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gpusnowxv.cpp
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gpusnowxv.cpp
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//copied from File snowx.f
// Subroutines and function subprograms for the Utah Energy Balance
// Snow Accumulation and Melt Model.
// David G. Tarboton, Utah Water Research Laboratory, Utah State University
//
// Last Change 9/9/12 to accommodate glacier melt.
//
//**********************************************************************************************
//
// Copyright (C) 2012 David Tarboton, Utah State University, dtarb@usu.edu. http://hydrology.usu.edu/dtarb
//
// This file is part of UEB.
//
// UEB is open source software: you can redistribute it and/or modify it under the terms of the
// MIT Open Source License as published by the Open Source Initiative https://opensource.org/licenses/MIT.
//
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to deal
// in the Software without restriction, including without limitation the rights
// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
// copies of the Software, and to permit persons to whom the Software is
// furnished to do so, subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in all
// copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
// SOFTWARE.
//
// If you wish to use or incorporate this program (or parts of it) into
// other software that does not meet the MIT Open Source License
// conditions contact the author to request permission.
// David G. Tarboton
// Utah State University
// 8200 Old Main Hill
// Logan, UT 84322-8200
// USA
// http://hydrology.edu/dtarb/
// email: dtarb@usu.edu
//
//**********************************************************************************************
//common declarations
#include "gpuuebpgdecls.h"
//********UPDATEtime () Update time for each time step
__host__ __device__ void uebCell::UPDATEtime(int &YEAR, int &MONTH, int &DAY, double &HOUR, double DT)
{
int DM; // 30/03/2004 ITB
// 30/03/2004 ITB
//real hour, dt // DGT Dec 10, 2004. Fixing ITB errors
int DMON[12] = {31,28,31,30,31,30,31,31,30,31,30,31};
HOUR = HOUR + DT;
DM = DMON[MONTH-1];
// check for leap years
if(MONTH == 2)
DM = lyear (YEAR);
while(HOUR >= 24.0)
{
HOUR = HOUR - 24.0;
DAY++;
}
while ( DAY > DM)
{
DAY = DAY - DM;
MONTH++;
if(MONTH>12){
MONTH = 1;
YEAR++;
}
//modified from the original by separating the above two lines in the if (month>12)
//#_6.27.13
DM = DMON[MONTH-1];
if(MONTH == 2)
DM= lyear(YEAR);
//}
}
return;
}
// ************************** lyear () ***************************
// function to return number of days in February checking for leap years
__host__ __device__ int uebCell::lyear(int year)
{
int lyear; // Leap years are every 4 years
// - except for years that are multiples of centuries (e.g. 1800, 1900)
// - except again that when the century is divisible by 4 (e.g. 1600, 2000)
if( (year % 4 > 0) || ((year % 100 == 0) && (year %400 != 0)))
lyear=28;
else
lyear=29;
return lyear;
}
//**************************** atf () ****************************
// to get the atmospheric transmissivity using the Bristow and Campbell (1984) approach
__host__ __device__ void uebCell::atf(float &atff,float trange,int month, float *dtbar, float a, float c)
{
//DIMENSION dtbar(12)
float b = 0.036* expf(-0.154*dtbar[month-1]);
atff = a*(1-expf(-b * powf(trange,c)));
// write(6,*)trange,month,a,c,dtbar(month),atf
return;
}
//************************** hourlyRI () To get hourly radiation index
__host__ __device__ void uebCell::hyri(int YEAR, int MONTH, int DAY, float HOUR, float DT, float SLOPE, float AZI, float LAT, float &HRI, float &COSZEN)
{
float LP,LAT1;
// lp= latitude of equivalent plane in radians
// lat1 = latitude in radians
// lat = latitude in degrees
// a number that speaks for itself - every kissable digit
float PI=3.141592653589793238462643383279502884197169399375105820974944592308;
float CRAD = PI/180.0;
// crad = degree to radian conversion factor
// CONVERT timeS TO RADIANS FROM NOON
float T = (HOUR-12.0)*PI/12.0;
float DELT1= DT*PI/12.0;
// CONVERT angles TO RADIANS
float SLOPE1=SLOPE*CRAD;
float AZI1=AZI*CRAD;
LAT1=LAT*CRAD;
float FJULIAN = (float) julian(YEAR,MONTH,DAY);
float D = CRAD*23.5* sin((FJULIAN-82.0)*0.017214206321);
// 0.017214206321 is 2 pi / 365
// D is solar declination
LP=asin(sin(SLOPE1)*cos(AZI1)*cos(LAT1) + cos(SLOPE1)*sin(LAT1));
// LP is latitude of equivalent plane
// TD=ACOS(-TAN(LAT1)*TAN(D)) This formula abandoned 1/8/04
// to make the code work for polar conditions
// TD is half day length, i.e. the time from noon to sunset. Sunrise is at -TD
float tanprod = tan(LAT1)* tan(D);
float td;
if(tanprod > 1.0)
td=PI; // This is the condition for perpetual light
else if(tanprod < -1.)
