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#ifndef lint |
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static const char RCSid[] = "$Id$"; |
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#endif |
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/* Copyright (c) 1994 *Fraunhofer Institut for Solar Energy Systems |
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* Oltmannstr 5, D-79100 Freiburg, Germany |
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/* Copyright (c) 1994,2006 *Fraunhofer Institut for Solar Energy Systems |
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* Heidenhofstr. 2, D-79110 Freiburg, Germany |
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* *Agence de l'Environnement et de la Maitrise de l'Energie |
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* Centre de Valbonne, 500 route des Lucioles, 06565 Sophia Antipolis Cedex, France |
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* *BOUYGUES |
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* 1 Avenue Eugene Freyssinet, Saint-Quentin-Yvelines, France |
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*/ |
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|
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|
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|
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/* |
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* gendaylit.c program to generate the angular distribution of the daylight. |
16 |
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* Our zenith is along the Z-axis, the X-axis |
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* points east, and the Y-axis points north. |
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*/ |
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|
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#define _USE_MATH_DEFINES |
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#include <stdio.h> |
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#include <string.h> |
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#include <math.h> |
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#include <stdlib.h> |
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#include <ctype.h> |
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|
26 |
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#include "rtio.h" |
27 |
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#include "fvect.h" |
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#include "color.h" |
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#include "sun.h" |
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#include "paths.h" |
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|
19 |
< |
extern int jdate(int month, int day); |
32 |
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extern double stadj(int jd); |
33 |
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extern double sdec(int jd); |
34 |
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extern double salt(double sd, double st); |
35 |
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extern double sazi(double sd, double st); |
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#define DOT(v1,v2) (v1[0]*v2[0]+v1[1]*v2[1]+v1[2]*v2[2]) |
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|
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double normsc(); |
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|
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#define DATFILE "coeff_perez.dat" |
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/*static char *rcsid="$Header$";*/ |
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|
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float coeff_perez[] = { |
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1.3525,-0.2576,-0.2690,-1.4366,-0.7670,0.0007,1.2734,-0.1233,2.8000,0.6004,1.2375,1.000,1.8734,0.6297, |
27 |
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0.9738,0.2809,0.0356,-0.1246,-0.5718,0.9938,-1.2219,-0.7730,1.4148,1.1016,-0.2054,0.0367,-3.9128,0.9156, |
28 |
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6.9750,0.1774,6.4477,-0.1239,-1.5798,-0.5081,-1.7812,0.1080,0.2624,0.0672,-0.2190,-0.4285,-1.1000,-0.2515, |
29 |
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0.8952,0.0156,0.2782,-0.1812,-4.5000,1.1766,24.7219,-13.0812,-37.7000,34.8438,-5.0000,1.5218,3.9229, |
30 |
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-2.6204,-0.0156,0.1597,0.4199,-0.5562,-0.5484,-0.6654,-0.2672,0.7117,0.7234,-0.6219,-5.6812,2.6297, |
31 |
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33.3389,-18.3000,-62.2500,52.0781,-3.5000,0.0016,1.1477,0.1062,0.4659,-0.3296,-0.0876,-0.0329,-0.6000, |
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-0.3566,-2.5000,2.3250,0.2937,0.0496,-5.6812,1.8415,21.0000,-4.7656,-21.5906,7.2492,-3.5000,-0.1554, |
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1.4062,0.3988,0.0032,0.0766,-0.0656,-0.1294,-1.0156,-0.3670,1.0078,1.4051,0.2875,-0.5328,-3.8500,3.3750, |
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14.0000,-0.9999,-7.1406,7.5469,-3.4000,-0.1078,-1.0750,1.5702,-0.0672,0.4016,0.3017,-0.4844,-1.0000, |
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0.0211,0.5025,-0.5119,-0.3000,0.1922,0.7023,-1.6317,19.0000,-5.0000,1.2438,-1.9094,-4.0000,0.0250,0.3844, |
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0.2656,1.0468,-0.3788,-2.4517,1.4656,-1.0500,0.0289,0.4260,0.3590,-0.3250,0.1156,0.7781,0.0025,31.0625, |
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-14.5000,-46.1148,55.3750,-7.2312,0.4050,13.3500,0.6234,1.5000,-0.6426,1.8564,0.5636}; |
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|
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float defangle_theta[] = { |
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84, 84, 84, 84, 84, 84, 84, 84, 84, 84, 84, 84, 84, 84, 84, 84, 84, 84, 84, 84, 84, 84, 84, 84, 84, 84, |
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84, 84, 84, 84, 72, 72, 72, 72, 72, 72, 72, 72, 72, 72, 72, 72, 72, 72, 72, 72, 72, 72, 72, 72, 72, 72, |
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72, 72, 72, 72, 72, 72, 72, 72, 60, 60, 60, 60, 60, 60, 60, 60, 60, 60, 60, 60, 60, 60, 60, 60, 60, 60, |
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60, 60, 60, 60, 60, 60, 48, 48, 48, 48, 48, 48, 48, 48, 48, 48, 48, 48, 48, 48, 48, 48, 48, 48, 48, 48, |
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48, 48, 48, 48, 36, 36, 36, 36, 36, 36, 36, 36, 36, 36, 36, 36, 36, 36, 36, 36, 36, 36, 24, 24, 24, 24, |
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24, 24, 24, 24, 24, 24, 24, 24, 12, 12, 12, 12, 12, 12, 0}; |
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|
48 |
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float defangle_phi[] = { |
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0, 12, 24, 36, 48, 60, 72, 84, 96, 108, 120, 132, 144, 156, 168, 180, 192, 204, 216, 228, 240, 252, 264, |
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276, 288, 300, 312, 324, 336, 348, 0, 12, 24, 36, 48, 60, 72, 84, 96, 108, 120, 132, 144, 156, 168, 180, |
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192, 204, 216, 228, 240, 252, 264, 276, 288, 300, 312, 324, 336, 348, 0, 15, 30, 45, 60, 75, 90, 105, |
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120, 135, 150, 165, 180, 195, 210, 225, 240, 255, 270, 285, 300, 315, 330, 345, 0, 15, 30, 45, 60, 75, |
