void get_wsparameters2() {
getstrnwarn("wss",wss);
gcrushws = getvalnwarn("gcrushws");
tcrushws = getvalnwarn("tcrushws");
ws_delay = getvalnwarn("ws_delay");
wsflipf = getvalnwarn("wsflipf");
wsflipf_last = getval("wsflipf_last");
getstrnwarn("wsrf", wsrf);
restol = getvalnwarn("restol");
}
void get_ovsparameters2() {
getstrnwarn("ovs",ovs);
ovsthk = getvalnwarn("ovsthk");
ovsgap = getvalnwarn("ovsgap"); /* convert from mm to cm */
csd_ppm = getvalnwarn("csd_ppm");
ovsflipf = getvalnwarn("ovsflipf");
tpwrdx = getval("tpwrdx");
tpwrdy = getval("tpwrdy");
tpwrdz = getval("tpwrdz");
}
void calc_grad_duty(double time)
{
double gradenergy[3],gradduty[3];
double mult=1.0;
double currentlimit,RMScurrentlimit;
double sglduty,dutylimit;
int checksilent,r,nrcvrs,arraydim,error=0;
char rcvrs[MAXSTR];
currentlimit = getval("currentlimit");
RMScurrentlimit = getval("RMScurrentlimit");
getRealSetDefault(GLOBAL, "sglduty", &sglduty,0.0);
dutylimit = RMScurrentlimit/currentlimit;
checksilent = option_check("checksilent");
/* Adjust array dimenstion for multiple receivers */
nrcvrs = 0;
getstr("rcvrs",rcvrs);
arraydim = getvalnwarn("arraydim");
for (r = 0; r < strlen(rcvrs); r++) {
if (rcvrs[r] == 'y') nrcvrs++;
}
arraydim /= nrcvrs;
if (seqcon[2] == 'c')
mult *= nv;
if (seqcon[3] == 'c')
mult *= nv2;
if (!checkflag)
mult *= arraydim;
getgradpowerintegral(gradenergy);
gradduty[0] = sqrt(gradenergy[0]/(mult*time));
gradduty[1] = sqrt(gradenergy[1]/(mult*time));
gradduty[2] = sqrt(gradenergy[2]/(mult*time));
if (sglduty && ((checkflag && !checksilent) || (!checksilent && ix == arraydim))) {
text_message("Grad energy X: %.3g Grad energy Y: %.3g Grad energy Z: %.3g",gradenergy[0],gradenergy[1],gradenergy[2]);
text_message("Grad duty X: %.3g%% Grad duty Y: %.3g%% Grad duty Z: %.3g%%",100*gradduty[0],100*gradduty[1],100*gradduty[2]);
}
if ((gradduty[0] > dutylimit) && ((checkflag && !checksilent) || (!checksilent && ix == arraydim))) {
text_message("%s: X gradient duty cycle %5.1f%% exceeds allowed limit of %5.1f%%",seqfil,100*gradduty[0],100*dutylimit);
error = 1;
}
if ((gradduty[1] > dutylimit) && ((checkflag && !checksilent) || (!checksilent && ix == arraydim))) {
text_message("%s: Y gradient duty cycle %5.1f%% exceeds allowed limit of %5.1f%%",seqfil,100*gradduty[1],100*dutylimit);
error = 1;
}
if ((gradduty[2] > dutylimit) && ((checkflag && !checksilent) || (!checksilent && ix == arraydim))) {
text_message("%s: Z gradient duty cycle %5.1f%% exceeds allowed limit of %5.1f%%",seqfil,100*gradduty[2],100*dutylimit);
error = 1;
}
if (error) {
if (sglduty)
warn_message("%s: Duty cycle exceeds allowed limit",seqfil);
else
abort_message("%s: Duty cycle exceeds allowed limit",seqfil);
}
}
/********************************************************************
* Function Name: set_pe_order
* Example: table = set_pe_order();
* Purpose: define the phase encode order based on a VnmrJ parameter petype.
* petype is evaluated, and an appropriate phase encoding table i
* written to tablib as required. The VnmrJ parameter, petable, is
* set according to the name of the phase encoding table
* that was generated.
*
* defined values of petype:
* 0 - linear phase encoding - no table generated
* 1 - user defined pe - users set petable explicitly
* 2 - center to max phase encoding
* 3 - max to center phase encoding
* other values undefined
* Input
* Formal: none
* Private: none
* Public: none
* Output
* Return: 1 if a table was generated, 0 otherwise
* Formal: none
* Private: none
* Public: none
* Notes: none
*********************************************************************/
int set_pe_order()
{
/* short routine to set the phase encoding order
petype = 0 is standard linear
petype = 1 is user defined. This means that the user
defines their own pe table from a macro
and set "petable" to be the tabfile name
petype = 2 is center-out - generated from nv
other petype to be defined as required for types > 2
*/
int pe_type;
int *pe_order;
int i;
int inv;
int table = 0;
int numPESteps;
pe_type = getvalnwarn("petype");
switch( pe_type )
{
case 1:
/* Check for external PE table ***************************/
if (strcmp(petable,"n") && strcmp(petable,"N") && strcmp(petable,"")) {
loadtable(petable);
table = 1;
}
break;
case 2:
/*center to max phase encoding */
/* sets t1 to the phase encoding order */
numPESteps = nv;
if(( pe_order = (int *)malloc(numPESteps*sizeof(int)))==NULL)
{
abort_message("set_pe_order: Memory allocation problem!");
}
inv = 1;
pe_order[0] = 0;
for(i=1;i<numPESteps;i++)
{
inv = -inv;
pe_order[i] = pe_order[i-1] + inv*i;
}
strcpy(petable,"centertomax");
write_tab_file(petable,1,1,numPESteps,pe_order);
settable(t1,numPESteps,pe_order);
putstring("petable",petable);
table=1;
break;
case 3:
/* max to center phase encoding*/
numPESteps = nv;
if(( pe_order = (int *)malloc(numPESteps*sizeof(int)))==NULL)
{
abort_message("set_pe_order: Memory allocation problem!");
}
inv = 1;
pe_order[numPESteps-1] = 0;
for(i=1;i<numPESteps;i++)
{
inv = -inv;
pe_order[numPESteps-i-1] = pe_order[numPESteps-i] + inv*i;
}
strcpy(petable,"maxtocenter");
write_tab_file(petable,1,1,numPESteps,pe_order);
settable(t1,numPESteps,pe_order);
putstring("petable",petable);
table=1;
break;
default:
/* this the default of center-out so make sure that petable is an empty string */
putstring("petable","");
table = 0;
break;
}
return table;
}
pulsesequence()
{
double d3 = getval("d3"),
vtcomplvl = getval("vtcomplvl"),
gzlvl = getval("gzlvl"),
shapedpw90 = getvalnwarn("shapedpw90"),
shapedpw180 = getvalnwarn("shapedpw180"),
shapedpwr90 = getvalnwarn("shapedpwr90"),
shapedpwr180 = getvalnwarn("shapedpwr180"),
gt,gts,lvlf;
int hs_gradtype;
char shaped[MAXSTR], shapename90[MAXSTR], shapename180[MAXSTR];
getstrnwarn("shaped", shaped);
getstrnwarn("shapename90", shapename90);
getstrnwarn("shapename180", shapename180);
settmpgradtype("tmpgradtype");
hs_gradtype = ((specialGradtype == 'h') || (specialGradtype == 'a'));
if ((p1==0.0) && ((vtcomplvl>0.5) || (hs_gradtype)))
{
p1 = 2.0*pw;
}
if ((vtcomplvl==2) && ((hs_gradtype) || (spin>0)))
{
vtcomplvl = 1;
if (ix==1)
{
text_message("gmapz: vtcomplvl set to 1\n");
putCmd("setvalue('vtcomplvl',%.0f)\n",vtcomplvl);
putCmd("setvalue('vtcomplvl',%.0f,'processed')\n",vtcomplvl);
}
}
/* lvlf, gt, gts only used for convection compensation */
if (gradtype[2]=='l')
lvlf=2.5;
else
lvlf=3.0;
if ((hs_gradtype) || (spin>0))
lvlf=1.0;
gt = (0.5*at + d2)/lvlf;
gts=0.18*at/lvlf;
gts = 0.2*at/lvlf;
if (vtcomplvl==2)
gt += gts;
gt *= 2.0;
settable(t1,16,ph1);
settable(t2,2,ph2);
settable(t3,8,ph3);
settable(t4,16,ph4);
sub(ct,ssctr,v12);
getelem(t1,v12,v1);
getelem(t2,v12,v2);
getelem(t3,v12,v3);
getelem(t4,v12,oph);
if (vtcomplvl < 0.5)
{
getelem(t4,v12,v1);
getelem(t1,v12,v2);
}
/* --- equilibration period --- */
status(A);
delay(d1);
/* --- initial pulse --- */
status(B);
if (shaped[A] == 'y') {
obspower(shapedpwr90);
shaped_pulse(shapename90,shapedpw90,v1,rof1,rof2);
obspower(tpwr);
}
else
pulse(pw,v1);
/* instead of hard pulse, could use shapedpulse("gauss",pw,oph,rof1,rof2);
or "bir4_90_512" or other shape for selective excitation.
