PSI sics-cvs-psi_pre-ansto

tacov.c

@@ -0,0 +1,601 @@
+/* tacov.f -- translated by f2c (version 20000817).
+   You must link the resulting object file with the libraries:
+	-lf2c -lm   (in that order)
+*/
+
+#include "f2c.h"
+
+/* Common Block Declarations */
+
+struct {
+    integer inx;
+    real c1rx, c2rx, rmin, rmax, cl1r;
+} curve_;
+
+#define curve_1 curve_
+
+/* Table of constant values */
+
+static doublereal c_b7 = 1.;
+static doublereal c_b9 = 360.;
+
+/* ----------------------------------------------------------------------- */
+/*       FILE T_CONV */
+/*       SUBROUTINE T_CONV(EI,AKI,EF,AKF,QHKL,EN,HX,HY,HZ,IF1,IF2,LDK,LDH,LDF */
+/*       1       LPA,DM,DA,HELM,F1H,F1V,F2H,F2V,F,IFX,ISS,ISM,ISA, */
+/*       2       T_A,T_RM,T_ALM,LDRA,LDR_RM,LDR_ALM,P_IH,C_IH,IER) */
+/*       SUBROUTINE EX_CASE(DX,ISX,AKX,AX1,AX2,RX,ALX,IER) */
+/*       SUBROUTINE SAM_CASE(QT,QM,QS,AKI,AKF,AX3,AX4,ISS,IER) */
+/*       SUBROUTINE HELM_CASE(HX,HY,HZ,P_IH,AKI,AKF,A4,QM,HELM,IER) */
+/*       SUBROUTINE FLIP_CASE(IF1,IF2,P_IH,F1V,F1H,F2V,F2H,AKI,AKF,IER) */
+/* ----------------------------------------------------------------------- */
+/* Subroutine */ int t_conv__(real *ei, real *aki, real *ef, real *akf, real *
+	qhkl, real *en, real *hx, real *hy, real *hz, integer *if1, integer *
+	if2, logical *ldk, logical *ldh, logical *ldf, logical *lpa, real *dm,
+	 real *da, real *helm, real *f1h, real *f1v, real *f2h, real *f2v, 
+	real *f, integer *ifx, integer *iss, integer *ism, integer *isa, real 
+	*t_a__, real *t_rm__, real *t_alm__, real *qm, logical *ldra, logical 
+	*ldr_rm__, logical *ldr_alm__, real *p_ih__, real *c_ih__, integer *
+	ier)
+{
+    /* System generated locals */
+    doublereal d__1;
+
+    /* Builtin functions */
+    double sqrt(doublereal);
+
+    /* Local variables */
+    static doublereal edef[2], dakf, daki;
+    static integer imod;
+    extern /* Subroutine */ int sam_case__(doublereal *, doublereal *, 
+	    doublereal *, doublereal *, doublereal *, doublereal *, 
+	    doublereal *, integer *, integer *);
+    static integer i__;
+    static doublereal akdef[2];
+    extern /* Subroutine */ int helm_case__(real *, real *, real *, real *, 
+	    real *, real *, real *, doublereal *, real *, real *, integer *);
+    static doublereal dqhkl[3];
+    extern /* Subroutine */ int flip_case__(integer *, integer *, real *, 
+	    real *, real *, real *, real *, real *, real *, integer *);
+    static logical lmoan[2];
+    static doublereal a1, a2, a3, a4, a5, a6;
+    static integer id;
+    static doublereal ra;
+    extern /* Subroutine */ int rl2spv_(doublereal *, doublereal *, 
+	    doublereal *, doublereal *, integer *);
+    static integer iq;
+    static doublereal rm;
+    static logical lqhkle;
+    extern /* Subroutine */ int erreso_(integer *, integer *);