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90, 105, 120, 135, 150, 165, 180, 195, 210, 225, 240, 255, 270, 285, 300, 315, 330, 345, 0, 20, 40, 60, |
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80, 100, 120, 140, 160, 180, 200, 220, 240, 260, 280, 300, 320, 340, 0, 30, 60, 90, 120, 150, 180, 210, |
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240, 270, 300, 330, 0, 60, 120, 180, 240, 300, 0}; |
56 |
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|
57 |
+ |
|
58 |
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|
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/* Perez sky parametrization : epsilon and delta calculations from the direct and diffuse irradiances */ |
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double sky_brightness(); |
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double sky_clearness(); |
46 |
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void computesky(); |
62 |
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|
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/* calculation of the direct and diffuse components from the Perez parametrization */ |
64 |
< |
double diffus_irradiance_from_sky_brightness(); |
64 |
> |
double diffuse_irradiance_from_sky_brightness(); |
65 |
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double direct_irradiance_from_sky_clearness(); |
66 |
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|
67 |
+ |
/* Perez global horizontal, diffuse horizontal and direct normal luminous efficacy models : */ |
68 |
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/* input w(cm)=2cm, solar zenith angle(degrees); output efficacy(lm/W) */ |
69 |
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|
53 |
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/* Perez global horizontal, diffuse horizontal and direct normal luminous efficacy models : input w(cm)=2cm, solar zenith angle(degrees); output efficacy(lm/W) */ |
70 |
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double glob_h_effi_PEREZ(); |
71 |
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double glob_h_diffuse_effi_PEREZ(); |
72 |
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double direct_n_effi_PEREZ(); |
73 |
+ |
|
74 |
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/*likelihood check of the epsilon, delta, direct and diffuse components*/ |
75 |
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void check_parametrization(); |
76 |
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void check_irradiances(); |
77 |
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void check_illuminances(); |
78 |
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void illu_to_irra_index(); |
79 |
+ |
void print_error_sky(); |
80 |
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|
81 |
< |
|
82 |
< |
/* Perez sky luminance model */ |
65 |
< |
int lect_coeff_perez(char *filename,float **coeff_perez); |
66 |
< |
double calc_rel_lum_perez(double dzeta,double gamma,double Z, |
67 |
< |
double epsilon,double Delta,float *coeff_perez); |
68 |
< |
/* coefficients for the sky luminance perez model */ |
69 |
< |
void coeff_lum_perez(double Z, double epsilon, double Delta, float *coeff_perez); |
81 |
> |
double calc_rel_lum_perez(double dzeta,double gamma,double Z,double epsilon,double Delta,float coeff_perez[]); |
82 |
> |
void coeff_lum_perez(double Z, double epsilon, double Delta, float coeff_perez[]); |
83 |
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double radians(double degres); |
84 |
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double degres(double radians); |
85 |
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void theta_phi_to_dzeta_gamma(double theta,double phi,double *dzeta,double *gamma, double Z); |
86 |
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double integ_lv(float *lv,float *theta); |
74 |
– |
float *theta_ordered(char *filename); |
75 |
– |
float *phi_ordered(char *filename); |
76 |
– |
void skip_comments(FILE *fp); |
87 |
|
|
88 |
+ |
void printdefaults(); |
89 |
+ |
void check_sun_position(); |
90 |
+ |
void computesky(); |
91 |
+ |
void printhead(int ac, char** av); |
92 |
+ |
void userror(char* msg); |
93 |
+ |
void printsky(); |
94 |
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|
95 |
+ |
FILE * frlibopen(char* fname); |
96 |
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|
97 |
|
/* astronomy and geometry*/ |
98 |
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double get_eccentricity(); |
99 |
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double air_mass(); |
83 |
– |
double get_angle_sun_direction(double sun_zenith, double sun_azimut, double direction_zenith, double direction_azimut); |
100 |
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|
101 |
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|
102 |
< |
/* date*/ |
101 |
> |
double solar_sunset(); |
102 |
> |
double solar_sunrise(); |
103 |
> |
double stadj(); |
104 |
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int jdate(int month, int day); |
105 |
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|
106 |
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|
107 |
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91 |
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|
92 |
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|
108 |
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/* sun calculation constants */ |
109 |
< |
extern double s_latitude; |
110 |
< |
extern double s_longitude; |
111 |
< |
extern double s_meridian; |
109 |
> |
extern double s_latitude; |
110 |
> |
extern double s_longitude; |
111 |
> |
extern double s_meridian; |
112 |
|
|
113 |
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const double AU = 149597890E3; |
114 |
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const double solar_constant_e = 1367; /* solar constant W/m^2 */ |
117 |
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const double half_sun_angle = 0.2665; |
118 |
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const double half_direct_angle = 2.85; |
119 |
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|
120 |
< |
const double skyclearinf = 1.000; /* limitations for the variation of the Perez parameters */ |
120 |
> |
const double skyclearinf = 1.0; /* limitations for the variation of the Perez parameters */ |
121 |
|
const double skyclearsup = 12.1; |
122 |
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const double skybriginf = 0.01; |
123 |
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const double skybrigsup = 0.6; |
133 |
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|
134 |
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|
135 |
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/* definition of the sky conditions through the Perez parametrization */ |
136 |
< |
double skyclearness, skybrightness; |
137 |
< |
double solarradiance; /*radiance of the sun disk and of the circumsolar area*/ |
138 |
< |
double diffusilluminance, directilluminance, diffusirradiance, directirradiance; |
139 |
< |
double sunzenith, daynumber=150, atm_preci_water=2; |
136 |
> |
double skyclearness = 0; |
137 |
> |
double skybrightness = 0; |
138 |
> |
double solarradiance; |
139 |
> |
double diffuseilluminance, directilluminance, diffuseirradiance, directirradiance, globalirradiance; |
140 |
> |
double sunzenith, daynumber, atm_preci_water=2; |
141 |
|
|
142 |
< |
double diffnormalization, dirnormalization; |
142 |
> |
/*double sunaltitude_border = 0;*/ |
143 |
> |
double diffnormalization = 0; |
144 |
> |
double dirnormalization = 0; |
145 |
|
double *c_perez; |