selective inversion pulses may or may not work as well. */
/* --- shim phase encode, not during PFG recovery --- */
delay(2e-5+d3);
/* First case: No convection compensation, traditional sequence */
if (vtcomplvl < 0.5)
{
if (p1 > 0)
{
zgradpulse(gzlvl,at/2+d2);
delay(d2);
if (shaped[A] == 'y') {
obspower(shapedpwr180);
shaped_pulse(shapename180,shapedpw180,v2,rof1,rof2);
obspower(tpwr);
}
else
pulse(p1,v2);
delay(d2);
}
else
{
zgradpulse(-gzlvl,at/2+d2);
delay(d2*2);
}
}
else /* (vtcomplvl > 0.5) */
{
/* Second case: convection compensation */
zgradpulse(gzlvl,at/2+d2);
delay(d2);
if (vtcomplvl==2)
{
zgradpulse(lvlf*gzlvl,gts);
delay(d2);
}
if (shaped[A] == 'y') {
obspower(shapedpwr180);
shaped_pulse(shapename180,shapedpw180,v2,rof1,rof2);
}
else
pulse(p1,v2);
delay(d2);
zgradpulse(lvlf*gzlvl,gt);
delay(d2);
if (shaped[A] == 'y') {
shaped_pulse(shapename180,shapedpw180,v3,rof1,rof2);
obspower(tpwr);
}
else
pulse(p1,v3);
delay(d2);
if (vtcomplvl==2)
{
zgradpulse(lvlf*gzlvl,gts);
delay(d2);
}
}
/* --- acq. of echo during gradient --- */
rgradient('z',gzlvl);
delay(d2);
/* gradient switches off at end of acq. */
}
pulsesequence()
{
/* declaration of SGL kernel structures */
SGL_KERNEL_INFO_T read, phase, slice, ss_pre, ss_post;
/* declaration of internal variables */
double freqlist[MAXNSLICE];
double pe_steps;
int shapelist1, table;
double xtime, grad_duration, ror_pad,rod_pad;
double temp_tr;
double readAmp, phaseAmp, sliceAmp;
double tepad, tepad2, temin2, htrmin, delayToRF, delayRFToAcq, delayAcqToRF;
double rof_pad, delRof;
double sliceRephTrim, sliceDephTrim;
double readRephTrim, readDephTrim;
int rfPhase[2] = {0,2};
/* declaration of realtime variables */
int vpe_steps = v1;
int vpe_ctr = v2;
int vms_slices = v3;
int vms_ctr = v4;
int vpe_offset = v5;
int vpe_index = v6;
int vss = v7;
int vssc = v8;
int vacquire = v9;
int vphase = v10;
settable(t2,2,rfPhase);
/* setup phase encoding order */
table = set_pe_order();
init_mri();
if( (sliceRephTrim = getvalnwarn("sliceRephTrim")) == 0.0 ) {
sliceRephTrim = 1.0;
}
if( (sliceDephTrim = getvalnwarn("sliceDephTrim")) == 0.0 ) {
sliceDephTrim = 1.0;
}
if( (readRephTrim = getvalnwarn("readRephTrim")) == 0.0 ) {
readRephTrim = 1.0;
}
if( (readDephTrim = getvalnwarn("readDephTrim")) == 0.0 ) {
readDephTrim = 1.0;
}
shape_rf( &p1_rf, "p1", p1pat, p1, flip1, rof1, rof2 ); // excitation pulse
init_slice( &ss_grad, "ss", thk ); // slice gradient
init_slice_refocus( &ssr_grad, "ssr" ); // slice refocus
init_slice_refocus( &ssd_grad, "ssd" ); // slice refocus
init_readout( &ro_grad, "ro", lro, np, sw ); // read gradient
init_readout_refocus( &ror_grad, "ror" ); // read dephase
init_readout_refocus( &rod_grad, "ror" ); // read dephase
init_phase( &pe_grad, "pe", lpe, nv ); // phase gradient
ss_grad.maxGrad = gmax * 0.57;
ssr_grad.maxGrad = gmax * 0.57;
ssd_grad.maxGrad = gmax * 0.57;
ro_grad.maxGrad = gmax * 0.57;
ror_grad.maxGrad = gmax * 0.57;
rod_grad.maxGrad = gmax * 0.57;
pe_grad.maxGrad = glimpe < 0.57? gmax*glimpe : gmax * 0.57;
/* calculate the RF pulses, gradient pulses and their interdependencies */
calc_rf( &p1_rf, "tpwr1", "tpwr1f" );
calc_slice( &ss_grad, &p1_rf, NOWRITE, "gss" );
ssr_grad.amp = ss_grad.amp;
ssr_grad.gmult = sliceRephTrim;
ssr_grad.calcFlag = DURATION_FROM_MOMENT_AMPLITUDE;
calc_slice_refocus( &ssr_grad, &ss_grad, NOWRITE, "gssr" );
ssd_grad.amp = ss_grad.amp;
ssd_grad.gmult = sliceDephTrim;
ssd_grad.calcFlag = DURATION_FROM_MOMENT_AMPLITUDE;
calc_slice_dephase( &ssd_grad, &ss_grad, NOWRITE, "gssd" );
calc_readout( &ro_grad, NOWRITE, "gro", "sw", "at" );
ror_grad.amp = ro_grad.amp;
ror_grad.calcFlag = DURATION_FROM_MOMENT_AMPLITUDE;
rod_grad.amp = ro_grad.amp;
rod_grad.calcFlag = DURATION_FROM_MOMENT_AMPLITUDE;
ror_grad.gmult = readRephTrim;
calc_readout_refocus( &ror_grad, &ro_grad, NOWRITE, "gror" );
rod_grad.gmult = readDephTrim;
calc_readout_rephase( &rod_grad, &ro_grad, NOWRITE, "grod" );
calc_phase( &pe_grad, NOWRITE, "gpe", "tpe" );
/* work out the position of the markers */
/* markerA */
/* ss_grad.rfDelayFront indicates the starting point of the
RF pulse measured from the start of the slice gradient
( rof1:pulse length:rof2 ) */
double granulatedRFDelayFront = granularity( ss_grad.rfDelayFront, GRADIENT_RES );
if( granulatedRFDelayFront > ss_grad.rfDelayFront ) {
granulatedRFDelayFront -= GRADIENT_RES;
}
/* ss_grad.rfDelayBack indicates the end point of the
RF pulse measured to the end of the slice gradient
( rof1:pulse length:rof2 ) */
double granulatedRFDelayBack = granularity( ss_grad.rfDelayBack, GRADIENT_RES );
if( granulatedRFDelayBack > ss_grad.rfDelayBack ) {
granulatedRFDelayBack -= GRADIENT_RES;
}
double granulatedRFDelay = granulatedRFDelayFront < granulatedRFDelayBack ? granulatedRFDelayFront : granulatedRFDelayBack;
double markerADelay = granulatedRFDelay;
/* read and phase gradients can overlap the start or end of the slice gradient by max of granulatedRFDElay */
double granulatedATDelayFront = granularity(ro_grad.atDelayFront, GRADIENT_RES);
if( granulatedATDelayFront > ro_grad.atDelayFront ) {
granulatedATDelayFront -= GRADIENT_RES;
}
double granulatedATDelayBack = granularity(ro_grad.atDelayBack, GRADIENT_RES);
if( granulatedATDelayBack > ro_grad.atDelayBack ) {
granulatedATDelayBack -= GRADIENT_RES;
}
double granulatedATDelay = granulatedATDelayFront < granulatedATDelayBack ? granulatedATDelayFront : granulatedATDelayBack;
/* longest gradient between RF pulse and acquire dominates */
xtime = ssr_grad.duration + granulatedRFDelay;
xtime = xtime > ssd_grad.duration + granulatedRFDelay ? xtime : ssd_grad.duration + granulatedRFDelay;
xtime = xtime > ror_grad.duration + granulatedATDelay ? xtime : ror_grad.duration + granulatedATDelay;
xtime = xtime > rod_grad.duration + granulatedATDelay ? xtime : rod_grad.duration + granulatedATDelay;
xtime = xtime > pe_grad.duration ? xtime : pe_grad.duration;
ror_pad = xtime - ror_grad.duration - granulatedATDelay;
rod_pad = xtime - rod_grad.duration - granulatedATDelay;
/* make a gradient list */
start_kernel( &sk );
add_gradient( (void*)&ss_grad, "slice", SLICE, START_TIME, "", 0.0, PRESERVE );
add_gradient( (void*)&ssr_grad, "sliceReph", SLICE, BEHIND, "slice", 0.0, INVERT );
add_gradient( (void*)&ror_grad, "readDeph", READ, BEHIND, "slice", -granulatedRFDelay + ror_pad, INVERT );
add_gradient( (void*)&ro_grad, "read", READ, BEHIND, "readDeph", 0.0, PRESERVE );
add_gradient( (void*)&pe_grad, "phase", PHASE, SAME_START, "readDeph", 0.0, PRESERVE );
add_gradient( (void*)&rod_grad, "readReph", READ, BEHIND, "read", 0.0, INVERT );
add_gradient( (void*)&pe_grad, "rewind", PHASE, SAME_END, "readReph", 0.0, INVERT );
add_gradient( (void*)&ss_grad, "nextSlice", SLICE, BEHIND, "readReph", rod_pad - granulatedRFDelay, PRESERVE );
add_gradient( (void*)&ssd_grad, "sliceDeph", SLICE, BEFORE, "nextSlice", 0, INVERT );
add_marker( "markerA", SAME_START, "slice", granulatedRFDelay );
add_marker( "markerB", SAME_START, "nextSlice", granulatedRFDelay );
/* get the minimum echo time */
temin = get_timing( FROM_RF_CENTER_OF, "slice", TO_ECHO_OF, "read" );
temin2 = get_timing( FROM_ECHO_OF, "read", TO_RF_CENTER_OF, "nextSlice" );
htrmin = MAX( temin, temin2 );
if( minte[0] == 'y' ){
te = htrmin;
}
tepad = granularity( te - temin, GRADIENT_RES );
tepad2 = granularity( te - temin2, GRADIENT_RES );
te = temin + tepad;
putCmd("setvalue('te', %f, 'current')\n", te );
if( tepad>0.0 ) change_timing( "readDeph", tepad );
if( tepad2>0.0 ) change_timing( "nextSlice", tepad2 );
tr = get_timing( FROM_START_OF, "slice", TO_START_OF, "nextSlice" );
putvalue("tr", tr );
delayRFToAcq = get_timing( FROM_RF_PULSE_OF, "slice", TO_ACQ_OF, "read" );
delayAcqToRF = get_timing( FROM_ACQ_OF, "read", TO_RF_PULSE_OF, "nextSlice" );
set_comp_info( &ss_pre, "ss_pre" );
write_comp_grads_snippet( NULL, NULL, &ss_pre, "START_OF_KERNEL", "markerA" );
