBGSerial.print(")");
}
#endif
for (LegIndex = 0; LegIndex < (CNT_LEGS/2); LegIndex++) { // balance calculations for all Right legs
DoBackgroundProcess();
BalCalcOneLeg (-LegPosX[LegIndex]+GaitPosX[LegIndex], LegPosZ[LegIndex]+GaitPosZ[LegIndex],
(LegPosY[LegIndex]-(short)pgm_read_word(&cInitPosY[LegIndex]))+GaitPosY[LegIndex], LegIndex);
}
for (LegIndex = (CNT_LEGS/2); LegIndex < CNT_LEGS; LegIndex++) { // balance calculations for all Right legs
DoBackgroundProcess();
BalCalcOneLeg(LegPosX[LegIndex]+GaitPosX[LegIndex], LegPosZ[LegIndex]+GaitPosZ[LegIndex],
(LegPosY[LegIndex]-(short)pgm_read_word(&cInitPosY[LegIndex]))+GaitPosY[LegIndex], LegIndex);
}
BalanceBody();
}
//Reset IKsolution indicators
IKSolution = 0 ;
IKSolutionWarning = 0;
IKSolutionError = 0 ;
//Do IK for all Right legs
#ifdef DEBUG
if (g_fDebugOutput && g_InControlState.fRobotOn) {
DBGSerial.print(g_InControlState.GaitStep,DEC);
DBGSerial.print(":");
}
#endif
for (LegIndex = 0; LegIndex < (CNT_LEGS/2); LegIndex++) {
DoBackgroundProcess();
BodyFK(-LegPosX[LegIndex]+g_InControlState.BodyPos.x+GaitPosX[LegIndex] - TotalTransX,
LegPosZ[LegIndex]+g_InControlState.BodyPos.z+GaitPosZ[LegIndex] - TotalTransZ,
LegPosY[LegIndex]+g_InControlState.BodyPos.y+GaitPosY[LegIndex] - TotalTransY,
GaitRotY[LegIndex], LegIndex);
LegIK (LegPosX[LegIndex]-g_InControlState.BodyPos.x+BodyFKPosX-(GaitPosX[LegIndex] - TotalTransX),
LegPosY[LegIndex]+g_InControlState.BodyPos.y-BodyFKPosY+GaitPosY[LegIndex] - TotalTransY,
LegPosZ[LegIndex]+g_InControlState.BodyPos.z-BodyFKPosZ+GaitPosZ[LegIndex] - TotalTransZ, LegIndex);
}
//Do IK for all Left legs
for (LegIndex = (CNT_LEGS/2); LegIndex < CNT_LEGS; LegIndex++) {
DoBackgroundProcess();
BodyFK(LegPosX[LegIndex]-g_InControlState.BodyPos.x+GaitPosX[LegIndex] - TotalTransX,
LegPosZ[LegIndex]+g_InControlState.BodyPos.z+GaitPosZ[LegIndex] - TotalTransZ,
LegPosY[LegIndex]+g_InControlState.BodyPos.y+GaitPosY[LegIndex] - TotalTransY,
GaitRotY[LegIndex], LegIndex);
LegIK (LegPosX[LegIndex]+g_InControlState.BodyPos.x-BodyFKPosX+GaitPosX[LegIndex] - TotalTransX,
LegPosY[LegIndex]+g_InControlState.BodyPos.y-BodyFKPosY+GaitPosY[LegIndex] - TotalTransY,
LegPosZ[LegIndex]+g_InControlState.BodyPos.z-BodyFKPosZ+GaitPosZ[LegIndex] - TotalTransZ, LegIndex);
}
#ifdef OPT_WALK_UPSIDE_DOWN
if (g_fRobotUpsideDown){ //Need to set them back for not messing with the SmoothControl
g_InControlState.BodyPos.x = -g_InControlState.BodyPos.x;
g_InControlState.SLLeg.x = -g_InControlState.SLLeg.x;
g_InControlState.BodyRot1.z = -g_InControlState.BodyRot1.z;
}
#endif
//Check mechanical limits
CheckAngles();
//Write IK errors to leds
LedC = IKSolutionWarning;
LedA = IKSolutionError;
//Drive Servos
if (g_InControlState.fRobotOn) {
if (g_InControlState.fRobotOn && !g_InControlState.fPrev_RobotOn) {
MSound(3, 60, 2000, 80, 2250, 100, 2500);
#ifdef USEXBEE
XBeePlaySounds(3, 60, 2000, 80, 2250, 100, 2500);
#endif
Eyes = 1;
}
//Calculate Servo Move time
if ((abs(g_InControlState.TravelLength.x)>cTravelDeadZone) || (abs(g_InControlState.TravelLength.z)>cTravelDeadZone) ||
(abs(g_InControlState.TravelLength.y*2)>cTravelDeadZone)) {
ServoMoveTime = g_InControlState.gaitCur.NomGaitSpeed + (g_InControlState.InputTimeDelay*2) + g_InControlState.SpeedControl;
//Add aditional delay when Balance mode is on
if (g_InControlState.BalanceMode)
ServoMoveTime = ServoMoveTime + BALANCE_DELAY;
}
else //Movement speed excl. Walking
ServoMoveTime = 200 + g_InControlState.SpeedControl;
// note we broke up the servo driver into start/commit that way we can output all of the servo information
// before we wait and only have the termination information to output after the wait. That way we hopefully