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root/radiance/src/gen/gendaymtx.c
Revision: 2.44
Committed: Sat Jun 7 05:09:45 2025 UTC (4 months, 2 weeks ago) by greg
Content type: text/plain
Branch: MAIN
CVS Tags: rad6R0, HEAD
Changes since 2.43: +1 -2 lines
Log Message: 
refactor: Put some declarations into "paths.h" and included in "platform.h"

File Contents

# User Rev Content
1 greg 2.1 #ifndef lint
2 greg 2.44 static const char RCSid[] = "$Id: gendaymtx.c,v 2.43 2025/06/06 19:11:21 greg Exp $";
3 greg 2.1 #endif
4     /*
5     * gendaymtx.c
6     *
7     * Generate a daylight matrix based on Perez Sky Model.
8     *
9     * Most of this code is borrowed (see copyright below) from Ian Ashdown's
10     * excellent re-implementation of Jean-Jacques Delaunay's gendaylit.c
11     *
12     * Created by Greg Ward on 1/16/13.
13     */
14    
15     /*********************************************************************
16     *
17     * H32_gendaylit.CPP - Perez Sky Model Calculation
18     *
19     * Version: 1.00A
20     *
21     * History: 09/10/01 - Created.
22     * 11/10/08 - Modified for Unix compilation.
23     * 11/10/12 - Fixed conditional __max directive.
24     * 1/11/13 - Tweaks and optimizations (G.Ward)
25     *
26     * Compilers: Microsoft Visual C/C++ Professional V10.0
27     *
28     * Author: Ian Ashdown, P.Eng.
29     * byHeart Consultants Limited
30     * 620 Ballantree Road
31     * West Vancouver, B.C.
32     * Canada V7S 1W3
33     * e-mail: [email protected]
34     *
35     * References: Perez, R., P. Ineichen, R. Seals, J. Michalsky, and R.
36     * Stewart. 1990. ìModeling Daylight Availability and
37     * Irradiance Components from Direct and Global
38     * Irradiance,î Solar Energy 44(5):271-289.
39     *
40     * Perez, R., R. Seals, and J. Michalsky. 1993.
41     * ìAll-Weather Model for Sky Luminance Distribution -
42     * Preliminary Configuration and Validation,î Solar Energy
43     * 50(3):235-245.
44     *
45     * Perez, R., R. Seals, and J. Michalsky. 1993. "ERRATUM to
46     * All-Weather Model for Sky Luminance Distribution -
47     * Preliminary Configuration and Validation,î Solar Energy
48     * 51(5):423.
49     *
50     * NOTE: This program is a completely rewritten version of
51     * gendaylit.c written by Jean-Jacques Delaunay (1994).
52     *
53     * Copyright 2009-2012 byHeart Consultants Limited. All rights
54     * reserved.
55     *
56     * Redistribution and use in source and binary forms, with or without
57     * modification, are permitted for personal and commercial purposes
58     * provided that redistribution of source code must retain the above
59     * copyright notice, this list of conditions and the following
60     * disclaimer:
61     *
62     * THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESSED OR IMPLIED
63     * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
64     * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
65     * DISCLAIMED. IN NO EVENT SHALL byHeart Consultants Limited OR
66     * ITS EMPLOYEES BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
67     * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
68     * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF
69     * USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
70     * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
71     * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
72     * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
73     * POSSIBILITY OF SUCH DAMAGE.
74     *
75     *********************************************************************/
76    
77     /* Zenith is along the Z-axis */
78     /* X-axis points east */
79     /* Y-axis points north */
80     /* azimuth is measured as degrees or radians east of North */
81    
82     /* Include files */
83     #define _USE_MATH_DEFINES
84     #include <stdlib.h>
85     #include <ctype.h>
86 greg 2.30 #include "platform.h"
87 greg 2.1 #include "rtmath.h"
88 greg 2.23 #include "rtio.h"
89 greg 2.1 #include "color.h"
90 greg 2.30 #include "sun.h"
91 greg 2.41 #include "loadEPW.h"
92 greg 2.1
93     const double DC_SolarConstantE = 1367.0; /* Solar constant W/m^2 */
94     const double DC_SolarConstantL = 127.5; /* Solar constant klux */
95    
96     double altitude; /* Solar altitude (radians) */
97     double azimuth; /* Solar azimuth (radians) */
98     double apwc; /* Atmospheric precipitable water content */
99     double dew_point = 11.0; /* Surface dew point temperature (deg. C) */
100     double diff_illum; /* Diffuse illuminance */
101     double diff_irrad; /* Diffuse irradiance */
102     double dir_illum; /* Direct illuminance */
103     double dir_irrad; /* Direct irradiance */
104     int julian_date; /* Julian date */
105     double perez_param[5]; /* Perez sky model parameters */
106     double sky_brightness; /* Sky brightness */
107     double sky_clearness; /* Sky clearness */
108     double solar_rad; /* Solar radiance */
109     double sun_zenith; /* Sun zenith angle (radians) */
110     int input = 0; /* Input type */
111 greg 2.11 int output = 0; /* Output type */
112 greg 2.1
113     extern double dmax( double, double );
114     extern double CalcAirMass();
115     extern double CalcDiffuseIllumRatio( int );
116     extern double CalcDiffuseIrradiance();
117     extern double CalcDirectIllumRatio( int );
118     extern double CalcDirectIrradiance();
119     extern double CalcEccentricity();
120     extern double CalcPrecipWater( double );
121     extern double CalcRelHorzIllum( float *parr );
122     extern double CalcRelLuminance( double, double );
123     extern double CalcSkyBrightness();
124     extern double CalcSkyClearness();
125     extern int CalcSkyParamFromIllum();
126     extern int GetCategoryIndex();
127     extern void CalcPerezParam( double, double, double, int );
128     extern void CalcSkyPatchLumin( float *parr );
129     extern void ComputeSky( float *parr );
130    
131 greg 2.40
132     extern double solar_sunset(int month, int day);
133     extern double solar_sunrise(int month, int day);
134    
135 greg 2.1 /* Degrees into radians */
136     #define DegToRad(deg) ((deg)*(PI/180.))