set_comp_info( &read, "ro" );
set_comp_info( &phase, "pe" );
set_comp_info( &slice, "ss" );
write_comp_grads_snippet( &read, &phase, &slice, "markerA", "markerB" );
set_comp_info( &ss_post, "ss_post" );
write_comp_grads_snippet( NULL, NULL, &ss_post, "markerB", "END_OF_KERNEL" );
/* Set up frequency offset pulse shape list ********/
offsetlist(pss,ss_grad.ssamp,0,freqlist,ns,seqcon[1]);
shapelist1 = shapelist(p1_rf.pulseName,ss_grad.rfDuration,freqlist,ns,ss_grad.rfFraction, seqcon[1]);
/* Set pe_steps for profile or full image **********/
pe_steps = prep_profile(profile[0],nv,&pe_grad,&pe_grad);/* profile[0] is n y or r */
F_initval(pe_steps/2.0,vpe_offset);
g_setExpTime(trmean*(ntmean*pe_steps*arraydim + (1+fabs(ssc))*arraydim));
/* Shift DDR for pro *******************************/
roff = -poffset(pro,ro_grad.roamp);
/* PULSE SEQUENCE */
status( A );
rotate();
triggerSelect(trigger);
obsoffset( resto );
delay( GRADIENT_RES );
initval( 1+fabs( ssc ), vss );
obspower( p1_rf.powerCoarse );
obspwrf( p1_rf.powerFine );
delay( GRADIENT_RES );
assign(one,vacquire); // real-time acquire flag
setacqvar(vacquire); // Turn on acquire when vacquire is zero
obl_shapedgradient(ss_pre.name,ss_pre.dur,0,0,ss_pre.amp,NOWAIT);
sp1on();
delay(GRADIENT_RES);
sp1off();
delay(ss_pre.dur-GRADIENT_RES );
msloop( seqcon[1], ns, vms_slices, vms_ctr );
assign(vss,vssc);
peloop( seqcon[2], pe_steps, vpe_steps, vpe_ctr );
sub(vpe_ctr,vssc,vpe_ctr); // vpe_ctr counts up from -ssc
assign(zero,vssc);
if (seqcon[2] == 's')
assign(zero,vacquire); // Always acquire for non-compressed loop
else {
ifzero(vpe_ctr);
assign(zero,vacquire); // Start acquiring when vpe_ctr reaches zero
endif(vpe_ctr);
}
if (table)
getelem(t1,vpe_ctr,vpe_index);
else {
ifzero(vacquire);
sub(vpe_ctr,vpe_offset,vpe_index);
elsenz(vacquire);
sub(zero,vpe_offset,vpe_index);
endif(vacquire);
}
pe_shaped3gradient( read.name, phase.name, slice.name,
read.dur, read.amp, 0, slice.amp,
-pe_grad.increment, vpe_index, NOWAIT );
delay(ss_grad.rfDelayFront - granulatedRFDelay);
shapedpulselist( shapelist1, ss_grad.rfDuration, oph, rof1, rof2, seqcon[1], vms_ctr );
delay( delayRFToAcq - alfa );
startacq(alfa);
acquire( np, 1/ro_grad.bandwidth );
endacq();
delay( delayAcqToRF - ss_grad.rfDelayFront + granulatedRFDelay - GRADIENT_RES );
sp1on();
delay(GRADIENT_RES);
sp1off();
endpeloop( seqcon[2], vpe_ctr );
endmsloop( seqcon[1], vms_ctr );
obl_shapedgradient(ss_post.name,ss_post.dur,0,0,ss_post.amp,WAIT);
}
pulsesequence()
{
/* Internal variable declarations *********************/
double freq90[MAXNSLICE],freq180[MAXNSLICE];
double te_delay1,te_delay2,tr_delay,tau1,tau2,thk2fact,te_delay3=0.0,te_delay4=0.0,navTime=0.0;
double crushm0,pem0,gcrushr,gcrushp,gcrushs,pecrush;
double refsign=1,crushsign=1,navsign=1;
int shape90,shape180,table=0,sepRefocus;
char slprofile[MAXSTR];
/* sequence dependent diffusion variables */
double Gro,Gss; // "gdiff" for readout/readout refocus and slice/slice refocus
double dgro,dgss; // "delta" for readout/readout refocus and slice/slice refocus
double Dgro,Dgss; // "DELTA" for readout/readout refocus and slice/slice refocus
double dcrush,dgss2; // "delta" for crusher and gss2 gradients
double Dcrush,Dgss2; // "DELTA" for crusher and gss2 gradients
int i;
/* Real-time variables used in this sequence **********/
int vpe_steps = v1; // Number of PE steps
int vpe_ctr = v2; // PE loop counter
int vms_slices = v3; // Number of slices
int vms_ctr = v4; // Slice loop counter
int vpe_offset = v5; // PE/2 for non-table offset
int vpe_mult = v6; // PE multiplier, ranges from -PE/2 to PE/2
int vph180 = v7; // Phase of 180 pulse
int vph2 = v8; // alternate phase of 180 on odd transients
int vssc = v9; // Compressed steady-states
int vtrimage = v10; // Counts down from nt, trimage delay when 0
int vacquire = v11; // Argument for setacqvar, to skip steady state acquires
int vtrigblock = v12; // Number of slices per trigger block
/* Initialize paramaters *****************************/
init_mri();
thk2fact=getval("thk2fact");
pecrush=getval("pecrush");
sepRefocus=getvalnwarn("sepRefocus");
getstrnwarn("slprofile",slprofile);
/* Check for external PE table ***********************/
init_tablepar("pelist"); // Initialize pelist parameter
if (strcmp(petable,"n") && strcmp(petable,"N") && strcmp(petable,"")) {
loadtable(petable);
writetabletopar(t1,"pelist"); // Write t1 table to pelist parameter
table = 1;
}
/* RF Power & Bandwidth Calculations ******************/
shape_rf(&p1_rf,"p1",p1pat,p1,flip1,rof1,rof2);
shape_rf(&p2_rf,"p2",p2pat,p2,flip2,rof1,rof2);
calc_rf(&p1_rf,"tpwr1","tpwr1f");
calc_rf(&p2_rf,"tpwr2","tpwr2f");
/* Initialize gradient structures *********************/
init_slice(&ss_grad,"ss",thk);
init_slice(&ss2_grad,"ss2",thk*thk2fact);
init_dephase(&crush_grad,"crush");
init_slice_refocus(&ssr_grad,"ssr");
if (FP_LT(tcrushro,alfa)) tcrushro=alfa;
init_readout_butterfly(&ro_grad,"ro",lro,np,sw,gcrushro,tcrushro);
init_readout_refocus(&ror_grad,"ror");
init_phase(&pe_grad,"pe",lpe,nv);
init_generic(&spoil_grad,"spoil",gspoil,tspoil);
/* Gradient calculations ******************************/
calc_readout(&ro_grad, WRITE,"gro","sw","at");
ro_grad.m0ref *= grof;
calc_readout_refocus(&ror_grad,&ro_grad,NOWRITE,"gror");
calc_phase(&pe_grad,NOWRITE,"gpe","tpe");
calc_slice(&ss_grad,&p1_rf,WRITE,"gss");
calc_slice(&ss2_grad,&p2_rf,WRITE,"gss2");
calc_slice_refocus(&ssr_grad,&ss_grad,WRITE,"gssr");
calc_generic(&spoil_grad,WRITE,"","");
/* Make sure crushing in PE dimension does not refocus signal from 180 */
crushm0=fabs(gcrush*tcrush);
pem0=0.0; gcrushp=0.0;
if (pecrush) pem0=pe_grad.m0;
calc_dephase(&crush_grad,WRITE,crushm0+pem0,"","");
gcrushr = crush_grad.amp*crushm0/crush_grad.m0;
if (pecrush) gcrushp = crush_grad.amp;
gcrushs = crush_grad.amp*crushm0/crush_grad.m0;
/* Allow phase encode and read dephase to be separated from slice refocus */
if (sepRefocus) {
/* Equalize read dephase and PE gradient durations */
calc_sim_gradient(&ror_grad,&pe_grad,&null_grad,0,WRITE);
crushsign=-1;
} else {
if (slprofile[0] == 'y') {
/* Combined slice refocusing and read dephasing,
reverse gradient sign if ror > ssr integral */
refsign = (ss_grad.m0ref > ro_grad.m0ref) ? 1.0 : -1.0;
ss_grad.m0ref -= ro_grad.m0ref;
calc_slice_refocus(&ssr_grad,&ss_grad,NOWRITE,"gssr");
}
/* Equalize both refocus and PE gradient durations */
calc_sim_gradient(&ror_grad,&pe_grad,&ssr_grad,0,WRITE);
}
/* Create optional prepulse events ********************/
if (fsat[0] == 'y') create_fatsat();
if (sat[0] == 'y') create_satbands();
if (mt[0] == 'y') create_mtc();
if (ir[0] == 'y') create_inversion_recovery();
if (diff[0] == 'y') init_diffusion(&diffusion,&diff_grad,"diff",gdiff,tdelta);
sgl_error_check(sglerror);
/* Min TE *********************************************/
te = granularity(te,2*GRADIENT_RES);
/* tau1, tau2 are the sum of events in each half echo period */
/* tau1, tau2 include a GRADIENT_RES as this is minimum delay time */
tau1 = ss_grad.rfCenterBack + ssr_grad.duration + crush_grad.duration + ss2_grad.rfCenterFront + 2*GRADIENT_RES;
tau2 = ss2_grad.rfCenterBack + crush_grad.duration + ro_grad.timeToEcho + GRADIENT_RES;
if (sepRefocus) tau2 += ror_grad.duration;
temin = 2*MAX(tau1,tau2);
/* Diffusion ******************************************/
if (diff[0] == 'y') {
/* granulate tDELTA */
tDELTA = granularity(tDELTA,GRADIENT_RES);
/* taudiff is the duration of events between diffusion gradients */
taudiff = ss2_grad.duration + 2*crush_grad.duration + GRADIENT_RES;
/* set minimum diffusion structure requirements for gradient echo: taudiff, tDELTA, te and minte[0] */
set_diffusion(&diffusion,taudiff,tDELTA,te,minte[0]);
/* set additional diffusion structure requirements for spin echo: tau1 and tau2 */
set_diffusion_se(&diffusion,tau1,tau2);
/* calculate the diffusion structure delays.