+    static doublereal dda, ala, def, dei, ddm, alm, dqm;
+    extern /* Subroutine */ int ex_case__(doublereal *, integer *, doublereal 
+	    *, doublereal *, doublereal *, doublereal *, doublereal *, 
+	    integer *);
+    static doublereal dqt[3], dqs;
+
+/* ----------------------------------------------------------------------- */
+
+/*       INPUT */
+/*       EI,AKI,EF,AKF,QHKL,EN,HX,HY,HZ : POTENTIAL TARGETS */
+/* 	IF1,IF2 Status of flippers On (1) Off (0) */
+/*       LDK(8)          LOGICAL INDICATING IF (ENERGY,K OR Q) ARE DRIVEN */
+/*       LDH,LDF         LOGICAL INDICATING IF (HX,HY,HZ) OR (F1,F2) ARE DRIVEN */
+
+/*       configuration of the machine */
+/*       LPA             LOGICAL  TRUE IF MACHINE IN POLARIZATION MODE */
+/*       DM,DA,HELM,F1H,F1V,F2H,F2V,F,IFX,ISS,ISM,ISA,QM (F ENERGY UNIT) */
+
+/*       OUTPUT */
+/*       T_A             TARGETS OF ANGLES A1-A6 */
+/*       T_RM,T_ALM      TARGETS OF RM ,LM */
+/*       QM                      TARGETS OF QM */
+/*       LDRA                    LOGICAL INDICATING WHICH ANGLES ARE TO BE DRIVEN */
+/*       LDR_RM,LDR_ALM  LOGICAL INDICATING IF RM OR ALM ARE TO BE DRIVEN */
+/*       P_IH    TARGETS OF CURRENTS FOR FLIPPERS AND HELMOTZ (8 CURRENTS) */
+/*       C_IH    CONVERSION FACTORS FOR HELMOTZ (4 CURRENTS) */
+
+/*       SPECIAL OUTPUTS */
+/*       TARGET OF EI(EF) IS UPDATED IS KI(KF) IS DRIVEN */
+/*       TARGET OF VARIABLE ENERGY IS UPDATED IF EN IS DRIVEN */
+/* ----------------------------------------------------------------------- */
+/* ----------------------------------------------------------------------- */
+/*       PASSED PARAMETERS */
+/* ----------------------------------------------------------------------- */
+/*        LOCAL VARIABLES */
+
+/* ----------------------------------------------------------------------- */
+/*       SET UP */
+/*       IMOD  INDEX FOR ERROR TREATMENAT BY ERRESO */
+/*       LDQHKLE : LOGICAL INDICATING THAT WE ARE DEALING WITH A MOVE */
+/*       IN RECIPROCICAL SPACE */
+/*       WE REMAP THE ENERGY PB AS FIXED ENERGY IN EDEF(1) */
+/*       AND VARIABLE ENERGY IN EDEF(2) */
+/*       IF ISA IS NUL  SET IFX TO 1 AND PUT EF,KF, EQUAL TO EI,KI */
+
+    /* Parameter adjustments */
+    --c_ih__;
+    --p_ih__;
+    --ldra;
+    --t_a__;
+    --ldk;
+    --qhkl;
+
+    /* Function Body */
+    imod = 3;
+    ddm = *dm;
+    dda = *da;
+    for (i__ = 1; i__ <= 2; ++i__) {
+	lmoan[i__ - 1] = FALSE_;
+    }
+    lqhkle = FALSE_;
+    for (iq = 5; iq <= 8; ++iq) {
+	lqhkle = lqhkle || ldk[iq];
+    }
+    daki = *aki;
+    dakf = *akf;
+    if (*isa == 0) {
+	*ifx = 1;
+    }
+    edef[*ifx - 1] = *ei;
+    akdef[*ifx - 1] = *aki;
+    edef[3 - *ifx - 1] = *ef;
+    akdef[3 - *ifx - 1] = *akf;
+    if (*isa == 0) {
+	edef[1] = edef[0];
+	akdef[1] = akdef[0];
+	ldk[3] = TRUE_;
+	ldk[4] = TRUE_;
+	t_a__[5] = 0.f;
+	t_a__[6] = 0.f;
