rpa.cpp @ 3a39c2e

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Last change on this file since 3a39c2e was 79492222, checked in by krzywon, 9 years ago
Changed the file and folder names to remove all SANS references.
Property mode set to `100644`
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1	/**
2	This software was developed by the University of Tennessee as part of the
3	Distributed Data Analysis of Neutron Scattering Experiments (DANSE)
4	project funded by the US National Science Foundation.
5
6	If you use DANSE applications to do scientific research that leads to
7	publication, we ask that you acknowledge the use of the software with the
8	following sentence:
9
10	"This work benefited from DANSE software developed under NSF award DMR-0520547."
11
12	copyright 2008, University of Tennessee
13	*/
14
15	/**
16	* Scattering model classes
17	* The classes use the IGOR library found in
18	* sansmodels/src/libigor
19	*
20	*/
21
22	#include <math.h>
23	#include "parameters.hh"
24	#include <stdio.h>
25	#include "rpa.h"
26
27	using namespace std;
28
29	static double rpa_kernel(double dp[], double q) {
30	int lCASE = dp[0];
31
32	double Na,Nb,Nc,Nd,Nab,Nac,Nad,Nbc,Nbd,Ncd;
33	double Phia,Phib,Phic,Phid,Phiab,Phiac,Phiad;
34	double Phibc,Phibd,Phicd;
35	double va,vb,vc,vd,vab,vac,vad,vbc,vbd,vcd;
36	double m;
37	double ba,bb,bc,bd;
38	double Xa,Xb,Xc,Xd;
39	double Paa,S0aa,Pab,S0ab,Pac,S0ac,Pad,S0ad;
40	double S0ba,Pbb,S0bb,Pbc,S0bc,Pbd,S0bd;
41	double S0ca,S0cb,Pcc,S0cc,Pcd,S0cd;
42	double S0da,S0db,S0dc,Pdd,S0dd;
43	double Kaa,Kab,Kac,Kad,Kba,Kbb,Kbc,Kbd;
44	double Kca,Kcb,Kcc,Kcd,Kda,Kdb,Kdc,Kdd;
45	double Zaa,Zab,Zac,Zba,Zbb,Zbc,Zca,Zcb,Zcc;
46	double DenT,T11,T12,T13,T21,T22,T23,T31,T32,T33;
47	double Y1,Y2,Y3,X11,X12,X13,X21,X22,X23,X31,X32,X33;
48	double ZZ,DenQ1,DenQ2,DenQ3,DenQ,Q11,Q12,Q13,Q21,Q22,Q23,Q31,Q32,Q33;
49	double N11,N12,N13,N21,N22,N23,N31,N32,N33;
50	double M11,M12,M13,M21,M22,M23,M31,M32,M33;
51	double S11,S12,S13,S14,S21,S22,S23,S24;
52	double S31,S32,S33,S34,S41,S42,S43,S44;
53	double La,Lb,Lc,Ld,Lad,Lbd,Lcd,Nav,Intg;
54	double scale, background;
55
56	int ii=13; //dp[ii<13] = fittable, else fixed
57
58	Na=1000.0;
59	Nb=1000.0;
60	Nc=1000.0;
61	Nd=1000.0; //DEGREE OF POLYMERIZATION
62	Phia=0.25;
63	Phib=0.25;
64	Phic=0.25;
65	Phid=0.25 ; //VOL FRACTION
66	Kab=-0.0004;
67	Kac=-0.0004;
68	Kad=-0.0004; //CHI PARAM
69	Kbc=-0.0004;
70	Kbd=-0.0004;
71	Kcd=-0.0004;
72	La=1.0e-12;
73	Lb=1.0e-12;
74	Lc=1.0e-12;
75	Ld=0.0e-12; //SCATT. LENGTH
76	va=100.0;
77	vb=100.0;
78	vc=100.0;