137    
138     /* Radiuans into degrees */
139     #define RadToDeg(rad) ((rad)*(180./PI))
140    
141     /* Perez sky model coefficients */
142    
143     /* Reference: Perez, R., R. Seals, and J. Michalsky, 1993. "All- */
144     /* Weather Model for Sky Luminance Distribution - */
145     /* Preliminary Configuration and Validation," Solar */
146     /* Energy 50(3):235-245, Table 1. */
147    
148     static const double PerezCoeff[8][20] =
149     {
150     /* Sky clearness (epsilon): 1.000 to 1.065 */
151     { 1.3525, -0.2576, -0.2690, -1.4366, -0.7670,
152     0.0007, 1.2734, -0.1233, 2.8000, 0.6004,
153     1.2375, 1.0000, 1.8734, 0.6297, 0.9738,
154     0.2809, 0.0356, -0.1246, -0.5718, 0.9938 },
155     /* Sky clearness (epsilon): 1.065 to 1.230 */
156     { -1.2219, -0.7730, 1.4148, 1.1016, -0.2054,
157     0.0367, -3.9128, 0.9156, 6.9750, 0.1774,
158     6.4477, -0.1239, -1.5798, -0.5081, -1.7812,
159     0.1080, 0.2624, 0.0672, -0.2190, -0.4285 },
160     /* Sky clearness (epsilon): 1.230 to 1.500 */
161     { -1.1000, -0.2515, 0.8952, 0.0156, 0.2782,
162     -0.1812, - 4.5000, 1.1766, 24.7219, -13.0812,
163     -37.7000, 34.8438, -5.0000, 1.5218, 3.9229,
164     -2.6204, -0.0156, 0.1597, 0.4199, -0.5562 },
165     /* Sky clearness (epsilon): 1.500 to 1.950 */
166     { -0.5484, -0.6654, -0.2672, 0.7117, 0.7234,
167     -0.6219, -5.6812, 2.6297, 33.3389, -18.3000,
168     -62.2500, 52.0781, -3.5000, 0.0016, 1.1477,
169     0.1062, 0.4659, -0.3296, -0.0876, -0.0329 },
170     /* Sky clearness (epsilon): 1.950 to 2.800 */
171     { -0.6000, -0.3566, -2.5000, 2.3250, 0.2937,
172     0.0496, -5.6812, 1.8415, 21.0000, -4.7656 ,
173     -21.5906, 7.2492, -3.5000, -0.1554, 1.4062,
174     0.3988, 0.0032, 0.0766, -0.0656, -0.1294 },
175     /* Sky clearness (epsilon): 2.800 to 4.500 */
176     { -1.0156, -0.3670, 1.0078, 1.4051, 0.2875,
177     -0.5328, -3.8500, 3.3750, 14.0000, -0.9999,
178     -7.1406, 7.5469, -3.4000, -0.1078, -1.0750,
179     1.5702, -0.0672, 0.4016, 0.3017, -0.4844 },
180     /* Sky clearness (epsilon): 4.500 to 6.200 */
181     { -1.0000, 0.0211, 0.5025, -0.5119, -0.3000,
182     0.1922, 0.7023, -1.6317, 19.0000, -5.0000,
183     1.2438, -1.9094, -4.0000, 0.0250, 0.3844,
184     0.2656, 1.0468, -0.3788, -2.4517, 1.4656 },
185     /* Sky clearness (epsilon): 6.200 to ... */
186     { -1.0500, 0.0289, 0.4260, 0.3590, -0.3250,
187     0.1156, 0.7781, 0.0025, 31.0625, -14.5000,
188     -46.1148, 55.3750, -7.2312, 0.4050, 13.3500,
189     0.6234, 1.5000, -0.6426, 1.8564, 0.5636 }
190     };
191    
192     /* Perez irradiance component model coefficients */
193    
194     /* Reference: Perez, R., P. Ineichen, R. Seals, J. Michalsky, and R. */
195     /* Stewart. 1990. ìModeling Daylight Availability and */
196     /* Irradiance Components from Direct and Global */
197     /* Irradiance,î Solar Energy 44(5):271-289. */
198    
199     typedef struct
200     {
201     double lower; /* Lower bound */
202     double upper; /* Upper bound */
203     } CategoryBounds;
204    
205     /* Perez sky clearness (epsilon) categories (Table 1) */
206     static const CategoryBounds SkyClearCat[8] =
207     {
208     { 1.000, 1.065 }, /* Overcast */
209     { 1.065, 1.230 },
210     { 1.230, 1.500 },
211     { 1.500, 1.950 },
212     { 1.950, 2.800 },
213     { 2.800, 4.500 },
214     { 4.500, 6.200 },
215 greg 2.12 { 6.200, 12.01 } /* Clear */
216 greg 2.1 };
217    
218     /* Luminous efficacy model coefficients */
219     typedef struct
220     {
221     double a;
222     double b;
223     double c;
224     double d;
225     } ModelCoeff;
226    
227     /* Diffuse luminous efficacy model coefficients (Table 4, Eqn. 7) */
228     static const ModelCoeff DiffuseLumEff[8] =
229     {
230     { 97.24, -0.46, 12.00, -8.91 },
231     { 107.22, 1.15, 0.59, -3.95 },
232     { 104.97, 2.96, -5.53, -8.77 },
233     { 102.39, 5.59, -13.95, -13.90 },
234     { 100.71, 5.94, -22.75, -23.74 },
235     { 106.42, 3.83, -36.15, -28.83 },
236     { 141.88, 1.90, -53.24, -14.03 },
237     { 152.23, 0.35, -45.27, -7.98 }
238     };
239    
240     /* Direct luminous efficacy model coefficients (Table 4, Eqn. 8) */
241     static const ModelCoeff DirectLumEff[8] =
242     {
243     { 57.20, -4.55, -2.98, 117.12 },
244     { 98.99, -3.46, -1.21, 12.38 },
245     { 109.83, -4.90, -1.71, -8.81 },
246     { 110.34, -5.84, -1.99, -4.56 },
247     { 106.36, -3.97, -1.75, -6.16 },
248     { 107.19, -1.25, -1.51, -26.73 },
249     { 105.75, 0.77, -1.26, -34.44 },
250     { 101.18, 1.58, -1.10, -8.29 }
251     };
252    
253 greg 2.3 #ifndef NSUNPATCH
254 greg 2.10 #define NSUNPATCH 4 /* max. # patches to spread sun into */
255 greg 2.3 #endif
256    
257 greg 2.35 #define SUN_ANG_DEG 0.533 /* sun full-angle in degrees */
258    
259 greg 2.10 int nsuns = NSUNPATCH; /* number of sun patches to use */
260     double fixed_sun_sa = -1; /* fixed solid angle per sun? */
261    
262 greg 2.1 int verbose = 0; /* progress reports to stderr? */
263    
264     int outfmt = 'a'; /* output format */
265    
266     int rhsubdiv = 1; /* Reinhart sky subdivisions */
267    
268 greg 2.4 COLOR skycolor = {.96, 1.004, 1.118}; /* sky coloration */
269     COLOR suncolor = {1., 1., 1.}; /* sun color */
270     COLOR grefl = {.2, .2, .2}; /* ground reflectance */
271 greg 2.1
272     int nskypatch; /* number of Reinhart patches */
273     float *rh_palt; /* sky patch altitudes (radians) */
274     float *rh_pazi; /* sky patch azimuths (radians) */
275     float *rh_dom; /* sky patch solid angle (sr) */
276    
277 greg 2.36 #define vector(v,alt,azi) ( (v)[1] = cos(alt), \
278     (v)[0] = (v)[1]*sin(azi), \
279     (v)[1] *= cos(azi), \
280     (v)[2] = sin(alt) )
281 greg 2.1
282     #define rh_vector(v,i) vector(v,rh_palt[i],rh_pazi[i])
283    
284     #define rh_cos(i) tsin(rh_palt[i])
285    
286 greg 2.36 #define solar_minute(jd,hr) ((24*60)*((jd)-1)+(int)((hr)*60.+.5))
287    
288 greg 2.1 extern int rh_init(void);
289     extern float * resize_dmatrix(float *mtx_data, int nsteps, int npatch);