+	ldra[5] = TRUE_;
+	ldra[6] = TRUE_;
+    }
+/* ----------------------------------------------------------------------- */
+/*       FIRST TAKE IN ACCOUNT THE FIXED ENERGY PB */
+
+    if (ldk[(*ifx << 1) - 1] || ldk[*ifx * 2]) {
+	lmoan[*ifx - 1] = TRUE_;
+	if (ldk[(*ifx << 1) - 1]) {
+	    *ier = 1;
+	    if (edef[0] < .1) {
+		goto L999;
+	    }
+	    *ier = 0;
+	    akdef[0] = sqrt(edef[0] / *f);
+	} else {
+	    *ier = 1;
+	    if (akdef[0] < .1) {
+		goto L999;
+	    }
+	    *ier = 0;
+/* Computing 2nd power */
+	    d__1 = akdef[0];
+	    edef[0] = *f * (d__1 * d__1);
+	}
+    }
+/* ----------------------------------------------------------------------- */
+/*       NOW TAKE IN ACCOUNT THE VARIABLE ENERGY PB */
+/*       VARIABLE ENERGUY IS DRIVEN EITHER EXPLICITLY */
+/*       E.G. BY DRIVING EI OR KI WITH IFX=2 */
+/*        ( AND WE MUST CALCULATE EN FROM EVAR) */
+/*       THE RULE IS : EI=EF+EN : EN IS THE ENERGY LOSS OF NEUTRONS */
+/*       OR ENERGY GAIN OF SAMPLE */
+/*       OR IMPLICITLY  BY DRIVING THE TRANSFERED ENERGY EN */
+/*        ( AND WE MUST CALCULATE EVAR FROM EN) */
+/*       IF KI IS CONSTANT USE THE CURRENT VALUE CONTAINED IN POSN ARRAY */
+/*       TO CALCULATE THE NON-"CONSTANT" K. */
+/*       IF KF IS CONSTANT USE ALWAYS THE VALUE IN TARGET AND */
+/*        DO A DRIVE OF KF TO KEEP A5/A6 IN RIGHT POSITION */
+
+    if (ldk[5 - (*ifx << 1)] || ldk[6 - (*ifx << 1)]) {
+	lmoan[3 - *ifx - 1] = TRUE_;
+	if (ldk[5 - (*ifx << 1)]) {
+	    *ier = 1;
+	    if (edef[1] < 1e-4) {
+		goto L999;
+	    }
+	    *ier = 0;
+	    akdef[1] = sqrt(edef[1] / *f);
+	} else {
+	    *ier = 1;
+	    if (akdef[1] < 1e-4) {
+		goto L999;
+	    }
+	    *ier = 0;
+/* Computing 2nd power */
+	    d__1 = akdef[1];
+	    edef[1] = *f * (d__1 * d__1);
+	}
+	*en = (3 - (*ifx << 1)) * (edef[0] - edef[1]);
+    } else if (lqhkle) {
+	lmoan[3 - *ifx - 1] = TRUE_;
+	edef[1] = edef[0] + ((*ifx << 1) - 3) * *en;
+	*ier = 1;
+	if (edef[1] < 1e-4) {
+	    goto L999;
+	}
+	*ier = 0;
+	akdef[1] = sqrt(edef[1] / *f);
+    }
+/* ----------------------------------------------------------------------- */
+/*       CALCULATE MONOCHROMATOR AND ANALYSER ANGLES */
+
+    if (lmoan[0]) {
+	dei = edef[*ifx - 1];
+	daki = akdef[*ifx - 1];
+	ex_case__(&ddm, ism, &daki, &a1, &a2, &rm, &alm, ier);
+	if (*ier == 0) {
+	    *aki = daki;
+	    *ei = dei;
+	    t_a__[1] = a1;
+	    t_a__[2] = a2;
+	    *t_rm__ = rm;
+	    *t_alm__ = alm;
+	    ldra[1] = TRUE_;
+	    ldra[2] = TRUE_;
+	    *ldr_rm__ = TRUE_;
+	    *ldr_alm__ = TRUE_;
+	} else {
+	    goto L999;
+	}
+    }
+    if (lmoan[1]) {
+	def = edef[3 - *ifx - 1];
+	dakf = akdef[3 - *ifx - 1];
+	ex_case__(&dda, isa, &dakf, &a5, &a6, &ra, &ala, ier);
+	if (*ier == 0) {
+	    *akf = dakf;
+	    *ef = def;
+	    t_a__[5] = a5;
+	    t_a__[6] = a6;
+	    ldra[5] = TRUE_;
+	    ldra[6] = TRUE_;