address &temin is required in order to update temin accordingly */
calc_diffTime(&diffusion,&temin);
}
/* TE delays ******************************************/
if (minte[0] == 'y') {
te = temin;
putvalue("te",te);
}
if (FP_LT(te,temin)) {
abort_message("TE too short, minimum TE = %.3f ms\n",temin*1000);
}
te_delay1 = te/2 - tau1 + GRADIENT_RES;
te_delay2 = te/2 - tau2 + GRADIENT_RES;
if (navigator[0] == 'y') {
/* tau1, tau2 are the sum of events in each half echo period */
tau1 = ro_grad.timeFromEcho + pe_grad.duration + crush_grad.duration + ss2_grad.rfCenterFront;
tau2 = ss2_grad.rfCenterBack + crush_grad.duration + ro_grad.timeToEcho;
if (FP_GT(tau1,tau2)) {
te_delay3 = GRADIENT_RES;
te_delay4 = tau1-tau2+GRADIENT_RES;
} else {
te_delay3 = tau2-tau1+GRADIENT_RES;
te_delay4 = GRADIENT_RES;
}
navTime = te_delay3 + ss2_grad.duration + 2*crush_grad.duration + ro_grad.duration + te_delay4 + 2*GRADIENT_RES;
}
/* Check nsblock, the number of slices blocked together
(used for triggering and/or inversion recovery) */
check_nsblock();
/* Min TR *********************************************/
trmin = ss_grad.rfCenterFront + te + ro_grad.timeFromEcho + pe_grad.duration + 2*GRADIENT_RES;
/* Increase TR if any options are selected ************/
if (spoilflag[0] == 'y') trmin += spoil_grad.duration;
if (navigator[0] == 'y') trmin += navTime;
if (sat[0] == 'y') trmin += satTime;
if (fsat[0] == 'y') trmin += fsatTime;
if (mt[0] == 'y') trmin += mtTime;
if (ticks > 0) trmin += GRADIENT_RES;
/* Adjust for all slices ******************************/
trmin *= ns;
/* Inversion recovery *********************************/
if (ir[0] == 'y') {
/* tauti is the additional time beyond IR component to be included in ti */
/* satTime, fsatTime and mtTime all included as those modules will be after IR */
tauti = satTime + fsatTime + mtTime + GRADIENT_RES + ss_grad.rfCenterFront;
/* calc_irTime checks ti and returns the time of all IR components */
trmin += calc_irTime(tauti,trmin,mintr[0],tr,&trtype);
}
if (mintr[0] == 'y') {
tr = trmin;
putvalue("tr",tr);
}
if (FP_LT(tr,trmin)) {
abort_message("TR too short, minimum TR = %.3f ms\n",trmin*1000);
}
/* TR delay *******************************************/
tr_delay = granularity((tr-trmin)/ns,GRADIENT_RES);
/* Calculate B values *********************************/
if (ix == 1) {
/* Calculate bvalues according to main diffusion gradients */
calc_bvalues(&diffusion,"dro","dpe","dsl");
/* Add components from additional diffusion encoding imaging gradients peculiar to this sequence */
/* Initialize variables */
dgro = 0.5*(ror_grad.duration+ro_grad.timeToEcho);
Gro = ro_grad.m0ref/dgro; Dgro = dgro;
if (!sepRefocus) Dgro = te-ss_grad.rfCenterBack-ro_grad.timeToEcho;
dgss = 0.5*(ss_grad.rfCenterBack+ssr_grad.duration);
Gss = ss_grad.m0ref/dgss; Dgss = dgss;
dgss2 = ss2_grad.duration/2; Dgss2 = dgss2;
dcrush = crush_grad.duration-crush_grad.tramp; Dcrush = crush_grad.duration+ss2_grad.duration;
for (i = 0; i < diffusion.nbval; i++) {
/* set droval, dpeval and dslval */
set_dvalues(&diffusion,&droval,&dpeval,&dslval,i);
/* Readout */
diffusion.bro[i] += bval(Gro,dgro,Dgro);
diffusion.bro[i] += bval(crushsign*gcrushr,dcrush,Dcrush);
diffusion.bro[i] += bval_nested(gdiff*droval,tdelta,tDELTA,crushsign*gcrushr,dcrush,Dcrush);
if (!sepRefocus) {
diffusion.bro[i] += bval_nested(Gro,dgro,Dgro,gdiff*droval,tdelta,tDELTA);
diffusion.bro[i] += bval_nested(Gro,dgro,Dgro,crushsign*gcrushr,dcrush,Dcrush);
}
/* Phase */
if (pecrush) {
diffusion.bpe[i] += bval(gcrushp,dcrush,Dcrush);
diffusion.bpe[i] += bval_nested(gdiff*dpeval,tdelta,tDELTA,gcrushp,dcrush,Dcrush);
}
/* Slice */
diffusion.bsl[i] += bval(Gss,dgss,Dgss);
diffusion.bsl[i] += bval(gcrushs,dcrush,Dcrush);
diffusion.bsl[i] += bval(ss2_grad.ssamp,dgss2,Dgss2);
diffusion.bsl[i] += bval_nested(gdiff*dslval,tdelta,tDELTA,gcrushs,dcrush,Dcrush);
diffusion.bsl[i] += bval_nested(gdiff*dslval,tdelta,tDELTA,ss2_grad.ssamp,dgss2,Dgss2);
diffusion.bsl[i] += bval_nested(gcrushs,dcrush,Dcrush,ss2_grad.ssamp,dgss2,Dgss2);
/* Readout/Phase Cross-terms */
diffusion.brp[i] += bval_cross(gdiff*dpeval,tdelta,tDELTA,crushsign*gcrushr,dcrush,Dcrush);
diffusion.brp[i] += bval_cross(gdiff*dpeval,tdelta,tDELTA,crushsign*gcrushr,dcrush,Dcrush);
if (pecrush) diffusion.brp[i] += bval_cross(gdiff*droval,tdelta,tDELTA,gcrushp,dcrush,Dcrush);
if (!sepRefocus) {
diffusion.brp[i] += bval_cross(Gro,dgro,Dgro,gdiff*dpeval,tdelta,tDELTA);
if (pecrush) diffusion.brp[i] += bval_cross(Gro,dgro,Dgro,gcrushp,dcrush,Dcrush);
}
/* Readout/Slice Cross-terms */
diffusion.brs[i] += bval2(crushsign*gcrushr,gcrushs,dcrush,Dcrush);
diffusion.brs[i] += bval_cross(gdiff*droval,tdelta,tDELTA,gcrushs,dcrush,Dcrush);
diffusion.brs[i] += bval_cross(gdiff*dslval,tdelta,tDELTA,crushsign*gcrushr,dcrush,Dcrush);
diffusion.brs[i] += bval_cross(gdiff*droval,tdelta,tDELTA,ss2_grad.ssamp,dgss2,Dgss2);
if (!sepRefocus) {
diffusion.brs[i] += bval_cross(Gro,dgro,Dgro,gdiff*dslval,tdelta,tDELTA);
diffusion.brs[i] += bval_cross(Gro,dgro,Dgro,gcrushs,dcrush,Dcrush);
diffusion.brs[i] += bval_cross(Gro,dgro,Dgro,ss2_grad.ssamp,dgss2,Dgss2);
}
/* Slice/Phase Cross-terms */
diffusion.bsp[i] += bval_cross(gdiff*dpeval,tdelta,tDELTA,gcrushs,dcrush,Dcrush);
diffusion.bsp[i] += bval_cross(gdiff*dpeval,tdelta,tDELTA,ss2_grad.ssamp,dgss2,Dgss2);
if (pecrush) {
diffusion.bsp[i] += bval2(gcrushs,gcrushp,dcrush,Dcrush);
diffusion.bsp[i] += bval_cross(gdiff*dslval,tdelta,tDELTA,gcrushp,dcrush,Dcrush);
diffusion.bsp[i] += bval_cross(gcrushp,dcrush,Dcrush,ss2_grad.ssamp,dgss2,Dgss2);
}
} /* End for-all-directions */
/* Write the values */
write_bvalues(&diffusion,"bval","bvalue","max_bval");
}
/* Generate phase-ramped pulses ***********************/
offsetlist(pss,ss_grad.ssamp,0,freq90,ns,seqcon[1]);
offsetlist(pss,ss2_grad.ssamp,0,freq180,ns,seqcon[1]);
shape90 = shapelist(p1_rf.pulseName,ss_grad.rfDuration,freq90,ns,ss_grad.rfFraction,seqcon[1]);
shape180 = shapelist(p2_rf.pulseName,ss2_grad.rfDuration,freq180,ns,ss2_grad.rfFraction,seqcon[1]);
/* Set pe_steps for profile or full image *************/
pe_steps = prep_profile(profile[0],nv,&pe_grad,&null_grad);
F_initval(pe_steps/2.0,vpe_offset);
/* Shift DDR for pro **********************************/
roff = -poffset(pro,ro_grad.roamp);
/* Adjust experiment time for VnmrJ *******************/
if (ssc<0) {
if (seqcon[2] == 'c') g_setExpTime(trmean*(ntmean*pe_steps*arraydim - ssc*arraydim));
else g_setExpTime(trmean*(ntmean*pe_steps*arraydim - ssc*pe_steps*arraydim));
}
else g_setExpTime(trmean*ntmean*pe_steps*arraydim + tr*ssc);
/* Slice profile **************************************/
if (slprofile[0] == 'y' && !sepRefocus) ror_grad.amp = 0;
/* Set phase cycle table ******************************/
if (sepRefocus) settable(t2,1,ph180); // Phase encode is just before readout
else settable(t2,2,ph180);
/* PULSE SEQUENCE *************************************/
status(A); // Set status A
rotate(); // Set gradient rotation according to psi, phi and theta
triggerSelect(trigger); // Select trigger input 1/2/3
obsoffset(resto); // Set spectrometer frequency
delay(GRADIENT_RES); // Delay for frequency setting
initval(fabs(ssc),vssc); // Compressed steady-state counter
if (seqcon[2]=='s') assign(zero,vssc); // Zero for standard peloop
assign(one,vacquire); // real-time acquire flag
setacqvar(vacquire); // Turn on acquire when vacquire is zero
/* trigger */
if (ticks > 0) F_initval((double)nsblock,vtrigblock);
/* Begin phase-encode loop ****************************/
peloop(seqcon[2],pe_steps,vpe_steps,vpe_ctr);
if (trtype) delay(ns*tr_delay); // relaxation delay
/* Compressed steady-states: 1st array & transient, all arrays if ssc is negative */
if ((ix > 1) && (ssc > 0))
assign(zero,vssc);
sub(vpe_ctr,vssc,vpe_ctr); // vpe_ctr counts up from -ssc
assign(zero,vssc);
if (seqcon[2] == 's')
assign(zero,vacquire); // Always acquire for non-compressed loop
else {
ifzero(vpe_ctr);
assign(zero,vacquire); // Start acquiring when vpe_ctr reaches zero
endif(vpe_ctr);
}
/* Read external kspace table if set ******************/
if (table)
getelem(t1,vpe_ctr,vpe_mult);
