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root/radiance/ray/src/gen/gensky.c
Revision: 2.9
Committed: Wed Dec 9 08:32:52 1992 UTC (31 years, 4 months ago) by greg
Content type: text/plain
Branch: MAIN
Changes since 2.8: +9 -1 lines
Log Message: 
Added protection against sun too close to zenith

File Contents

# Content
1 /* Copyright (c) 1992 Regents of the University of California */
2
3 #ifndef lint
4 static char SCCSid[] = "$SunId$ LBL";
5 #endif
6
7 /*
8 * gensky.c - program to generate sky functions.
9 * Our zenith is along the Z-axis, the X-axis
10 * points east, and the Y-axis points north.
11 * Radiance is in watts/steradian/sq. meter.
12 *
13 * 3/26/86
14 */
15
16 #include <stdio.h>
17
18 #include <math.h>
19
20 #include "color.h"
21
22 #ifndef atof
23 extern double atof();
24 #endif
25 extern char *strcpy(), *strcat(), *malloc();
26 extern double stadj(), sdec(), sazi(), salt();
27
28 #define PI 3.141592654
29
30 #define DOT(v1,v2) (v1[0]*v2[0]+v1[1]*v2[1]+v1[2]*v2[2])
31
32 double normsc();
33 /* sun calculation constants */
34 extern double s_latitude;
35 extern double s_longitude;
36 extern double s_meridian;
37 /* required values */
38 int month, day; /* date */
39 double hour; /* time */
40 int tsolar; /* 0=standard, 1=solar */
41 double altitude, azimuth; /* or solar angles */
42 /* default values */
43 int cloudy = 0; /* 1=standard, 2=uniform */
44 int dosun = 1;
45 double zenithbr = -1.0;
46 double turbidity = 2.75;
47 double gprefl = 0.2;
48 /* computed values */
49 double sundir[3];
50 double groundbr;
51 double F2;
52 double solarbr = -1.0;
53
54 char *progname;
55 char errmsg[128];
56
57
58 main(argc, argv)
59 int argc;
60 char *argv[];
61 {
62 int i;
63
64 progname = argv[0];
65 if (argc == 2 && !strcmp(argv[1], "-defaults")) {
66 printdefaults();
67 exit(0);
68 }
69 if (argc < 4)
70 userror("arg count");
71 if (!strcmp(argv[1], "-ang")) {
72 altitude = atof(argv[2]) * (PI/180);
73 azimuth = atof(argv[3]) * (PI/180);
74 month = 0;
75 } else {
76 month = atoi(argv[1]);
77 if (month < 1 || month > 12)
78 userror("bad month");
79 day = atoi(argv[2]);
80 if (day < 1 || day > 31)
81 userror("bad day");
82 hour = atof(argv[3]);
83 if (hour < 0 || hour >= 24)
84 userror("bad hour");
85 tsolar = argv[3][0] == '+';
86 }
87 for (i = 4; i < argc; i++)
88 if (argv[i][0] == '-' || argv[i][0] == '+')
89 switch (argv[i][1]) {
90 case 's':
91 cloudy = 0;
92 dosun = argv[i][0] == '+';
93 break;
94 case 'r':
95 solarbr = atof(argv[++i]);
96 break;
97 case 'c':
98 cloudy = argv[i][0] == '+' ? 2 : 1;
99 dosun = 0;
100 break;
101 case 't':
102 turbidity = atof(argv[++i]);
103 break;
104 case 'b':
105 zenithbr = atof(argv[++i]);
106 break;
107 case 'g':
108 gprefl = atof(argv[++i]);
109 break;
110 case 'a':
111 s_latitude = atof(argv[++i]) * (PI/180);
112 break;
113 case 'o':
114 s_longitude = atof(argv[++i]) * (PI/180);
115 break;
116 case 'm':
117 s_meridian = atof(argv[++i]) * (PI/180);
118 break;
119 default:
120 sprintf(errmsg, "unknown option: %s", argv[i]);
121 userror(errmsg);
122 }
123 else
124 userror("bad option");
125
126 if (fabs(s_meridian-s_longitude) > 30*PI/180)
127 fprintf(stderr,
128 "%s: warning: %.1f hours btwn. standard meridian and longitude\n",
129 progname, (s_longitude-s_meridian)*12/PI);
130
131 printhead(argc, argv);
132
133 computesky();
134 printsky();
135 }
136
137
138 computesky() /* compute sky parameters */
139 {
140 /* compute solar direction */
141 if (month) { /* from date and time */
142 int jd;
143 double sd, st;
144
145 jd = jdate(month, day); /* Julian date */
146 sd = sdec(jd); /* solar declination */
147 if (tsolar) /* solar time */
148 st = hour;
149 else
150 st = hour + stadj(jd);
151 altitude = salt(sd, st);
152 azimuth = sazi(sd, st);
153 }