146 |
|
|
147 |
< |
int output=0; /*define the unit of the output (sky luminance or radiance): visible watt=0, solar watt=1, lumen=2*/ |
148 |
< |
int input=0; /*define the input for the calulation*/ |
147 |
> |
int output=0; /* define the unit of the output (sky luminance or radiance): */ |
148 |
> |
/* visible watt=0, solar watt=1, lumen=2 */ |
149 |
> |
int input=0; /* define the input for the calulation */ |
150 |
|
|
151 |
+ |
int suppress_warnings=0; |
152 |
+ |
|
153 |
|
/* default values */ |
154 |
< |
int cloudy = 0; /* 1=standard, 2=uniform */ |
155 |
< |
int dosun = 1; |
154 |
> |
int cloudy = 0; /* 1=standard, 2=uniform */ |
155 |
> |
int dosun = 1; |
156 |
|
double zenithbr = -1.0; |
157 |
|
double betaturbidity = 0.1; |
158 |
|
double gprefl = 0.2; |
160 |
|
|
161 |
|
/* computed values */ |
162 |
|
double sundir[3]; |
163 |
< |
double groundbr; |
163 |
> |
double groundbr = 0; |
164 |
|
double F2; |
165 |
|
double solarbr = 0.0; |
166 |
|
int u_solar = 0; /* -1=irradiance, 1=radiance */ |
167 |
+ |
float timeinterval = 0; |
168 |
|
|
169 |
< |
char *progname; |
170 |
< |
char errmsg[128]; |
169 |
> |
char *progname; |
170 |
> |
char errmsg[128]; |
171 |
|
|
172 |
|
|
173 |
< |
main(argc, argv) |
174 |
< |
int argc; |
175 |
< |
char *argv[]; |
173 |
> |
|
174 |
> |
|
175 |
> |
int main(int argc, char** argv) |
176 |
|
{ |
177 |
|
int i; |
178 |
|
|
179 |
|
progname = argv[0]; |
180 |
|
if (argc == 2 && !strcmp(argv[1], "-defaults")) { |
181 |
|
printdefaults(); |
182 |
< |
exit(0); |
182 |
> |
return 0; |
183 |
|
} |
184 |
|
if (argc < 4) |
185 |
|
userror("arg count"); |
206 |
|
cloudy = 0; |
207 |
|
dosun = argv[i][0] == '+'; |
208 |
|
break; |
187 |
– |
case 'r': |
209 |
|
case 'R': |
210 |
|
u_solar = argv[i][1] == 'R' ? -1 : 1; |
211 |
|
solarbr = atof(argv[++i]); |
217 |
|
case 't': |
218 |
|
betaturbidity = atof(argv[++i]); |
219 |
|
break; |
220 |
+ |
case 'w': |
221 |
+ |
suppress_warnings = 1; |
222 |
+ |
break; |
223 |
|
case 'b': |
224 |
|
zenithbr = atof(argv[++i]); |
225 |
|
break; |
235 |
|
case 'm': |
236 |
|
s_meridian = atof(argv[++i]) * (M_PI/180); |
237 |
|
break; |
214 |
– |
|
238 |
|
|
239 |
|
case 'O': |
240 |
|
output = atof(argv[++i]); /*define the unit of the output of the program : |
241 |
< |
sky and sun luminance/radiance (0==W visible, 1==W solar radiation, 2==lm) |
219 |
< |
default is set to 0*/ |
241 |
> |
sky and sun luminance/radiance (0==W visible, 1==W solar radiation, 2==lm) */ |
242 |
|
break; |
243 |
|
|
244 |
|
case 'P': |
250 |
|
case 'W': /* direct normal Irradiance [W/m^2] */ |
251 |
|
input = 1; /* diffuse horizontal Irrad. [W/m^2] */ |
252 |
|
directirradiance = atof(argv[++i]); |
253 |
< |
diffusirradiance = atof(argv[++i]); |
253 |
> |
diffuseirradiance = atof(argv[++i]); |
254 |
|
break; |
255 |
|
|
256 |
|
case 'L': /* direct normal Illuminance [Lux] */ |
257 |
|
input = 2; /* diffuse horizontal Ill. [Lux] */ |
258 |
|
directilluminance = atof(argv[++i]); |
259 |
< |
diffusilluminance = atof(argv[++i]); |
259 |
> |
diffuseilluminance = atof(argv[++i]); |
260 |
|
break; |
261 |
|
|
262 |
|
case 'G': /* direct horizontal Irradiance [W/m^2] */ |
263 |
|
input = 3; /* diffuse horizontal Irrad. [W/m^2] */ |
264 |
|
directirradiance = atof(argv[++i]); |
265 |
< |
diffusirradiance = atof(argv[++i]); |
265 |
> |
diffuseirradiance = atof(argv[++i]); |
266 |
|
break; |
267 |
+ |
|
268 |
+ |
case 'E': /* Erbs model based on the */ |
269 |
+ |
input = 4; /* global-horizontal irradiance [W/m^2] */ |
270 |
+ |
globalirradiance = atof(argv[++i]); |
271 |
+ |
break; |
272 |
+ |
|
273 |
+ |
/* |
274 |
+ |
case 'l': |
275 |
+ |
sunaltitude_border = atof(argv[++i]); |
276 |
+ |
break; |
277 |
+ |
*/ |
278 |
|
|
279 |
+ |
case 'i': |
280 |
+ |
timeinterval = atof(argv[++i]); |
281 |
+ |
break; |
282 |
|
|
283 |
+ |
|
284 |
|
default: |
285 |
|
sprintf(errmsg, "unknown option: %s", argv[i]); |
286 |
|
userror(errmsg); |
294 |
|
progname, (s_longitude-s_meridian)*12/M_PI); |
295 |
|
|
296 |
|
|
297 |
< |
/* allocation dynamique de memoire pour les pointeurs */ |
298 |
< |
if ( (c_perez = malloc(5*sizeof(double))) == NULL ) |
297 |
> |
/* dynamic memory allocation for the pointers */ |
298 |
> |
|
299 |
> |
if ( (c_perez = calloc(5, sizeof(double))) == NULL ) |
300 |
|
{ |
301 |
< |
fprintf(stderr,"Out of memory error in function main !"); |
302 |
< |
exit(1); |
301 |
> |
fprintf(stderr,"Out of memory error in function main"); |
302 |
> |
return 1; |
303 |
|
} |
304 |
|
|
267 |
– |
|
305 |
|
printhead(argc, argv); |
269 |
– |
|
306 |
|
computesky(); |
307 |
+ |
|
308 |
+ |
if(*(c_perez+1)>0) |
309 |
+ |
{ |
310 |
+ |
fprintf(stderr, "Warning: positive Perez parameter B (= %lf), printing error sky\n",*(c_perez+1)); |
311 |
+ |
print_error_sky(); |
312 |
+ |
exit(1); |
313 |
+ |
} |
314 |
+ |
|
315 |
|
printsky(); |
316 |
< |
|
273 |
< |
exit(0); |
316 |
> |
return 0; |
317 |
|
} |
318 |
|
|
319 |
|
|
320 |
< |
void |
321 |
< |
computesky() /* compute sky parameters */ |
320 |
> |
|
321 |
> |
|
322 |
> |
|
323 |
> |
|
324 |
> |
|
325 |
> |
|
326 |
> |
void computesky() |
327 |
|
{ |
328 |
|
|
281 |
– |
/* new variables */ |
329 |
|
int j; |
330 |
< |
float *lv_mod; /* 145 luminance values*/ |
331 |
< |
/* 145 directions for the calculation of the normalization coefficient, coefficient Perez model */ |
332 |
< |
float *theta_o, *phi_o, *coeff_perez; |
330 |
> |
|
331 |
> |
float *lv_mod; /* 145 luminance values */ |
332 |
> |
float *theta_o, *phi_o; |
333 |
|
double dzeta, gamma; |
334 |
|
double normfactor; |
335 |
+ |
double erbs_s0, erbs_kt; |
336 |
|
|
337 |
|
|
290 |
– |
|
338 |
|
/* compute solar direction */ |
339 |
< |
|
339 |
> |
|
340 |
|
if (month) { /* from date and time */ |
341 |
|
int jd; |
342 |
|
double sd, st; |
347 |
|
st = hour; |
348 |
|
else |
349 |
|
st = hour + stadj(jd); |
350 |
+ |
|
351 |
+ |
|
352 |
+ |
if(st<solar_sunrise(month,day) || st>solar_sunset(month,day)) { |
353 |
+ |
print_error_sky(); |
354 |
+ |
exit(1); |
355 |
+ |
} |
356 |
+ |
|
357 |
+ |
|
358 |
+ |
if(timeinterval) { |
359 |
+ |
|
360 |
+ |
if(timeinterval<0) { |
361 |
+ |
fprintf(stderr, "time interval negative\n"); |
362 |
+ |
exit(1); |
363 |
+ |
} |
364 |
+ |
|
365 |
+ |
if(fabs(solar_sunrise(month,day)-st)<timeinterval/60) { |
366 |
+ |
|
367 |
+ |
fprintf(stderr, "Solar position corrected at %d %d %.3f\n",month,day,hour); |
368 |
+ |
st= (st+timeinterval/120+solar_sunrise(month,day))/2; |
369 |
+ |
} |
370 |
+ |
|
371 |
+ |
if(fabs(solar_sunset(month,day)-st)<timeinterval/60) { |
372 |
+ |
fprintf(stderr, "Solar position corrected at %d %d %.3f\n",month,day,hour); |
373 |
+ |
st= (st-timeinterval/120+solar_sunset(month,day))/2; |
374 |
+ |
} |
375 |
+ |
} |
376 |
+ |
|
377 |
+ |
|
378 |
|
altitude = salt(sd, st); |
379 |
|
azimuth = sazi(sd, st); |
380 |
|
|
381 |
|
daynumber = (double)jdate(month, day); |
382 |
+ |
|
383 |
+ |
} |
384 |
+ |
|
385 |
+ |
|
386 |
|
|
387 |
+ |
|
388 |
+ |
/* if loop for the -l option. W.Sprenger (01/2013) */ |
389 |
+ |
/* |
390 |
+ |
if (altitude*180/M_PI < sunaltitude_border) { |
391 |
+ |
|
392 |
+ |
if (suppress_warnings==0) { |
393 |
+ |
fprintf(stderr, "Warning: sun altitude (%.3f degrees) below the border (%.3f degrees)\n",altitude*180/M_PI,sunaltitude_border); |
394 |
+ |
} |
395 |
+ |
print_error_sky(); |
396 |
+ |
exit(1); |
397 |
|
} |
398 |
+ |
*/ |
399 |
+ |
|
400 |
+ |
|
401 |
|
if (!cloudy && altitude > 87.*M_PI/180.) { |
402 |
< |
fprintf(stderr, |
402 |
> |
|
403 |
> |
if (suppress_warnings==0) { |
404 |
> |
fprintf(stderr, |
405 |
|
"%s: warning - sun too close to zenith, reducing altitude to 87 degrees\n", |