+	} else {
+	    goto L999;
+	}
+    }
+/* ----------------------------------------------------------------------- */
+/*       USE (QH,QK,QL) TO CALCULATE A3 AND A4 */
+/*       CALCULATE Q1 AND Q2 IN SCATTERING PLANE */
+
+    imod = 2;
+    if (lqhkle) {
+	for (id = 1; id <= 3; ++id) {
+	    dqhkl[id - 1] = qhkl[id];
+	}
+	rl2spv_(dqhkl, dqt, &dqm, &dqs, ier);
+	if (*ier != 0) {
+	    goto L999;
+	}
+	sam_case__(dqt, &dqm, &dqs, &daki, &dakf, &a3, &a4, iss, ier);
+	if (*ier == 0) {
+	    t_a__[3] = a3;
+	    t_a__[4] = a4;
+	    ldra[3] = TRUE_;
+	    ldra[4] = TRUE_;
+	    *qm = dqm;
+	} else {
+	    goto L999;
+	}
+    }
+/* ----------------------------------------------------------------------- */
+/*        DEAL WITH FLIPPERS AND HELMOTZ COILS IF LPA */
+
+    if (*lpa && (lmoan[0] || lmoan[1])) {
+	if (*ldf) {
+	    flip_case__(if1, if2, &p_ih__[1], f1v, f1h, f2v, f2h, aki, akf, 
+		    ier);
+	}
+	if (*ldh) {
+	    helm_case__(hx, hy, hz, &p_ih__[1], &c_ih__[1], aki, akf, &a4, qm,
+		     helm, ier);
+	}
+    }
+/* ----------------------------------------------------------------------- */
+L999:
+    if (*ier != 0) {
+	erreso_(&imod, ier);
+    }
+    return 0;
+} /* t_conv__ */
+
+/* Subroutine */ int ex_case__(doublereal *dx, integer *isx, doublereal *akx, 
+	doublereal *ax1, doublereal *ax2, doublereal *rx, doublereal *alx, 
+	integer *ier)
+{
+    /* System generated locals */
+    doublereal d__1, d__2;
+
+    /* Builtin functions */
+    double asin(doublereal), sin(doublereal), cos(doublereal), sqrt(
+	    doublereal);
+
+    /* Local variables */
+    static doublereal dcl1r, dc1rx, dc2rx, drmin, drmax, arg;
+
+/* ----------------------------------------------------------------------- */
+/*        CALCULATE  ANGLES ON MONO/ANALYSER */
+/*       CALCULATE AX1  AX2 */
+/*       CALCULATE RX LX MONO CURVATURE AND LM FOR IN8 */
+
+/*       INPUT */
+/*       DX      D-SPACINGS */
+/*       ISX     SENS OF SCATTERING ON CRYSTAL */
+/*       AKX     TARGET OF MOMENTUM */
+/*       OUTPUT */
+/*       AX1 AX2  THETA 2*THETA ANGLES */
+/*       RX      MONO OR ANALYSER CURVATURE */
+/*       ALX     SPECIAL TRANSLATION FOR IN8 */
+/*       IER */
+/*        1       ' KI OR KF CANNOT BE OBTAINED CHECK D-SPACINGS', */
+/*        2       ' KI OR KF TOO SMALL', */
+/*        3       ' KI OR KF TOO BIG', */
+
+/* ----------------------------------------------------------------------- */
+/* 	Values of parameters */
+
+/* 	INX=1 IN8 , INX=0 others instruments */
+/* 	C1RX C2RX constants values to calculate RM on all instruments */
+/* 	RMIN, RMAX min max on RNM */
+/* 	CL1R constant value to calculate LM for IN8 */
+
+/* ----------------------------------------------------------------------- */
+/* ----------------------------------------------------------------------- */
+/*       PASSED PARAMETERS */