290 greg 2.36 extern void OutputSun(int id, int goodsun, FILE *fp, FILE *mfp);
291 greg 2.1 extern void AddDirect(float *parr);
292    
293 greg 2.14
294     static const char *
295     getfmtname(int fmt)
296     {
297     switch (fmt) {
298     case 'a':
299     return("ascii");
300     case 'f':
301     return("float");
302     case 'd':
303     return("double");
304     }
305     return("unknown");
306     }
307    
308    
309 greg 2.1 int
310     main(int argc, char *argv[])
311     {
312 greg 2.41 EPWheader *epw = NULL; /* EPW/WEA input file */
313     EPWrecord erec; /* current EPW/WEA input record */
314     float dpthist[2]; /* previous dew point temps */
315     double dir, dif;
316 greg 2.14 int doheader = 1; /* output header? */
317 greg 2.8 double rotation = 0; /* site rotation (degrees) */
318 greg 2.1 double elevation; /* site elevation (meters) */
319 greg 2.36 int leap_day = 0; /* add leap day? */
320 greg 2.37 int sun_hours_only = 0; /* only output sun hours? */
321 greg 2.1 int dir_is_horiz; /* direct is meas. on horizontal? */
322 greg 2.34 FILE *sunsfp = NULL; /* output file for individual suns */
323 greg 2.36 FILE *modsfp = NULL; /* modifier output file */
324 greg 2.1 float *mtx_data = NULL; /* our matrix data */
325 greg 2.28 int avgSky = 0; /* compute average sky r.t. matrix? */
326 greg 2.27 int ntsteps = 0; /* number of time steps */
327 greg 2.28 int tstorage = 0; /* number of allocated time steps */
328     int nstored = 0; /* number of time steps in matrix */
329 greg 2.1 int last_monthly = 0; /* month of last report */
330     int mtx_offset;
331     int i, j;
332 greg 2.40 double timeinterval = 0;
333 greg 2.1
334 greg 2.43 fixargv0(argv[0]);
335 greg 2.1 /* get options */
336     for (i = 1; i < argc && argv[i][0] == '-'; i++)
337     switch (argv[i][1]) {
338 greg 2.4 case 'g': /* ground reflectance */
339     grefl[0] = atof(argv[++i]);
340     grefl[1] = atof(argv[++i]);
341     grefl[2] = atof(argv[++i]);
342 greg 2.1 break;
343 greg 2.4 case 'v': /* verbose progress reports */
344 greg 2.1 verbose++;
345     break;
346 greg 2.14 case 'h': /* turn off header */
347     doheader = 0;
348     break;
349 greg 2.4 case 'o': /* output format */
350 greg 2.1 switch (argv[i][2]) {
351     case 'f':
352     case 'd':
353     case 'a':
354     outfmt = argv[i][2];
355     break;
356     default:
357     goto userr;
358     }
359     break;
360 greg 2.11 case 'O': /* output type */
361     switch (argv[i][2]) {
362     case '0':
363     output = 0;
364     break;
365     case '1':
366     output = 1;
367     break;
368     default:
369     goto userr;
370     }
371     if (argv[i][3])
372     goto userr;
373     break;
374 greg 2.4 case 'm': /* Reinhart subdivisions */
375 greg 2.1 rhsubdiv = atoi(argv[++i]);
376     break;
377 greg 2.4 case 'c': /* sky color */
378 greg 2.1 skycolor[0] = atof(argv[++i]);
379     skycolor[1] = atof(argv[++i]);
380     skycolor[2] = atof(argv[++i]);
381     break;
382 greg 2.36 case 'D': /* output suns to file */
383     if (strcmp(argv[++i], "-")) {
384     sunsfp = fopen(argv[i], "w");
385     if (sunsfp == NULL) {
386     fprintf(stderr,
387     "%s: cannot open '%s' for output\n",
388     progname, argv[i]);
389     exit(1);
390     }
391     break; /* still may output matrix */
392     }
393     sunsfp = stdout; /* sending to stdout, so... */
394     /* fall through */
395 greg 2.34 case 'n': /* no matrix output */
396     avgSky = -1;
397     rhsubdiv = 1;
398     /* fall through */
399 greg 2.4 case 'd': /* solar (direct) only */
400 greg 2.1 skycolor[0] = skycolor[1] = skycolor[2] = 0;
401 greg 2.33 grefl[0] = grefl[1] = grefl[2] = 0;
402 greg 2.1 break;
403 greg 2.36 case 'M': /* send sun modifiers to file */
404     if ((modsfp = fopen(argv[++i], "w")) == NULL) {
405 greg 2.34 fprintf(stderr, "%s: cannot open '%s' for output\n",
406 greg 2.35 progname, argv[i]);
407 greg 2.34 exit(1);
408     }
409     break;
410 greg 2.4 case 's': /* sky only (no direct) */
411     suncolor[0] = suncolor[1] = suncolor[2] = 0;
412 greg 2.1 break;
413 greg 2.37 case 'u': /* solar hours only */
414     sun_hours_only = 1;
415     break;
416 greg 2.8 case 'r': /* rotate distribution */
417     if (argv[i][2] && argv[i][2] != 'z')
418     goto userr;
419     rotation = atof(argv[++i]);
420     break;
421 greg 2.10 case '5': /* 5-phase calculation */
422     nsuns = 1;
423 greg 2.19 fixed_sun_sa = PI/360.*atof(argv[++i]);
424 greg 2.21 if (fixed_sun_sa <= 0) {
425     fprintf(stderr, "%s: missing solar disk size argument for '-5' option\n",
426 greg 2.35 progname);
427 greg 2.21 exit(1);
428     }
429 greg 2.19 fixed_sun_sa *= fixed_sun_sa*PI;
430 greg 2.10 break;
431 greg 2.27 case 'A': /* compute average sky */
432     avgSky = 1;
433     break;
434 greg 2.40 case 'i':
435     timeinterval = atof(argv[++i]);
436     break;
437 greg 2.1 default:
438     goto userr;
439     }
440 greg 2.41 if ((i < argc-1) | (i > argc))
441 greg 2.1 goto userr;
442 greg 2.41 epw = EPWopen(argv[i]);
443     if (epw == NULL)
444 greg 2.1 exit(1);
445 greg 2.36 if ((modsfp != NULL) & (sunsfp == NULL))
446     fprintf(stderr, "%s: warning -M output will be empty without -D\n",
447     progname);
448 greg 2.1 if (verbose) {
449     if (i == argc-1)
450     fprintf(stderr, "%s: reading weather tape '%s'\n",
451     progname, argv[i]);
452     else
453     fprintf(stderr, "%s: reading weather tape from <stdin>\n",
454     progname);
455     }
456     /* read weather tape header */
457 greg 2.41 s_latitude = epw->loc.latitude;
458     s_longitude = -epw->loc.longitude;
459     s_meridian = -15.*epw->loc.timezone;
460     elevation = epw->loc.elevation;
461     switch (epw->isWEA) { /* translate units */
462     case WEAnot:
463     case WEAradnorm:
464 greg 2.1 input = 1; /* radiometric quantities */
465     dir_is_horiz = 0; /* direct is perpendicular meas. */
466     break;
467 greg 2.41 case WEAradhoriz:
468 greg 2.1 input = 1; /* radiometric quantities */
469     dir_is_horiz = 1; /* solar measured horizontally */
470     break;
471 greg 2.41 case WEAphotnorm:
472 greg 2.1 input = 2; /* photometric quantities */
473     dir_is_horiz = 0; /* direct is perpendicular meas. */
474     break;
475     default:
476     goto fmterr;
477     }
478     rh_init(); /* initialize sky patches */
479     if (verbose) {
480 greg 2.41 fprintf(stderr, "%s: location '%s, %s'\n", progname,
481     epw->loc.city, epw->loc.country);
482 greg 2.1 fprintf(stderr, "%s: (lat,long)=(%.1f,%.1f) degrees north, west\n",
483     progname, s_latitude, s_longitude);
484 greg 2.35 if (avgSky >= 0)
485     fprintf(stderr, "%s: %d sky patches\n",
486     progname, nskypatch);
487     if (sunsfp)
488 greg 2.39 fprintf(stderr, "%s: outputting suns to %s\n",
489     progname, sunsfp==stdout ? "stdout" : "file");
490 greg 2.8 if (rotation != 0)
491     fprintf(stderr, "%s: rotating output %.0f degrees\n",
492     progname, rotation);
493 greg 2.1 }
494 greg 2.2 /* convert quantities to radians */
495     s_latitude = DegToRad(s_latitude);
496     s_longitude = DegToRad(s_longitude);
497     s_meridian = DegToRad(s_meridian);
498 greg 2.27 /* initial allocation */
499 greg 2.28 mtx_data = resize_dmatrix(mtx_data, tstorage=2, nskypatch);
500 greg 2.41 dpthist[0] = -100;
501 greg 2.1 /* process each time step in tape */
502 greg 2.41 while ((j = EPWread(epw, &erec)) > 0) {
503 greg 2.42 const int mo = erec.date.month+1;
504     const int da = erec.date.day;
505     const double hr = erec.date.hour;
506 greg 2.40 double sda, sta, st;
507 greg 2.37 int sun_in_sky;
508 greg 2.42 /* 3-hour dew point temp */
509     if (EPWisset(&erec,dptemp)) {
510     if (dpthist[0] < -99)
511     dpthist[0] = dpthist[1] = erec.dptemp;
512     dew_point = (1./3.)*(dpthist[0] + dpthist[1] + erec.dptemp);
513     dpthist[0] = dpthist[1]; dpthist[1] = erec.dptemp;
514     } else
515     dpthist[0] = -100;
516 greg 2.1 /* compute solar position */
517 greg 2.36 if ((mo == 2) & (da == 29)) {
518     julian_date = 60;
519     leap_day = 1;
520     } else
521     julian_date = jdate(mo, da) + leap_day;
522 greg 2.1 sda = sdec(julian_date);
523     sta = stadj(julian_date);
524 greg 2.40 st = hr + sta;
525    
526     if (timeinterval > 0) {
527     if (fabs(solar_sunrise(mo, da) - st) <= timeinterval/120)
528     st = (st + timeinterval/120 + solar_sunrise(mo, da))/2;
529     else if (fabs(solar_sunset(mo, da) - st) < timeinterval/120)
530     st = (st - timeinterval/120 + solar_sunset(mo, da))/2;
531     }
532     altitude = salt(sda, st);
533 greg 2.37 sun_in_sky = (altitude > -DegToRad(SUN_ANG_DEG/2.));
534 greg 2.42 if (sun_hours_only & !sun_in_sky)
535 greg 2.37 continue; /* skipping nighttime points */
536 greg 2.40 azimuth = sazi(sda, st) + PI - DegToRad(rotation);
537 greg 2.36
538 greg 2.41 switch (epw->isWEA) { /* translate units */
539     case WEAnot:
540     case WEAradnorm:
541     if (!EPWisset(&erec,dirirrad) |
542     !EPWisset(&erec,horizdiffirrad)) {
543     fprintf(stderr, "%s: missing required irradiances at line %d\n",
544     progname, epw->lino);
545     exit(1);
546     }
547     dir = erec.dirirrad;
548     dif = erec.horizdiffirrad;
549     break;
550     case WEAradhoriz:
551     dir = erec.globhorizirrad - erec.horizdiffirrad;
552     dif = erec.horizdiffirrad;
553     break;
554     case WEAphotnorm:
555     dir = erec.dirillum;
556     dif = erec.diffillum;
557     break;
558     }
559 greg 2.37 mtx_offset = 3*nskypatch*nstored;
560     nstored += !avgSky | !nstored;
561     /* make space for next row */
562     if (nstored > tstorage) {
563     tstorage += (tstorage>>1) + nstored + 7;
564     mtx_data = resize_dmatrix(mtx_data, tstorage, nskypatch);
565     }
566     ntsteps++; /* keep count of time steps */
567    
568 greg 2.36 if (dir+dif <= 1e-4) { /* effectively nighttime? */
569     if (!avgSky | !mtx_offset)
570     memset(mtx_data+mtx_offset, 0,
571     sizeof(float)*3*nskypatch);
572 greg 2.37 /* output black sun? */
573     if (sunsfp && sun_in_sky)
574 greg 2.36 OutputSun(solar_minute(julian_date,hr), 0,
575     sunsfp, modsfp);
576     continue;
577     }
578 greg 2.38 if (!sun_in_sky && dir > (input==1 ? 20. : 20.*WHTEFFICACY))
579     fprintf(stderr,
580     "%s: warning - unusually bright at %.1f on %d-%d\n",
581     progname, hr, mo, da);
582 greg 2.1 /* convert measured values */
583 greg 2.38 if (dir_is_horiz && altitude > FTINY)
584 greg 2.1 dir /= sin(altitude);
585     if (input == 1) {
586     dir_irrad = dir;
587     diff_irrad = dif;
588     } else /* input == 2 */ {
589     dir_illum = dir;
590     diff_illum = dif;
591     }
592     /* compute sky patch values */
593     ComputeSky(mtx_data+mtx_offset);
594 greg 2.37 /* output sun if requested */
595     if (sunsfp && sun_in_sky)
596 greg 2.36 OutputSun(solar_minute(julian_date,hr), 1,
597     sunsfp, modsfp);
598 greg 2.35
599 greg 2.34 if (avgSky < 0) /* no matrix? */
600     continue;
601    
602 greg 2.4 AddDirect(mtx_data+mtx_offset);
603 greg 2.27 /* update cumulative sky? */
604     for (i = 3*nskypatch*(avgSky&(ntsteps>1)); i--; )
605     mtx_data[i] += mtx_data[mtx_offset+i];
606 greg 2.34 /* monthly reporting */
607     if (verbose && mo != last_monthly)
608     fprintf(stderr, "%s: stepping through month %d...\n",
609     progname, last_monthly=mo);
610 greg 2.36 /* note whether leap-day was given */
611 greg 2.34 }
612 greg 2.41 if (j != EOF) {
613     fprintf(stderr, "%s: error on input\n", progname);
614     exit(1);
615     }
616     EPWclose(epw); epw = NULL;
617 greg 2.34 if (!ntsteps) {
618     fprintf(stderr, "%s: no valid time steps on input\n", progname);
619     exit(1);
620 greg 2.1 }
621 greg 2.34 if (avgSky < 0) /* no matrix output? */
622     goto alldone;
623    
624 greg 2.27 dif = 1./(double)ntsteps; /* average sky? */
625     for (i = 3*nskypatch*(avgSky&(ntsteps>1)); i--; )
626     mtx_data[i] *= dif;
627 greg 2.1 /* write out matrix */
628 greg 2.14 if (outfmt != 'a')
629     SET_FILE_BINARY(stdout);
630 greg 2.1 #ifdef getc_unlocked
631     flockfile(stdout);
632     #endif
633     if (verbose)
634     fprintf(stderr, "%s: writing %smatrix with %d time steps...\n",
635 greg 2.28 progname, outfmt=='a' ? "" : "binary ", nstored);