406 |
|
progname); |
407 |
< |
printf( |
314 |
< |
"# warning - sun too close to zenith, reducing altitude to 87 degrees\n"); |
407 |
> |
} |
408 |
|
altitude = 87.*M_PI/180.; |
409 |
|
} |
410 |
+ |
|
411 |
|
sundir[0] = -sin(azimuth)*cos(altitude); |
412 |
|
sundir[1] = -cos(azimuth)*cos(altitude); |
413 |
|
sundir[2] = sin(altitude); |
418 |
|
|
419 |
|
|
420 |
|
|
421 |
< |
/* compute the inputs for the calculation of the light distribution over the sky*/ |
422 |
< |
if (input==0) |
421 |
> |
/* compute the inputs for the calculation of the light distribution over the sky*/ |
422 |
> |
if (input==0) /* P */ |
423 |
|
{ |
424 |
|
check_parametrization(); |
425 |
< |
diffusirradiance = diffus_irradiance_from_sky_brightness(); /*diffuse horizontal irradiance*/ |
425 |
> |
diffuseirradiance = diffuse_irradiance_from_sky_brightness(); /*diffuse horizontal irradiance*/ |
426 |
|
directirradiance = direct_irradiance_from_sky_clearness(); |
427 |
|
check_irradiances(); |
428 |
|
|
429 |
|
if (output==0 || output==2) |
430 |
|
{ |
431 |
< |
diffusilluminance = diffusirradiance*glob_h_diffuse_effi_PEREZ();/*diffuse horizontal illuminance*/ |
431 |
> |
diffuseilluminance = diffuseirradiance*glob_h_diffuse_effi_PEREZ();/*diffuse horizontal illuminance*/ |
432 |
|
directilluminance = directirradiance*direct_n_effi_PEREZ(); |
433 |
|
check_illuminances(); |
434 |
|
} |
435 |
|
} |
436 |
|
|
437 |
|
|
438 |
< |
else if (input==1) |
438 |
> |
else if (input==1) /* W */ |
439 |
|
{ |
440 |
|
check_irradiances(); |
441 |
|
skybrightness = sky_brightness(); |
444 |
|
|
445 |
|
if (output==0 || output==2) |
446 |
|
{ |
447 |
< |
diffusilluminance = diffusirradiance*glob_h_diffuse_effi_PEREZ();/*diffuse horizontal illuminance*/ |
447 |
> |
diffuseilluminance = diffuseirradiance*glob_h_diffuse_effi_PEREZ();/*diffuse horizontal illuminance*/ |
448 |
|
directilluminance = directirradiance*direct_n_effi_PEREZ(); |
449 |
|
check_illuminances(); |
450 |
|
} |
452 |
|
} |
453 |
|
|
454 |
|
|
455 |
< |
else if (input==2) |
455 |
> |
else if (input==2) /* L */ |
456 |
|
{ |
457 |
|
check_illuminances(); |
458 |
|
illu_to_irra_index(); |
460 |
|
} |
461 |
|
|
462 |
|
|
463 |
< |
else if (input==3) |
463 |
> |
else if (input==3) /* G */ |
464 |
|
{ |
465 |
|
if (altitude<=0) |
466 |
|
{ |
467 |
< |
fprintf(stderr, "solar zenith angle larger than 90� \n the models used are not more valid\n"); |
468 |
< |
exit(1); |
467 |
> |
if (suppress_warnings==0) |
468 |
> |
fprintf(stderr, "Warning: solar zenith angle larger than 90 degrees; using zero irradiance to proceed\n"); |
469 |
> |
directirradiance = 0; |
470 |
> |
diffuseirradiance = 0; |
471 |
> |
} else { |
472 |
> |
|
473 |
> |
directirradiance=directirradiance/sin(altitude); |
474 |
|
} |
475 |
< |
|
377 |
< |
directirradiance=directirradiance/sin(altitude); |
475 |
> |
|
476 |
|
check_irradiances(); |
477 |
|
skybrightness = sky_brightness(); |
478 |
|
skyclearness = sky_clearness(); |
480 |
|
|
481 |
|
if (output==0 || output==2) |
482 |
|
{ |
483 |
< |
diffusilluminance = diffusirradiance*glob_h_diffuse_effi_PEREZ();/*diffuse horizontal illuminance*/ |
483 |
> |
diffuseilluminance = diffuseirradiance*glob_h_diffuse_effi_PEREZ();/*diffuse horizontal illuminance*/ |
484 |
|
directilluminance = directirradiance*direct_n_effi_PEREZ(); |
485 |
|
check_illuminances(); |
486 |
|
} |
487 |
|
|
488 |
|
} |
489 |
|
|
392 |
– |
|
393 |
– |
else {fprintf(stderr,"error in giving the input arguments"); exit(1);} |
490 |
|
|
491 |
+ |
else if (input==4) /* E */ /* Implementation of the Erbs model. W.Sprenger (04/13) */ |
492 |
+ |
{ |
493 |
+ |
|
494 |
+ |
if (altitude<=0) |
495 |
+ |
{ |
496 |
+ |
if (suppress_warnings==0 && globalirradiance > 50) |
497 |
+ |
fprintf(stderr, "Warning: global irradiance higher than 50 W/m^2 while the sun altitude is lower than zero\n"); |
498 |
+ |
globalirradiance = 0; diffuseirradiance = 0; directirradiance = 0; |
499 |
+ |
|
500 |
+ |
} else { |
501 |
+ |
|
502 |
+ |
erbs_s0 = solar_constant_e*get_eccentricity()*sin(altitude); |
503 |
+ |
|
504 |
+ |
if (globalirradiance>erbs_s0) |
505 |
+ |
{ |
506 |
+ |
if (suppress_warnings==0) |
507 |
+ |
fprintf(stderr, "Warning: global irradiance is higher than the time-dependent solar constant s0\n"); |
508 |
+ |
|
509 |
+ |
globalirradiance=erbs_s0*0.999; |
510 |
+ |
} |
511 |
+ |
|
512 |
+ |
erbs_kt=globalirradiance/erbs_s0; |
513 |
+ |
|
514 |
+ |
if (erbs_kt<=0.22) diffuseirradiance=globalirradiance*(1-0.09*erbs_kt); |
515 |
+ |
else if (erbs_kt<=0.8) diffuseirradiance=globalirradiance*(0.9511-0.1604*erbs_kt+4.388*pow(erbs_kt,2)-16.638*pow(erbs_kt,3)+12.336*pow(erbs_kt,4)); |
516 |
+ |
else if (erbs_kt<1) diffuseirradiance=globalirradiance*(0.165); |
517 |
+ |
|
518 |
+ |
directirradiance=globalirradiance-diffuseirradiance; |
519 |
+ |
|
520 |
+ |
printf("# erbs_s0, erbs_kt, irr_dir_h, irr_diff: %.3f %.3f %.3f %.3f\n", erbs_s0, erbs_kt, directirradiance, diffuseirradiance); |
521 |
+ |
printf("# WARNING: the -E option is only recommended for a rough estimation!"); |
522 |
+ |
|
523 |
+ |
directirradiance=directirradiance/sin(altitude); |
524 |
+ |
|
525 |
+ |
} |
526 |
+ |
|
527 |
+ |
check_irradiances(); |
528 |
+ |
skybrightness = sky_brightness(); |
529 |
+ |
skyclearness = sky_clearness(); |
530 |
+ |
check_parametrization(); |
531 |
|
|
532 |
+ |
if (output==0 || output==2) |
533 |
+ |
{ |
534 |
+ |
diffuseilluminance = diffuseirradiance*glob_h_diffuse_effi_PEREZ();/*diffuse horizontal illuminance*/ |
535 |
+ |
directilluminance = directirradiance*direct_n_effi_PEREZ(); |
536 |
+ |
check_illuminances(); |
537 |
+ |
} |
538 |
+ |
|
539 |
+ |
} |
540 |
+ |
|
541 |
+ |
|
542 |
+ |
|
543 |
|
|
544 |
< |
/* normalization factor for the relative sky luminance distribution, diffuse part*/ |
544 |
> |
else {fprintf(stderr,"error at the input arguments"); exit(1);} |
545 |
|
|
399 |
– |
/* allocation dynamique de memoire pour les pointeurs */ |
400 |
– |
if ( (coeff_perez = malloc(8*20*sizeof(float))) == NULL ) |
401 |
– |
{ |
402 |
– |
fprintf(stderr,"Out of memory error in function main !"); |
403 |
– |
exit(1); |
404 |
– |
} |
546 |
|
|
547 |
< |
/* read the coefficients for the Perez sky luminance model */ |
548 |
< |
if (lect_coeff_perez(DATFILE, &coeff_perez) > 0) |
549 |
< |
{ |
409 |
< |
fprintf(stderr,"lect_coeff_perez does not work\n"); |
410 |
< |
exit(2); |
411 |
< |
} |
412 |
< |
|
547 |
> |
|
548 |
> |
/* normalization factor for the relative sky luminance distribution, diffuse part*/ |
549 |
> |
|
550 |
|
if ( (lv_mod = malloc(145*sizeof(float))) == NULL) |
551 |
|
{ |
552 |
|
fprintf(stderr,"Out of memory in function main"); |
554 |
|
} |
555 |
|
|
556 |
|
/* read the angles */ |
557 |
< |
theta_o = theta_ordered("defangle.dat"); |
558 |
< |
phi_o = phi_ordered("defangle.dat"); |
557 |
> |
theta_o = defangle_theta; |
558 |
> |
phi_o = defangle_phi; |
559 |
> |
|
560 |
|
|
561 |
< |
/* parameters for the perez model */ |
561 |
> |
/* parameters for the perez model */ |
562 |
|
coeff_lum_perez(radians(sunzenith), skyclearness, skybrightness, coeff_perez); |
563 |
|
|
564 |
< |
/*calculation of the modelled luminance */ |
564 |
> |
|
565 |
> |
|
566 |
> |
|
567 |
> |
|
568 |
> |
/*calculation of the modelled luminance */ |
569 |
|
for (j=0;j<145;j++) |
570 |
|
{ |
571 |
|
theta_phi_to_dzeta_gamma(radians(*(theta_o+j)),radians(*(phi_o+j)),&dzeta,&gamma,radians(sunzenith)); |
572 |
+ |
|
573 |
|
*(lv_mod+j) = calc_rel_lum_perez(dzeta,gamma,radians(sunzenith),skyclearness,skybrightness,coeff_perez); |
574 |
< |