else {
ifzero(vacquire);
sub(vpe_ctr,vpe_offset,vpe_mult);
elsenz(vacquire);
sub(zero,vpe_offset,vpe_mult); // Hold PE mult at initial value for steady states
endif(vacquire);
}
/* Phase cycle ****************************************/
getelem(t2,vpe_ctr,vph180); // For phase encoding with slice rephase
add(oph,vph180,vph180); // 180 deg pulse phase alternates +/- 90 from receiver
mod2(ct,vph2);
dbl(vph2,vph2);
add(vph180,vph2,vph180); // Alternate phase for 180 on odd transients
/* Begin multislice loop ******************************/
msloop(seqcon[1],ns,vms_slices,vms_ctr);
if (!trtype) delay(tr_delay); // Relaxation delay
if (ticks > 0) {
modn(vms_ctr,vtrigblock,vtest);
ifzero(vtest); // if the beginning of an trigger block
xgate(ticks);
grad_advance(gpropdelay);
delay(GRADIENT_RES);
elsenz(vtest);
delay(GRADIENT_RES);
endif(vtest);
}
sp1on(); delay(GRADIENT_RES); sp1off(); // Scope trigger
/* Prepulse options ***********************************/
if (ir[0] == 'y') inversion_recovery();
if (sat[0] == 'y') satbands();
if (fsat[0] == 'y') fatsat();
if (mt[0] == 'y') mtc();
/* Slice select RF pulse ******************************/
obspower(p1_rf.powerCoarse);
obspwrf(p1_rf.powerFine);
delay(GRADIENT_RES);
obl_shapedgradient(ss_grad.name,ss_grad.duration,0,0,ss_grad.amp,NOWAIT);
delay(ss_grad.rfDelayFront);
shapedpulselist(shape90,ss_grad.rfDuration,oph,rof1,rof2,seqcon[1],vms_ctr);
delay(ss_grad.rfDelayBack);
/* Slice refocus gradient *****************************/
if (sepRefocus)
obl_shapedgradient(ssr_grad.name,ssr_grad.duration,0,0,-ssr_grad.amp,WAIT);
else
/* Include phase encode and readout dephase gradient if refocus gradients not separated */
pe_shapedgradient(pe_grad.name,pe_grad.duration,ror_grad.amp,0,-ssr_grad.amp*refsign,pe_grad.increment,vpe_mult,WAIT);
if (diff[0] == 'y') {
delay(diffusion.d1);
diffusion_dephase(&diffusion,dro,dpe,dsl);
delay(diffusion.d2);
}
else
delay(te_delay1);
/* Refocusing RF pulse ********************************/
obspower(p2_rf.powerCoarse);
obspwrf(p2_rf.powerFine);
delay(GRADIENT_RES);
obl_shapedgradient(crush_grad.name,crush_grad.duration,crushsign*gcrushr,gcrushp,gcrushs,WAIT);
obl_shapedgradient(ss2_grad.name,ss2_grad.duration,0,0,ss2_grad.amp,NOWAIT);
delay(ss2_grad.rfDelayFront);
shapedpulselist(shape180,ss2_grad.rfDuration,vph180,rof2,rof2,seqcon[1],vms_ctr);
delay(ss2_grad.rfDelayBack);
obl_shapedgradient(crush_grad.name,crush_grad.duration,crushsign*gcrushr,gcrushp,gcrushs,WAIT);
if (diff[0] == 'y') {
delay(diffusion.d3);
diffusion_rephase(&diffusion,dro,dpe,dsl);
delay(diffusion.d4);
}
else
delay(te_delay2);
/* Readout dephase, phase encode & readout gradients **/
roff = -poffset(pro,ro_grad.roamp); // incase inverted navigator is acquired
if (slprofile[0] == 'y') {
/* Readout gradient only if refocus gradients not separated */
if (sepRefocus)
obl_shapedgradient(ror_grad.name,ror_grad.duration,0,0,-ror_grad.amp,WAIT);
obl_shapedgradient(ro_grad.name,ro_grad.duration,0,0,ro_grad.amp,NOWAIT);
} else {
/* Readout gradient only if refocus gradients not separated */
if (sepRefocus)
pe_shapedgradient(pe_grad.name,pe_grad.duration,-ror_grad.amp,0,0,-pe_grad.increment,vpe_mult,WAIT);
obl_shapedgradient(ro_grad.name,ro_grad.duration,ro_grad.amp,0,0,NOWAIT);
}
/* Acquisition ****************************************/
delay(ro_grad.atDelayFront-alfa);
startacq(alfa);
acquire(np,1.0/sw);
delay(ro_grad.atDelayBack);
endacq();
/* Rewind Phase encoding ******************************/
pe_shapedgradient(pe_grad.name,pe_grad.duration,0,0,0,pe_grad.increment,vpe_mult,WAIT);
/* Navigator acquisition ******************************/
if (navigator[0] == 'y') {
delay(te_delay3);
obl_shapedgradient(crush_grad.name,crush_grad.duration,-crushsign*gcrushr,0,-gcrushs,WAIT);
obl_shapedgradient(ss2_grad.name,ss2_grad.duration,0,0,ss2_grad.amp,NOWAIT);
delay(ss2_grad.rfDelayFront);
shapedpulselist(shape180,ss2_grad.rfDuration,vph180,rof2,rof2,seqcon[1],vms_ctr);
delay(ss2_grad.rfDelayBack);
obl_shapedgradient(crush_grad.name,crush_grad.duration,-crushsign*gcrushr,0,-gcrushs,WAIT);
delay(te_delay4);
obl_shapedgradient(ro_grad.name,ro_grad.duration,navsign*ro_grad.amp,0,0,NOWAIT);
delay(ro_grad.atDelayFront-alfa);
startacq(alfa);
acquire(np,1.0/sw);
delay(ro_grad.atDelayBack);
endacq();
}
if (spoilflag[0] == 'y') {
obl_shapedgradient(spoil_grad.name,spoil_grad.duration,navsign*spoil_grad.amp,0,spoil_grad.amp,WAIT);
}
endmsloop(seqcon[1],vms_ctr);
endpeloop(seqcon[2],vpe_ctr);
/* Inter-image delay **********************************/
sub(ntrt,ct,vtrimage);
decr(vtrimage);
ifzero(vtrimage);
delay(trimage);
endif(vtrimage);
/* Duty cycle *****************************************/
calc_grad_duty(tr);
}
void phase_encode3_oblshapedgradient(char *pat1, char *pat2, char *pat3, double width, \
double stat1, double stat2, double stat3, \
double step1, double step2, double step3, \
int vmult1, int vmult2, int vmult3, \
double lim1, double lim2, double lim3, \
int loops, int wait4me, int tag)
{
if (gradtype[0] != gradtype[1])
abort_message("error in gradient or pfg configuration parameter gradtype. abort!\n");
if (gradtype[0] != gradtype[2])
abort_message("error in gradient or pfg configuration parameter gradtype. abort!\n");
int divs1=0, divs2=0, divs3=0, duration=0;
long long ticks;
int peR_step,peP_step,peS_step, peR_lim,peP_lim,peS_lim;
GradientBase *gC = P2TheConsole->getConfiguredGradient();
if (ix == 1) gC->errorCheck(0,stat1,stat2,stat3,step1,step2,step3);
P2TheConsole->eventStartAction();
if (gC->isNoWaitMode())
abort_message("gradient event requested too soon after previous one in NOWAIT mode. abort!\n");
cPatternEntry *tmp1=NULL, *tmp2=NULL, *tmp3=NULL;
/* set the GRADSCALE here, for GRADIENT it is all 0x4000; for Triax PFG they may be different */
gC->setGradScale("X",gC->GXSCALE);
gC->setGradScale("Y",gC->GYSCALE);
gC->setGradScale("Z",gC->GZSCALE);
int buffer[9];
if (step1 != 0.0)
{
if (! validrtvar(vmult1))
abort_message("invalid real time variable specified for phase encode multiplier. abort!\n");
// send SETPEVALUE
buffer[0] = 1; // destination RO
buffer[1] = (int)(step1*(gC->GMAX_TO_DAC));
buffer[2] = vmult1;
buffer[3] = (int) (lim1+0.5);
gC->outputACode(SETPEVALUE,4,buffer);
peR_step = buffer[1];
peR_lim = buffer[3];
}
else
{
peR_step = 0;
peR_lim = 0;
}
if (step2 != 0.0)
{
if (! validrtvar(vmult2))
abort_message("invalid real time variable specified for phase encode multiplier. abort!\n");
// send SETPEVALUE
buffer[0] = 2; // destination PE
buffer[1] = (int)(step2*(gC->GMAX_TO_DAC));
buffer[2] = vmult2;
buffer[3] = (int) (lim2+0.5);
gC->outputACode(SETPEVALUE,4,buffer);
peP_step = buffer[1];
peP_lim = buffer[3];
}
else
{
peP_step = 0;
peP_lim = 0;
}
if (step3 != 0.0)
{
if (! validrtvar(vmult3))
abort_message("invalid real time variable specified for phase encode multiplier. abort!\n");
// send SETPEVALUE
buffer[0] = 3; // destination SS
buffer[1] = (int)(step3*(gC->GMAX_TO_DAC));
buffer[2] = vmult3;
buffer[3] = (int) (lim3+0.5);
gC->outputACode(SETPEVALUE,4,buffer);
peS_step = buffer[1];
peS_lim = buffer[3];
}
else
{
peS_step = 0;
peS_lim = 0;
}
/* figure out which logical gradients are active? */
int tempType=0;
char gradPwrId[512], swidth[256];
strcpy(gradPwrId,"OblPEShp ");
// if shape name blank, that logical axis has no gradient
if (strcmp(pat1,"") != 0)
{
tempType |= 0x1;
strcat(gradPwrId,pat1);
strcat(gradPwrId," ");
}
if (strcmp(pat2,"") != 0)
{
tempType |= 0x2;
strcat(gradPwrId,pat2);
strcat(gradPwrId," ");
}
if (strcmp(pat3,"") != 0)
{
tempType |= 0x4;
strcat(gradPwrId,pat3);
strcat(gradPwrId," ");
}
sprintf(swidth,"%5.4f",width);
strcat(gradPwrId,swidth);
P2TheConsole->newEvent();
gC->clearSmallTicker();
if (wait4me)
gC->setActive();
else
gC->setNOWAITMode();
// axisCode=7 for oblique shaped gradient
// Gradient Logical Axis READOUT (R)
if (tempType & 0x1)
{
// OblShpGrd pattern has only 16 bits amp info; no KEYS or latch bit
tmp1 = gC->resolveOblShpGrdPattern(pat1,7,"oblpeshapedgradient",1);
divs1 = tmp1->getNumberStates();
duration = gC->calcTicksPerState(width,divs1,4,0.1,"PE Shaped Gradient",0);
if (duration < 320) // 4 us is lower limit.
