jv.c @ b9a5f0e

ESS_GUIESS_GUI_DocsESS_GUI_batch_fittingESS_GUI_bumps_abstractionESS_GUI_iss1116ESS_GUI_iss879ESS_GUI_iss959ESS_GUI_openclESS_GUI_orderingESS_GUI_sync_sascalccostrafo411magnetic_scattrelease-4.1.1release-4.1.2release-4.2.2release_4.0.1ticket-1009ticket-1094-headlessticket-1242-2d-resolutionticket-1243ticket-1249ticket885unittest-saveload

Last change on this file since b9a5f0e was 79492222, checked in by krzywon, 10 years ago
Changed the file and folder names to remove all SANS references.
Property mode set to `100644`
File size: 14.8 KB

Rev	Line
[230f479]	1	/* jv.c
	2	*
	3	* Bessel function of noninteger order
	4	*
	5	*
	6	*
	7	* SYNOPSIS:
	8	*
	9	* double v, x, y, jv();
	10	*
	11	* y = jv( v, x );
	12	*
	13	*
	14	*
	15	* DESCRIPTION:
	16	*
	17	* Returns Bessel function of order v of the argument,
	18	* where v is real. Negative x is allowed if v is an integer.
	19	*
	20	* Several expansions are included: the ascending power
	21	* series, the Hankel expansion, and two transitional
	22	* expansions for large v. If v is not too large, it
	23	* is reduced by recurrence to a region of best accuracy.
	24	* The transitional expansions give 12D accuracy for v > 500.
	25	*
	26	*
	27	*
	28	* ACCURACY:
	29	* Results for integer v are indicated by *, where x and v
	30	* both vary from -125 to +125. Otherwise,
	31	* x ranges from 0 to 125, v ranges as indicated by "domain."
	32	* Error criterion is absolute, except relative when \|jv()\| > 1.
	33	*
	34	* arithmetic v domain x domain # trials peak rms
	35	* IEEE 0,125 0,125 100000 4.6e-15 2.2e-16
	36	* IEEE -125,0 0,125 40000 5.4e-11 3.7e-13
	37	* IEEE 0,500 0,500 20000 4.4e-15 4.0e-16
	38	* Integer v:
	39	* IEEE -125,125 -125,125 50000 3.5e-15* 1.9e-16*
	40	*
	41	*/
	42
	43
	44	/*
	45	Cephes Math Library Release 2.8: June, 2000
	46	Copyright 1984, 1987, 1989, 1992, 2000 by Stephen L. Moshier
	47	*/
	48
	49
	50	#include "mconf.h"
	51	#define DEBUG 0
	52
	53	#ifdef DEC
	54	#define MAXGAM 34.84425627277176174
	55	#else
	56	#define MAXGAM 171.624376956302725
	57	#endif
	58
	59	#ifdef ANSIPROT
	60	extern int airy ( double, double , double , double , double );
	61	extern double fabs ( double );
	62	extern double floor ( double );
	63	extern double frexp ( double, int * );
	64	extern double polevl ( double, void *, int );
	65	extern double j0 ( double );
	66	extern double j1 ( double );
	67	extern double sqrt ( double );
	68	extern double cbrt ( double );
	69	extern double exp ( double );
	70	extern double log ( double );
	71	extern double sin ( double );
	72	extern double cos ( double );
	73	extern double acos ( double );
	74	extern double pow ( double, double );
	75	extern double gamma ( double );
	76	extern double lgam ( double );
	77	static double recur(double , double, double , int);
	78	static double jvs(double, double);
	79	static double hankel(double, double);
	80	static double jnx(double, double);
	81	static double jnt(double, double);
	82	#else
	83	int airy();