/*printf("theta, phi, lv_mod %lf\t %lf\t %lf\n", *(theta_o+j),*(phi_o+j),*(lv_mod+j));*/ |
574 |
> |
|
575 |
> |
/* fprintf(stderr,"theta, phi, lv_mod %f\t %f\t %f\n", *(theta_o+j),*(phi_o+j),*(lv_mod+j)); */ |
576 |
|
} |
577 |
< |
|
577 |
> |
|
578 |
|
/* integration of luminance for the normalization factor, diffuse part of the sky*/ |
579 |
+ |
|
580 |
|
diffnormalization = integ_lv(lv_mod, theta_o); |
436 |
– |
/*printf("perez integration %lf\n", diffnormalization);*/ |
581 |
|
|
438 |
– |
|
582 |
|
|
583 |
|
|
584 |
< |
/*normalization coefficient in lumen or in watt*/ |
584 |
> |
/*normalization coefficient in lumen or in watt*/ |
585 |
|
if (output==0) |
586 |
|
{ |
587 |
< |
diffnormalization = diffusilluminance/diffnormalization/WHTEFFICACY; |
587 |
> |
diffnormalization = diffuseilluminance/diffnormalization/WHTEFFICACY; |
588 |
|
} |
589 |
|
else if (output==1) |
590 |
|
{ |
591 |
< |
diffnormalization = diffusirradiance/diffnormalization; |
591 |
> |
diffnormalization = diffuseirradiance/diffnormalization; |
592 |
|
} |
593 |
|
else if (output==2) |
594 |
|
{ |
595 |
< |
diffnormalization = diffusilluminance/diffnormalization; |
595 |
> |
diffnormalization = diffuseilluminance/diffnormalization; |
596 |
|
} |
597 |
|
|
598 |
< |
else {fprintf(stderr,"output argument : wrong number"); exit(1);} |
598 |
> |
else {fprintf(stderr,"Wrong output specification.\n"); exit(1);} |
599 |
|
|
600 |
|
|
601 |
|
|
602 |
|
|
603 |
< |
/* calculation for the solar source */ |
603 |
> |
/* calculation for the solar source */ |
604 |
|
if (output==0) |
605 |
|
solarradiance = directilluminance/(2*M_PI*(1-cos(half_sun_angle*M_PI/180)))/WHTEFFICACY; |
606 |
|
|
616 |
|
/* Compute the ground radiance */ |
617 |
|
zenithbr=calc_rel_lum_perez(0.0,radians(sunzenith),radians(sunzenith),skyclearness,skybrightness,coeff_perez); |
618 |
|
zenithbr*=diffnormalization; |
619 |
< |
/* |
477 |
< |
fprintf(stderr, "gendaylit : the actual zenith radiance(W/m^2/sr) or luminance(cd/m^2) is : %.0lf\n", zenithbr); |
478 |
< |
*/ |
479 |
< |
|
619 |
> |
|
620 |
|
if (skyclearness==1) |
621 |
|
normfactor = 0.777778; |
622 |
|
|
634 |
|
} |
635 |
|
|
636 |
|
groundbr = zenithbr*normfactor; |
497 |
– |
printf("# Ground ambient level: %.1f\n", groundbr); |
637 |
|
|
638 |
|
if (dosun&&(skyclearness>1)) |
639 |
< |
groundbr += 6.8e-5/M_PI*solarradiance*sundir[2]; |
639 |
> |
groundbr += 6.8e-5/M_PI*solarradiance*sundir[2]; |
640 |
|
|
641 |
|
groundbr *= gprefl; |
642 |
|
|
648 |
|
|
649 |
|
|
650 |
|
|
651 |
+ |
void print_error_sky() |
652 |
+ |
{ |
653 |
+ |
sundir[0] = -sin(azimuth)*cos(altitude); |
654 |
+ |
sundir[1] = -cos(azimuth)*cos(altitude); |
655 |
+ |
sundir[2] = sin(altitude); |
656 |
+ |
|
657 |
+ |
printf("\nvoid brightfunc skyfunc\n"); |
658 |
+ |
printf("2 skybright perezlum.cal\n"); |
659 |
+ |
printf("0\n"); |
660 |
+ |
printf("10 0.00 0.00 0.000 0.000 0.000 0.000 0.000 %f %f %f \n", sundir[0], sundir[1], sundir[2]); |
661 |
+ |
} |
662 |
+ |
|
663 |
|
|
664 |
|
|
665 |
|
|
666 |
< |
printsky() /* print out sky */ |
666 |
> |
|
667 |
> |
|
668 |
> |
|
669 |
> |
double solar_sunset(int month,int day) |
670 |
|
{ |
671 |
+ |
float W; |
672 |
+ |
extern double s_latitude; |
673 |
+ |
W=-1*(tan(s_latitude)*tan(sdec(jdate(month, day)))); |
674 |
+ |
return(12+(M_PI/2 - atan2(W,sqrt(1-W*W)))*180/(M_PI*15)); |
675 |
+ |
} |
676 |
+ |
|
677 |
+ |
|
678 |
+ |
double solar_sunrise(int month,int day) |
679 |
+ |
{ |
680 |
+ |
float W; |
681 |
+ |
extern double s_latitude; |
682 |
+ |
W=-1*(tan(s_latitude)*tan(sdec(jdate(month, day)))); |
683 |
+ |
return(12-(M_PI/2 - atan2(W,sqrt(1-W*W)))*180/(M_PI*15)); |
684 |
+ |
} |
685 |
+ |
|
686 |
+ |
|
687 |
+ |
|
688 |
+ |
|
689 |
+ |
|
690 |
+ |
|
691 |
+ |
|
692 |
+ |
|
693 |
+ |
|
694 |
+ |
|
695 |
+ |
|
696 |
+ |
void printsky() /* print out sky */ |
697 |
+ |
{ |
698 |
|
if (dosun&&(skyclearness>1)) |
699 |
< |
{ |
699 |
> |
{ |
700 |
|
printf("\nvoid light solar\n"); |
701 |
|
printf("0\n0\n"); |
702 |
|
printf("3 %.3e %.3e %.3e\n", solarradiance, solarradiance, solarradiance); |
703 |
|
printf("\nsolar source sun\n"); |
704 |
|
printf("0\n0\n"); |
705 |
|
printf("4 %f %f %f %f\n", sundir[0], sundir[1], sundir[2], 2*half_sun_angle); |
706 |
< |
} |
526 |
< |
|
527 |
< |
if (dosun&&(skyclearness==1)) |
528 |
< |
{ |
706 |
> |
} else if (dosun) { |
707 |
|
printf("\nvoid light solar\n"); |
708 |
|
printf("0\n0\n"); |
709 |
|
printf("3 0.0 0.0 0.0\n"); |
710 |
|
printf("\nsolar source sun\n"); |
711 |
|
printf("0\n0\n"); |
712 |
|
printf("4 %f %f %f %f\n", sundir[0], sundir[1], sundir[2], 2*half_sun_angle); |
713 |
< |
} |
713 |
> |
} |
714 |
|
|
715 |
|
|
716 |
|
printf("\nvoid brightfunc skyfunc\n"); |
717 |
|
printf("2 skybright perezlum.cal\n"); |
718 |
|
printf("0\n"); |
719 |
|
printf("10 %.3e %.3e %lf %lf %lf %lf %lf %f %f %f \n", diffnormalization, groundbr, |
720 |
< |
*(c_perez+0),*(c_perez+1),*(c_perez+2),*(c_perez+3),*(c_perez+4), |
721 |
< |
sundir[0], sundir[1], sundir[2]); |
720 |
> |
*(c_perez+0),*(c_perez+1),*(c_perez+2),*(c_perez+3),*(c_perez+4), |
721 |
> |
sundir[0], sundir[1], sundir[2]); |
722 |
> |
|
723 |
|
} |
724 |
|
|
725 |
|
|
726 |
< |
printdefaults() /* print default values */ |
726 |
> |
void printdefaults() /* print default values */ |
727 |
|
{ |
728 |
|
printf("-g %f\t\t\t# Ground plane reflectance\n", gprefl); |
729 |
|
if (zenithbr > 0.0) |
736 |
|
} |
737 |
|
|
738 |
|
|
739 |
< |
userror(msg) /* print usage error and quit */ |
561 |
< |
char *msg; |
739 |
> |
void userror(char* msg) /* print usage error and quit */ |
740 |
|
{ |
741 |
|
if (msg != NULL) |
742 |
< |
fprintf(stderr, "%s: Use error - %s\n", progname, msg); |
743 |
< |
fprintf(stderr, "Usage: %s month day hour [-P|-W|-L] direct_value diffus_value [options]\n", progname); |
744 |
< |
fprintf(stderr, "or : %s -ang altitude azimuth [-P|-W|-L] direct_value diffus_value [options]\n", progname); |
742 |
> |
fprintf(stderr, "%s: Use error - %s\n\n", progname, msg); |
743 |
> |
fprintf(stderr, "Usage: %s month day hour [...]\n", progname); |
744 |
> |
fprintf(stderr, " or: %s -ang altitude azimuth [...]\n", progname); |
745 |
> |
fprintf(stderr, " followed by: -P epsilon delta [options]\n"); |
746 |
> |
fprintf(stderr, " or: [-W|-L|-G] direct_value diffuse_value [options]\n"); |
747 |
> |
fprintf(stderr, " or: -E global_irradiance [options]\n\n"); |
748 |
> |
fprintf(stderr, " Description:\n"); |
749 |
|
fprintf(stderr, " -P epsilon delta (these are the Perez parameters) \n"); |
750 |
|
fprintf(stderr, " -W direct-normal-irradiance diffuse-horizontal-irradiance (W/m^2)\n"); |
751 |
|
fprintf(stderr, " -L direct-normal-illuminance diffuse-horizontal-illuminance (lux)\n"); |
752 |
|
fprintf(stderr, " -G direct-horizontal-irradiance diffuse-horizontal-irradiance (W/m^2)\n"); |
753 |
+ |
fprintf(stderr, " -E global-horizontal-irradiance (W/m^2)\n\n"); |
754 |
+ |
fprintf(stderr, " Output specification with option:\n"); |
755 |
|
fprintf(stderr, " -O [0|1|2] (0=output in W/m^2/sr visible, 1=output in W/m^2/sr solar, 2=output in candela/m^2), default is 0 \n"); |
756 |
+ |
fprintf(stderr, " gendaylit version 2.3 (2013/08/08) \n\n"); |
757 |
|
exit(1); |
758 |
|
} |
759 |
|
|
760 |
|
|
761 |
|
|
762 |
< |
double |
578 |
< |
normsc() /* compute normalization factor (E0*F2/L0) */ |
762 |
> |
double normsc() /* compute normalization factor (E0*F2/L0) */ |
763 |
|
{ |
764 |
|
static double nfc[2][5] = { |
765 |
|
/* clear sky approx. */ |
782 |
|
|
783 |
|
|
784 |
|
|
785 |
< |
printhead(ac, av) /* print command header */ |
602 |
< |
register int ac; |
603 |
< |
register char **av; |