154 if (!cloudy && altitude > 87.*PI/180.) {
155 fprintf(stderr,
156 "%s: warning - sun too close to zenith, reducing altitude to 87 degrees\n",
157 progname);
158 printf(
159 "# warning - sun too close to zenith, reducing altitude to 87 degrees\n");
160 altitude = 87.*PI/180.;
161 }
162 sundir[0] = -sin(azimuth)*cos(altitude);
163 sundir[1] = -cos(azimuth)*cos(altitude);
164 sundir[2] = sin(altitude);
165
166 /* Compute zenith brightness */
167 if (zenithbr <= 0.0)
168 if (cloudy) {
169 zenithbr = 8.6*sundir[2] + .123;
170 zenithbr *= 1000.0/WHTEFFICACY;
171 } else {
172 zenithbr = (1.376*turbidity-1.81)*tan(altitude)+0.38;
173 zenithbr *= 1000.0/SKYEFFICACY;
174 }
175 if (zenithbr < 0.0)
176 zenithbr = 0.0;
177 /* Compute horizontal radiance */
178 if (cloudy) {
179 if (cloudy == 2)
180 groundbr = zenithbr;
181 else
182 groundbr = zenithbr*0.777778;
183 printf("# Ground ambient level: %f\n", groundbr);
184 } else {
185 F2 = 0.274*(0.91 + 10.0*exp(-3.0*(PI/2.0-altitude)) +
186 0.45*sundir[2]*sundir[2]);
187 groundbr = zenithbr*normsc(altitude)/F2/PI;
188 printf("# Ground ambient level: %f\n", groundbr);
189 if (sundir[2] > 0.0 && solarbr != 0.0) {
190 if (solarbr < 0.0)
191 solarbr = 1.5e9/SUNEFFICACY *
192 (1.147 - .147/(sundir[2]>.16?sundir[2]:.16));
193 groundbr += solarbr*6e-5*sundir[2]/PI;
194 } else
195 dosun = 0;
196 }
197 groundbr *= gprefl;
198 }
199
200
201 printsky() /* print out sky */
202 {
203 if (dosun) {
204 printf("\nvoid light solar\n");
205 printf("0\n0\n");
206 printf("3 %.2e %.2e %.2e\n", solarbr, solarbr, solarbr);
207 printf("\nsolar source sun\n");
208 printf("0\n0\n");
209 printf("4 %f %f %f 0.5\n", sundir[0], sundir[1], sundir[2]);
210 }
211
212 printf("\nvoid brightfunc skyfunc\n");
213 printf("2 skybright skybright.cal\n");
214 printf("0\n");
215 if (cloudy)
216 printf("3 %d %.2e %.2e\n", cloudy, zenithbr, groundbr);
217 else
218 printf("7 -1 %.2e %.2e %.2e %f %f %f\n", zenithbr, groundbr,
219 F2, sundir[0], sundir[1], sundir[2]);
220 }
221
222
223 printdefaults() /* print default values */
224 {
225 if (cloudy == 1)
226 printf("-c\t\t\t\t# Cloudy sky\n");
227 else if (cloudy == 2)
228 printf("+c\t\t\t\t# Uniform cloudy sky\n");
229 else if (dosun)
230 printf("+s\t\t\t\t# Sunny sky with sun\n");
231 else
232 printf("-s\t\t\t\t# Sunny sky without sun\n");
233 printf("-g %f\t\t\t# Ground plane reflectance\n", gprefl);
234 if (zenithbr > 0.0)
235 printf("-b %f\t\t\t# Zenith radiance (watts/ster/m2\n", zenithbr);
236 else
237 printf("-t %f\t\t\t# Atmospheric turbidity\n", turbidity);
238 printf("-a %f\t\t\t# Site latitude (degrees)\n", s_latitude*(180/PI));
239 printf("-o %f\t\t\t# Site longitude (degrees)\n", s_longitude*(180/PI));
240 printf("-m %f\t\t\t# Standard meridian (degrees)\n", s_meridian*(180/PI));
241 }
242
243
244 userror(msg) /* print usage error and quit */
245 char *msg;
246 {
247 if (msg != NULL)
248 fprintf(stderr, "%s: Use error - %s\n", progname, msg);
249 fprintf(stderr, "Usage: %s month day hour [options]\n", progname);
250 fprintf(stderr, " Or: %s -ang altitude azimuth [options]\n", progname);
251 fprintf(stderr, " Or: %s -defaults\n", progname);
252 exit(1);
253 }
254
255
256 double
257 normsc(theta) /* compute normalization factor (E0*F2/L0) */
258 double theta;
259 {
260 static double nf[5] = {2.766521, 0.547665,
261 -0.369832, 0.009237, 0.059229};
262 double x, nsc;
263 register int i;
264 /* polynomial approximation */
265 x = (theta - PI/4.0)/(PI/4.0);
266 nsc = nf[4];
267 for (i = 3; i >= 0; i--)
268 nsc = nsc*x + nf[i];
269
270 return(nsc);
271 }
272
273
274 printhead(ac, av) /* print command header */
275 register int ac;
276 register char **av;
277 {
278 putchar('#');
279 while (ac--) {
280 putchar(' ');
281 fputs(*av++, stdout);
282 }
283 putchar('\n');
284 }