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MakeLocalMetData.c
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MakeLocalMetData.c
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/*
* SUMMARY: MakeLocalMetData.c - Generates meteorological conditions
* USAGE: Part of DHSVM
*
* AUTHOR: Bart Nijssen
* ORG: University of Washington, Department of Civil Engineering
* E-MAIL: [email protected]
* ORIG-DATE: Apr-96
* DESCRIPTION: Generates meteorological conditions for each individual cell
* DESCRIP-END.
* FUNCTIONS: MakeLocalMetData()
* COMMENTS:
* $Id: MakeLocalMetData.c,v 1.5 2004/02/19 15:36:17 colleen Exp $
*/
#include <assert.h>
#include <math.h>
#include <stdio.h>
#include <stdlib.h>
#include "settings.h"
#include "data.h"
#include "snow.h"
#include "DHSVMerror.h"
#include "functions.h"
#include "constants.h"
#include "rad.h"
/*****************************************************************************
Function name: MakeLocalMetData()
Purpose : Generates meteorological for each individual cell
Required :
int y
int x
MAPSIZE Map
int DayStep
unsigned char PrecipType
int NStats
METLOCATION *Stat
uchar *MetWeights
float LocalElev
RADCLASSPIX *RadMap
PRECIPPIX *PrecipMap
MAPSIZE Radar
RADARPIX **RadarMap
Returns :
PIXMET LocalMet
Modifies :
Comments :
Reference: Shuttleworth, W.J., Evaporation, In: Maidment, D. R. (ed.),
Handbook of hydrology, 1993, McGraw-Hill, New York, etc..
*****************************************************************************/
PIXMET MakeLocalMetData(int y, int x, MAPSIZE * Map, int DayStep,
OPTIONSTRUCT * Options, int NStats,
METLOCATION * Stat, uchar * MetWeights,
float LocalElev, RADCLASSPIX * RadMap,
PRECIPPIX * PrecipMap, MAPSIZE * Radar,
RADARPIX ** RadarMap, float **PrismMap,
SNOWPIX * LocalSnow, SNOWTABLE * SnowAlbedo,
float ***MM5Input, float ***WindModel,
float **PrecipLapseMap, MET_MAP_PIX *** MetMap,
int NGraphics, int Month, float skyview,
unsigned char shadow, float SunMax,
float SineSolarAltitude)
{
float CurrentWeight; /* weight for current station */
float ScaleWind = 1; /* Wind to be scaled by model factors if
WindSource == MODEL */
float Temp; /* Temporary variable */
float WeightSum; /* sum of the weights */
int i; /* counter */
int RadarX; /* X coordinate of radar map coordinate */
int RadarY; /* Y coordinate of radar map coordinate */
float TempLapseRate;
int WindDirection = 0; /* Direction of model wind */
PIXMET LocalMet; /* local met data */
LocalMet.Tair = 0.0;
LocalMet.Rh = 0.0;
LocalMet.Wind = 0.0;
LocalMet.Sin = 0.0;
LocalMet.SinBeam = 0.0;
LocalMet.SinDiffuse = 0.0;
LocalMet.Lin = 0.0;
TempLapseRate = 0.0;
if (Options->MM5 == TRUE && Options->QPF == TRUE) {
WeightSum = 0.0;
for (i = 0; i < NStats; i++)
WeightSum += (float) MetWeights[i];
}
if (Options->MM5 == TRUE) {
LocalMet.Tair = MM5Input[MM5_temperature - 1][y][x] +
(LocalElev - MM5Input[MM5_terrain - 1][y][x]) * MM5Input[MM5_lapse -
1][y][x];
LocalMet.Rh = MM5Input[MM5_humidity - 1][y][x];
LocalMet.Wind = MM5Input[MM5_wind - 1][y][x];
LocalMet.Sin = MM5Input[MM5_shortwave - 1][y][x];
if (Options->Shading == TRUE) {
if (SunMax > 0.0) {
SeparateRadiation(LocalMet.Sin, LocalMet.Sin / SunMax,
&(LocalMet.SinBeam), &(LocalMet.SinDiffuse));
}
else {
/* if sun is below horizon, the force all shortwave to zero */
LocalMet.Sin = 0.0;
LocalMet.SinBeam = 0.0;
LocalMet.SinDiffuse = 0.0;
}
}
LocalMet.Lin = MM5Input[MM5_longwave - 1][y][x];
LocalMet.Press = 101300.0;
PrecipMap->Precip = MM5Input[MM5_precip - 1][y][x];
/* if(LocalMet.Sin>0) {
printf("LocalMet.Sin, LocalMet.Lin are: %f %f \n",LocalMet.Sin, LocalMet.Lin);
} */
}
else { /* MM5 is false and we need to interpolate the basic met records */