785 |
> |
void printhead(int ac, char** av) /* print command header */ |
786 |
|
{ |
787 |
|
putchar('#'); |
788 |
|
while (ac--) { |
795 |
|
|
796 |
|
|
797 |
|
|
616 |
– |
void |
617 |
– |
skip_comments(FILE *fp) /* skip comments in file */ |
618 |
– |
{ |
619 |
– |
int c; |
620 |
– |
|
621 |
– |
while ((c = getc(fp)) != EOF) |
622 |
– |
if (c == '#') { |
623 |
– |
while ((c = getc(fp)) != EOF) |
624 |
– |
if (c == '\n') |
625 |
– |
break; |
626 |
– |
} else if (!isspace(c)) { |
627 |
– |
ungetc(c, fp); |
628 |
– |
break; |
629 |
– |
} |
630 |
– |
} |
631 |
– |
|
632 |
– |
|
633 |
– |
|
798 |
|
/* Perez models */ |
799 |
|
|
800 |
|
/* Perez global horizontal luminous efficacy model */ |
804 |
|
double value; |
805 |
|
double category_bounds[10], a[10], b[10], c[10], d[10]; |
806 |
|
int category_total_number, category_number, i; |
807 |
< |
|
808 |
< |
|
809 |
< |
if (skyclearness<skyclearinf || skyclearness>skyclearsup || skybrightness<=skybriginf || skybrightness>skybrigsup) |
810 |
< |
fprintf(stderr, "Warning : skyclearness or skybrightness out of range ; \n Check your input parameters\n"); |
811 |
< |
|
807 |
> |
|
808 |
> |
check_parametrization(); |
809 |
> |
|
810 |
> |
|
811 |
> |
/*if ((skyclearness<skyclearinf || skyclearness>skyclearsup || skybrightness<skybriginf || skybrightness>skybrigsup) && suppress_warnings==0) |
812 |
> |
fprintf(stderr, "Warning: skyclearness or skybrightness out of range in function glob_h_effi_PEREZ \n"); */ |
813 |
> |
|
814 |
> |
|
815 |
|
/* initialize category bounds (clearness index bounds) */ |
816 |
|
|
817 |
|
category_total_number = 8; |
887 |
|
double category_bounds[10], a[10], b[10], c[10], d[10]; |
888 |
|
int category_total_number, category_number, i; |
889 |
|
|
890 |
+ |
|
891 |
+ |
|
892 |
|
|
893 |
< |
if (skyclearness<skyclearinf || skyclearness>skyclearsup || skybrightness<=skybriginf || skybrightness>skybrigsup) |
894 |
< |
fprintf(stderr, "Warning : skyclearness or skybrightness out of range ; \n Check your input parameters\n"); |
893 |
> |
check_parametrization(); |
894 |
> |
|
895 |
> |
|
896 |
> |
/*if ((skyclearness<skyclearinf || skyclearness>skyclearsup || skybrightness<skybriginf || skybrightness>skybrigsup) && suppress_warnings==0) |
897 |
> |
fprintf(stderr, "Warning: skyclearness or skybrightness out of range in function glob_h_diffuse_PEREZ \n"); */ |
898 |
> |
|
899 |
> |
|
900 |
|
|
901 |
|
/* initialize category bounds (clearness index bounds) */ |
902 |
|
|
903 |
|
category_total_number = 8; |
904 |
|
|
905 |
+ |
//XXX: category_bounds > 0.1 |
906 |
|
category_bounds[1] = 1; |
907 |
|
category_bounds[2] = 1.065; |
908 |
|
category_bounds[3] = 1.230; |
954 |
|
|
955 |
|
|
956 |
|
|
957 |
+ |
category_number = -1; |
958 |
|
for (i=1; i<=category_total_number; i++) |
959 |
|
{ |
960 |
|
if ( (skyclearness >= category_bounds[i]) && (skyclearness < category_bounds[i+1]) ) |
961 |
|
category_number = i; |
962 |
|
} |
963 |
|
|
964 |
+ |
if (category_number == -1) { |
965 |
+ |
if (suppress_warnings==0) |
966 |
+ |
fprintf(stderr, "ERROR: Model parameters out of range, skyclearness = %lf \n", skyclearness); |
967 |
+ |
print_error_sky(); |
968 |
+ |
exit(1); |
969 |
+ |
} |
970 |
+ |
|
971 |
+ |
|
972 |
|
value = a[category_number] + b[category_number]*atm_preci_water + c[category_number]*cos(sunzenith*M_PI/180) + |
973 |
|
d[category_number]*log(skybrightness); |
974 |
|
|
975 |
|
return(value); |
976 |
+ |
|
977 |
|
} |
978 |
|
|
979 |
|
|
980 |
+ |
|
981 |
|
/* direct normal efficacy model, according to PEREZ */ |
982 |
|
|
983 |
|
double direct_n_effi_PEREZ() |
988 |
|
int category_total_number, category_number, i; |
989 |
|
|
990 |
|
|
991 |
< |
if (skyclearness<skyclearinf || skyclearness>skyclearsup || skybrightness<=skybriginf || skybrightness>skybrigsup) |
992 |
< |
fprintf(stderr, "Warning : skyclearness or skybrightness out of range ; \n Check your input parameters\n"); |
991 |
> |
if ((skyclearness<skyclearinf || skyclearness>skyclearsup || skybrightness<skybriginf || skybrightness>skybrigsup) && suppress_warnings==0) |
992 |
> |
fprintf(stderr, "Warning: skyclearness or skybrightness out of range in function direct_n_effi_PEREZ \n"); |
993 |
|
|
994 |
|
|
995 |
|
/* initialize category bounds (clearness index bounds) */ |
1063 |
|
/*check the range of epsilon and delta indexes of the perez parametrization*/ |
1064 |
|
void check_parametrization() |
1065 |
|
{ |
1066 |
< |
if (skyclearness<skyclearinf || skyclearness>skyclearsup || skybrightness<=skybriginf || skybrightness>skybrigsup) |
1066 |
> |
if (skyclearness<skyclearinf || skyclearness>skyclearsup || skybrightness<skybriginf || skybrightness>skybrigsup) |
1067 |
|
{ |
1068 |
< |
fprintf(stderr,"sky clearness or sky brightness out of range %lf\t %lf\n", skyclearness, skybrightness); |
1069 |
< |
exit(1); |
1068 |
> |
|
1069 |
> |
/* limit sky clearness or sky brightness, 2009 11 13 by J. Wienold */ |
1070 |
> |
if (skyclearness<skyclearinf){ |
1071 |
> |
if (suppress_warnings==0) |
1072 |
> |
/* fprintf(stderr,"Range warning: sky clearness too low (%lf)\n", skyclearness); */ |
1073 |
> |
skyclearness=skyclearinf; |
1074 |
|
} |
1075 |
+ |
if (skyclearness>skyclearsup){ |
1076 |
+ |
if (suppress_warnings==0) |
1077 |
+ |
/* fprintf(stderr,"Range warning: sky clearness too high (%lf)\n", skyclearness); */ |
1078 |
+ |
skyclearness=skyclearsup-0.1; |
1079 |
+ |
} |
1080 |
+ |
if (skybrightness<skybriginf){ |
1081 |
+ |
if (suppress_warnings==0) |
1082 |
+ |
/* fprintf(stderr,"Range warning: sky brightness too low (%lf)\n", skybrightness); */ |
1083 |
+ |
skybrightness=skybriginf; |
1084 |
+ |
} |
1085 |
+ |
if (skybrightness>skybrigsup){ |
1086 |
+ |
if (suppress_warnings==0) |
1087 |
+ |
/* fprintf(stderr,"Range warning: sky brightness too high (%lf)\n", skybrightness); */ |
1088 |
+ |
skybrightness=skybrigsup; |
1089 |
+ |
} |
1090 |
+ |
|
1091 |
+ |
return; } |
1092 |
|
else return; |
1093 |
|
} |
1094 |
|
|
1095 |
|
|
1096 |
< |
/* likelihood of the direct and diffuse components */ |
1096 |
> |
/* validity of the direct and diffuse components */ |
1097 |
|
void check_illuminances() |
1098 |
|
{ |
1099 |
< |
if (!( (directilluminance>=0) && (directilluminance<=solar_constant_l*1000) && (diffusilluminance>0) )) |
1100 |
< |
{ |
1101 |
< |
fprintf(stderr,"direct or diffuse illuminances out of range\n"); |
895 |
< |
exit(1); |
1099 |
> |
if (directilluminance < 0) { |
1100 |
> |
fprintf(stderr,"WARNING: direct illuminance < 0. Using 0.0\n"); |
1101 |
> |
directilluminance = 0.0; |
1102 |
|
} |
1103 |
< |
return; |
1103 |
> |
if (diffuseilluminance < 0) { |
1104 |
> |
fprintf(stderr,"WARNING: diffuse illuminance < 0. Using 0.0\n"); |
1105 |
> |
diffuseilluminance = 0.0; |
1106 |
> |
} |
1107 |
> |
if (directilluminance > solar_constant_l*1000.0) { |
1108 |
> |
fprintf(stderr,"ERROR: direct illuminance exceeds solar constant\n"); |
1109 |
> |
exit(1); |
1110 |
> |
} |
1111 |
|
} |
1112 |
|
|
1113 |
|
|
1114 |
|
void check_irradiances() |
1115 |
|
{ |
1116 |
< |
if (!( (directirradiance>=0) && (directirradiance<=solar_constant_e) && (diffusirradiance>0) )) |
1117 |
< |
{ |
1118 |
< |
fprintf(stderr,"direct or diffuse irradiances out of range\n"); |
1119 |
< |
exit(1); |
1120 |
< |
} |
1121 |
< |
return; |
1116 |
> |
if (directirradiance < 0) { |
1117 |
> |
fprintf(stderr,"WARNING: direct irradiance < 0. Using 0.0\n"); |
1118 |
> |
directirradiance = 0.0; |
1119 |
> |
} |
1120 |
> |
if (diffuseirradiance < 0) { |
1121 |
> |
fprintf(stderr,"WARNING: diffuse irradiance < 0. Using 0.0\n"); |
1122 |
> |
diffuseirradiance = 0.0; |