+/* ----------------------------------------------------------------------- */
+/*       LOCAL VAR */
+/* ----------------------------------------------------------------------- */
+/*       INIT AND TEST */
+
+    *ier = 0;
+    dc1rx = curve_1.c1rx;
+    dc2rx = curve_1.c2rx;
+    drmin = curve_1.rmin;
+    drmax = curve_1.rmax;
+    dcl1r = curve_1.cl1r;
+    if (*dx < .1f) {
+	*ier = 1;
+    }
+    if (*akx < .1f) {
+	*ier = 2;
+    }
+    arg = 3.1415926535897932384626433832795f / (*dx * *akx);
+    if (abs(arg) > 1.f) {
+	*ier = 3;
+    }
+    if (*ier != 0) {
+	goto L999;
+    }
+/* ----------------------------------------------------------------------- */
+/*       CALCULATION OF THE TWO ANGLES */
+
+    *ax1 = asin(arg) * *isx * 57.29577951308232087679815481410517f;
+    *ax2 = *ax1 * 2.;
+/* ----------------------------------------------------------------------- */
+/*        CALCULATION OF MONO CURVATURE RM OR ANALYSER CURVATURE RA */
+/*       STANDARD LAW IS  C1RX+C2RX/SIN(A1/RD) */
+/*       C1RX AND C2RX ARE CONSTANTS DEPENDING ON MONO AND MACHINES */
+
+/*        C1RX=.47 */
+/*        C2RX=.244 */
+/*        RMIN=0. */
+/*       RMAX=20. */
+/* 	IN1/IN3/IN12/IN14/IN20 CASE */
+    if (curve_1.inx == 0) {
+/* Computing MIN */
+/* Computing MAX */
+	d__2 = dc1rx + dc2rx / sin(abs(*ax1) / 
+		57.29577951308232087679815481410517f);
+	d__1 = max(d__2,drmin);
+	*rx = min(d__1,drmax);
+    } else {
+/* 	IN8 CASE */
+	*alx = dcl1r / sin(*ax2 / 57.29577951308232087679815481410517f) * cos(
+		*ax2 / 57.29577951308232087679815481410517f);
+	*rx = dc2rx * sqrt(sin(*ax2 / 57.29577951308232087679815481410517f)) 
+		- dc1rx;
+    }
+/* ----------------------------------------------------------------------- */
+L999:
+    return 0;
+} /* ex_case__ */
+
+/* ========================================================================= */
+/* Subroutine */ int sam_case__(doublereal *qt, doublereal *qm, doublereal *
+	qs, doublereal *aki, doublereal *akf, doublereal *ax3, doublereal *
+	ax4, integer *iss, integer *ier)
+{
+    /* System generated locals */
+    doublereal d__1, d__2;
+
+    /* Builtin functions */
+    double acos(doublereal), atan2(doublereal, doublereal), d_sign(doublereal 
+	    *, doublereal *), d_mod(doublereal *, doublereal *);
+
+    /* Local variables */
+    static doublereal arg, sax3;
+
+/* ----------------------------------------------------------------------- */
+/*               DEAL WITH SAMPLE ANGLES CALCULATION FROM Q VERTOR IN C-N PLANE */
+/*       CALCULATE A3 AND A4 */
+/*       INPUT */
+/*       QT      Q-VECTOR IN SCATTERING PLANE */
+/*       QM,QS   Q MODULUS AND QMODULUS SQUARED */
+/*       AKI,AKF MOMEMTA ON MONO AND ANYLSER */
+/*       ISS             SENS OF SCATTERING ON SAMPLE */
+
+/*       OUTPUT */
+/*       AX3 AX4         ANGLES ON SAMPLES */
+/*       IER SAME ERROR AS RL2SPV */