79	vd=100.0 ; //SPECIFIC VOLUME
80	ba=5.0;
81	bb=5.0;
82	bc=5.0;
83	bd=5.0; //SEGMENT LENGTH
84
85	//lCASE was shifted to N-1 from the original code
86	if (lCASE <= 1){
87	Phia=0.0000001;
88	Phib=0.0000001;
89	Phic=0.5;
90	Phid=0.5;
91	Nc=dp[ii+8];
92	Phic=dp[ii+9];
93	vc=dp[ii+10];
94	Lc=dp[ii+11];
95	bc=dp[3];
96	Nd=dp[ii+12];
97	Phid=dp[ii+13];
98	vd=dp[ii+14];
99	Ld=dp[ii+15];
100	bd=dp[4];
101	Kcd=dp[10];
102	scale=dp[11];
103	background=dp[12];
104	}
105	else if ((lCASE > 1) && (lCASE <= 4)){
106	Phia=0.0000001;
107	Phib=0.333333;
108	Phic=0.333333;
109	Phid=0.333333;
110	Nb=dp[ii+4];
111	Phib=dp[ii+5];
112	vb=dp[ii+6];
113	Lb=dp[ii+7];
114	bb=dp[2];
115	Nc=dp[ii+8];
116	Phic=dp[ii+9];
117	vc=dp[ii+10];
118	Lc=dp[ii+11];
119	bc=dp[3];
120	Nd=dp[ii+12];
121	Phid=dp[ii+13];
122	vd=dp[ii+14];
123	Ld=dp[ii+15];
124	bd=dp[4];
125	Kbc=dp[8];
126	Kbd=dp[9];
127	Kcd=dp[10];
128	scale=dp[11];
129	background=dp[12];
130	}
131	else {
132	Phia=0.25;
133	Phib=0.25;
134	Phic=0.25;
135	Phid=0.25;
136	Na=dp[ii+0];
137	Phia=dp[ii+1];
138	va=dp[ii+2];
139	La=dp[ii+3];
140	ba=dp[1];
141	Nb=dp[ii+4];
142	Phib=dp[ii+5];
143	vb=dp[ii+6];
144	Lb=dp[ii+7];
145	bb=dp[2];
146	Nc=dp[ii+8];
147	Phic=dp[ii+9];
148	vc=dp[ii+10];
149	Lc=dp[ii+11];
150	bc=dp[3];
151	Nd=dp[ii+12];
152	Phid=dp[ii+13];
153	vd=dp[ii+14];
154	Ld=dp[ii+15];
155	bd=dp[4];
156	Kab=dp[5];
157	Kac=dp[6];
158	Kad=dp[7];
159	Kbc=dp[8];
160	Kbd=dp[9];
161	Kcd=dp[10];
162	scale=dp[11];
163	background=dp[12];
164	}
165
166	Nab=pow((Na*Nb),(0.5));
167	Nac=pow((Na*Nc),(0.5));
168	Nad=pow((Na*Nd),(0.5));
169	Nbc=pow((Nb*Nc),(0.5));
170	Nbd=pow((Nb*Nd),(0.5));
171	Ncd=pow((Nc*Nd),(0.5));
172
173	vab=pow((va*vb),(0.5));
174	vac=pow((va*vc),(0.5));
175	vad=pow((va*vd),(0.5));
176	vbc=pow((vb*vc),(0.5));
177	vbd=pow((vb*vd),(0.5));
178	vcd=pow((vc*vd),(0.5));
179
180	Phiab=pow((Phia*Phib),(0.5));
181	Phiac=pow((Phia*Phic),(0.5));
182	Phiad=pow((Phia*Phid),(0.5));
183	Phibc=pow((Phib*Phic),(0.5));
184	Phibd=pow((Phib*Phid),(0.5));
185	Phicd=pow((Phic*Phid),(0.5));
186
187	Xa=qqbabaNa/6.0;
188	Xb=qqbbbbNb/6.0;
189	Xc=qqbcbbNc/6.0;
190	Xd=qqbdbbNd/6.0;
191
192	Paa=2.0*(exp(-Xa)-1.0+Xa)/pow(Xa,2.0);
193	S0aa=NaPhiava*Paa;
194	Pab=((1.0-exp(-Xa))/Xa)*((1.0-exp(-Xb))/Xb);
195	S0ab=(PhiabvabNab)*Pab;
196	Pac=((1.0-exp(-Xa))/Xa)exp(-Xb)((1.0-exp(-Xc))/Xc);
197	S0ac=(PhiacvacNac)*Pac;
198	Pad=((1.0-exp(-Xa))/Xa)exp(-Xb-Xc)((1.0-exp(-Xd))/Xd);
199	S0ad=(PhiadvadNad)*Pad;
200
201	S0ba=S0ab;
202	Pbb=2.0*(exp(-Xb)-1.0+Xb)/pow(Xb,2.0);
203	S0bb=NbPhibvb*Pbb;
204	Pbc=((1.0-exp(-Xb))/Xb)*((1.0-exp(-Xc))/Xc);