1123 |
> |
} |
1124 |
> |
if (directirradiance > solar_constant_e) { |
1125 |
> |
fprintf(stderr,"ERROR: direct irradiance exceeds solar constant\n"); |
1126 |
> |
exit(1); |
1127 |
> |
} |
1128 |
|
} |
1129 |
|
|
1130 |
|
|
1134 |
|
{ |
1135 |
|
double value; |
1136 |
|
|
1137 |
< |
value = diffusirradiance * air_mass() / ( solar_constant_e*get_eccentricity()); |
1137 |
> |
value = diffuseirradiance * air_mass() / ( solar_constant_e*get_eccentricity()); |
1138 |
|
|
1139 |
|
return(value); |
1140 |
|
} |
1143 |
|
/* Perez sky's clearness */ |
1144 |
|
double sky_clearness() |
1145 |
|
{ |
1146 |
< |
double value; |
1146 |
> |
double value; |
1147 |
|
|
1148 |
< |
value = ( (diffusirradiance + directirradiance)/(diffusirradiance) + 1.041*sunzenith*M_PI/180*sunzenith*M_PI/180*sunzenith*M_PI/180 ) / (1 + 1.041*sunzenith*M_PI/180*sunzenith*M_PI/180*sunzenith*M_PI/180) ; |
1148 |
> |
value = ( (diffuseirradiance + directirradiance)/(diffuseirradiance) + 1.041*sunzenith*M_PI/180*sunzenith*M_PI/180*sunzenith*M_PI/180 ) / (1 + 1.041*sunzenith*M_PI/180*sunzenith*M_PI/180*sunzenith*M_PI/180) ; |
1149 |
|
|
1150 |
< |
return(value); |
1150 |
> |
return(value); |
1151 |
|
} |
1152 |
|
|
1153 |
|
|
1154 |
|
|
1155 |
|
/* diffus horizontal irradiance from Perez sky's brightness */ |
1156 |
< |
double diffus_irradiance_from_sky_brightness() |
1156 |
> |
double diffuse_irradiance_from_sky_brightness() |
1157 |
|
{ |
1158 |
|
double value; |
1159 |
|
|
1168 |
|
{ |
1169 |
|
double value; |
1170 |
|
|
1171 |
< |
value = diffus_irradiance_from_sky_brightness(); |
1171 |
> |
value = diffuse_irradiance_from_sky_brightness(); |
1172 |
|
value = value * ( (skyclearness-1) * (1+1.041*sunzenith*M_PI/180*sunzenith*M_PI/180*sunzenith*M_PI/180) ); |
1173 |
|
|
1174 |
|
return(value); |
1175 |
|
} |
1176 |
|
|
1177 |
|
|
1178 |
< |
void illu_to_irra_index(void) |
1178 |
> |
|
1179 |
> |
|
1180 |
> |
void illu_to_irra_index() |
1181 |
|
{ |
1182 |
< |
double test1=0.1, test2=0.1; |
1182 |
> |
double test1=0.1, test2=0.1, d_eff; |
1183 |
|
int counter=0; |
1184 |
|
|
1185 |
< |
diffusirradiance = diffusilluminance*solar_constant_e/(solar_constant_l*1000); |
1185 |
> |
diffuseirradiance = diffuseilluminance*solar_constant_e/(solar_constant_l*1000); |
1186 |
|
directirradiance = directilluminance*solar_constant_e/(solar_constant_l*1000); |
1187 |
|
skyclearness = sky_clearness(); |
1188 |
|
skybrightness = sky_brightness(); |
1189 |
< |
if (skyclearness>12) skyclearness=12; |
969 |
< |
if (skybrightness<0.05) skybrightness=0.01; |
970 |
< |
|
971 |
< |
|
972 |
< |
while ( ((fabs(diffusirradiance-test1)>10) || (fabs(directirradiance-test2)>10) |
973 |
< |
|| skyclearness>skyclearinf || skyclearness<skyclearsup |
974 |
< |
|| skybrightness>skybriginf || skybrightness<skybrigsup ) |
975 |
< |
&& !(counter==5) ) |
976 |
< |
{ |
977 |
< |
/*fprintf(stderr, "conversion illuminance into irradiance %lf\t %lf\n", diffusirradiance, directirradiance);*/ |
1189 |
> |
check_parametrization(); |
1190 |
|
|
1191 |
< |
test1=diffusirradiance; |
1191 |
> |
|
1192 |
> |
while ( ((fabs(diffuseirradiance-test1)>10) || (fabs(directirradiance-test2)>10) |
1193 |
> |
|| (!(skyclearness<skyclearinf || skyclearness>skyclearsup)) |
1194 |
> |
|| (!(skybrightness<skybriginf || skybrightness>skybrigsup)) ) |
1195 |
> |
&& !(counter==9) ) |
1196 |
> |
{ |
1197 |
> |
|
1198 |
> |
test1=diffuseirradiance; |
1199 |
|
test2=directirradiance; |
1200 |
|
counter++; |
1201 |
|
|
1202 |
< |
diffusirradiance = diffusilluminance/glob_h_diffuse_effi_PEREZ(); |
1203 |
< |
directirradiance = directilluminance/direct_n_effi_PEREZ(); |
985 |
< |
/*fprintf(stderr, "conversion illuminance into irradiance %lf\t %lf\n", diffusirradiance, directirradiance);*/ |
1202 |
> |
diffuseirradiance = diffuseilluminance/glob_h_diffuse_effi_PEREZ(); |
1203 |
> |
d_eff = direct_n_effi_PEREZ(); |
1204 |
|
|
1205 |
+ |
|
1206 |
+ |
if (d_eff < 0.1) |
1207 |
+ |
directirradiance = 0; |
1208 |
+ |
else |
1209 |
+ |
directirradiance = directilluminance/d_eff; |
1210 |
+ |
|
1211 |
|
skybrightness = sky_brightness(); |
1212 |
|
skyclearness = sky_clearness(); |
1213 |
< |
if (skyclearness>12) skyclearness=12; |
1214 |
< |
if (skybrightness<0.05) skybrightness=0.01; |
1215 |
< |
|
1216 |
< |
/*fprintf(stderr, "%lf\t %lf\n", skybrightness, skyclearness);*/ |
993 |
< |
|
1213 |
> |
check_parametrization(); |
1214 |
> |
|
1215 |
> |
/*fprintf(stderr,"skyclearness = %lf, skybrightness = %lf, directirradiance = %lf, diffuseirradiance = %lf\n",skyclearness, skybrightness, directirradiance, diffuseirradiance);*/ |
1216 |
> |
|
1217 |
|
} |
1218 |
|
|
1219 |
|
|
1220 |
|
return; |
1221 |
|
} |
1222 |
|
|
1223 |
< |
|
1001 |
< |
int lect_coeff_perez(char *filename,float **coeff_perez) |
1223 |
> |
static int get_numlin(float epsilon) |
1224 |
|
{ |
1225 |
< |
FILE *fcoeff_perez; |
1226 |
< |
float temp; |
1227 |
< |
int i,j; |
1228 |
< |
|
1229 |
< |
if ((fcoeff_perez = frlibopen(filename)) == NULL) |
1230 |
< |
{ |
1231 |
< |
fprintf(stderr,"file %s cannot be opened\n", filename); |
1232 |
< |
return 1; /* il y a un probleme de fichier */ |
1233 |
< |
} |
1234 |
< |
else |
1235 |
< |
{ |
1236 |
< |
/*printf("file %s open\n", filename);*/ |
1237 |
< |
} |
1238 |
< |
|
1239 |
< |
skip_comments(fcoeff_perez); |
1018 |
< |
|
1019 |
< |
for (i=0;i<8;i++) |
1020 |
< |
for (j=0;j<20;j++) |
1021 |
< |
{ |
1022 |
< |
fscanf(fcoeff_perez,"%f",&temp); |
1023 |
< |
*(*coeff_perez+i*20+j) = temp; |
1024 |
< |
} |
1025 |
< |
fclose(fcoeff_perez); |
1026 |
< |
|
1027 |
< |
return 0; /* tout est OK */ |
1225 |
> |
if (epsilon < 1.065) |
1226 |
> |
return 0; |
1227 |
> |
else if (epsilon < 1.230) |
1228 |
> |
return 1; |
1229 |
> |
else if (epsilon < 1.500) |
1230 |
> |
return 2; |
1231 |
> |
else if (epsilon < 1.950) |
1232 |
> |
return 3; |
1233 |
> |
else if (epsilon < 2.800) |
1234 |
> |
return 4; |
1235 |
> |
else if (epsilon < 4.500) |
1236 |
> |
return 5; |
1237 |
> |
else if (epsilon < 6.200) |
1238 |
> |
return 6; |
1239 |
> |
return 7; |
1240 |
|
} |
1241 |
|
|
1030 |
– |
|
1031 |
– |
|
1242 |
|
/* sky luminance perez model */ |
1243 |
< |
double calc_rel_lum_perez(double dzeta,double gamma,double Z, |
1034 |
< |
double epsilon,double Delta,float *coeff_perez) |
1243 |
> |
double calc_rel_lum_perez(double dzeta,double gamma,double Z,double epsilon,double Delta,float coeff_perez[]) |
1244 |
|
{ |
1245 |
+ |
|
1246 |
|
float x[5][4]; |
1247 |
|
int i,j,num_lin; |
1248 |
|
double c_perez[5]; |
1249 |
|
|
1250 |
|
if ( (epsilon < skyclearinf) || (epsilon >= skyclearsup) ) |
1251 |
|
{ |
1252 |
< |
fprintf(stderr,"Epsilon out of range in function calc_rel_lum_perez !\n"); |
1252 |
> |
fprintf(stderr,"Epsilon out of range in function calc_rel_lum_perez!\n"); |
1253 |
|
exit(1); |
1254 |
|
} |
1255 |
|
|
1258 |
|
{ |
1259 |
|
if ( Delta < 0.2 ) Delta = 0.2; |
1260 |
|
} |
1261 |
< |
|
1262 |
< |
if ( (epsilon >= 1.000) && (epsilon < 1.065) ) num_lin = 0; |
1263 |
< |
if ( (epsilon >= 1.065) && (epsilon < 1.230) ) num_lin = 1; |
1264 |
< |
if ( (epsilon >= 1.230) && (epsilon < 1.500) ) num_lin = 2; |
1055 |
< |
if ( (epsilon >= 1.500) && (epsilon < 1.950) ) num_lin = 3; |
1056 |
< |
if ( (epsilon >= 1.950) && (epsilon < 2.800) ) num_lin = 4; |
1057 |
< |
if ( (epsilon >= 2.800) && (epsilon < 4.500) ) num_lin = 5; |
1058 |
< |
if ( (epsilon >= 4.500) && (epsilon < 6.200) ) num_lin = 6; |
1059 |
< |
if ( (epsilon >= 6.200) && (epsilon < 14.00) ) num_lin = 7; |
1060 |
< |
|
1261 |
> |
|
1262 |
> |
|
1263 |
> |
num_lin = get_numlin(epsilon); |
1264 |
> |
|
1265 |
|
for (i=0;i<5;i++) |
1266 |
|