+/*       IER */
+/*        1       ' MATRIX S NOT OK', */
+/*        2       ' Q NOT IN SCATTERING PLANE', */
+/*        3       ' Q MODULUS TOO SMALL', */
+/*        4       ' Q MODULUS TOO BIG', */
+/* ----------------------------------------------------------------------- */
+/* ----------------------------------------------------------------------- */
+/*       PASSED PARAMETERS */
+/* ----------------------------------------------------------------------- */
+/*       INIT AND TEST */
+
+    /* Parameter adjustments */
+    --qt;
+
+    /* Function Body */
+    *ier = 0;
+    if (abs(*qs) < 1e-6 || abs(*qm) < .001) {
+	*ier = 3;
+	goto L999;
+    }
+/* ----------------------------------------------------------------------- */
+/*       CALCULATE A3 AND MOVE IT INTHE -180 ,+180 INTERVAL */
+
+/* Computing 2nd power */
+    d__1 = *aki;
+/* Computing 2nd power */
+    d__2 = *akf;
+    arg = (d__1 * d__1 + d__2 * d__2 - *qs) / (*aki * 2. * *akf);
+    if (abs(arg) > 1.) {
+	*ier = 4;
+	goto L999;
+    } else {
+	*ax4 = acos(arg) * *iss * 57.29577951308232087679815481410517;
+    }
+/* Computing 2nd power */
+    d__1 = *akf;
+/* Computing 2nd power */
+    d__2 = *aki;
+    *ax3 = (-atan2(qt[2], qt[1]) - acos((d__1 * d__1 - *qs - d__2 * d__2) / (*
+	    qm * -2. * *aki)) * d_sign(&c_b7, ax4)) * 
+	    57.29577951308232087679815481410517;
+    sax3 = d_sign(&c_b7, ax3);
+    d__1 = *ax3 + sax3 * 180.;
+    *ax3 = d_mod(&d__1, &c_b9) - sax3 * 180.;
+
+/*       IF(LPLATE) AX3=-ATAN(SIN(AX4/RD)/(LSA*TAN(AX5/RD)/(ALMS*C */
+/*       1       TAN(AX1/RD))*(AKI/KF)**2-COS(AX4/RD)))*RD       !PLATE FOCALIZATION OPTION */
+/*       IF(AXX3.GT.180.D0) AX3=AX3-360.D0 */
+/*       IF( A3.LT.-180.D0) AX3=AX3+360.D0 */
+/*       IF(LPLATE.AND.A3.GT.0.0) AX3=AX3-180 */
+/* C----------------------------------------------------------------------- */
+L999:
+    return 0;
+} /* sam_case__ */
+
+/* ============================================================================ */
+/* Subroutine */ int helm_case__(real *hx, real *hy, real *hz, real *t_ih__, 
+	real *c_ih__, real *aki, real *akf, doublereal *a4, real *qm, real *
+	helm, integer *ier)
+{
+    /* System generated locals */
+    real r__1, r__2;
+
+    /* Builtin functions */
+    double cos(doublereal), sin(doublereal), atan2(doublereal, doublereal), 
+	    sqrt(doublereal);
+
+    /* Local variables */
+    static real hrad, hdir, qpar, hdir2, qperp;
+    static integer ic;
+    static real phi;
+
+/* ----------------------------------------------------------------------- */
+/*               DEAL WITH HELMOTZ COIL FIELD CALCULATIONS */
+/*       CALCULATE HX HY HZ */
+/* ----------------------------------------------------------------------- */
+/* ----------------------------------------------------------------------- */
+/*       PASSED PARAMETERS */
