pulsesequence() { /* DECLARE VARIABLES */ char satmode[MAXSTR], fscuba[MAXSTR], cbdecseq[MAXSTR]; int icosel, ni = getval("ni"), t1_counter; /* used for states tppi in t1 */ double tau1, /* t1 delay */ tau2, /* t2 delay */ tau3, /* t3 delay */ taua, /* ~ 1/4JNH = 2.25 ms */ taub, /* ~ 1/4JNH = 2.25 ms */ tauc, /* ~ 1/4JNCa = ~13 ms */ taud, /* ~ 1/4JCaC' = 3~4.5 ms ms */ d2_init=0.0, /* used for states tppi in t1 */ bigTN, /* nitrogen T period */ bigTC, /* carbon T period */ BigT1, /* delay about 200 us */ satpwr, /* low level 1H trans.power for presat */ sw1, /* sweep width in f1 */ sw2, /* sweep width in f2 */ at, sphase, cbpwr, /* power level for selective CB decoupling */ cbdmf, /* pulse width for selective CB decoupling */ cbres, /* decoupling resolution of CB decoupling */ pwS1, /* length of 90 on Ca */ pwS2, /* length of 90 on CO */ pwS3, /* length of 180 on Ca */ pwS4, /* length of 180 on CO */ gt1, gt2, gt3, gt4, gt5, gt6, gt7, gt8, gt9, gt10, gt11, gzlvl1, gzlvl2, gzlvl3, gzlvl4, gzlvl5, gzlvl6, gzlvl7, gzlvl8, gzlvl9, gzlvl10, gzlvl11, compH = getval("compH"), /* adjustment for amplifier compression */ pwHs = getval ("pwHs"), /* H1 90 degree pulse at tpwrs */ tpwrs, /* power for pwHs ("H2osinc") pulse */ waltzB1 = getval("waltzB1"), pwClvl = getval("pwClvl"), /* coarse power for C13 pulse */ pwC = getval("pwC"), /* C13 90 degree pulse length at pwClvl */ pwNlvl = getval("pwNlvl"), /* power for N15 pulses */ pwN = getval("pwN"), /* N15 90 degree pulse length at pwNlvl */ swCa = getval("swCa"), swCO = getval("swCO"), swN = getval("swN"), swTilt, /* This is the sweep width of the tilt vector */ cos_N, cos_CO, cos_Ca, angle_N, angle_CO, angle_Ca; angle_N=0.0; /* LOAD VARIABLES */ getstr("satmode",satmode); getstr("fscuba",fscuba); taua = getval("taua"); taub = getval("taub"); tauc = getval("tauc"); taud = getval("taud"); bigTN = getval("bigTN"); bigTC = getval("bigTC"); BigT1 = getval("BigT1"); tpwr = getval("tpwr"); satpwr = getval("satpwr"); dpwr = getval("dpwr"); sw1 = getval("sw1"); sw2 = getval("sw2"); at = getval("at"); sphase = getval("sphase"); gt1 = getval("gt1"); gt2 = getval("gt2"); gt3 = getval("gt3"); gt4 = getval("gt4"); gt5 = getval("gt5"); gt6 = getval("gt6"); gt7 = getval("gt7"); gt8 = getval("gt8"); gt9 = getval("gt9"); gt10 = getval("gt10"); gt11 = getval("gt11"); gzlvl1 = getval("gzlvl1"); gzlvl2 = getval("gzlvl2"); gzlvl3 = getval("gzlvl3"); gzlvl4 = getval("gzlvl4"); gzlvl5 = getval("gzlvl5"); gzlvl6 = getval("gzlvl6"); gzlvl7 = getval("gzlvl7"); gzlvl8 = getval("gzlvl8"); gzlvl9 = getval("gzlvl9"); gzlvl10 = getval("gzlvl10"); gzlvl11 = getval("gzlvl11"); /* Load variable */ cbpwr = getval("cbpwr"); cbdmf = getval("cbdmf"); cbres = getval("cbres"); tau1 = 0; tau2 = 0; tau3 = 0; cos_N = 0; cos_CO = 0; cos_Ca = 0; kappa = 5.4e-3; getstr("cbdecseq", cbdecseq); /* LOAD PHASE TABLE */ settable(t1,1,phi1); settable(t2,4,phi2); settable(t3,1,phi3); settable(t4,1,phi4); settable(t5,4,phi5); settable(t7,4,phi7); settable(t6,4,rec); /* get calculated pulse lengths of shaped C13 pulses */ pwS1 = c13pulsepw("ca", "co", "square", 90.0); pwS2 = c13pulsepw("co", "ca", "sinc", 90.0); pwS3 = c13pulsepw("ca","co","square",180.0); pwS4 = c13pulsepw("co","ca","sinc",180.0); tpwrs = tpwr - 20.0*log10(pwHs/(compH*pw*1.69)); /*needs 1.69 times more*/ tpwrs = (int) (tpwrs); /*power than a square pulse */ widthHd = 2.681*waltzB1/sfrq; /* bandwidth of H1 WALTZ16 decoupling */ pwHd = h1dec90pw("WALTZ16", widthHd, 0.0); /* H1 90 length for WALTZ16 */ /* CHECK VALIDITY OF PARAMETER RANGES */ if((dm[A] == 'y' || dm[B] == 'y' || dm[C] == 'y' )) { printf("incorrect dec1 decoupler flags! "); psg_abort(1); } if((dm2[A] == 'y' || dm2[B] == 'y' || dm2[C] == 'n')) { printf("incorrect dec2 decoupler flags! Should be 'nny' "); psg_abort(1); } if( satpwr > 6 ) { printf("SATPWR too large !!! "); psg_abort(1); } if( dpwr > 46 ) { printf("don't fry the probe, DPWR too large! "); psg_abort(1); } if( dpwr2 > 47 ) { printf("don't fry the probe, DPWR2 too large! "); psg_abort(1); } if( pw > 200.0e-6 ) { printf("dont fry the probe, pw too high ! "); psg_abort(1); } if( pwN > 200.0e-6 ) { printf("dont fry the probe, pwN too high ! "); psg_abort(1); } if( gt1 > 15e-3 || gt2 > 15e-3 || gt3 > 15e-3 || gt4 > 15e-3 || gt5 > 15e-3 || gt6 > 15e-3 || gt7 > 15e-3 || gt8 > 15e-3 || gt9 > 15e-3 || gt10 > 15.0e-3 || gt11>15.0e-3) { printf("gti values must be < 15e-3\n"); psg_abort(1); } if( dpwr3 > 56) { printf("dpwr3 too high\n"); psg_abort(1); } /* PHASES AND INCREMENTED TIMES */ /* Set up angles and phases */ angle_CO=getval("angle_CO"); cos_CO=cos(PI*angle_CO/180.0); angle_Ca=getval("angle_Ca"); cos_Ca=cos(PI*angle_Ca/180.0); if ( (angle_CO < 0) || (angle_CO > 90) ) { printf ("angle_CO must be between 0 and 90 degree.\n"); psg_abort(1); } if ( (angle_Ca < 0) || (angle_Ca > 90) ) { printf ("angle_Ca must be between 0 and 90 degree.\n"); psg_abort(1); } if ( 1.0 < (cos_CO*cos_CO + cos_Ca*cos_Ca) ) { printf ("Impossible angles.\n"); psg_abort(1); } else { cos_N=sqrt(1.0- (cos_CO*cos_CO + cos_Ca*cos_Ca)); angle_N = 180.0*acos(cos_N)/PI; } swTilt=swCO*cos_CO + swCa*cos_Ca + swN*cos_N; if (ix ==1) { printf("\n\nn\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n"); printf ("Maximum Sweep Width: \t\t %f Hz\n", swTilt); printf ("Angle_CO:\t%6.2f\n", angle_CO); printf ("Angle_Ca:\t%6.2f\n", angle_Ca); printf ("Angle_N :\t%6.2f\n", angle_N ); } /* Set up hyper complex */ /* sw1 is used as symbolic index */ if ( sw1 < 1000 ) { printf ("Please set sw1 to some value larger than 1000.