	84	double fabs(), floor(), frexp(), polevl(), j0(), j1(), sqrt(), cbrt();
	85	double exp(), log(), sin(), cos(), acos(), pow(), gamma(), lgam();
	86	static double recur(), jvs(), hankel(), jnx(), jnt();
	87	#endif
	88
	89	extern double MAXNUM, MACHEP, MINLOG, MAXLOG;
	90	#define BIG 1.44115188075855872E+17
	91
	92	double jv( n, x )
	93	double n, x;
	94	{
	95	double k, q, t, y, an;
	96	int i, sign, nint;
	97
	98	nint = 0; /* Flag for integer n */
	99	sign = 1; /* Flag for sign inversion */
	100	an = fabs( n );
	101	y = floor( an );
	102	if( y == an )
	103	{
	104	nint = 1;
	105	i = an - 16384.0 * floor( an/16384.0 );
	106	if( n < 0.0 )
	107	{
	108	if( i & 1 )
	109	sign = -sign;
	110	n = an;
	111	}
	112	if( x < 0.0 )
	113	{
	114	if( i & 1 )
	115	sign = -sign;
	116	x = -x;
	117	}
	118	if( n == 0.0 )
	119	return( j0(x) );
	120	if( n == 1.0 )
	121	return( sign * j1(x) );
	122	}
	123
	124	if( (x < 0.0) && (y != an) )
	125	{
	126	mtherr( "Jv", DOMAIN );
	127	y = 0.0;
	128	goto done;
	129	}
	130
	131	y = fabs(x);
	132
	133	if( y < MACHEP )
	134	goto underf;
	135
	136	k = 3.6 * sqrt(y);
	137	t = 3.6 * sqrt(an);
	138	if( (y < t) && (an > 21.0) )
	139	return( sign * jvs(n,x) );
	140	if( (an < k) && (y > 21.0) )
	141	return( sign * hankel(n,x) );
	142
	143	if( an < 500.0 )
	144	{
	145	/* Note: if x is too large, the continued
	146	* fraction will fail; but then the
	147	* Hankel expansion can be used.
	148	*/
	149	if( nint != 0 )
	150	{
	151	k = 0.0;
	152	q = recur( &n, x, &k, 1 );
	153	if( k == 0.0 )
	154	{
	155	y = j0(x)/q;
	156	goto done;
	157	}
	158	if( k == 1.0 )
	159	{
	160	y = j1(x)/q;
	161	goto done;
	162	}
	163	}
	164
	165	if( an > 2.0 * y )
	166	goto rlarger;
	167
	168	if( (n >= 0.0) && (n < 20.0)
	169	&& (y > 6.0) && (y < 20.0) )
	170	{
	171	/* Recur backwards from a larger value of n
	172	*/
	173	rlarger:
	174	k = n;
	175
	176	y = y + an + 1.0;
	177	if( y < 30.0 )
	178	y = 30.0;
	179	y = n + floor(y-n);
	180	q = recur( &y, x, &k, 0 );
	181	y = jvs(y,x) * q;
	182	goto done;
	183	}
	184
	185	if( k <= 30.0 )
	186	{
	187	k = 2.0;
	188	}
	189	else if( k < 90.0 )
	190	{
	191	k = (3*k)/4;
	192	}
	193	if( an > (k + 3.0) )
	194	{
	195	if( n < 0.0 )
	196	k = -k;
	197	q = n - floor(n);
	198	k = floor(k) + q;
	199	if( n > 0.0 )
	200	q = recur( &n, x, &k, 1 );
	201	else
	202	{
	203	t = k;
	204	k = n;
	205	q = recur( &t, x, &k, 1 );
	206	k = t;
	207	}
	208	if( q == 0.0 )
	209	{
	210	underf:
	211	y = 0.0;
	212	goto done;
	213	}
	214	}
	215	else
	216	{
	217	k = n;
	218	q = 1.0;
	219	}
	220
	221	/* boundary between convergence of
	222	* power series and Hankel expansion
	223	*/
	224	y = fabs(k);
	225	if( y < 26.0 )
	226	t = (0.0083y + 0.09)y + 12.9;
	227	else
	228	t = 0.9 * y;
	229
	230	if( x > t )
	231	y = hankel(k,x);
	232	else
	233	y = jvs(k,x);
	234	#if DEBUG
	235	printf( "y = %.16e, recur q = %.16e\n", y, q );
	236	#endif
	237	if( n > 0.0 )
	238	y /= q;
	239	else
	240	y *= q;
	241	}
	242
	243	else
	244	{
	245	/* For large n, use the uniform expansion
	246	* or the transitional expansion.