205	S0bc=(PhibcvbcNbc)*Pbc;
206	Pbd=((1.0-exp(-Xb))/Xb)exp(-Xc)((1.0-exp(-Xd))/Xd);
207	S0bd=(PhibdvbdNbd)*Pbd;
208
209	S0ca=S0ac;
210	S0cb=S0bc;
211	Pcc=2.0*(exp(-Xc)-1.0+Xc)/pow(Xc,2.0);
212	S0cc=NcPhicvc*Pcc;
213	Pcd=((1.0-exp(-Xc))/Xc)*((1.0-exp(-Xd))/Xd);
214	S0cd=(PhicdvcdNcd)*Pcd;
215
216	S0da=S0ad;
217	S0db=S0bd;
218	S0dc=S0cd;
219	Pdd=2.0*(exp(-Xd)-1.0+Xd)/pow(Xd,2.0);
220	S0dd=NdPhidvd*Pdd;
221	//lCASE was shifted to N-1 from the original code
222	switch(lCASE){
223	case 0:
224	S0aa=0.000001;
225	S0ab=0.000002;
226	S0ac=0.000003;
227	S0ad=0.000004;
228	S0bb=0.000005;
229	S0bc=0.000006;
230	S0bd=0.000007;
231	S0cd=0.000008;
232	break;
233	case 1:
234	S0aa=0.000001;
235	S0ab=0.000002;
236	S0ac=0.000003;
237	S0ad=0.000004;
238	S0bb=0.000005;
239	S0bc=0.000006;
240	S0bd=0.000007;
241	break;
242	case 2:
243	S0aa=0.000001;
244	S0ab=0.000002;
245	S0ac=0.000003;
246	S0ad=0.000004;
247	S0bc=0.000005;
248	S0bd=0.000006;
249	S0cd=0.000007;
250	break;
251	case 3:
252	S0aa=0.000001;
253	S0ab=0.000002;
254	S0ac=0.000003;
255	S0ad=0.000004;
256	S0bc=0.000005;
257	S0bd=0.000006;
258	break;
259	case 4:
260	S0aa=0.000001;
261	S0ab=0.000002;
262	S0ac=0.000003;
263	S0ad=0.000004;
264	break;
265	case 5:
266	S0ab=0.000001;
267	S0ac=0.000002;
268	S0ad=0.000003;
269	S0bc=0.000004;
270	S0bd=0.000005;
271	S0cd=0.000006;
272	break;
273	case 6:
274	S0ab=0.000001;
275	S0ac=0.000002;
276	S0ad=0.000003;
277	S0bc=0.000004;
278	S0bd=0.000005;
279	break;
280	case 7:
281	S0ab=0.000001;
282	S0ac=0.000002;
283	S0ad=0.000003;
284	break;
285	case 8:
286	S0ac=0.000001;
287	S0ad=0.000002;
288	S0bc=0.000003;
289	S0bd=0.000004;
290	break;
291	default : //case 9:
292	break;
293	}
294	S0ba=S0ab;
295	S0ca=S0ac;
296	S0cb=S0bc;
297	S0da=S0ad;
298	S0db=S0bd;
299	S0dc=S0cd;
300
301	Kaa=0.0;
302	Kbb=0.0;
303	Kcc=0.0;
304	Kdd=0.0;
305
306	Kba=Kab;
307	Kca=Kac;
308	Kcb=Kbc;
309	Kda=Kad;
310	Kdb=Kbd;
311	Kdc=Kcd;
312
313	Zaa=Kaa-Kad-Kad;
314	Zab=Kab-Kad-Kbd;
315	Zac=Kac-Kad-Kcd;
316	Zba=Kba-Kbd-Kad;
317	Zbb=Kbb-Kbd-Kbd;
318	Zbc=Kbc-Kbd-Kcd;
319	Zca=Kca-Kcd-Kad;
320	Zcb=Kcb-Kcd-Kbd;
321	Zcc=Kcc-Kcd-Kcd;
322
323	DenT=(-(S0acS0bbS0ca) + S0abS0bcS0ca + S0acS0baS0cb - S0aaS0bcS0cb - S0abS0baS0cc + S0aaS0bbS0cc);
324
325	T11= (-(S0bcS0cb) + S0bbS0cc)/DenT;
326	T12= (S0acS0cb - S0abS0cc)/DenT;
327	T13= (-(S0acS0bb) + S0abS0bc)/DenT;
328	T21= (S0bcS0ca - S0baS0cc)/DenT;
329	T22= (-(S0acS0ca) + S0aaS0cc)/DenT;
330	T23= (S0acS0ba - S0aaS0bc)/DenT;
331	T31= (-(S0bbS0ca) + S0baS0cb)/DenT;
332	T32= (S0abS0ca - S0aaS0cb)/DenT;
333	T33= (-(S0abS0ba) + S0aaS0bb)/DenT;