WeightSum = 0.0;
for (i = 0; i < NStats; i++) {
WeightSum += (float) MetWeights[i];
if (Options->WindSource == MODEL && Stat[i].IsWindModelLocation) {
ScaleWind = Stat[i].Data.Wind;
WindDirection = Stat[i].Data.WindDirection;
}
}
for (i = 0; i < NStats; i++) {
CurrentWeight = ((float) MetWeights[i]) / WeightSum;
LocalMet.Tair += CurrentWeight *
LapseT(Stat[i].Data.Tair, Stat[i].Elev, LocalElev,
Stat[i].Data.TempLapse);
LocalMet.Rh += CurrentWeight * Stat[i].Data.Rh;
if (Options->WindSource == STATION)
LocalMet.Wind += CurrentWeight * Stat[i].Data.Wind;
LocalMet.Lin += CurrentWeight * Stat[i].Data.Lin;
LocalMet.Sin += CurrentWeight * Stat[i].Data.Sin;
if (Options->Shading == TRUE) {
LocalMet.SinBeam += CurrentWeight * Stat[i].Data.SinBeamObs;
LocalMet.SinDiffuse += CurrentWeight * Stat[i].Data.SinDiffuseObs;
}
TempLapseRate += CurrentWeight * Stat[i].Data.TempLapse;
}
if (Options->WindSource == MODEL)
LocalMet.Wind = ScaleWind * WindModel[WindDirection - 1][y][x];
if (Options->PrecipType == RADAR) {
RadarY = (int) ((y + Radar->OffsetY) * Map->DY / Radar->DY);
RadarX = (int) ((x - Radar->OffsetX) * Map->DX / Radar->DX);
PrecipMap->Precip = RadarMap[RadarY][RadarX].Precip;
}
/* WORK IN PROGRESS, taken from old DHSVM version */
/* Air pressure */
/* In rare cases - i.e. when the lapse rate has a different sign for
different met stations - you can end up with a TemplapseRate of 0.0
This will result in a crash, so a check was put in (Jul 28, 1997 - Bart
Nijssen). It is somewhat awkward to interpolate lapse rates anyway, so
a better way of doing this would be welcome */
if (TempLapseRate != 0.0) {
Temp = 9.8067 / (TempLapseRate * 287.0);
LocalMet.Press =
101300. * pow(((288.0 - TempLapseRate * LocalElev) / 288.0), Temp);
}
else
LocalMet.Press = 101300.;
} /* end of else MM5==TRUE, i.e. all basic met, except for precip */
/* has been interpolated */
/* Here is how the following section works */
/* Arc-Info (through use of the hillshade command) will give */
/* an output file that ranges from 0 to 255 (the shade factor) */
/* These correspond to the reflectance of the direct beam radiation */
/* for a given sun position (altitude and azimuth) taking */
/* into account the slope and aspect and topographic shading */
/* of the local pixel. If we wanted to use this value directly */
/* then the correction to the observed beam w.r.t. a horizontal plane */
/* would be actual = horizontal*shadefactor/255/sin(solar_altitude) */
/* the sin(solar_altitude) is necessary to convert horizontal into the maximum */
/* possible flux */
/* We can either have DHSVM make the solar_altitude calculation, which */
/* is not all that hard, but is prone to user error (e.g. GMT time shifts, etc) */
/* or we can simply include the solar_altitude info in the shade_factor */
/* the question is how do we include the sin(solar_altitude) while */
/* keeping new_shade_factor = shadefactor/255/sin(solar_altitude) defined */
/* as a unsigned character */
/* Answer: At sal = 5 degrees max_new_shadefactor = 11.47 */
/* i.e. the actual flux normal to sal is 11.47*observed_horizontal_flux */
/* if we adopt this 5 degree value as a cutoff, we can then be assured that */
/* 0<=newshadefactor<=11.47 and then scale it between 0 and 255 */
/* the final calculation becomes, */
/* actual = horizontal*(float)shadefactor/255.0*11.47 or simply
acutal = horizontal*(float)shadefactor/22.23191 */
/* thus radiation increases from 0 to 11.47 times the observed value in */
/* increments of 4.5 percent */
/* a finer resolution than this would require a higher min angle or more memory */
if (Options->Shading == TRUE) {