	247	* But if x is of the order of n**2,
	248	* these may blow up, whereas the
	249	* Hankel expansion will then work.
	250	*/
	251	if( n < 0.0 )
	252	{
	253	mtherr( "Jv", TLOSS );
	254	y = 0.0;
	255	goto done;
	256	}
	257	t = x/n;
	258	t /= n;
	259	if( t > 0.3 )
	260	y = hankel(n,x);
	261	else
	262	y = jnx(n,x);
	263	}
	264
	265	done: return( sign * y);
	266	}
	267
	268	/* Reduce the order by backward recurrence.
	269	* AMS55 #9.1.27 and 9.1.73.
	270	*/
	271
	272	static double recur( n, x, newn, cancel )
	273	double *n;
	274	double x;
	275	double *newn;
	276	int cancel;
	277	{
	278	double pkm2, pkm1, pk, qkm2, qkm1;
	279	/* double pkp1; */
	280	double k, ans, qk, xk, yk, r, t, kf;
	281	static double big = BIG;
	282	int nflag, ctr;
	283
	284	/* continued fraction for Jn(x)/Jn-1(x) */
	285	if( *n < 0.0 )
	286	nflag = 1;
	287	else
	288	nflag = 0;
	289
	290	fstart:
	291
	292	#if DEBUG
	293	printf( "recur: n = %.6e, newn = %.6e, cfrac = ", n, newn );
	294	#endif
	295
	296	pkm2 = 0.0;
	297	qkm2 = 1.0;
	298	pkm1 = x;
	299	qkm1 = n + n;
	300	xk = -x * x;
	301	yk = qkm1;
	302	ans = 1.0;
	303	ctr = 0;
	304	do
	305	{
	306	yk += 2.0;
	307	pk = pkm1 * yk + pkm2 * xk;
	308	qk = qkm1 * yk + qkm2 * xk;
	309	pkm2 = pkm1;
	310	pkm1 = pk;
	311	qkm2 = qkm1;
	312	qkm1 = qk;
	313	if( qk != 0 )
	314	r = pk/qk;
	315	else
	316	r = 0.0;
	317	if( r != 0 )
	318	{
	319	t = fabs( (ans - r)/r );
	320	ans = r;
	321	}
	322	else
	323	t = 1.0;
	324
	325	if( ++ctr > 1000 )
	326	{
	327	mtherr( "jv", UNDERFLOW );
	328	goto done;
	329	}
	330	if( t < MACHEP )
	331	goto done;
	332
	333	if( fabs(pk) > big )
	334	{
	335	pkm2 /= big;
	336	pkm1 /= big;
	337	qkm2 /= big;
	338	qkm1 /= big;
	339	}
	340	}
	341	while( t > MACHEP );
	342
	343	done:
	344
	345	#if DEBUG
	346	printf( "%.6e\n", ans );
	347	#endif
	348
	349	/* Change n to n-1 if n < 0 and the continued fraction is small
	350	*/
	351	if( nflag > 0 )
	352	{
	353	if( fabs(ans) < 0.125 )
	354	{
	355	nflag = -1;
	356	n = n - 1.0;
	357	goto fstart;
	358	}
	359	}
	360
	361
	362	kf = *newn;
	363
	364	/* backward recurrence
	365	* 2k
	366	* J (x) = --- J (x) - J (x)
	367	* k-1 x k k+1
	368	*/
	369
	370	pk = 1.0;
	371	pkm1 = 1.0/ans;
	372	k = *n - 1.0;
	373	r = 2 * k;
	374	do
	375	{
	376	pkm2 = (pkm1 * r - pk * x) / x;
	377	/* pkp1 = pk; */
	378	pk = pkm1;
	379	pkm1 = pkm2;
	380	r -= 2.0;
	381	/*
	382	t = fabs(pkp1) + fabs(pk);
	383	if( (k > (kf + 2.5)) && (fabs(pkm1) < 0.25*t) )
	384	{
	385	k -= 1.0;
	386	t = x*x;
	387	pkm2 = ( (r(r+2.0)-t)pk - rxpkp1 )/t;
	388	pkp1 = pk;
	389	pk = pkm1;
	390	pkm1 = pkm2;
	391	r -= 2.0;
	392	}
	393	*/
	394	k -= 1.0;
	395	}
	396	while( k > (kf + 0.5) );
	397
	398	/* Take the larger of the last two iterates
	399	* on the theory that it may have less cancellation error.