td=0; // The condition for perpetual night
else
td=acos(-tanprod); // The condition where there is a sunrise and set
// Equivalent longitude offset. Modified on 1/8/04
// so that it correctly accounts for shift in longitude if equivalent
// plane slope goes over a pole. Achieved using atan2.
// DDT=ATAN(sin(AZI1)*sin(SLOPE1)/(cos(SLOPE1)*cos(LAT1)
// * -cos(AZI1)*sin(SLOPE1)*sin(LAT1)))
float ddt= atan2(sin(AZI1)*sin(SLOPE1), (cos(SLOPE1)*cos(LAT1) - cos(AZI1)*sin(SLOPE1)*sin(LAT1)));
// Now similar logic as before needs to be repeated for equivalent plane
// but with times reflecting
float tpeqp = tan(LP)*tan(D);
// Keep track of beginning and end of exposure of equiv plane to sunlight
float tpbeg, tpend;
if(tpeqp > 1.0)
{
tpbeg = -PI; // perpetual light
tpend= PI;
}
else if (tpeqp < -1.)
{
tpbeg=0.0; // perpetual dark
tpend=0.0 ;
}
else
{
tpbeg = -acos(-tpeqp) - ddt;
tpend = acos(-tpeqp) - ddt;
}
// Start and end times for integration of radiation exposure
// need to account for both horizon, slope and time step
float T1, T2;
T1 = findMax(T,tpbeg);
T1 = findMax(T1,-td);
T2 = findMin(T+DELT1,td);
T2 = findMin(T2,tpend);
// write(6,*)t1,t2
if(T2 <= T1)
HRI=0.0;
else
HRI = (sin(D)*sin(LP)*(T2-T1) + cos(D)*cos(LP)*(sin(T2+ddt) - sin(T1+ddt)) ) / (cos(SLOPE1)*DELT1);
// In the above the divide by cos slope normalizes illumination to per unit horizontal area
// There is a special case if tpbeg is less than -pi that occurs in polar regions
// where a poleward facing slope may be illuminated at night more than the day.
// Add this in
if(tpbeg < -PI)
{
T1 = findMax(T, 2*PI-tpbeg);
T1 = findMax(T1,-td);
T2 = findMin(T+DELT1,td);
if(T2 > T1)
{
HRI = HRI + (sin(D)*sin(LP)*(T2-T1) + cos(D)*cos(LP)*(sin(T2+ddt) - sin(T1+ddt))) / (cos(SLOPE1)*DELT1);
}
}
// for the purposes of calculating albedo we need a cosine of the
// illumination angle. This does not have slope correction so back
// this out again. This is an average over the time step
COSZEN = HRI*cos(SLOPE1);
// write(6,*)hri,coszen
return;
}
//***************************** JULIAN () ****************************
// To convert the real date to julian date
// YJS The Julian are change to a new version to take the Leap Yean into consideration
// in the old version, there are 365 days each year.
// FUNCTION JULIAN(MONTH,DAY)
__host__ __device__ int uebCell::julian(int yy, int mm, int dd)
{
int julian;
int mmstrt[12] = {0,31,59,90,120,151,181,212,243,273,304,334};
int jday = mmstrt[mm-1] + dd;
int ileap = yy - ((int)(yy/4)) * 4 ;
if((ileap == 0) && (mm >=3))
jday = jday + 1;
julian = jday;
return julian;
}
//******************** For cloudiness fraction cf *********************
// Computes the incoming longwave radiation using satterlund Formula
// Modified 10/13/94 to account for cloudiness. Emissivity of cloud cover fraction is assumed to be 1.