636 greg 2.14 if (doheader) {
637     newheader("RADIANCE", stdout);
638     printargs(argc, argv, stdout);
639     printf("LATLONG= %.8f %.8f\n", RadToDeg(s_latitude),
640     -RadToDeg(s_longitude));
641     printf("NROWS=%d\n", nskypatch);
642 greg 2.28 printf("NCOLS=%d\n", nstored);
643 greg 2.14 printf("NCOMP=3\n");
644 greg 2.29 if ((outfmt == 'f') | (outfmt == 'd'))
645     fputendian(stdout);
646 greg 2.18 fputformat((char *)getfmtname(outfmt), stdout);
647 greg 2.14 putchar('\n');
648     }
649 greg 2.1 /* patches are rows (outer sort) */
650     for (i = 0; i < nskypatch; i++) {
651     mtx_offset = 3*i;
652     switch (outfmt) {
653     case 'a':
654 greg 2.28 for (j = 0; j < nstored; j++) {
655 greg 2.3 printf("%.3g %.3g %.3g\n", mtx_data[mtx_offset],
656 greg 2.1 mtx_data[mtx_offset+1],
657     mtx_data[mtx_offset+2]);
658     mtx_offset += 3*nskypatch;
659     }
660 greg 2.28 if (nstored > 1)
661 greg 2.2 fputc('\n', stdout);
662 greg 2.1 break;
663     case 'f':
664 greg 2.28 for (j = 0; j < nstored; j++) {
665 greg 2.23 putbinary(mtx_data+mtx_offset, sizeof(float), 3,
666 greg 2.1 stdout);
667     mtx_offset += 3*nskypatch;
668     }
669     break;
670     case 'd':
671 greg 2.28 for (j = 0; j < nstored; j++) {
672 greg 2.1 double ment[3];
673     ment[0] = mtx_data[mtx_offset];
674     ment[1] = mtx_data[mtx_offset+1];
675     ment[2] = mtx_data[mtx_offset+2];
676 greg 2.23 putbinary(ment, sizeof(double), 3, stdout);
677 greg 2.1 mtx_offset += 3*nskypatch;
678     }
679     break;
680     }
681     if (ferror(stdout))
682     goto writerr;
683     }
684 greg 2.34 alldone:
685     if (fflush(NULL) == EOF)
686 greg 2.1 goto writerr;
687     if (verbose)
688     fprintf(stderr, "%s: done.\n", progname);
689     exit(0);
690     userr:
691 greg 2.37 fprintf(stderr, "Usage: %s [-v][-h][-A][-d|-s|-n][-u][-D file [-M modfile]][-r deg][-m N][-g r g b][-c r g b][-o{f|d}][-O{0|1}] [tape.wea]\n",
692 greg 2.1 progname);
693     exit(1);
694     fmterr:
695 greg 2.34 fprintf(stderr, "%s: weather tape format error in header\n", progname);
696 greg 2.1 exit(1);
697     writerr:
698     fprintf(stderr, "%s: write error on output\n", progname);
699     exit(1);
700     }
701    
702 greg 2.40
703 greg 2.1 /* Return maximum of two doubles */
704     double dmax( double a, double b )
705     { return (a > b) ? a : b; }
706    
707     /* Compute sky patch radiance values (modified by GW) */
708     void
709     ComputeSky(float *parr)
710     {
711     int index; /* Category index */
712     double norm_diff_illum; /* Normalized diffuse illuimnance */
713     int i;
714 greg 2.42
715 greg 2.1 /* Calculate atmospheric precipitable water content */
716     apwc = CalcPrecipWater(dew_point);
717    
718 greg 2.6 /* Calculate sun zenith angle (don't let it dip below horizon) */
719     /* Also limit minimum angle to keep circumsolar off zenith */
720     if (altitude <= 0.0)
721     sun_zenith = DegToRad(90.0);
722     else if (altitude >= DegToRad(87.0))
723     sun_zenith = DegToRad(3.0);
724     else
725     sun_zenith = DegToRad(90.0) - altitude;
726 greg 2.1
727     /* Compute the inputs for the calculation of the sky distribution */
728    
729     if (input == 0) /* XXX never used */
730     {
731     /* Calculate irradiance */
732     diff_irrad = CalcDiffuseIrradiance();
733     dir_irrad = CalcDirectIrradiance();
734    
735     /* Calculate illuminance */
736     index = GetCategoryIndex();
737     diff_illum = diff_irrad * CalcDiffuseIllumRatio(index);
738     dir_illum = dir_irrad * CalcDirectIllumRatio(index);
739     }
740     else if (input == 1)
741     {
742     sky_brightness = CalcSkyBrightness();
743     sky_clearness = CalcSkyClearness();
744    
745 greg 2.9 /* Limit sky clearness */
746     if (sky_clearness > 11.9)
747     sky_clearness = 11.9;
748 greg 2.40 else if (sky_clearness < 1.0)
749     sky_clearness = 1.0;
750 greg 2.9
751     /* Limit sky brightness */
752     if (sky_brightness < 0.01)
753 greg 2.11 sky_brightness = 0.01;
754 greg 2.40 else if (sky_brightness > 0.6)
755     sky_brightness = 0.6;
756 greg 2.9
757 greg 2.1 /* Calculate illuminance */
758     index = GetCategoryIndex();
759     diff_illum = diff_irrad * CalcDiffuseIllumRatio(index);
760     dir_illum = dir_irrad * CalcDirectIllumRatio(index);
761     }
762     else if (input == 2)
763     {
764     /* Calculate sky brightness and clearness from illuminance values */
765     index = CalcSkyParamFromIllum();
766     }
767    
768 greg 2.11 if (output == 1) { /* hack for solar radiance */
769     diff_illum = diff_irrad * WHTEFFICACY;
770     dir_illum = dir_irrad * WHTEFFICACY;
771     }
772 greg 2.1 /* Compute ground radiance (include solar contribution if any) */
773 greg 2.3 parr[0] = diff_illum;
774 greg 2.1 if (altitude > 0)
775 greg 2.3 parr[0] += dir_illum * sin(altitude);
776 greg 2.4 parr[2] = parr[1] = parr[0] *= (1./PI/WHTEFFICACY);
777     multcolor(parr, grefl);
778 greg 2.1
779 greg 2.32 if (bright(skycolor) <= 1e-4) { /* 0 sky component? */
780     memset(parr+3, 0, sizeof(float)*3*(nskypatch-1));
781     return;
782     }
783 greg 2.1 /* Calculate Perez sky model parameters */
784     CalcPerezParam(sun_zenith, sky_clearness, sky_brightness, index);
785    
786     /* Calculate sky patch luminance values */
787     CalcSkyPatchLumin(parr);
788    
789     /* Calculate relative horizontal illuminance */
790     norm_diff_illum = CalcRelHorzIllum(parr);
791    
792 greg 2.13 /* Check for zero sky -- make uniform in that case */
793     if (norm_diff_illum <= FTINY) {
794     for (i = 1; i < nskypatch; i++)
795     setcolor(parr+3*i, 1., 1., 1.);
796     norm_diff_illum = PI;
797     }
798 greg 2.1 /* Normalization coefficient */
799     norm_diff_illum = diff_illum / norm_diff_illum;
800    
801     /* Apply to sky patches to get absolute radiance values */
802     for (i = 1; i < nskypatch; i++) {
803 greg 2.7 scalecolor(parr+3*i, norm_diff_illum*(1./WHTEFFICACY));
804 greg 2.1 multcolor(parr+3*i, skycolor);
805     }
806     }
807    
808 greg 2.40
809     double