	400	*/
	401
	402	if( cancel )
	403	{
	404	if( (kf >= 0.0) && (fabs(pk) > fabs(pkm1)) )
	405	{
	406	k += 1.0;
	407	pkm2 = pk;
	408	}
	409	}
	410	*newn = k;
	411	#if DEBUG
	412	printf( "newn %.6e rans %.6e\n", k, pkm2 );
	413	#endif
	414	return( pkm2 );
	415	}
	416
	417
	418
	419	/* Ascending power series for Jv(x).
	420	* AMS55 #9.1.10.
	421	*/
	422
	423	extern double PI;
	424	extern int sgngam;
	425
	426	static double jvs( n, x )
	427	double n, x;
	428	{
	429	double t, u, y, z, k;
	430	int ex;
	431
	432	z = -x * x / 4.0;
	433	u = 1.0;
	434	y = u;
	435	k = 1.0;
	436	t = 1.0;
	437
	438	while( t > MACHEP )
	439	{
	440	u = z / (k (n+k));
	441	y += u;
	442	k += 1.0;
	443	if( y != 0 )
	444	t = fabs( u/y );
	445	}
	446	#if DEBUG
	447	printf( "power series=%.5e ", y );
	448	#endif
	449	t = frexp( 0.5*x, &ex );
	450	ex = ex * n;
	451	if( (ex > -1023)
	452	&& (ex < 1023)
	453	&& (n > 0.0)
	454	&& (n < (MAXGAM-1.0)) )
	455	{
	456	t = pow( 0.5*x, n ) / gamma( n + 1.0 );
	457	#if DEBUG
	458	printf( "pow(.5*x, %.4e)/gamma(n+1)=%.5e\n", n, t );
	459	#endif
	460	y *= t;
	461	}
	462	else
	463	{
	464	#if DEBUG
	465	z = n * log(0.5*x);
	466	k = lgam( n+1.0 );
	467	t = z - k;
	468	printf( "log pow=%.5e, lgam(%.4e)=%.5e\n", z, n+1.0, k );
	469	#else
	470	t = n * log(0.5*x) - lgam(n + 1.0);
	471	#endif
	472	if( y < 0 )
	473	{
	474	sgngam = -sgngam;
	475	y = -y;
	476	}
	477	t += log(y);
	478	#if DEBUG
	479	printf( "log y=%.5e\n", log(y) );
	480	#endif
	481	if( t < -MAXLOG )
	482	{
	483	return( 0.0 );
	484	}
	485	if( t > MAXLOG )
	486	{
	487	mtherr( "Jv", OVERFLOW );
	488	return( MAXNUM );
	489	}
	490	y = sgngam * exp( t );
	491	}
	492	return(y);
	493	}
	494
	495	/* Hankel's asymptotic expansion
	496	* for large x.
	497	* AMS55 #9.2.5.