abort_message("PFG Pattern duration too short. abort!\n");
}
if (tempType & 0x2)
{
// OblShpGrd pattern has only 16 bits amp info; no KEYS or latch bit
tmp2 = gC->resolveOblShpGrdPattern(pat2,7,"oblpeshapedgradient",1);
divs2 = tmp2->getNumberStates();
if ( (divs1 != 0) && (divs1 != divs2) )
abort_message("phase_encode3_oblshapedgradient: number of steps in waveforms must be the same. abort!\n");
duration = gC->calcTicksPerState(width,divs2,4,0.1,"PE Shaped Gradient",0);
if (duration < 320) // 4 us is lower limit.
abort_message("PFG Pattern duration too short. abort!\n");
divs1 = divs2;
}
if (tempType & 0x4)
{
// OblShpGrd pattern has only 16 bits amp info; no KEYS or latch bit
tmp3 = gC->resolveOblShpGrdPattern(pat3,7,"oblpeshapedgradient",1);
divs3 = tmp3->getNumberStates();
if ( (divs1 != 0) && (divs1 != divs3) )
abort_message("phase_encode3_oblshapedgradient: number of steps in waveforms must be the same. abort!\n");
duration = gC->calcTicksPerState(width,divs3,4,0.1,"PE Shaped Gradient",0);
if (duration < 320) // 4 us is lower limit.
abort_message("PFG Pattern duration too short. abort!\n");
divs1 = divs3;
}
/* ACode
OBLPESHAPEDGRD (9 args)
Type Info
patID 1
pat1D 2
patID 3
stat1
stat2
stat3
Duration Count
Loops
*/
buffer[0] = tempType;
if (tempType & 0x1)
buffer[1] = tmp1->getReferenceID();
else
buffer[1] = 0;
if (tempType & 0x2)
buffer[2] = tmp2->getReferenceID();
else
buffer[2] = 0;
if (tempType & 0x4)
buffer[3] = tmp3->getReferenceID();
else
buffer[3] = 0;
buffer[4] = (int)(stat1*gC->GMAX_TO_DAC);
buffer[5] = (int)(stat2*gC->GMAX_TO_DAC);
buffer[6] = (int)(stat3*gC->GMAX_TO_DAC);
buffer[7] = duration; // DURATION COUNT
buffer[8] = 1; // LOOPS
gC->oblpegrad_limit_check(buffer[4],buffer[5],buffer[6], \
peR_step,peP_step,peS_step, peR_lim,peP_lim,peS_lim);
gC->computeOBLPESHPGradPower(START,tmp1,tmp2,tmp3,tempType,buffer[4],buffer[5],buffer[6], \
peR_step,peP_step,peS_step,vmult1,vmult2,vmult3, \
peR_lim,peP_lim,peS_lim, 1);
gC->outputACode(OBLPESHAPEDGRD, 9, buffer);
if (bgflag)
{
printf("OBLPESHAPEDGRD\n");
for(int i=0; i<9; i++)
printf("%d ",buffer[i]);
printf("\n");
}
gC->noteDelay(duration*divs1);
ticks = gC->getSmallTicker();
if (wait4me)
P2TheConsole->update4Sync(ticks);
else
gC->incr_NOWAIT_eventTicker(ticks);
gC->computeOBLPESHPGradPower(END,tmp1,tmp2,tmp3,tempType,buffer[4],buffer[5],buffer[6], \
peR_step, peP_step, peS_step, peR_lim,peP_lim, peS_lim, \
peR_lim, peP_lim, peS_lim, 1);
int gradenergyaction = (int)(getvalnwarn("gradenergyaction")+0.49);
if ( (gradenergyaction & 0x2) ) P2TheConsole->showEventPowerIntegral(gradPwrId);
grad_flag = TRUE;
return;
}
/*-----------------------------------------------------------------
| initparms()/
| initializes the main variables used
+------------------------------------------------------------------*/
void initparms()
{
double tmpval;
char tmpstr[36];
int tmp, getchan;
sw = getval("sw");
np = getval("np");
if ( P_getreal(CURRENT,"nf",&nf,1) < 0 )
{
nf = 0.0; /* if not found assume 0 */
}
if (nf < 2.0)
nf = 1.0;
nt = getval("nt");
sfrq = getval("sfrq");
filter = getval("filter"); /* pulse Amp filter setting */
tof = getval("tof");
bs = getval("bs");
if (!var_active("bs",CURRENT))
bs = 0.0;
pw = getval("pw");
pw90 = getval("pw90");
p1 = getval("p1");
pwx = getvalnwarn("pwx");
pwxlvl = getvalnwarn("pwxlvl");
tau = getvalnwarn("tau");
satdly = getvalnwarn("satdly");
satfrq = getvalnwarn("satfrq");
satpwr = getvalnwarn("satpwr");
getstrnwarn("satmode",satmode);
/* ddr */
roff=getvalnwarn("roff");
/* --- delays --- */
d1 = getval("d1"); /* delay */
d2 = getval("d2"); /* a delay: used in 2D experiments */
d3 = getvalnwarn("d3"); /* a delay: used in 3D experiments */
d4 = getvalnwarn("d4"); /* a delay: used in 4D experiments */
phase1 = (int) sign_add(getvalnwarn("phase"),0.005);
phase2 = (int) sign_add(getvalnwarn("phase2"),0.005);
phase3 = (int) sign_add(getvalnwarn("phase3"),0.005);
rof1 = getval("rof1"); /* Time receiver is turned off before pulse */
rof2 = getval("rof2"); /* Time after pulse before receiver turned on */
alfa = getval("alfa"); /* Time after rec is turned on that acqbegins */
pad = getval("pad"); /* Pre-acquisition delay */
padactive = var_active("pad",CURRENT);
hst = getval("hst"); /* HomoSpoil delay */
tpwr = getval("tpwr");
if ( P_getreal(CURRENT,"tpwrm",&tpwrf,1) < 0 )
if ( P_getreal(CURRENT,"tpwrf",&tpwrf,1) < 0 )
tpwrf = 4095.0;
//getstr("rfband",rfband); /* RF band, high or low */
getstr("hs",hs);
hssize = strlen(hs);
/* setlockmode(); */ /* set up lockmode variable,h**o bits */
if (bgflag)
{
fprintf(stderr,"sw = %lf, sfrq = %10.8lf\n",sw,sfrq);
fprintf(stderr,"hs='%s',%d\n",hs,hssize);
}
gain = getval("gain");
gainactive = var_active("gain",CURRENT); /* non arrayable */
/* InterLocks is set by go. It will have three chars.
* char 0 is for lock
* char 1 is for spin
* char 2 is for temp
*/
getstr("interLocks",interLock); /* non arrayable */
spin = (int) sign_add(getval("spin"),0.005);
spinactive = var_active("spin",CURRENT); /* non arrayable */
HSrotor = 0; /* high speed spinner selected */
/* spinTresh is created and set by go.c inside Vnmrbg */
if (spin >= (int) sign_add(getval("spinThresh"),0.005))
{
/* Selected Solids spinner */
HSrotor = 1;
}
vttemp = getval("temp"); /* get vt temperature */
tempactive = var_active("temp",CURRENT); /* non arrayable */
vtwait = getval("vtwait"); /* get vt timeout setting */
vtc = getval("vtc"); /* get vt timeout setting */
if (getparm("traymax","real",GLOBAL,&tmpval,1))
{
traymax=0;
}
else
{
traymax= (int) (tmpval + 0.5);
}
if (getparm("loc","real",GLOBAL,&tmpval,1))
psg_abort(1);
loc = (int) sign_add(tmpval,0.005);
if (!var_active("loc",GLOBAL) || (loc<0) )
{
locActive = 0;
loc = 0;
tmpval = 0.0;
if (setparm("loc","real",GLOBAL,&tmpval,1))
psg_abort(1);
}
else
locActive = 1;
/* if using Gilson Liquid Handler Racks then gilpar is defined
* and is an array of 4 values */
if ((traymax == 96) || (traymax == (8*96))) /* test for Gilson/Hermes */
{
int trayloc=1;
int trayzone=1;
if ( P_getreal(GLOBAL, "vrack", &tmpval, 1) >= 0 )
trayloc = (int) (tmpval + 0.5);
if ( P_getreal(GLOBAL, "vzone", &tmpval, 1) >= 0 )
trayzone = (int) (tmpval + 0.5);
/* rrzzllll */
loc = loc + (10000 * trayzone) + (1000000 * trayloc);
if (bgflag)
fprintf(stderr,"GILSON: ----- vrack: %d, vzone: %d, Encoded Loc = %d\n",trayloc,trayzone,loc);
}
getstr("alock",alock);
getstr("wshim",wshim);
getlockmode(alock,&lockmode); /* type of autolocking */
whenshim = setshimflag(wshim,&shimatanyfid); /* when to shim */
if ( ( tmp=P_getstring(CURRENT, "sampling", tmpstr, 1, 20)) >= 0)
{
samplingScale = 1.01;
samplingAngle = 0.0;
samplingTransX = 0.0;
samplingTransY = 0.0;
if (tmpstr[0] == 'e')
{
double rtmp = 0.0;
sampling = SAMPLING_ELLIPTICAL;
P_getreal(CURRENT, "ni", &rtmp, 1);
samplingRows = (int) rtmp;
rtmp = 0.0;
P_getreal(CURRENT, "ni2", &rtmp, 1);
samplingCols = (int) rtmp;
if ((samplingRows < 2) || (samplingCols < 2))
sampling = SAMPLING_STANDARD;
if (sampling == SAMPLING_ELLIPTICAL)
{
if ( P_getreal(CURRENT, "samplingEScale", &rtmp, 1) >= 0)
samplingScale = rtmp;
if ( P_getreal(CURRENT, "samplingEAngle", &rtmp, 1) >= 0)
samplingAngle = rtmp;
if ( P_getreal(CURRENT, "samplingETransX", &rtmp, 1) >= 0)
samplingTransX = rtmp;
if ( P_getreal(CURRENT, "samplingETransY", &rtmp, 1) >= 0)
samplingTransY = rtmp;
}
}
else
sampling = SAMPLING_STANDARD;
}
else
sampling = SAMPLING_STANDARD;
// this looks REDUNDANT to instantiation...