810     solar_sunset(int month, int day)
811     {
812     float W;
813     W = -1 * (tan(s_latitude) * tan(sdec(jdate(month, day))));
814     return(12 + (M_PI / 2 - atan2(W, sqrt(1 - W * W))) * 180 / (M_PI * 15));
815     }
816    
817    
818     double
819     solar_sunrise(int month, int day)
820     {
821     float W;
822     W = -1 * (tan(s_latitude) * tan(sdec(jdate(month, day))));
823     return(12 - (M_PI / 2 - atan2(W, sqrt(1 - W * W))) * 180 / (M_PI * 15));
824     }
825    
826    
827 greg 2.1 /* Add in solar direct to nearest sky patches (GW) */
828     void
829     AddDirect(float *parr)
830     {
831     FVECT svec;
832 greg 2.3 double near_dprod[NSUNPATCH];
833     int near_patch[NSUNPATCH];
834     double wta[NSUNPATCH], wtot;
835 greg 2.1 int i, j, p;
836    
837 greg 2.4 if (dir_illum <= 1e-4 || bright(suncolor) <= 1e-4)
838 greg 2.1 return;
839 greg 2.10 /* identify nsuns closest patches */
840     if (nsuns > NSUNPATCH)
841     nsuns = NSUNPATCH;
842     else if (nsuns <= 0)
843     nsuns = 1;
844     for (i = nsuns; i--; )
845 greg 2.1 near_dprod[i] = -1.;
846     vector(svec, altitude, azimuth);
847     for (p = 1; p < nskypatch; p++) {
848     FVECT pvec;
849     double dprod;
850     rh_vector(pvec, p);
851     dprod = DOT(pvec, svec);
852 greg 2.10 for (i = 0; i < nsuns; i++)
853 greg 2.1 if (dprod > near_dprod[i]) {
854 greg 2.10 for (j = nsuns; --j > i; ) {
855 greg 2.1 near_dprod[j] = near_dprod[j-1];
856     near_patch[j] = near_patch[j-1];
857     }
858     near_dprod[i] = dprod;
859     near_patch[i] = p;
860     break;
861     }
862     }
863     wtot = 0; /* weight by proximity */
864 greg 2.10 for (i = nsuns; i--; )
865 greg 2.1 wtot += wta[i] = 1./(1.002 - near_dprod[i]);
866     /* add to nearest patch radiances */
867 greg 2.10 for (i = nsuns; i--; ) {
868 greg 2.2 float *pdest = parr + 3*near_patch[i];
869 greg 2.10 float val_add = wta[i] * dir_illum / (WHTEFFICACY * wtot);
870    
871     val_add /= (fixed_sun_sa > 0) ? fixed_sun_sa
872     : rh_dom[near_patch[i]] ;
873 greg 2.4 *pdest++ += val_add*suncolor[0];
874     *pdest++ += val_add*suncolor[1];
875     *pdest++ += val_add*suncolor[2];
876 greg 2.2 }
877 greg 2.1 }
878    
879 greg 2.35 /* Output a sun to indicated file if appropriate for this time step */
880     void
881 greg 2.36 OutputSun(int id, int goodsun, FILE *fp, FILE *mfp)
882 greg 2.35 {
883     double srad;
884     FVECT sv;
885    
886 greg 2.36 srad = DegToRad(SUN_ANG_DEG/2.);
887     srad = goodsun ? dir_illum/(WHTEFFICACY * PI*srad*srad) : 0;
888 greg 2.35 vector(sv, altitude, azimuth);
889     fprintf(fp, "\nvoid light solar%d\n0\n0\n", id);
890     fprintf(fp, "3 %.3e %.3e %.3e\n", srad*suncolor[0],
891     srad*suncolor[1], srad*suncolor[2]);
892     fprintf(fp, "\nsolar%d source sun%d\n0\n0\n", id, id);
893     fprintf(fp, "4 %.6f %.6f %.6f %.4f\n", sv[0], sv[1], sv[2], SUN_ANG_DEG);
894 greg 2.36
895     if (mfp != NULL) /* saving modifier IDs? */
896     fprintf(mfp, "solar%d\n", id);
897 greg 2.35 }
898    
899 greg 2.1 /* Initialize Reinhart sky patch positions (GW) */
900     int
901     rh_init(void)
902     {
903     #define NROW 7
904     static const int tnaz[NROW] = {30, 30, 24, 24, 18, 12, 6};
905     const double alpha = (PI/2.)/(NROW*rhsubdiv + .5);
906     int p, i, j;
907     /* allocate patch angle arrays */
908     nskypatch = 0;
909     for (p = 0; p < NROW; p++)
910     nskypatch += tnaz[p];
911     nskypatch *= rhsubdiv*rhsubdiv;
912     nskypatch += 2;
913     rh_palt = (float *)malloc(sizeof(float)*nskypatch);
914     rh_pazi = (float *)malloc(sizeof(float)*nskypatch);
915     rh_dom = (float *)malloc(sizeof(float)*nskypatch);
916     if ((rh_palt == NULL) | (rh_pazi == NULL) | (rh_dom == NULL)) {
917     fprintf(stderr, "%s: out of memory in rh_init()\n", progname);
918     exit(1);
919     }
920     rh_palt[0] = -PI/2.; /* ground & zenith patches */
921     rh_pazi[0] = 0.;
922     rh_dom[0] = 2.*PI;
923     rh_palt[nskypatch-1] = PI/2.;
924     rh_pazi[nskypatch-1] = 0.;
925     rh_dom[nskypatch-1] = 2.*PI*(1. - cos(alpha*.5));
926     p = 1; /* "normal" patches */
927     for (i = 0; i < NROW*rhsubdiv; i++) {
928     const float ralt = alpha*(i + .5);
929     const int ninrow = tnaz[i/rhsubdiv]*rhsubdiv;
930 greg 2.3 const float dom = 2.*PI*(sin(alpha*(i+1)) - sin(alpha*i)) /
931     (double)ninrow;
932 greg 2.1 for (j = 0; j < ninrow; j++) {
933     rh_palt[p] = ralt;
934     rh_pazi[p] = 2.*PI * j / (double)ninrow;
935     rh_dom[p++] = dom;
936     }
937     }
938     return nskypatch;
939     #undef NROW
940     }
941    
942     /* Resize daylight matrix (GW) */
943     float *
944     resize_dmatrix(float *mtx_data, int nsteps, int npatch)
945     {
946     if (mtx_data == NULL)
947     mtx_data = (float *)malloc(sizeof(float)*3*nsteps*npatch);
948     else
949     mtx_data = (float *)realloc(mtx_data,
950     sizeof(float)*3*nsteps*npatch);
951     if (mtx_data == NULL) {
952     fprintf(stderr, "%s: out of memory in resize_dmatrix(%d,%d)\n",
953     progname, nsteps, npatch);
954     exit(1);
955     }
956     return(mtx_data);
957     }
958    
959     /* Determine category index */
960     int GetCategoryIndex()
961     {
962     int index; /* Loop index */
963    
964     for (index = 0; index < 8; index++)
965     if ((sky_clearness >= SkyClearCat[index].lower) &&
966     (sky_clearness < SkyClearCat[index].upper))
967     break;
968    
969     return index;
970     }
971    
972     /* Calculate diffuse illuminance to diffuse irradiance ratio */
973    
974     /* Reference: Perez, R., P. Ineichen, R. Seals, J. Michalsky, and R. */
975     /* Stewart. 1990. ìModeling Daylight Availability and */
976     /* Irradiance Components from Direct and Global */
977     /* Irradiance,î Solar Energy 44(5):271-289, Eqn. 7. */
978    
979     double CalcDiffuseIllumRatio( int index )
980     {
981     ModelCoeff const *pnle; /* Category coefficient pointer */
982    
983     /* Get category coefficient pointer */
984     pnle = &(DiffuseLumEff[index]);
985    