	498	*/
	499
	500	static double hankel( n, x )
	501	double n, x;
	502	{
	503	double t, u, z, k, sign, conv;
	504	double p, q, j, m, pp, qq;
	505	int flag;
	506
	507	m = 4.0nn;
	508	j = 1.0;
	509	z = 8.0 * x;
	510	k = 1.0;
	511	p = 1.0;
	512	u = (m - 1.0)/z;
	513	q = u;
	514	sign = 1.0;
	515	conv = 1.0;
	516	flag = 0;
	517	t = 1.0;
	518	pp = 1.0e38;
	519	qq = 1.0e38;
	520
	521	while( t > MACHEP )
	522	{
	523	k += 2.0;
	524	j += 1.0;
	525	sign = -sign;
	526	u = (m - k k)/(j * z);
	527	p += sign * u;
	528	k += 2.0;
	529	j += 1.0;
	530	u = (m - k k)/(j * z);
	531	q += sign * u;
	532	t = fabs(u/p);
	533	if( t < conv )
	534	{
	535	conv = t;
	536	qq = q;
	537	pp = p;
	538	flag = 1;
	539	}
	540	/* stop if the terms start getting larger */
	541	if( (flag != 0) && (t > conv) )
	542	{
	543	#if DEBUG
	544	printf( "Hankel: convergence to %.4E\n", conv );
	545	#endif
	546	goto hank1;
	547	}
	548	}
	549
	550	hank1:
	551	u = x - (0.5n + 0.25) PI;
	552	t = sqrt( 2.0/(PIx) ) ( pp * cos(u) - qq * sin(u) );
	553	#if DEBUG
	554	printf( "hank: %.6e\n", t );
	555	#endif
	556	return( t );
	557	}
	558
	559
	560	/* Asymptotic expansion for large n.
	561	* AMS55 #9.3.35.
	562	*/
	563
	564	static double lambda[] = {
	565	1.0,
	566	1.041666666666666666666667E-1,
	567	8.355034722222222222222222E-2,
	568	1.282265745563271604938272E-1,
	569	2.918490264641404642489712E-1,
	570	8.816272674437576524187671E-1,
	571	3.321408281862767544702647E+0,
	572	1.499576298686255465867237E+1,
	573	7.892301301158651813848139E+1,
	574	4.744515388682643231611949E+2,
	575	3.207490090890661934704328E+3
	576	};
	577	static double mu[] = {
	578	1.0,
	579	-1.458333333333333333333333E-1,
	580	-9.874131944444444444444444E-2,
	581	-1.433120539158950617283951E-1,
	582	-3.172272026784135480967078E-1,
	583	-9.424291479571202491373028E-1,
	584	-3.511203040826354261542798E+0,
	585	-1.572726362036804512982712E+1,
	586	-8.228143909718594444224656E+1,
	587	-4.923553705236705240352022E+2,
	588	-3.316218568547972508762102E+3
	589	};
	590	static double P1[] = {
	591	-2.083333333333333333333333E-1,
	592	1.250000000000000000000000E-1
	593	};
	594	static double P2[] = {
	595	3.342013888888888888888889E-1,
	596	-4.010416666666666666666667E-1,
	597	7.031250000000000000000000E-2
	598	};
	599	static double P3[] = {
	600	-1.025812596450617283950617E+0,
	601	1.846462673611111111111111E+0,
	602	-8.912109375000000000000000E-1,
	603	7.324218750000000000000000E-2
	604	};
	605	static double P4[] = {
	606	4.669584423426247427983539E+0,
	607	-1.120700261622299382716049E+1,
	608	8.789123535156250000000000E+0,
	609	-2.364086914062500000000000E+0,
	610	1.121520996093750000000000E-1
	611	};
	612	static double P5[] = {
	613	-2.8212072558200244877E1,
	614	8.4636217674600734632E1,
	615	-9.1818241543240017361E1,
	616	4.2534998745388454861E1,
	617	-7.3687943594796316964E0,
	618	2.27108001708984375E-1
	619	};
	620	static double P6[] = {
	621	2.1257013003921712286E2,
	622	-7.6525246814118164230E2,
	623	1.0599904525279998779E3,
	624	-6.9957962737613254123E2,
	625	2.1819051174421159048E2,
	626	-2.6491430486951555525E1,
	627	5.7250142097473144531E-1
	628	};
	629	static double P7[] = {
	630	-1.9194576623184069963E3,
	631	8.0617221817373093845E3,
	632	-1.3586550006434137439E4,
	633	1.1655393336864533248E4,
	634	-5.3056469786134031084E3,
	635	1.2009029132163524628E3,
	636	-1.0809091978839465550E2,
	637	1.7277275025844573975E0
	638	};
	639
	640
	641	static double jnx( n, x )
	642	double n, x;
	643	{
	644	double zeta, sqz, zz, zp, np;
	645	double cbn, n23, t, z, sz;
	646	double pp, qq, z32i, zzi;
	647	double ak, bk, akl, bkl;
	648	int sign, doa, dob, nflg, k, s, tk, tkp1, m;
	649	static double u[8];
	650	static double ai, aip, bi, bip;
	651
	652	/* Test for x very close to n.
