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aptdec/image.c

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  1. /*

  2.  *  Atpdec

  3.  *  Copyright (c) 2004 by Thierry Leconte (F4DWV)

  4.  *

  5.  *      $Id$

  6.  *

  7.  *   This library is free software; you can redistribute it and/or modify

  8.  *   it under the terms of the GNU Library General Public License as

  9.  *   published by the Free Software Foundation; either version 2 of

  10.  *   the License, or (at your option) any later version.

  11.  *

  12.  *   This program is distributed in the hope that it will be useful,

  13.  *   but WITHOUT ANY WARRANTY; without even the implied warranty of

  14.  *   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the

  15.  *   GNU Library General Public License for more details.

  16.  *

  17.  *   You should have received a copy of the GNU Library General Public

  18.  *   License along with this library; if not, write to the Free Software

  19.  *   Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.

  20.  *

  21.  */

  22. 

  23. #include <stdio.h>

  24. #include <string.h>

  25. #include <sndfile.h>

  26. #include <math.h>

  27. 

  28. #define REGORDER 3

  29. typedef struct {

  30.     double cf[REGORDER + 1];

  31. } rgparam;

  32. 

  33. static void rgcomp(double x[16], rgparam * rgpr)

  34. {

  35. /*{ 0.106,0.215,0.324,0.433,0.542,0.652,0.78,0.87 ,0.0 }; */

  36.     const double y[9] =

  37. 	{ 31.07, 63.02, 94.96, 126.9, 158.86, 191.1, 228.62, 255.0, 0.0 };

  38.     extern void polyreg(const int m, const int n, const double x[],

  39. 			const double y[], double c[]);

  40. 

  41.     polyreg(REGORDER, 9, x, y, rgpr->cf);

  42. }

  43. 

  44. static double rgcal(float x, rgparam * rgpr)

  45. {

  46.     double y, p;

  47.     int i;

  48. 

  49.     for (i = 0, y = 0.0, p = 1.0; i < REGORDER + 1; i++) {

  50. 	y += rgpr->cf[i] * p;

  51. 	p = p * x;

  52.     }

  53.     return (y);

  54. }

  55. 

  56. 

  57. static double tele[16];

  58. static double Cs;

  59. static int nbtele;

  60. 

  61. int Calibrate(float **prow, int nrow, int offset)

  62. {

  63. 

  64.     double teleline[3000];

  65.     double wedge[16];

  66.     rgparam regr[30];

  67.     int n;

  68.     int k;

  69.     int mtelestart, telestart;

  70.     int channel = -1;

  71.     float max;

  72. 

  73.     printf("Calibration ... ");

  74.     fflush(stdout);

  75. 

  76. /* build telemetry values lines */

  77.     for (n = 0; n < nrow; n++) {

  78. 	int i;

  79. 

  80. 	teleline[n] = 0.0;

  81. 	for (i = 3; i < 43; i++) {

  82. 	    teleline[n] += prow[n][i + offset + 956];

  83. 	}

  84. 	teleline[n] /= 40.0;

  85.     }

  86. 

  87.     if (nrow < 192) {

  88. 	fprintf(stderr, " impossible, not enought row\n");

  89. 	return (0);

  90.     }

  91. 

  92. /* find telemetry start in the 2nd third */

  93.     max = 0.0;

  94.     mtelestart = 0;

  95.     for (n = nrow / 3 - 64; n < 2 * nrow / 3 - 64; n++) {

  96. 	float df;

  97. 

  98. 	df = (teleline[n - 4] + teleline[n - 3] + teleline[n - 2] +

  99. 	      teleline[n - 1]) / (teleline[n] + teleline[n + 1] +

  100. 				  teleline[n + 2] + teleline[n + 3]);

  101. 	if (df > max) {

  102. 	    mtelestart = n;

  103. 	    max = df;

  104. 	}

  105.     }

  106. 

  107.     mtelestart -= 64;

  108.     telestart = mtelestart % 128;

  109. 