986     return pnle->a + pnle->b * apwc + pnle->c * cos(sun_zenith) +
987     pnle->d * log(sky_brightness);
988     }
989    
990     /* Calculate direct illuminance to direct irradiance ratio */
991    
992     /* Reference: Perez, R., P. Ineichen, R. Seals, J. Michalsky, and R. */
993     /* Stewart. 1990. ìModeling Daylight Availability and */
994     /* Irradiance Components from Direct and Global */
995     /* Irradiance,î Solar Energy 44(5):271-289, Eqn. 8. */
996    
997     double CalcDirectIllumRatio( int index )
998     {
999     ModelCoeff const *pnle; /* Category coefficient pointer */
1000    
1001     /* Get category coefficient pointer */
1002     pnle = &(DirectLumEff[index]);
1003    
1004     /* Calculate direct illuminance from direct irradiance */
1005    
1006     return dmax((pnle->a + pnle->b * apwc + pnle->c * exp(5.73 *
1007     sun_zenith - 5.0) + pnle->d * sky_brightness),
1008     0.0);
1009     }
1010    
1011     /* Calculate sky brightness */
1012    
1013     /* Reference: Perez, R., P. Ineichen, R. Seals, J. Michalsky, and R. */
1014     /* Stewart. 1990. ìModeling Daylight Availability and */
1015     /* Irradiance Components from Direct and Global */
1016     /* Irradiance,î Solar Energy 44(5):271-289, Eqn. 2. */
1017    
1018     double CalcSkyBrightness()
1019     {
1020     return diff_irrad * CalcAirMass() / (DC_SolarConstantE *
1021     CalcEccentricity());
1022     }
1023    
1024     /* Calculate sky clearness */
1025    
1026     /* Reference: Perez, R., P. Ineichen, R. Seals, J. Michalsky, and R. */
1027     /* Stewart. 1990. ìModeling Daylight Availability and */
1028     /* Irradiance Components from Direct and Global */
1029     /* Irradiance,î Solar Energy 44(5):271-289, Eqn. 1. */
1030    
1031     double CalcSkyClearness()
1032     {
1033     double sz_cubed; /* Sun zenith angle cubed */
1034    
1035     /* Calculate sun zenith angle cubed */
1036 greg 2.11 sz_cubed = sun_zenith*sun_zenith*sun_zenith;
1037 greg 2.1
1038     return ((diff_irrad + dir_irrad) / diff_irrad + 1.041 *
1039     sz_cubed) / (1.0 + 1.041 * sz_cubed);
1040     }
1041    
1042     /* Calculate diffuse horizontal irradiance from Perez sky brightness */
1043    
1044     /* Reference: Perez, R., P. Ineichen, R. Seals, J. Michalsky, and R. */
1045     /* Stewart. 1990. ìModeling Daylight Availability and */
1046     /* Irradiance Components from Direct and Global */
1047     /* Irradiance,î Solar Energy 44(5):271-289, Eqn. 2 */
1048     /* (inverse). */
1049    
1050     double CalcDiffuseIrradiance()
1051     {
1052     return sky_brightness * DC_SolarConstantE * CalcEccentricity() /
1053     CalcAirMass();
1054     }
1055    
1056     /* Calculate direct normal irradiance from Perez sky clearness */
1057    
1058     /* Reference: Perez, R., P. Ineichen, R. Seals, J. Michalsky, and R. */
1059     /* Stewart. 1990. ìModeling Daylight Availability and */
1060     /* Irradiance Components from Direct and Global */
1061     /* Irradiance,î Solar Energy 44(5):271-289, Eqn. 1 */
1062     /* (inverse). */
1063    
1064     double CalcDirectIrradiance()
1065     {
1066     return CalcDiffuseIrradiance() * ((sky_clearness - 1.0) * (1 + 1.041
1067 greg 2.11 * sun_zenith*sun_zenith*sun_zenith));
1068 greg 2.1 }
1069    
1070     /* Calculate sky brightness and clearness from illuminance values */
1071     int CalcSkyParamFromIllum()
1072     {
1073     double test1 = 0.1;
1074     double test2 = 0.1;
1075     int counter = 0;
1076     int index = 0; /* Category index */
1077    
1078     /* Convert illuminance to irradiance */
1079     diff_irrad = diff_illum * DC_SolarConstantE /
1080     (DC_SolarConstantL * 1000.0);
1081     dir_irrad = dir_illum * DC_SolarConstantE /
1082     (DC_SolarConstantL * 1000.0);
1083    
1084     /* Calculate sky brightness and clearness */
1085     sky_brightness = CalcSkyBrightness();
1086     sky_clearness = CalcSkyClearness();
1087    
1088     /* Limit sky clearness */
1089     if (sky_clearness > 12.0)
1090     sky_clearness = 12.0;
1091    
1092     /* Limit sky brightness */
1093 greg 2.9 if (sky_brightness < 0.01)
1094 greg 2.1 sky_brightness = 0.01;
1095    
1096 greg 2.40 if (sky_clearness < 1.0000)
1097     {
1098     sky_clearness = 1.0000;
1099     }
1100    
1101     if (sky_brightness > 0.6)
1102     {
1103     sky_brightness = 0.6;
1104     }
1105    
1106 greg 2.1 while (((fabs(diff_irrad - test1) > 10.0) ||
1107     (fabs(dir_irrad - test2) > 10.0)) && !(counter == 5))
1108     {
1109     test1 = diff_irrad;
1110     test2 = dir_irrad;
1111     counter++;
1112    
1113     /* Convert illuminance to irradiance */
1114     index = GetCategoryIndex();
1115     diff_irrad = diff_illum / CalcDiffuseIllumRatio(index);
1116 greg 2.26 dir_irrad = CalcDirectIllumRatio(index);
1117     if (dir_irrad > 0.1)
1118     dir_irrad = dir_illum / dir_irrad;
1119 greg 2.1
1120     /* Calculate sky brightness and clearness */
1121     sky_brightness = CalcSkyBrightness();
1122     sky_clearness = CalcSkyClearness();
1123    
1124     /* Limit sky clearness */
1125     if (sky_clearness > 12.0)
1126     sky_clearness = 12.0;
1127    
1128     /* Limit sky brightness */
1129 greg 2.9 if (sky_brightness < 0.01)
1130 greg 2.1 sky_brightness = 0.01;
1131 greg 2.40
1132     if (sky_clearness < 1.0000)
1133     {
1134     sky_clearness = 1.0000;
1135     }
1136    
1137     if (sky_brightness > 0.6)
1138     {
1139     sky_brightness = 0.6;
1140     }
1141 greg 2.1 }
1142    
1143     return GetCategoryIndex();
1144     }
1145    
1146     /* Calculate relative luminance */
1147    
1148     /* Reference: Perez, R., R. Seals, and J. Michalsky. 1993. */
1149     /* ìAll-Weather Model for Sky Luminance Distribution - */
1150     /* Preliminary Configuration and Validation,î Solar Energy */
1151     /* 50(3):235-245, Eqn. 1. */
1152    
1153     double CalcRelLuminance( double gamma, double zeta )
1154     {
1155     return (1.0 + perez_param[0] * exp(perez_param[1] / cos(zeta))) *
1156     (1.0 + perez_param[2] * exp(perez_param[3] * gamma) +
1157     perez_param[4] * cos(gamma) * cos(gamma));