334
335	Y1=T11S0ad+T12S0bd+T13*S0cd+1.0;
336	Y2=T21S0ad+T22S0bd+T23*S0cd+1.0;
337	Y3=T31S0ad+T32S0bd+T33*S0cd+1.0;
338
339	X11=Y1*Y1;
340	X12=Y1*Y2;
341	X13=Y1*Y3;
342	X21=Y2*Y1;
343	X22=Y2*Y2;
344	X23=Y2*Y3;
345	X31=Y3*Y1;
346	X32=Y3*Y2;
347	X33=Y3*Y3;
348
349	ZZ=S0ad(T11S0ad+T12S0bd+T13S0cd)+S0bd(T21S0ad+T22S0bd+T23S0cd)+S0cd(T31S0ad+T32S0bd+T33S0cd);
350
351	m=1.0/(S0dd-ZZ);
352
353	N11=m*X11+Zaa;
354	N12=m*X12+Zab;
355	N13=m*X13+Zac;
356	N21=m*X21+Zba;
357	N22=m*X22+Zbb;
358	N23=m*X23+Zbc;
359	N31=m*X31+Zca;
360	N32=m*X32+Zcb;
361	N33=m*X33+Zcc;
362
363	M11= N11S0aa + N12S0ab + N13*S0ac;
364	M12= N11S0ab + N12S0bb + N13*S0bc;
365	M13= N11S0ac + N12S0bc + N13*S0cc;
366	M21= N21S0aa + N22S0ab + N23*S0ac;
367	M22= N21S0ab + N22S0bb + N23*S0bc;
368	M23= N21S0ac + N22S0bc + N23*S0cc;
369	M31= N31S0aa + N32S0ab + N33*S0ac;
370	M32= N31S0ab + N32S0bb + N33*S0bc;
371	M33= N31S0ac + N32S0bc + N33*S0cc;
372
373	DenQ1=1.0+M11-M12M21+M22+M11M22-M13M31-M13M22*M31;
374	DenQ2= M12M23M31+M13M21M32-M23M32-M11M23M32+M33+M11M33;
375	DenQ3= -M12M21M33+M22M33+M11M22*M33;
376	DenQ=DenQ1+DenQ2+DenQ3;
377
378	Q11= (1.0 + M22-M23M32 + M33 + M22M33)/DenQ;
379	Q12= (-M12 + M13M32 - M12M33)/DenQ;
380	Q13= (-M13 - M13M22 + M12M23)/DenQ;
381	Q21= (-M21 + M23M31 - M21M33)/DenQ;
382	Q22= (1.0 + M11 - M13M31 + M33 + M11M33)/DenQ;
383	Q23= (M13M21 - M23 - M11M23)/DenQ;
384	Q31= (-M31 - M22M31 + M21M32)/DenQ;
385	Q32= (M12M31 - M32 - M11M32)/DenQ;
386	Q33= (1.0 + M11 - M12M21 + M22 + M11M22)/DenQ;
387
388	S11= Q11S0aa + Q21S0ab + Q31*S0ac;
389	S12= Q12S0aa + Q22S0ab + Q32*S0ac;
390	S13= Q13S0aa + Q23S0ab + Q33*S0ac;
391	S14=-S11-S12-S13;
392	S21= Q11S0ba + Q21S0bb + Q31*S0bc;
393	S22= Q12S0ba + Q22S0bb + Q32*S0bc;
394	S23= Q13S0ba + Q23S0bb + Q33*S0bc;
395	S24=-S21-S22-S23;
396	S31= Q11S0ca + Q21S0cb + Q31*S0cc;
397	S32= Q12S0ca + Q22S0cb + Q32*S0cc;
398	S33= Q13S0ca + Q23S0cb + Q33*S0cc;
399	S34=-S31-S32-S33;
400	S41=S14;
401	S42=S24;
402	S43=S34;
403	S44=S11+S22+S33+2.0S12+2.0S13+2.0*S23;
404
405	Nav=6.022045e+23;
406	Lad=(La/va-Ld/vd)*sqrt(Nav);
407	Lbd=(Lb/vb-Ld/vd)*sqrt(Nav);
408	Lcd=(Lc/vc-Ld/vd)*sqrt(Nav);
409
410	Intg=pow(Lad,2.0)S11+pow(Lbd,2.0)S22+pow(Lcd,2.0)S33+2.0LadLbdS12+2.0LbdLcdS23+2.0LadLcdS13;
411
412	Intg *= scale;
413	Intg += background;
414
415	return Intg;
416
417	}
418
419	RPAModel :: RPAModel() {
420	lcase_n = Parameter(0.0);
421	ba = Parameter(5.0);
422	bb = Parameter(5.0);
423	bc = Parameter(5.0);
424	bd = Parameter(5.0);
425
426	Kab = Parameter(-0.0004);
427	Kac = Parameter(-0.0004);
428	Kad = Parameter(-0.0004);