\n"); psg_abort(1); } if (ix == 1) d2_init = d2; t1_counter = (int) ( (d2-d2_init)*sw1 + 0.5 ); if (t1_counter % 2) { tsadd(t1,2,4); tsadd(t6,2,4); } if (phase1 == 1) { ;} /* CC */ else if (phase1 == 2) { tsadd(t7,1,4);} /* SC */ else if (phase1 == 3) { tsadd(t4,3,4); } /* CS */ else if (phase1 == 4) { tsadd(t7,1,4); tsadd(t4,3,4); } /* SS */ else { printf ("phase1 can only be 1,2,3,4. \n"); psg_abort(1); } if (phase2 == 2) { tsadd(t3,2,4); icosel = +1; } /* N */ else icosel = -1; tau1 = 1.0*t1_counter*cos_CO/swTilt; tau2 = 1.0*t1_counter*cos_Ca/swTilt; tau3 = 1.0*t1_counter*cos_N/swTilt; tau1 = tau1/2.0; tau2 = tau2/2.0; tau3 = tau3/2.0; /* CHECK VALIDITY OF PARAMETER RANGES */ if (bigTN - 0.5*ni*(cos_N/swTilt) + pwS3 < 0.2e-6) { printf(" ni is too big. Make ni equal to %d or less.\n", ((int)((bigTN + pwS3)*2.0*swTilt/cos_N))); psg_abort(1);} if (bigTC - 0.5*ni*(cos_Ca/swTilt) - pwS4 - pwS3/2 - WFG3_START_DELAY - WFG3_STOP_DELAY -3*POWER_DELAY - PRG_START_DELAY - PRG_STOP_DELAY - 4.0e-6 < 0.2e-6) { printf(" ni is too big for Ca. Make ni equal to %d or less.\n", (int) ((bigTC - pwS4 - pwS3/2 - WFG3_START_DELAY - WFG3_STOP_DELAY - 3*POWER_DELAY - PRG_START_DELAY - PRG_STOP_DELAY -4.0e-6 )/(0.5*cos_Ca/swTilt)) ); psg_abort(1); } /* BEGIN ACTUAL PULSE SEQUENCE */ status(A); obspower(satpwr); /* Set transmitter power for 1H presaturation */ obspwrf(4095.0); decpower(pwClvl); /* Set Dec1 power for hard 13C pulses */ decpwrf(4095.0); dec2power(pwNlvl); /* Set Dec2 power for hard 15N pulses */ dec2pwrf(4095.0); set_c13offset("ca"); /* Presaturation Period */ if (satmode[0] == 'y') { delay(2.0e-5); rgpulse(d1,zero,2.0e-6,2.0e-6); obspower(tpwr); /* Set transmitter power for hard 1H pulses */ delay(2.0e-5); if(fscuba[0] == 'y') { delay(2.2e-2); rgpulse(pw,zero,2.0e-6,0.0); rgpulse(2*pw,one,2.0e-6,0.0); rgpulse(pw,zero,2.0e-6,0.0); delay(2.2e-2); } } else { delay(d1); } obspower(tpwr); /* Set transmitter power for hard 1H pulses */ txphase(three); dec2phase(zero); delay(1.0e-5); /* Begin Pulses */ status(B); rcvroff(); shiftedpulse("sinc", pwHs, 90.0, 0.0, three, 2.0e-6, 2.0e-6); txphase(zero); /* xxxxxxxxxxxxxxxxxxxxxx 1HN to 15N TRANSFER xxxxxxxxxxxxxxxxxx */ rgpulse(pw,zero,0.0,0.0); /* 90 deg 1H pulse */ delay(0.2e-6); zgradpulse(gzlvl1, gt1); delay(2.0e-6); delay(taua - gt1 - 2.2e-6); /* taua <= 1/4JNH */ sim3pulse(2*pw,0.0,2*pwN,zero,zero,zero,0.0,0.0); txphase(one); dec2phase(zero); decphase(zero); delay(taua - gt1 - 200.2e-6 - 2.0e-6); delay(0.2e-6); zgradpulse(gzlvl1, gt1); delay(200.0e-6); /* xxxxxxxxxxxxxxxxxxxxxx 15N to 13CA TRANSFER xxxxxxxxxxxxxxxxxx */ rgpulse(pw,one,2.0e-6,0.0); delay(0.2e-6); zgradpulse(gzlvl2, gt2); delay(200.0e-6); dec2rgpulse(pwN,zero,0.0,0.0); delay(kappa - POWER_DELAY - PWRF_DELAY - pwHd - 4.0e-6 - PRG_START_DELAY); /* delays for h1waltzon subtracted */ h1waltzon("WALTZ16", widthHd, 0.0); decphase(zero); dec2phase(zero); delay(tauc - kappa - WFG3_START_DELAY ); dec2rgpulse(2*pwN,zero,0.0,0.0); c13pulse("ca", "co", "square", 180.0, zero, 0.0, 0.0); dec2phase(zero); delay(tauc - pwS3); dec2rgpulse(pwN,zero,0.0,0.0); h1waltzoff("WALTZ16", widthHd, 0.0); decphase(zero); delay(0.2e-6); zgradpulse(gzlvl3, gt3); delay(200.0e-6); /* xxxxxxxxxxxxxxxxxxxxx 13CA to 13CO TRANSFER xxxxxxxxxxxxxxxxxxxxxxx */ c13pulse("ca", "co", "square", 90.0, zero, 0.0, 0.0); decpower(cbpwr); decphase(zero); decprgon(cbdecseq,1/cbdmf,cbres); decon(); delay(taud - 2*POWER_DELAY - PRG_START_DELAY - PRG_STOP_DELAY - 0.5*10.933*pwC); decoff(); decprgoff(); decpower(pwClvl); /* CHECK if this freq jump is needed */ set_c13offset("co"); /* change Dec1 carrier to Co */ decrgpulse(pwC*158.0/90.0, zero, 0.0, 0.0); decrgpulse(pwC*171.2/90.0, two, 0.0, 0.0); decrgpulse(pwC*342.8/90.0, zero, 0.0, 0.0); /* Shaka 6 composite */ decrgpulse(pwC*145.5/90.0, two, 0.0, 0.0); decrgpulse(pwC*81.2/90.0, zero, 0.0, 0.0); decrgpulse(pwC*85.3/90.0, two, 0.0, 0.0); set_c13offset("ca"); /* change Dec1 carrier to Co */ decpower(cbpwr); decphase(zero); decprgon(cbdecseq,1/cbdmf,cbres); decon(); delay(taud - 2*POWER_DELAY - PRG_STOP_DELAY - PRG_START_DELAY - 0.5*10.933*pwC); decoff(); decprgoff(); decpower(pwClvl); c13pulse("ca", "co", "square", 90.0, one, 0.0, 0.0); set_c13offset("co"); /* change Dec1 carrier to Co */ delay(2.0e-7); zgradpulse(gzlvl4, gt4); delay(100.0e-6); /* xxxxxxxxxxxxxxxx 13CO CHEMICAL SHIFT EVOLUTION xxxxxxxxxxxxxx */ c13pulse("co", "ca", "sinc", 90.0, t7, 0.0, 0.0); if ((ni>1.0) && (tau1>0.0)) { if (tau1-2.0*pwS2/PI-pwN-WFG3_START_DELAY-POWER_DELAY-2.0e-6 > 0.0) { delay(tau1-2.0*pwS2/PI-pwN-WFG3_START_DELAY-POWER_DELAY-2.0e-6); sim3_c13pulse("", "ca", "co", "square", "", 0.0, 180.0, 2.0*pwN, zero, zero, zero, 2.0e-6, 2.0e-6); initval(1.0,v3); decstepsize(sphase); dcplrphase(v3); delay(tau1-2.0*pwS2/PI-SAPS_DELAY-pwN-WFG3_STOP_DELAY-POWER_DELAY-2.0e-6); } else { delay(2.0*tau1); delay(10.0e-6); c13pulse("co", "ca", "sinc", 180.0, zero, 0.0, 0.0); delay (10.0e-6); } } else { c13pulse("co", "ca", "sinc", 180.0, zero, 0.0, 0.0); } c13pulse("co", "ca", "sinc", 