1158     }
1159    
1160     /* Calculate Perez sky model parameters */
1161    
1162     /* Reference: Perez, R., R. Seals, and J. Michalsky. 1993. */
1163     /* ìAll-Weather Model for Sky Luminance Distribution - */
1164     /* Preliminary Configuration and Validation,î Solar Energy */
1165     /* 50(3):235-245, Eqns. 6 - 8. */
1166    
1167     void CalcPerezParam( double sz, double epsilon, double delta,
1168     int index )
1169     {
1170     double x[5][4]; /* Coefficents a, b, c, d, e */
1171     int i, j; /* Loop indices */
1172    
1173     /* Limit sky brightness */
1174     if (epsilon > 1.065 && epsilon < 2.8)
1175     {
1176     if (delta < 0.2)
1177     delta = 0.2;
1178     }
1179    
1180     /* Get Perez coefficients */
1181     for (i = 0; i < 5; i++)
1182     for (j = 0; j < 4; j++)
1183     x[i][j] = PerezCoeff[index][4 * i + j];
1184    
1185     if (index != 0)
1186     {
1187     /* Calculate parameter a, b, c, d and e (Eqn. 6) */
1188     for (i = 0; i < 5; i++)
1189     perez_param[i] = x[i][0] + x[i][1] * sz + delta * (x[i][2] +
1190     x[i][3] * sz);
1191     }
1192     else
1193     {
1194     /* Parameters a, b and e (Eqn. 6) */
1195     perez_param[0] = x[0][0] + x[0][1] * sz + delta * (x[0][2] +
1196     x[0][3] * sz);
1197     perez_param[1] = x[1][0] + x[1][1] * sz + delta * (x[1][2] +
1198     x[1][3] * sz);
1199     perez_param[4] = x[4][0] + x[4][1] * sz + delta * (x[4][2] +
1200     x[4][3] * sz);
1201    
1202     /* Parameter c (Eqn. 7) */
1203     perez_param[2] = exp(pow(delta * (x[2][0] + x[2][1] * sz),
1204     x[2][2])) - x[2][3];
1205    
1206     /* Parameter d (Eqn. 8) */
1207     perez_param[3] = -exp(delta * (x[3][0] + x[3][1] * sz)) +
1208     x[3][2] + delta * x[3][3];
1209     }
1210     }
1211    
1212     /* Calculate relative horizontal illuminance (modified by GW) */
1213    
1214     /* Reference: Perez, R., R. Seals, and J. Michalsky. 1993. */
1215     /* ìAll-Weather Model for Sky Luminance Distribution - */
1216     /* Preliminary Configuration and Validation,î Solar Energy */
1217     /* 50(3):235-245, Eqn. 3. */
1218    
1219     double CalcRelHorzIllum( float *parr )
1220     {
1221     int i;
1222     double rh_illum = 0.0; /* Relative horizontal illuminance */
1223    
1224     for (i = 1; i < nskypatch; i++)
1225 greg 2.7 rh_illum += parr[3*i+1] * rh_cos(i) * rh_dom[i];
1226 greg 2.1
1227 greg 2.7 return rh_illum;
1228 greg 2.1 }
1229    
1230     /* Calculate earth orbit eccentricity correction factor */
1231    
1232     /* Reference: Sen, Z. 2008. Solar Energy Fundamental and Modeling */
1233     /* Techniques. Springer, p. 72. */
1234    
1235     double CalcEccentricity()
1236     {
1237     double day_angle; /* Day angle (radians) */
1238     double E0; /* Eccentricity */
1239    
1240     /* Calculate day angle */
1241     day_angle = (julian_date - 1.0) * (2.0 * PI / 365.0);
1242    
1243     /* Calculate eccentricity */
1244     E0 = 1.00011 + 0.034221 * cos(day_angle) + 0.00128 * sin(day_angle)
1245     + 0.000719 * cos(2.0 * day_angle) + 0.000077 * sin(2.0 *
1246     day_angle);
1247    
1248     return E0;
1249     }
1250    
1251     /* Calculate atmospheric precipitable water content */
1252    
1253     /* Reference: Perez, R., P. Ineichen, R. Seals, J. Michalsky, and R. */
1254     /* Stewart. 1990. ìModeling Daylight Availability and */
1255     /* Irradiance Components from Direct and Global */
1256     /* Irradiance,î Solar Energy 44(5):271-289, Eqn. 3. */
1257    
1258     /* Note: The default surface dew point temperature is 11 deg. C */
1259     /* (52 deg. F). Typical values are: */
1260    
1261     /* Celsius Fahrenheit Human Perception */
1262     /* > 24 > 75 Extremely uncomfortable */
1263     /* 21 - 24 70 - 74 Very humid */
1264     /* 18 - 21 65 - 69 Somewhat uncomfortable */
1265     /* 16 - 18 60 - 64 OK for most people */
1266     /* 13 - 16 55 - 59 Comfortable */
1267     /* 10 - 12 50 - 54 Very comfortable */
1268     /* < 10 < 49 A bit dry for some */
1269    
1270     double CalcPrecipWater( double dpt )
1271     { return exp(0.07 * dpt - 0.075); }
1272    
1273     /* Calculate relative air mass */
1274    
1275     /* Reference: Kasten, F. 1966. "A New Table and Approximation Formula */
1276     /* for the Relative Optical Air Mass," Arch. Meteorol. */
1277     /* Geophys. Bioklimataol. Ser. B14, pp. 206-233. */
1278    
1279     /* Note: More sophisticated relative air mass models are */
1280     /* available, but they differ significantly only for */
1281     /* sun zenith angles greater than 80 degrees. */
1282    
1283     double CalcAirMass()
1284     {
1285     return (1.0 / (cos(sun_zenith) + 0.15 * pow(93.885 -
1286     RadToDeg(sun_zenith), -1.253)));
1287     }
1288    
1289     /* Calculate Perez All-Weather sky patch luminances (modified by GW) */
1290    
1291     /* NOTE: The sky patches centers are determined in accordance with the */
1292     /* BRE-IDMP sky luminance measurement procedures. (See for example */
1293     /* Mardaljevic, J. 2001. "The BRE-IDMP Dataset: A New Benchmark */
1294     /* for the Validation of Illuminance Prediction Techniques," */
1295     /* Lighting Research & Technology 33(2):117-136.) */
1296    
1297     void CalcSkyPatchLumin( float *parr )
1298     {
1299     int i;
1300     double aas; /* Sun-sky point azimuthal angle */
1301     double sspa; /* Sun-sky point angle */
1302     double zsa; /* Zenithal sun angle */
1303    
1304     for (i = 1; i < nskypatch; i++)
1305     {
1306     /* Calculate sun-sky point azimuthal angle */
1307     aas = fabs(rh_pazi[i] - azimuth);
1308    
1309     /* Calculate zenithal sun angle */
1310     zsa = PI * 0.5 - rh_palt[i];
1311    
1312     /* Calculate sun-sky point angle (Equation 8-20) */
1313     sspa = acos(cos(sun_zenith) * cos(zsa) + sin(sun_zenith) *
1314     sin(zsa) * cos(aas));
1315    
1316     /* Calculate patch luminance */
1317     parr[3*i] = CalcRelLuminance(sspa, zsa);
1318     if (parr[3*i] < 0) parr[3*i] = 0;
1319     parr[3*i+2] = parr[3*i+1] = parr[3*i];
1320     }
1321     }