  110.     if (mtelestart < 0 || nrow < telestart + 128) {

  111. 	fprintf(stderr, " impossible, not enought row\n");

  112. 	return (0);

  113.     }

  114. 

  115. /* compute wedges and regression */

  116.     for (n = telestart, k = 0; n < nrow - 128; n += 128, k++) {

  117. 	int j;

  118. 

  119. 	for (j = 0; j < 16; j++) {

  120. 	    int i;

  121. 

  122. 	    wedge[j] = 0.0;

  123. 	    for (i = 1; i < 7; i++)

  124. 		wedge[j] += teleline[n + j * 8 + i];

  125. 	    wedge[j] /= 6;

  126. 	}

  127. 

  128. 	rgcomp(wedge, &(regr[k]));

  129. 

  130. 	if (k == nrow / 256) {

  131. 	    int i, l;

  132. 

  133. 	    /* telemetry calibration */

  134. 	    for (j = 0; j < 16; j++) {

  135. 		tele[j] = rgcal(wedge[j], &(regr[k]));

  136. 	    }

  137. 

  138. 

  139. 

  140. 	    /* channel ID */

  141. 	    for (j = 0, max = 10000.0, channel = -1; j < 6; j++) {

  142. 		float df;

  143. 

  144. 		df = wedge[15] - wedge[j];

  145. 		df = df * df;

  146. 		if (df < max) {

  147. 		    channel = j;

  148. 		    max = df;

  149. 		}

  150. 	    }

  151. 

  152. 	    /* Cs computation */

  153. 	    for (Cs = 0.0, i = 0, j = n; j < n + 128; j++) {

  154. 		double csline;

  155. 

  156. 		for (csline = 0.0, l = 3; l < 43; l++)

  157. 		    csline += prow[n][l + offset];

  158. 		csline /= 40.0;

  159. 		if (csline > 50.0) {

  160. 		    Cs += csline;

  161. 		    i++;

  162. 		}

  163. 	    }

  164. 	    Cs /= i;

  165. 	    Cs = rgcal(Cs, &(regr[k]));

  166. 	}

  167.     }

  168.     nbtele = k;

  169. 

  170. /* calibrate */

  171.     for (n = 0; n < nrow; n++) {

  172. 	float *pixelv;

  173. 	int i;

  174. 

  175. 	pixelv = prow[n];

  176. 	for (i = 0; i < 1001; i++) {

  177. 	    float pv;

  178. 	    int k, kof;

  179. 

  180. 	    pv = pixelv[i + offset];

  181. 

  182. 	    k = (n - telestart) / 128;

  183. 	    if (k >= nbtele)

  184. 		k = nbtele - 1;

  185. 	    kof = (n - telestart) % 128;

  186. 	    if (kof < 64) {

  187. 		if (k < 1) {

  188. 		    pv = rgcal(pv, &(regr[k]));

  189. 		} else {

  190. 		    pv = rgcal(pv, &(regr[k])) * (64 + kof) / 128.0 +

  191. 			rgcal(pv, &(regr[k - 1])) * (64 - kof) / 128.0;

  192. 		}

  193. 	    } else {

  194. 		if ((k + 1) >= nbtele) {

  195. 		    pv = rgcal(pv, &(regr[k]));

  196. 		} else {

  197. 		    pv = rgcal(pv, &(regr[k])) * (192 - kof) / 128.0 +

  198. 			rgcal(pv, &(regr[k + 1])) * (kof - 64) / 128.0;

  199. 		}

  200. 	    }

  201. 

  202. 	    if (pv > 255.0)

  203. 		pv = 255.0;

  204. 	    if (pv < 0.0)

  205. 		pv = 0.0;

  206. 	    pixelv[i + offset] = pv;

  207. 	}

  208.     }

  209.     printf("Done\n");

  210.     return (channel);

  211. }

  212. 

  213. /* ------------------------------temperature calibration -----------------------*/

  214. extern int satnum;

  215. const struct {

  216.     float d[4][3];

  217.     struct {

  218. 	float vc, A, B;

  219.     } rad[3];

  220.     struct {

  221. 	float Ns;

  222. 	float b[3];

  223.     } cor[3];

  224. } satcal[4] =

  225. #include "satcal.h"

  226. 