LocalMet.SinBeam = LocalMet.Sin * (float) shadow / 22.23191;
LocalMet.SinDiffuse *= skyview;
if (LocalMet.SinBeam + LocalMet.SinDiffuse > SOLARCON)
LocalMet.SinBeam = SOLARCON - LocalMet.SinDiffuse;
}
else {
LocalMet.SinBeam = LocalMet.Sin;
LocalMet.SinDiffuse = 0;
}
RadMap->Beam = LocalMet.SinBeam;
RadMap->Diffuse = LocalMet.SinDiffuse;
LocalMet.Sin = RadMap->Beam + RadMap->Diffuse;
if (Options->QPF == TRUE || Options->MM5 == FALSE) {
if (Options->PrecipType == STATION && Options->Prism == FALSE) {
PrecipMap->Precip = 0.0;
for (i = 0; i < NStats; i++) {
CurrentWeight = ((float) MetWeights[i]) / WeightSum;
if (Options->PrecipLapse == MAP)
PrecipMap->Precip += CurrentWeight *
LapsePrecip(Stat[i].Data.Precip, 0, 1, PrecipLapseMap[y][x]);
else
PrecipMap->Precip += CurrentWeight *
LapsePrecip(Stat[i].Data.Precip, Stat[i].Elev, LocalElev,
Stat[i].Data.PrecipLapse);
}
}
else if (Options->PrecipType == STATION && Options->Prism == TRUE) {
PrecipMap->Precip = 0.0;
for (i = 0; i < NStats; i++) {
CurrentWeight = ((float) MetWeights[i]) / WeightSum;
/* this is the real prism interpolation */
/* note that X = position from left boundary, ie # of columns */
/* note that Y = position from upper boundary, ie # of rows */
if (Options->Outside == FALSE)
PrecipMap->Precip +=
CurrentWeight * Stat[i].Data.Precip /
PrismMap[Stat[i].Loc.N][Stat[i].Loc.E] * PrismMap[y][x];
else
PrecipMap->Precip +=
CurrentWeight * Stat[i].Data.Precip /
Stat[i].PrismPrecip[Month - 1] * PrismMap[y][x];
if(PrismMap[y][x] < 0){
printf("negative PrismMap value in MakeLocalMetData.c\n");
exit(0);
}
}
}
}
/* due to the nature of the interpolation scheme in DHSVM and the */
/* interpolation scheme to handle the mess of different formats of met stations */
/* in the PRISM project */
/* relative humidities can be quite low when precip is occuring */
/* at times this will results in PET being greater than precip */
/* allow an option in DHSVM to override RH if Precip is occuring */
if (Options->Rhoverride == TRUE) {
if (PrecipMap->Precip > 0.0)
LocalMet.Rh = 100.0;
}
/* Separate precipitation into rainfall and snowfall */
if (PrecipMap->Precip > 0.0 && LocalMet.Tair < MAX_SNOW_TEMP) {
if (LocalMet.Tair > MIN_RAIN_TEMP)
PrecipMap->SnowFall = PrecipMap->Precip *
(MAX_SNOW_TEMP - LocalMet.Tair) / (MAX_SNOW_TEMP - MIN_RAIN_TEMP);
else
PrecipMap->SnowFall = PrecipMap->Precip;
}
else
PrecipMap->SnowFall = 0.0;
PrecipMap->RainFall = PrecipMap->Precip - PrecipMap->SnowFall;
/* Local heat of vaporization, Eq. 4.2.1, Shuttleworth (1993) */
LocalMet.Lv = 2501000 - 2361 * LocalMet.Tair;
/* Psychrometric constant */
LocalMet.Gamma = CP * LocalMet.Press / (EPS * LocalMet.Lv);
/* Saturated vapor pressure, Eq. 4.2.2, Shuttleworth (1993) */
LocalMet.Es = SatVaporPressure(LocalMet.Tair);
/* Slope of vapor pressure curve, Eq. 4.2.3, Shuttleworth (1993) */
LocalMet.Slope = 4098.0 * LocalMet.Es /
((237.3 + LocalMet.Tair) * (237.3 + LocalMet.Tair));
/* Actual vapor pressure */
LocalMet.Eact = LocalMet.Es * (LocalMet.Rh / 100.);
/* Vapor pressure deficit */
LocalMet.Vpd = LocalMet.Es - LocalMet.Eact;
/* Air density, Eq. 4.2.4 Shuttleworth (1993) */
LocalMet.AirDens = 0.003486 * LocalMet.Press / (275 + LocalMet.Tair);
if (LocalSnow->HasSnow) {
if (PrecipMap->SnowFall > 0.0)
LocalSnow->LastSnow = 0;
else
LocalSnow->LastSnow++;
LocalSnow->Albedo = CalcSnowAlbedo(LocalSnow->TSurf, LocalSnow->LastSnow,
SnowAlbedo);
}
else
LocalSnow->LastSnow = 0;
if (NGraphics > 0) {
(*MetMap)[y][x].accum_precip =
(*MetMap)[y][x].accum_precip + PrecipMap->Precip;
(*MetMap)[y][x].air_temp = LocalMet.Tair;
(*MetMap)[y][x].wind_speed = LocalMet.Wind;
(*MetMap)[y][x].humidity = LocalMet.Rh;
}
return LocalMet;
}