__host__ __device__ void uebCell::cloud(float as, float bs, float atff, float &cf)
{
//as = param(28) // Fraction of extraterrestaial radiation on cloudy day,Shuttleworth (1993)
//bs = param(29) // (as+bs):Fraction of extraterrestaial radiation on clear day, Shuttleworth (1993)
if (atff >= (as+bs))
cf=0; // Cloudiness fraction
else if(atff <= as)
cf=1;
else
cf = 1.0 - (atff - as)/bs;
return;
}
//************************************ QLIF ()*********************************
//???? long wave radiation from temperatrue and other weather variables??
//TBC_6.5.13
__host__ __device__ void uebCell::qlif(float TA, float RH, float TK, float SBC, float &Ema, float &Eacl, float cf, float &qliff )
{
float TAK = TA + TK;
float EA = RH * svpw(TA);
//****************************************************** old option
//
Eacl = 1.08 * (1.0 - expf(-1*powf(EA/100.0, TAK/2016.0))); // Clear sky emissivity
Ema = (cf + (1.0 - cf)*Eacl); // Emissivity for cloudy sky
qliff = Ema * SBC * powf(TAK, 4.0); // Incoming longwave
return;
}
//The following were copied from functions.f90
//# 6.8.13
//THIS SUBROUTINE COMPUTES JULIAN DATE, GIVEN CALENDAR DATE AND time. INPUT CALENDAR DATE MUST BE GREGORIAN. INPUT time VALUE
//CAN BE IN ANY UT-LIKE time SCALE (UTC, UT1, TT, ETC.) - OUTPUT. //JULIAN DATE WILL HAVE SAME BASIS.
//ALGORITHM BY FLIEGEL AND //VAN FLANDERN. //SOURCE: http://aa.usno.navy.mil/software/novas/novas_f/novasf_intro.php
//I = YEAR (IN) //M = MONTH NUMBER (IN) //K = DAY OF MONTH (IN) //H = UT HOURS (IN) //TJD = JULIAN DATE (OUT)
__host__ __device__ double uebCell::julian(int I, int M, int K, double H)
{
double TJD,JD;
//JD=JULIAN DAY NO FOR DAY BEGINNING AT GREENWICH NOON ON GIVEN DATE
JD = K-32075 + 1461*(I+4800 + (M-14)/12) / 4 + 367*(M-2-(M-14)/12*12)/12-3*((I+4900+(M-14)/12)/100)/4;
TJD = JD - 0.5 + H/24.0;
//##%^_TBC 6.8.13 //powf(10,0) in place of D0
return TJD;
}
//THIS SUBROUTINE COMPUTES CALENDAR DATE AND time, GIVEN JULIAN DATE. INPUT JULIAN DATE CAN BE BASED ON ANY UT-LIKE time SCALE
//(UTC, UT1, TT, ETC.) - OUTPUT time VALUE WILL HAVE SAME BASIS. OUTPUT CALENDAR DATE WILL BE GREGORIAN.
//ALGORITHM BY FLIEGEL AND VAN FLANDERN. //SOURCE: http://aa.usno.navy.mil/software/novas/novas_f/novasf_intro.php
//TJD = JULIAN DATE (IN) //I = YEAR (OUT) //M = MONTH NUMBER (OUT) //K = DAY OF MONTH (OUT) //H = UT HOURS (OUT)
__host__ __device__ void uebCell::calendardate (double TJD,int &I,int &M,int &K, double &H)
{
double DJD, JD;
int L, N;
DJD = TJD + 0.5;
JD = DJD;
H = fmod(DJD,1.0)*24; // 24.D0
//JD=JULIAN DAY NO FOR DAY BEGINNING AT GREENWICH NOON ON GIVEN DATE
L = JD + 68569;
N = 4*L/146097;
L = L - (146097*N+3)/4;
//I=YEAR, M=MONTH, K=DAY
I = 4000*(L+1)/1461001;
L = L - 1461*I/4 + 31;
M = 80*L/2447;
K = L - 2447*M/80;
L = M / 11;
M = M + 2 - 12*L;
I = 100*(N-49) + I + L;
return;
}