  227. typedef struct {

  228.     double Nbb;

  229.     double Cs;

  230.     double Cb;

  231.     int ch;

  232. } tempparam;

  233. 

  234. /* temperature compensation for IR channel */

  235. static void tempcomp(double t[16], int ch, tempparam * tpr)

  236. {

  237.     double Tbb, T[4];

  238.     double C;

  239.     int n;

  240. 

  241.     tpr->ch = ch - 3;

  242. 

  243.     /* compute equivalent T black body  */

  244.     for (n = 0; n < 4; n++) {

  245. 	float d0, d1, d2;

  246. 

  247. 	C = t[9 + n] * 4.0;

  248. 	d0 = satcal[satnum].d[n][0];

  249. 	d1 = satcal[satnum].d[n][1];

  250. 	d2 = satcal[satnum].d[n][2];

  251. 	T[n] = d0;

  252. 	T[n] += d1 * C;

  253. 	C = C * C;

  254. 	T[n] += d2 * C;

  255.     }

  256.     Tbb = (T[0] + T[1] + T[2] + T[3]) / 4.0;

  257.     Tbb =

  258. 	satcal[satnum].rad[tpr->ch].A +

  259. 	satcal[satnum].rad[tpr->ch].B * Tbb;

  260. 

  261.     /* compute radiance Black body */

  262.     C = satcal[satnum].rad[tpr->ch].vc;

  263.     tpr->Nbb = c1 * C * C * C / (exp(c2 * C / Tbb) - 1.0);

  264.     /* store Count Blackbody and space */

  265.     tpr->Cs = Cs * 4.0;

  266.     tpr->Cb = t[14] * 4.0;

  267. }

  268. 

  269. static double tempcal(float Ce, tempparam * rgpr)

  270. {

  271.     double Nl, Nc, Ns, Ne;

  272.     double T, vc;

  273. 

  274.     Ns = satcal[satnum].cor[rgpr->ch].Ns;

  275.     Nl = Ns + (rgpr->Nbb - Ns) * (rgpr->Cs - Ce * 4.0) / (rgpr->Cs -

  276. 							  rgpr->Cb);

  277.     Nc = satcal[satnum].cor[rgpr->ch].b[0] +

  278. 	satcal[satnum].cor[rgpr->ch].b[1] * Nl +

  279. 	satcal[satnum].cor[rgpr->ch].b[2] * Nl * Nl;

  280. 

  281.     Ne = Nl + Nc;

  282. 

  283.     vc = satcal[satnum].rad[rgpr->ch].vc;

  284.     T = c2 * vc / log(c1 * vc * vc * vc / Ne + 1.0);

  285.     T = (T -

  286. 	 satcal[satnum].rad[rgpr->ch].A) / satcal[satnum].rad[rgpr->ch].B;

  287. 

  288.     /* rescale to range 0-255 for +40-60 °C */

  289.     T = (-T + 273.15 + 40) / 100.0 * 255.0;

  290. 

  291.     return (T);

  292. }

  293. 

  294. void Temperature(float **prow, int nrow, int channel, int offset)

  295. {

  296.     tempparam temp;

  297.     int n;

  298. 

  299.     printf("Temperature ... ");

  300.     fflush(stdout);

  301. 

  302.     tempcomp(tele, channel, &temp);

  303. 

  304. 

  305.     for (n = 0; n < nrow; n++) {

  306. 	float *pixelv;

  307. 	int i;

  308. 

  309. 	pixelv = prow[n];

  310. 	for (i = 0; i < 1001; i++) {

  311. 	    float pv;

  312. 

  313. 	    pv = tempcal(pixelv[i + offset], &temp);

  314. 

  315. 	    if (pv > 255.0)

  316. 		pv = 255.0;

  317. 	    if (pv < 0.0)

  318. 		pv = 0.0;

  319. 	    pixelv[i + offset] = pv;

  320. 	}

  321.     }

  322.     printf("Done\n");

  323. }