	653	* Use expansion for transition region if so.
	654	*/
	655	cbn = cbrt(n);
	656	z = (x - n)/cbn;
	657	if( fabs(z) <= 0.7 )
	658	return( jnt(n,x) );
	659
	660	z = x/n;
	661	zz = 1.0 - z*z;
	662	if( zz == 0.0 )
	663	return(0.0);
	664
	665	if( zz > 0.0 )
	666	{
	667	sz = sqrt( zz );
	668	t = 1.5 * (log( (1.0+sz)/z ) - sz ); /* zeta ** 3/2 */
	669	zeta = cbrt( t * t );
	670	nflg = 1;
	671	}
	672	else
	673	{
	674	sz = sqrt(-zz);
	675	t = 1.5 * (sz - acos(1.0/z));
	676	zeta = -cbrt( t * t );
	677	nflg = -1;
	678	}
	679	z32i = fabs(1.0/t);
	680	sqz = cbrt(t);
	681
	682	/* Airy function */
	683	n23 = cbrt( n * n );
	684	t = n23 * zeta;
	685
	686	#if DEBUG
	687	printf("zeta %.5E, Airy(%.5E)\n", zeta, t );
	688	#endif
	689	airy( t, &ai, &aip, &bi, &bip );
	690
	691	/* polynomials in expansion */
	692	u[0] = 1.0;
	693	zzi = 1.0/zz;
	694	u[1] = polevl( zzi, P1, 1 )/sz;
	695	u[2] = polevl( zzi, P2, 2 )/zz;
	696	u[3] = polevl( zzi, P3, 3 )/(sz*zz);
	697	pp = zz*zz;
	698	u[4] = polevl( zzi, P4, 4 )/pp;
	699	u[5] = polevl( zzi, P5, 5 )/(pp*sz);
	700	pp *= zz;
	701	u[6] = polevl( zzi, P6, 6 )/pp;
	702	u[7] = polevl( zzi, P7, 7 )/(pp*sz);
	703
	704	#if DEBUG
	705	for( k=0; k<=7; k++ )
	706	printf( "u[%d] = %.5E\n", k, u[k] );
	707	#endif
	708
	709	pp = 0.0;
	710	qq = 0.0;
	711	np = 1.0;
	712	/* flags to stop when terms get larger */
	713	doa = 1;
	714	dob = 1;
	715	akl = MAXNUM;
	716	bkl = MAXNUM;
	717
	718	for( k=0; k<=3; k++ )
	719	{
	720	tk = 2 * k;
	721	tkp1 = tk + 1;
	722	zp = 1.0;
	723	ak = 0.0;
	724	bk = 0.0;
	725	for( s=0; s<=tk; s++ )
	726	{
	727	if( doa )
	728	{
	729	if( (s & 3) > 1 )
	730	sign = nflg;
	731	else
	732	sign = 1;
	733	ak += sign * mu[s] * zp * u[tk-s];
	734	}
	735
	736	if( dob )
	737	{
	738	m = tkp1 - s;
	739	if( ((m+1) & 3) > 1 )
	740	sign = nflg;
	741	else
	742	sign = 1;
	743	bk += sign * lambda[s] * zp * u[m];
	744	}
	745	zp *= z32i;
	746	}
	747
	748	if( doa )
	749	{
	750	ak *= np;
	751	t = fabs(ak);
	752	if( t < akl )
	753	{
	754	akl = t;
	755	pp += ak;
	756	}
	757	else
	758	doa = 0;
	759	}
	760
	761	if( dob )
	762	{
	763	bk += lambda[tkp1] * zp * u[0];
	764	bk *= -np/sqz;
	765	t = fabs(bk);
	766	if( t < bkl )
	767	{
	768	bkl = t;
	769	qq += bk;
	770	}
	771	else
	772	dob = 0;
	773	}
	774	#if DEBUG
	775	printf("a[%d] %.5E, b[%d] %.5E\n", k, ak, k, bk );
	776	#endif
	777	if( np < MACHEP )
	778	break;
	779	np /= n*n;
	780	}
	781
	782	/* normalizing factor ( 4zeta/(1 - z2) )1/4 /
	783	t = 4.0 * zeta/zz;
	784	t = sqrt( sqrt(t) );
	785
	786	t = aipp/cbrt(n) + aipqq/(n23n);
	787	return(t);
	788	}
	789
	790	/* Asymptotic expansion for transition region,
	791	* n large and x close to n.