// but is not completely dpwrf
if ( ( tmp=P_getstring(CURRENT, "dn", tmpstr, 1, 9)) >= 0)
getchan = TRUE;
else
getchan = FALSE;
/* if "dn" does not exist, don't bother with the rest of channel 2 */
getchan = (NUMch > 1) && getchan && (tmpstr[0]!='\000');
if (getchan) /* variables associated with 2nd channel */
{
dfrq = getval("dfrq");
dmf = getval("dmf"); /* 1st decoupler modulation freq */
dof = getval("dof");
dres = getvalnwarn("dres"); /* prg decoupler digital resolution */
if (dres < 1.0) dres = 1.0;
getstrnwarn("dseq",dseq);
dpwr = getval("dpwr");
dhp = 0.0;
dlp = 0.0;
if ( P_getreal(CURRENT,"dpwrm",&dpwrf,1) < 0 )
if ( P_getreal(CURRENT,"dpwrf",&dpwrf,1) < 0 )
dpwrf = 4095.0;
getstr("dm",dm);
dmsize = strlen(dm);
getstr("dmm",dmm);
dmmsize = strlen(dmm);
getstr("h**o",h**o);
homosize = strlen(h**o);
}
else
{
dfrq = 1.0;
dmf = 1000;
dof = 0.0;
dres = 1.0;
dseq[0] = '\000';
dhp = 0.0;
dlp = 0.0;
dpwr = 0.0;
dpwrf = 0.0;
strcpy(dm,"n");
dmsize = 1;
strcpy(dmm,"c");
dmmsize = 1;
strcpy(h**o,"n");
homosize= 1;
}
if (bgflag)
{
if (!getchan)
fprintf(stderr,"next line are default values for chan 2\n");
fprintf(stderr,"dm='%s',%d, dmm='%s',%d\n",dm,dmsize,dmm,dmmsize);
fprintf(stderr,"h**o='%s',%d\n",h**o,homosize);
}
if ( (tmp=P_getstring(CURRENT, "dn2", tmpstr, 1, 9)) >= 0)
getchan = TRUE;
else
getchan = FALSE;
/* if "dn2" does not exist, don't bother with the rest of channel 3 */
getchan = (NUMch > 2) && getchan && (tmpstr[0]!='\000');
if (getchan) /* variables associated with 3rd channel */
{
dfrq2 = getval("dfrq2");
dmf2 = getval("dmf2"); /* 2nd decoupler modulation freq */
dof2 = getval("dof2");
dres2 = getvalnwarn("dres2"); /* prg decoupler digital resolution */
if (dres2 < 1.0) dres2 = 1.0;
getstrnwarn("dseq2",dseq2);
dpwr2 = getval("dpwr2");
if ( P_getreal(CURRENT,"dpwrm2",&dpwrf2,1) < 0 )
if ( P_getreal(CURRENT,"dpwrf2",&dpwrf2,1) < 0 )
dpwrf2 = 4095.0;
getstr("dm2",dm2);
dm2size = strlen(dm2);
getstr("dmm2",dmm2);
dmm2size = strlen(dmm2);
getstr("homo2",homo2);
homo2size = strlen(homo2);
}
else
{
dfrq2 = 1.0;
dmf2 = 1000;
dof2 = 0.0;
dres2 = 1.0;
dseq2[0] = '\000';
dpwr2 = 0.0;
dpwrf2 = 0.0;
strcpy(dm2,"n");
dm2size = 1;
strcpy(dmm2,"c");
dmm2size = 1;
strcpy(homo2,"n");
homo2size= 1;
}
if (bgflag)
{
if (!getchan)
fprintf(stderr,"next two lines are default values for chan 3\n");
fprintf(stderr,"dfrq2 = %10.8lf, dof2 = %10.8lf, dpwr2 = %lf\n",
dfrq2,dof2,dpwr2);
fprintf(stderr,"dmf2 = %10.8lf, dm2='%s',%d, dmm2='%s',%d\n",
dmf2,dm2,dm2size,dmm2,dmm2size);
fprintf(stderr,"homo2='%s',%d\n",homo2,homo2size);
}
if ( (tmp=P_getstring(CURRENT, "dn3", tmpstr, 1, 9)) >= 0)
getchan = TRUE;
else
getchan = FALSE;
/* if "dn3" does not exist, don't bother with the rest of channel 3 */
getchan = (NUMch > 3) && getchan && (tmpstr[0]!='\000');
if (getchan) /* variables associated with 3rd channel */
{
dfrq3 = getval("dfrq3");
dmf3 = getval("dmf3"); /* 3nd decoupler modulation freq */
dof3 = getval("dof3");
dres3 = getvalnwarn("dres3"); /* prg decoupler digital resolution */
if (dres3 < 1.0) dres3 = 1.0;
getstrnwarn("dseq3",dseq3);
dpwr3 = getval("dpwr3");
if ( P_getreal(CURRENT,"dpwrm3",&dpwrf3,1) < 0 )
if ( P_getreal(CURRENT,"dpwrf3",&dpwrf3,1) < 0 )
dpwrf3 = 4095.0;
getstr("dm3",dm3);
dm3size = strlen(dm3);
getstr("dmm3",dmm3);
dmm3size = strlen(dmm3);
getstr("homo3",homo3);
homo3size = strlen(homo3);
}
else
{
dfrq3 = 1.0;
dmf3 = 1000;
dof3 = 0.0;
dres3 = 1.0;
dseq3[0] = '\000';
dpwr3 = 0.0;
dpwrf3 = 0.0;
strcpy(dm3,"n");
dm3size = 1;
strcpy(dmm3,"c");
dmm3size = 1;
strcpy(homo3,"n");
homo3size= 1;
}
if (bgflag)
{
if (!getchan)
fprintf(stderr,"next two lines are default values for chan 3\n");
fprintf(stderr,"dfrq3 = %10.8lf, dof3 = %10.8lf, dpwr3 = %lf\n",
dfrq3,dof3,dpwr3);
fprintf(stderr,"dmf3 = %10.8lf, dm3='%s',%d, dmm3='%s',%d\n",
dmf3,dm3,dm3size,dmm3,dmm3size);
fprintf(stderr,"homo3='%s',%d\n",homo3,homo3size);
}
if ( (tmp=P_getstring(CURRENT, "dn4", tmpstr, 1, 9)) >= 0)
getchan = TRUE;
else
getchan = FALSE;
/* if "dn4" does not exist, don't bother with the rest of channel 4 */
getchan = (NUMch > 4) && getchan && (tmpstr[0]!='\000');
if (getchan) /* variables associated with 4th channel */
{
dfrq4 = getval("dfrq4");
dmf4 = getval("dmf4"); /* 4nd decoupler modulation freq */
dof4 = getval("dof4");
dres4 = getvalnwarn("dres4"); /* prg decoupler digital resolution */
if (dres4 < 1.0) dres4 = 1.0;
getstrnwarn("dseq4",dseq4);
dpwr4 = getval("dpwr4");
if ( P_getreal(CURRENT,"dpwrm4",&dpwrf4,1) < 0 )
if ( P_getreal(CURRENT,"dpwrf4",&dpwrf4,1) < 0 )
dpwrf4 = 4095.0;
getstr("dm4",dm4);
dm4size = strlen(dm4);
getstr("dmm4",dmm4);
dmm4size = strlen(dmm4);
getstr("homo4",homo4);
homo4size = strlen(homo4);
}
else
{
dfrq4 = 1.0;
dmf4 = 1000;
dof4 = 0.0;
dres4 = 1.0;
dseq4[0] = '\000';
dpwr4 = 0.0;
dpwrf4 = 0.0;
strcpy(dm4,"n");
dm4size = 1;
strcpy(dmm4,"c");
dmm4size = 1;
strcpy(homo4,"n");
homo4size= 1;
}
if (bgflag)
{
if (!getchan)
fprintf(stderr,"next two lines are default values for chan 4\n");
fprintf(stderr,"dfrq4 = %10.8lf, dof4 = %10.8lf, dpwr4 = %lf\n",
dfrq4,dof4,dpwr4);
fprintf(stderr,"dmf4 = %10.8lf, dm4='%s',%d, dmm4='%s',%d\n",
dmf4,dm4,dm4size,dmm4,dmm4size);
fprintf(stderr,"homo4='%s',%d\n",homo4,homo4size);
}
// end of REDUNDANT ???
}
/**************************************************************
initparms_img()
Read in all parameters used by the Imaging
SEQD applications package. Build the array
of slice positions used in multislice loops.