for (j=0;j<4;j++) |
1267 |
|
{ |
1268 |
|
x[i][j] = *(coeff_perez + 20*num_lin + 4*i +j); |
1269 |
< |
/* printf("x %d %d vaut %f\n",i,j,x[i][j]); */ |
1269 |
> |
/* fprintf(stderr,"x %d %d vaut %f\n",i,j,x[i][j]); */ |
1270 |
|
} |
1271 |
|
|
1272 |
|
|
1293 |
|
|
1294 |
|
|
1295 |
|
/* coefficients for the sky luminance perez model */ |
1296 |
< |
void coeff_lum_perez(double Z, double epsilon, double Delta, float *coeff_perez) |
1296 |
> |
void coeff_lum_perez(double Z, double epsilon, double Delta, float coeff_perez[]) |
1297 |
|
{ |
1298 |
|
float x[5][4]; |
1299 |
|
int i,j,num_lin; |
1309 |
|
{ |
1310 |
|
if ( Delta < 0.2 ) Delta = 0.2; |
1311 |
|
} |
1312 |
+ |
|
1313 |
+ |
|
1314 |
+ |
num_lin = get_numlin(epsilon); |
1315 |
|
|
1316 |
< |
if ( (epsilon >= 1.000) && (epsilon < 1.065) ) num_lin = 0; |
1110 |
< |
if ( (epsilon >= 1.065) && (epsilon < 1.230) ) num_lin = 1; |
1111 |
< |
if ( (epsilon >= 1.230) && (epsilon < 1.500) ) num_lin = 2; |
1112 |
< |
if ( (epsilon >= 1.500) && (epsilon < 1.950) ) num_lin = 3; |
1113 |
< |
if ( (epsilon >= 1.950) && (epsilon < 2.800) ) num_lin = 4; |
1114 |
< |
if ( (epsilon >= 2.800) && (epsilon < 4.500) ) num_lin = 5; |
1115 |
< |
if ( (epsilon >= 4.500) && (epsilon < 6.200) ) num_lin = 6; |
1116 |
< |
if ( (epsilon >= 6.200) && (epsilon < 14.00) ) num_lin = 7; |
1316 |
> |
/*fprintf(stderr,"numlin %d\n", num_lin);*/ |
1317 |
|
|
1318 |
|
for (i=0;i<5;i++) |
1319 |
|
for (j=0;j<4;j++) |
1345 |
|
} |
1346 |
|
|
1347 |
|
|
1348 |
+ |
|
1349 |
|
/* degrees into radians */ |
1350 |
|
double radians(double degres) |
1351 |
|
{ |
1352 |
|
return degres*M_PI/180.0; |
1353 |
|
} |
1354 |
|
|
1355 |
+ |
|
1356 |
|
/* radian into degrees */ |
1357 |
|
double degres(double radians) |
1358 |
|
{ |
1359 |
|
return radians/M_PI*180.0; |
1360 |
|
} |
1361 |
|
|
1362 |
+ |
|
1363 |
|
/* calculation of the angles dzeta and gamma */ |
1364 |
|
void theta_phi_to_dzeta_gamma(double theta,double phi,double *dzeta,double *gamma, double Z) |
1365 |
|
{ |
1376 |
|
} |
1377 |
|
|
1378 |
|
|
1176 |
– |
/********************************************************************************/ |
1177 |
– |
/* Fonction: theta_ordered */ |
1178 |
– |
/* */ |
1179 |
– |
/* In: char *filename */ |
1180 |
– |
/* */ |
1181 |
– |
/* Out: float * */ |
1182 |
– |
/* */ |
1183 |
– |
/* Update: 29/08/93 */ |
1184 |
– |
/* */ |
1185 |
– |
/* Rem: theta en degres */ |
1186 |
– |
/* */ |
1187 |
– |
/* But: fournit les valeurs de theta du fichier d'entree a la memoire */ |
1188 |
– |
/* */ |
1189 |
– |
/********************************************************************************/ |
1190 |
– |
float *theta_ordered(char *filename) |
1191 |
– |
{ |
1192 |
– |
int i; |
1193 |
– |
float buffer,*ptr; |
1194 |
– |
FILE *file_in; |
1379 |
|
|
1196 |
– |
if ( (file_in = frlibopen(filename)) == NULL ) |
1197 |
– |
{ |
1198 |
– |
fprintf(stderr,"Cannot open file %s in function theta_ordered\n",filename); |
1199 |
– |
exit(1); |
1200 |
– |
} |
1201 |
– |
|
1202 |
– |
skip_comments(file_in); |
1203 |
– |
|
1204 |
– |
if ( (ptr = malloc(145*sizeof(float))) == NULL ) |
1205 |
– |
{ |
1206 |
– |
fprintf(stderr,"Out of memory in function theta_ordered\n"); |
1207 |
– |
exit(1); |
1208 |
– |
} |
1209 |
– |
|
1210 |
– |
for (i=0;i<145;i++) |
1211 |
– |
{ |
1212 |
– |
fscanf(file_in,"%f",&buffer); |
1213 |
– |
*(ptr+i) = buffer; |
1214 |
– |
fscanf(file_in,"%f",&buffer); |
1215 |
– |
} |
1216 |
– |
|
1217 |
– |
fclose(file_in); |
1218 |
– |
return ptr; |
1219 |
– |
} |
1220 |
– |
|
1221 |
– |
|
1222 |
– |
/********************************************************************************/ |
1223 |
– |
/* Fonction: phi_ordered */ |
1224 |
– |
/* */ |
1225 |
– |
/* In: char *filename */ |
1226 |
– |
/* */ |
1227 |
– |
/* Out: float * */ |
1228 |
– |
/* */ |
1229 |
– |
/* Update: 29/08/93 */ |
1230 |
– |
/* */ |
1231 |
– |
/* Rem: valeurs de Phi en DEGRES */ |
1232 |
– |
/* */ |
1233 |
– |
/* But: mettre les angles contenus dans le fichier d'entree dans la memoire */ |
1234 |
– |
/* */ |
1235 |
– |
/********************************************************************************/ |
1236 |
– |
float *phi_ordered(char *filename) |
1237 |
– |
{ |
1238 |
– |
int i; |
1239 |
– |
float buffer,*ptr; |
1240 |
– |
FILE *file_in; |
1241 |
– |
|
1242 |
– |
if ( (file_in = frlibopen(filename)) == NULL ) |
1243 |
– |
{ |
1244 |
– |
fprintf(stderr,"Cannot open file %s in function phi_ordered\n",filename); |
1245 |
– |
exit(1); |
1246 |
– |
} |
1247 |
– |
|
1248 |
– |
skip_comments(file_in); |
1249 |
– |
|
1250 |
– |
if ( (ptr = malloc(145*sizeof(float))) == NULL ) |
1251 |
– |
{ |
1252 |
– |
fprintf(stderr,"Out of memory in function phi_ordered"); |
1253 |
– |
exit(1); |
1254 |
– |
} |
1255 |
– |
|
1256 |
– |
for (i=0;i<145;i++) |
1257 |
– |
{ |
1258 |
– |
fscanf(file_in,"%f",&buffer); |
1259 |
– |
fscanf(file_in,"%f",&buffer); |
1260 |
– |
*(ptr+i) = buffer; |
1261 |
– |
} |
1262 |
– |
|
1263 |
– |
fclose(file_in); |
1264 |
– |
return ptr; |
1265 |
– |
} |
1266 |
– |
|
1267 |
– |
|
1268 |
– |
/********************************************************************************/ |
1269 |
– |
/* Fonction: integ_lv */ |
1270 |
– |
/* */ |
1271 |
– |
/* In: float *lv,*theta */ |
1272 |
– |
/* int sun_pos */ |
1273 |
– |
/* */ |
1274 |
– |
/* Out: double */ |
1275 |
– |
/* */ |
1276 |
– |
/* Update: 29/08/93 */ |
1277 |
– |
/* */ |
1278 |
– |
/* Rem: */ |
1279 |
– |
/* */ |
1280 |
– |
/* But: calcul l'integrale de luminance relative sans la dir. du soleil */ |
1281 |
– |
/* */ |
1282 |
– |
/********************************************************************************/ |
1380 |
|
double integ_lv(float *lv,float *theta) |
1381 |
|
{ |
1382 |
|
int i; |
1383 |
|
double buffer=0.0; |
1384 |
< |
|
1384 |
> |
|
1385 |
|
for (i=0;i<145;i++) |
1386 |
+ |
{ |
1387 |
|
buffer += (*(lv+i))*cos(radians(*(theta+i))); |
1388 |
< |
|
1388 |
> |
} |
1389 |
> |
|
1390 |
|
return buffer*2*M_PI/144; |
1292 |
– |
|
1391 |
|
} |
1392 |
|
|
1393 |
|
|
1394 |
|
|
1297 |
– |
|
1298 |
– |
|
1299 |
– |
|
1395 |
|
/* enter day number(double), return E0 = square(R0/R): eccentricity correction factor */ |
1396 |
|
|
1397 |
|
double get_eccentricity() |
1404 |
|
0.000719*cos(2*day_angle)+0.000077*sin(2*day_angle); |
1405 |
|
|
1406 |
|
return (E0); |
1312 |
– |
|
1407 |
|
} |
1408 |
|
|
1409 |
|
|
1411 |
|
double air_mass() |
1412 |
|
{ |
1413 |
|
double m; |
1320 |
– |
|
1414 |
|
if (sunzenith>90) |
1415 |
|
{ |
1416 |
< |
fprintf(stderr, "solar zenith angle larger than 90� in fuction air_mass():\n the models used are not more valid\n"); |
1416 |
> |
fprintf(stderr, "Solar zenith angle larger than 90 degrees in function air_mass()\n"); |
1417 |
|
exit(1); |
1418 |
|
} |
1326 |
– |
|
1419 |
|
m = 1/( cos(sunzenith*M_PI/180)+0.15*exp( log(93.885-sunzenith)*(-1.253) ) ); |
1420 |
|
return(m); |
1421 |
|
} |
1330 |
– |
|
1331 |
– |
|
1332 |
– |
double get_angle_sun_direction(double sun_zenith, double sun_azimut, double direction_zenith, double direction_azimut) |
1333 |
– |
|
1334 |
– |
{ |
1335 |
– |
|
1336 |
– |
double angle; |
1337 |
– |
|
1338 |
– |
|
1339 |
– |
if (sun_zenith == 0) |
1340 |
– |
puts("WARNING: zenith_angle = 0 in function get_angle_sun_vert_plan"); |
1341 |
– |
|
1342 |
– |
angle = acos( cos(sun_zenith*M_PI/180)*cos(direction_zenith*M_PI/180) + sin(sun_zenith*M_PI/180)*sin(direction_zenith*M_PI/180)*cos((sun_azimut-direction_azimut)*M_PI/180) ); |
1343 |
– |
angle = angle*180/M_PI; |
1344 |
– |
return(angle); |
1345 |
– |
} |
1346 |
– |
|
1347 |
– |
|
1348 |
– |
|
1349 |
– |
|
1350 |
– |
|
1422 |
|
|
1423 |
|
|
1424 |
|
|