	792	* AMS55 #9.3.23.
	793	*/
	794
	795	static double PF2[] = {
	796	-9.0000000000000000000e-2,
	797	8.5714285714285714286e-2
	798	};
	799	static double PF3[] = {
	800	1.3671428571428571429e-1,
	801	-5.4920634920634920635e-2,
	802	-4.4444444444444444444e-3
	803	};
	804	static double PF4[] = {
	805	1.3500000000000000000e-3,
	806	-1.6036054421768707483e-1,
	807	4.2590187590187590188e-2,
	808	2.7330447330447330447e-3
	809	};
	810	static double PG1[] = {
	811	-2.4285714285714285714e-1,
	812	1.4285714285714285714e-2
	813	};
	814	static double PG2[] = {
	815	-9.0000000000000000000e-3,
	816	1.9396825396825396825e-1,
	817	-1.1746031746031746032e-2
	818	};
	819	static double PG3[] = {
	820	1.9607142857142857143e-2,
	821	-1.5983694083694083694e-1,
	822	6.3838383838383838384e-3
	823	};
	824
	825
	826	static double jnt( n, x )
	827	double n, x;
	828	{
	829	double z, zz, z3;
	830	double cbn, n23, cbtwo;
	831	double ai, aip, bi, bip; /* Airy functions */
	832	double nk, fk, gk, pp, qq;
	833	double F[5], G[4];
	834	int k;
	835
	836	cbn = cbrt(n);
	837	z = (x - n)/cbn;
	838	cbtwo = cbrt( 2.0 );
	839
	840	/* Airy function */
	841	zz = -cbtwo * z;
	842	airy( zz, &ai, &aip, &bi, &bip );
	843
	844	/* polynomials in expansion */
	845	zz = z * z;
	846	z3 = zz * z;
	847	F[0] = 1.0;
	848	F[1] = -z/5.0;
	849	F[2] = polevl( z3, PF2, 1 ) * zz;
	850	F[3] = polevl( z3, PF3, 2 );
	851	F[4] = polevl( z3, PF4, 3 ) * z;
	852	G[0] = 0.3 * zz;
	853	G[1] = polevl( z3, PG1, 1 );
	854	G[2] = polevl( z3, PG2, 2 ) * z;
	855	G[3] = polevl( z3, PG3, 2 ) * zz;
	856	#if DEBUG
	857	for( k=0; k<=4; k++ )
	858	printf( "F[%d] = %.5E\n", k, F[k] );
	859	for( k=0; k<=3; k++ )
	860	printf( "G[%d] = %.5E\n", k, G[k] );
	861	#endif
	862	pp = 0.0;
	863	qq = 0.0;
	864	nk = 1.0;
	865	n23 = cbrt( n * n );
	866
	867	for( k=0; k<=4; k++ )
	868	{
	869	fk = F[k]*nk;
	870	pp += fk;
	871	if( k != 4 )
	872	{
	873	gk = G[k]*nk;
	874	qq += gk;
	875	}
	876	#if DEBUG
	877	printf("fk[%d] %.5E, gk[%d] %.5E\n", k, fk, k, gk );
	878	#endif
	879	nk /= n23;
	880	}
	881
	882	fk = cbtwo * ai * pp/cbn + cbrt(4.0) * aip * qq/n;
	883	return(fk);
	884	}

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source: sasview/src/sas/models/c_extension/cephes/jv.c @ b9a5f0e

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