*************************************************************/
void initparms_img()
{
int k; /*index for loops*/
/*-------------------------------------------------------------
INITIALIZE PARAMETERS
-------------------------------------------------------------*/
/*--------------------------------------
RFPULSES
--------------------------------------*/
p2 = getvalnwarn("p2");
p3 = getvalnwarn("p3");
p4 = getvalnwarn("p4");
p5 = getvalnwarn("p5");
pi = getvalnwarn("pi");
psat = getvalnwarn("psat");
pmt = getvalnwarn("pmt");
pwx2 = getvalnwarn("pwx2");
psl = getvalnwarn("psl");
getstrnwarn("pwpat",pwpat);
getstrnwarn("p1pat",p1pat);
getstrnwarn("p2pat",p2pat);
getstrnwarn("p3pat",p3pat);
getstrnwarn("p4pat",p4pat);
getstrnwarn("p5pat",p5pat);
getstrnwarn("pipat",pipat);
getstrnwarn("satpat",satpat);
getstrnwarn("mtpat",mtpat);
getstrnwarn("pslpat",pslpat);
tpwr1 = getvalnwarn("tpwr1");
tpwr2 = getvalnwarn("tpwr2");
tpwr3 = getvalnwarn("tpwr3");
tpwr4 = getvalnwarn("tpwr4");
tpwr5 = getvalnwarn("tpwr5");
tpwri = getvalnwarn("tpwri");
mtpwr = getvalnwarn("mtpwr");
pwxlvl2 = getvalnwarn("pwxlvl2");
tpwrsl = getvalnwarn("tpwrsl");
/*--------------------------------------
DECOUPLER PULSES
--------------------------------------*/
getstrnwarn("decpat",decpat);
getstrnwarn("decpat1",decpat1);
getstrnwarn("decpat2",decpat2);
getstrnwarn("decpat3",decpat3);
getstrnwarn("decpat4",decpat4);
getstrnwarn("decpat5",decpat5);
dpwr = getvalnwarn("dpwr");
dpwr1 = getvalnwarn("dpwr1");
dpwr4 = getvalnwarn("dpwr4");
dpwr5 = getvalnwarn("dpwr5");
/*--------------------------------------
GRADIENTS
--------------------------------------*/
gradunit = getvalnwarn("gradunit");
gro = getvalnwarn("gro");
gro2 = getvalnwarn("gro2");
gro3 = getvalnwarn("gro3");
gpe = getvalnwarn("gpe");
gpe2 = getvalnwarn("gpe2");
gpe3 = getvalnwarn("gpe3");
gss = getvalnwarn("gss");
gss2 = getvalnwarn("gss2");
gss3 = getvalnwarn("gss3");
gror = getvalnwarn("gror");
gssr = getvalnwarn("gssr");
grof = getvalnwarn("grof");
gssf = getvalnwarn("gssf");
g0 = getvalnwarn("g0");
g1 = getvalnwarn("g1");
g2 = getvalnwarn("g2");
g3 = getvalnwarn("g3");
g4 = getvalnwarn("g4");
g5 = getvalnwarn("g5");
g6 = getvalnwarn("g6");
g7 = getvalnwarn("g7");
g8 = getvalnwarn("g8");
g9 = getvalnwarn("g9");
gx = getvalnwarn("gx");
gy = getvalnwarn("gy");
gz = getvalnwarn("gz");
gvox1 = getvalnwarn("gvox1");
gvox2 = getvalnwarn("gvox2");
gvox3 = getvalnwarn("gvox3");
gdiff = getvalnwarn("gdiff");
gflow = getvalnwarn("gflow");
gspoil = getvalnwarn("gspoil");
gspoil2 = getvalnwarn("gspoil2");
gcrush = getvalnwarn("gcrush");
gcrush2 = getvalnwarn("gcrush2");
gtrim = getvalnwarn("gtrim");
gtrim2 = getvalnwarn("gtrim2");
gramp = getvalnwarn("gramp");
gramp2 = getvalnwarn("gramp2");
gxscale = getvalnwarn("gxscale");
gyscale = getvalnwarn("gyscale");
gzscale = getvalnwarn("gzscale");
gpemult = getvalnwarn("gpemult");
/* Get gmax or gxmax, gymax, gzmax */
if ( P_getreal(CURRENT,"gxmax",&gxmax,1) < 0 )
{
if ( P_getreal(CURRENT,"gmax",&gmax,1) < 0 )
{
gmax = 0;
}
gxmax = gmax;
}
if ( P_getreal(CURRENT,"gymax",&gymax,1) < 0 )
{
if ( P_getreal(CURRENT,"gmax",&gmax,1) < 0 )
{
gmax = 0;
}
gymax = gmax;
}
if ( P_getreal(CURRENT,"gzmax",&gzmax,1) < 0 )
{
if ( P_getreal(CURRENT,"gmax",&gmax,1) < 0 )
{
gmax = 0;
}
gzmax = gmax;
}
if (gxmax < gzmax)
if (gxmax < gymax)
gmax = gxmax;
else
gmax = gymax;
else
if (gxmax < gymax)
gmax = gxmax;
else
gmax = gymax;
/* --- Get gradient limit parameters --- */
if ( P_getreal(CURRENT,"gtotlimit",>otlimit,1) < 0 )
gtotlimit = gxmax + gymax + gzmax;
if (gtotlimit <= 0.0) gtotlimit = gxmax + gymax + gzmax;
if ( P_getreal(CURRENT,"gxlimit",&gxlimit,1) < 0 )
gxlimit = gxmax;
if (gxlimit <= 0.0) gxlimit = gxmax;
if ( P_getreal(CURRENT,"gylimit",&gylimit,1) < 0 )
gylimit = gymax;
if (gylimit <= 0.0) gylimit = gymax;
if ( P_getreal(CURRENT,"gzlimit",&gzlimit,1) < 0 )
gzlimit = gzmax;
if (gzlimit <= 0.0) gzlimit = gzmax;
/* --- Get gradstepsz if Present --- */
/* if gradstepsz is 32767 gradient waveshaping is being used */
if ( P_getreal(GLOBAL,"gradstepsz",&gradstepsz,1) >= 0 )
{
if (gradstepsz < 1.0)
{
if ((anygradcrwg) || (anygradwg) || (anypfga) || (anypfgw))
gradstepsz = 32767.0;
else
gradstepsz = 2047.0;
}
}
else
{
if ((anygradcrwg) || (anygradwg) || (anypfga) || (anypfgw))
gradstepsz = 32767.0;
else
gradstepsz = 2047.0;
}
getstrnwarn("gpatup",gpatup);
getstrnwarn("gpatdown",gpatdown);
getstrnwarn("gropat",gropat);
getstrnwarn("gpepat",gpepat);
getstrnwarn("gsspat",gsspat);
getstrnwarn("gpat",gpat);
getstrnwarn("gpat1",gpat1);
getstrnwarn("gpat2",gpat2);
getstrnwarn("gpat3",gpat3);
getstrnwarn("gpat4",gpat4);
getstrnwarn("gpat5",gpat5);
/*--------------------------------------
DELAYS
--------------------------------------*/
tr = getvalnwarn("tr");
te = getvalnwarn("te");
ti = getvalnwarn("ti");
tm = getvalnwarn("tm");
at = getvalnwarn("at");
tpe = getvalnwarn("tpe");
tpe2 = getvalnwarn("tpe2");
tpe3 = getvalnwarn("tpe3");
tcrush = getvalnwarn("tcrush");
tdiff = getvalnwarn("tdiff");
tdelta = getvalnwarn("tdelta");
tDELTA = getvalnwarn("tDELTA");
tflow = getvalnwarn("tflow");
tspoil = getvalnwarn("tspoil");
hold = getvalnwarn("hold");
trise = getvalnwarn("trise");
if (trise > 10e-3) abort_message("trise: %5.0f usec is excessive!",trise*1e6);
/*--------------------------------------
FREQUENCIES
--------------------------------------*/
resto = getvalnwarn("resto");
wsfrq = getvalnwarn("wsfrq");
chessfrq = getvalnwarn("chessfrq");
mtfrq = getvalnwarn("mtfrq");
/*--------------------------------------
PHYSICAL POSITIONS AND FOV
--------------------------------------*/
fovunit = getvalnwarn("fovunit");
pro = getvalnwarn("pro");
ppe = getvalnwarn("ppe");
ppe2 = getvalnwarn("ppe2");
ppe3 = getvalnwarn("ppe3");
pos1 = getvalnwarn("pos1");
pos2 = getvalnwarn("pos2");
pos3 = getvalnwarn("pos3");
lro = getvalnwarn("lro");
lpe = getvalnwarn("lpe");
lpe2 = getvalnwarn("lpe2");
lpe3 = getvalnwarn("lpe3");
lss = getvalnwarn("lss");
/*--------------------------------------
PHYSICAL SIZES
--------------------------------------*/
thkunit = getvalnwarn("thkunit");
vox1 = getvalnwarn("vox1");
vox2 = getvalnwarn("vox2");
vox3 = getvalnwarn("vox3");
thk = getvalnwarn("thk");
/*--------------------------------------
BANDWIDTHS
--------------------------------------*/
sw1 = getvalnwarn("sw1");
sw2 = getvalnwarn("sw2");
sw3 = getvalnwarn("sw3");
/*--------------------------------------
ORIENTATION PARAMETERS
--------------------------------------*/
getstrnwarn("orient",orient);
getstrnwarn("vorient",vorient);
getstrnwarn("dorient",dorient);
getstrnwarn("sorient",sorient);
getstrnwarn("orient2",orient2);
psi = getvalnwarn("psi");
phi = getvalnwarn("phi");
theta = getvalnwarn("theta");
vpsi = getvalnwarn("vpsi");
vphi = getvalnwarn("vphi");
vtheta = getvalnwarn("vtheta");
dpsi = getvalnwarn("dpsi");
dphi = getvalnwarn("dphi");
dtheta = getvalnwarn("dtheta");
spsi = getvalnwarn("spsi");
sphi = getvalnwarn("sphi");
stheta = getvalnwarn("stheta");
offsetx = getvalnwarn("offsetx");
offsety = getvalnwarn("offsety");
offsetz = getvalnwarn("offsetz");
gxdelay = getvalnwarn("gxdelay");
gydelay = getvalnwarn("gydelay");
gzdelay = getvalnwarn("gzdelay");
/*--------------------------------------
COUNTS AND FLAGS
--------------------------------------*/
nD = getvalnwarn("nD");
ns = getvalnwarn("ns");
ne = getvalnwarn("ne");
ni = getvalnwarn("ni");
nv = getvalnwarn("nv");
nv2 = getvalnwarn("nv2");
nv3 = getvalnwarn("nv3");
ssc = getvalnwarn("ssc");
ticks = getvalnwarn("ticks");
getstrnwarn("ir",ir);
getstrnwarn("ws",ws);
getstrnwarn("mt",mt);
getstrnwarn("pilot",pilot);
getstrnwarn("seqcon",seqcon);
getstrnwarn("petable",petable);
getstrnwarn("acqtype",acqtype);
getstrnwarn("exptype",exptype);
getstrnwarn("apptype",apptype);
getstrnwarn("seqfil",seqfil);
getstrnwarn("rfspoil",rfspoil);
getstrnwarn("verbose",verbose);
/*--------------------------------------
Miscellaneous
--------------------------------------*/
rfphase = getvalnwarn("rfphase");
B0 = getvalnwarn("B0");
gpropdelay = getvalnwarn("gpropdelay");
kzero = getvalnwarn("kzero");
aqtm = getvalnwarn("aqtm");
getstrnwarn("volumercv",volumercv);
/*--------------------------------------
Build slice position array
--------------------------------------*/
if (ns > MAXSLICE) {
text_error("ns exceeds maximum limit.\n");
psg_abort(1);
}
for (k = 0; k < MAXSLICE; k++) {
pss[k] = 0.0;
}
if (seqcon[1] == 's')
pss[0] = getval("pss");
else if (seqcon[1] == 'c')
getarray("pss",pss);
else
pss[0] = getvalnwarn("pss"); /* get it anyway but with no warning */
/*--------------------------------------
Old SISCO Imaging Parameters
--------------------------------------*/
slcto = getvalnwarn("slcto"); /* slice selection offset */
delto = getvalnwarn("delto"); /* slice spacing frequency */
tox = getvalnwarn("tox");
toy = getvalnwarn("toy");
toz = getvalnwarn("toz");
griserate = getvalnwarn("griserate");
}