+/* ----------------------------------------------------------------------- */
+/*       INIT AND TEST */
+
+    /* Parameter adjustments */
+    --c_ih__;
+    --t_ih__;
+
+    /* Function Body */
+    *ier = 1;
+    if (dabs(*qm) < 1e-4f) {
+	goto L999;
+    }
+    *ier = 0;
+    for (ic = 1; ic <= 4; ++ic) {
+	if (c_ih__[ic] < 1e-4f) {
+	    *ier = 2;
+	}
+    }
+    if (*ier != 0) {
+	goto L999;
+    }
+/* ----------------------------------------------------------------------- */
+/*       CALCULATE MODULE AND ANGLES OF IN PLANE FIELD H */
+/*       PHI                     !ANGLE BETWEEN Q AND KI */
+/*       HRAD            !RADIAL COMP. OF H */
+/*       HDIR            !DIRECTION OF H (IN RADIANS) */
+/*       HDIR2           !ANGLE BETWEEN FIELD AND AXE OF COIL 1 */
+
+    qpar = *aki - *akf * cos(*a4 / 57.29577951308232087679815481410517f);
+    qperp = *akf * sin(*a4 / 57.29577951308232087679815481410517f);
+    phi = atan2(qpar, qperp);
+/* Computing 2nd power */
+    r__1 = *hx;
+/* Computing 2nd power */
+    r__2 = *hy;
+    hrad = sqrt(r__1 * r__1 + r__2 * r__2);
+    if (hrad > 1e-4f) {
+	hdir = atan2(*hy, *hx);
+    }
+    hdir2 = phi + hdir + *helm / 57.29577951308232087679815481410517f + 
+	    1.5707963267948966f;
+/* ----------------------------------------------------------------------- */
+/*               !CALC CURRENTS */
+/*               !POSITION OF PSP FOR COIL I */
+
+    for (ic = 1; ic <= 3; ++ic) {
+	t_ih__[ic + 4] = cos(hdir2 + (ic - 1) * 2.f * 
+		3.1415926535897932384626433832795f / 3.f) * hrad / c_ih__[ic] 
+		/ 1.5f;
+    }
+    t_ih__[8] = *hz / c_ih__[4];
+/* ----------------------------------------------------------------------- */
+L999:
+    return 0;
+} /* helm_case__ */
+
+/* Subroutine */ int flip_case__(integer *if1, integer *if2, real *t_ih__, 
+	real *f1v, real *f1h, real *f2v, real *f2h, real *aki, real *akf, 
+	integer *ier)
+{
+/* ----------------------------------------------------------------------- */
+/*               DEAL WITH FLIPPER COIL  CALCULATIONS */
+/*       CALCULATE P_IF CURRENTS FOR THE TWO FLIPPERS */
+/* ----------------------------------------------------------------------- */
+/*       PASSED PARAMETERS */
+/* ----------------------------------------------------------------------- */
+/*       INIT AND TEST */
+
+    /* Parameter adjustments */
+    --t_ih__;
+
+    /* Function Body */
+    *ier = 0;
+/* ----------------------------------------------------------------------- */
+
+    if (*if1 == 1) {
+	t_ih__[1] = *f1v;
+	t_ih__[2] = *aki * *f1h;
+    } else {
+	t_ih__[1] = 0.f;
+	t_ih__[2] = 0.f;
+    }
+    if (*if2 == 1) {
+	t_ih__[3] = *f2v;
+	t_ih__[4] = *akf * *f2h;
+    } else {
+	t_ih__[3] = 0.f;
+	t_ih__[4] = 0.f;
+    }
+/* ----------------------------------------------------------------------- */
+/* L999: */
+    return 0;
+} /* flip_case__ */
+