429	Kbc = Parameter(-0.0004);
430	Kbd = Parameter(-0.0004);
431	Kcd = Parameter(-0.0004);
432
433	scale = Parameter(1.0);
434	background = Parameter(0.0);
435
436	Na = Parameter(1000.0);
437	Phia = Parameter(0.25);
438	va = Parameter(100.0);
439	La = Parameter(1.0e-012);
440
441	Nb = Parameter(1000.0);
442	Phib = Parameter(0.25);
443	vb = Parameter(100.0);
444	Lb = Parameter(1.0e-012);
445
446	Nc = Parameter(1000.0);
447	Phic = Parameter(0.25);
448	vc = Parameter(100.0);
449	Lc = Parameter(1.0e-012);
450
451	Nd = Parameter(1000.0);
452	Phid = Parameter(0.25);
453	vd = Parameter(100.0);
454	Ld = Parameter(0.0e-012);
455
456	}
457
458	/**
459	* Function to evaluate 1D scattering function
460	* The NIST IGOR library is used for the actual calculation.
461	* @param q: q-value
462	* @return: function value
463	*/
464	double RPAModel :: operator()(double q) {
465	double dp[29];
466	// Fill parameter array for IGOR library
467	// Add the background after averaging
468	//Fittable parameters
469	dp[0] = lcase_n();
470
471	dp[1] = ba();
472	dp[2] = bb();
473	dp[3] = bc();
474	dp[4] = bd();
475
476	dp[5] = Kab();
477	dp[6] = Kac();
478	dp[7] = Kad();
479	dp[8] = Kbc();
480	dp[9] = Kbd();
481	dp[10] = Kcd();
482
483	dp[11] = scale();
484	dp[12] = background();
485
486	//Fixed parameters
487	dp[13] = Na();
488	dp[14] = Phia();
489	dp[15] = va();
490	dp[16] = La();
491
492	dp[17] = Nb();
493	dp[18] = Phib();
494	dp[19] = vb();
495	dp[20] = Lb();
496
497	dp[21] = Nc();
498	dp[22] = Phic();
499	dp[23] = vc();
500	dp[24] = Lc();
501
502	dp[25] = Nd();
503	dp[26] = Phid();
504	dp[27] = vd();
505	dp[28] = Ld();
506
507	return rpa_kernel(dp,q);
508	}
509
510	/**
511	* Function to evaluate 2D scattering function
512	* @param q_x: value of Q along x
513	* @param q_y: value of Q along y
514	* @return: function value
515	*/
516	double RPAModel :: operator()(double qx, double qy) {
517	double q = sqrt(qxqx + qyqy);
518	return (*this).operator()(q);
519	}
520
521	/**
522	* Function to evaluate 2D scattering function
523	* @param pars: parameters of the sphere
524	* @param q: q-value
525	* @param phi: angle phi
526	* @return: function value
527	*/
528	double RPAModel :: evaluate_rphi(double q, double phi) {
529	return (*this).operator()(q);
530	}
531
532	/**
533	* Function to calculate effective radius
534	* @return: effective radius value
535	*/
536	double RPAModel :: calculate_ER() {
537	//NOT implemented!!!
538	return 0.0;
539	}
540	double RPAModel :: calculate_VR() {
541	return 1.0;
542	}

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