90.0, zero, 4.0e-6, 0.0); dcplrphase(zero); set_c13offset("ca"); /* set carrier to Ca */ decphase(t4); delay(2.0e-7); zgradpulse(gzlvl9, gt9); delay(100.0e-6); /* xxxxxxxxxxxxxx 13CO to 13CA TRANSFER and 13CA EVOLUTION xxxxxxxxxxxxxxxx */ c13pulse("ca", "co", "square", 90.0, t4, 2.0e-6, 0.0); decpower(cbpwr); decphase(zero); decprgon(cbdecseq,1/cbdmf,cbres); decon(); delay(bigTC - tau2 - 3*POWER_DELAY - 4.0e-6 - WFG3_START_DELAY - pwS4 - WFG3_STOP_DELAY - PRG_START_DELAY - PRG_STOP_DELAY - pwS3/2 - 4.0e-6); decoff(); decprgoff(); decpower(pwClvl); c13pulse("co", "ca", "sinc", 180.0, zero, 4.0e-6, 0.0); decphase(t5); c13pulse("ca", "co", "square", 180.0, t5, 4.0e-6, 0.0); decpower(cbpwr); decphase(zero); decprgon(cbdecseq,1/cbdmf,cbres); decon(); delay(bigTC -3*POWER_DELAY - 6.0e-6 -pwS3/2 - 2*pwN - WFG_START_DELAY- pwS4- WFG_STOP_DELAY - PRG_START_DELAY - PRG_STOP_DELAY - pwS1/2); dec2rgpulse(2*pwN,zero,0.0,0.0); delay(tau2); decoff(); decprgoff(); decpower(pwClvl); c13pulse("co", "ca", "sinc", 180.0, zero, 4.0e-6, 0.0); decphase(one); c13pulse("ca", "co", "square", 90.0, one, 2.0e-6, 0.0); txphase(zero); delay(2.0e-7); zgradpulse(gzlvl11, gt11); delay(100.0e-6); /* Constant 15N period */ h1waltzon("WALTZ16", widthHd, 0.0); dec2rgpulse(pwN,t1,2.0e-6,0.0); dec2phase(t2); delay(bigTN - tau3 + pwS3); dec2rgpulse(2*pwN,t2,0.0,0.0); c13pulse("ca", "co", "square", 180.0, zero, 2.0e-6, 0.0); dec2phase(t3); txphase(zero); if (tau3 > (kappa + PRG_STOP_DELAY + pwHd + 2.0e-6)) { delay(bigTN - pwS4 - WFG_START_DELAY - 2.0*POWER_DELAY - 2.0*PWRF_DELAY - 2.0e-6); c13pulse("co", "ca", "sinc", 180.0, zero, 0.0, 0.0); delay(tau3 - kappa - PRG_STOP_DELAY - pwHd - 2.0e-6 - POWER_DELAY - PWRF_DELAY); h1waltzoff("WALTZ16", widthHd, 0.0); delay(kappa - gt5 - 2.0*GRADIENT_DELAY - 1.0e-4); zgradpulse(gzlvl5, gt5); delay(1.0e-4); } else if (tau3 > (kappa - pwS4 - WFG_START_DELAY - 2.0*POWER_DELAY - 2.0*PWRF_DELAY - 2.0e-6)) { delay(bigTN + tau3 - kappa - PRG_STOP_DELAY - pwHd - 2.0e-6 - POWER_DELAY - PWRF_DELAY); h1waltzoff("WALTZ16", widthHd, 0.0); c13pulse("co", "ca", "sinc", 180.0, zero, 0.0, 0.0); delay(kappa - pwS4 - WFG_START_DELAY - 2.0*POWER_DELAY - 2.0*PWRF_DELAY - 2.0e-6 - gt5 - 2.0*GRADIENT_DELAY - 1.0e-4); zgradpulse(gzlvl5, gt5); delay(1.0e-4); } else if (tau3 > gt5 + 2.0*GRADIENT_DELAY + 1.0e-4) { delay(bigTN + tau3 - kappa - PRG_STOP_DELAY - pwHd - 2.0e-6 - POWER_DELAY - PWRF_DELAY); h1waltzoff("WALTZ16", widthHd, 0.0); delay(kappa - tau3 - pwS4 - WFG_START_DELAY - 2.0*POWER_DELAY - 2.0*PWRF_DELAY - 2.0e-6); c13pulse("co", "ca", "sinc", 180.0, zero, 0.0, 0.0); delay(tau3 - gt5 - 2.0*GRADIENT_DELAY - 1.0e-4); zgradpulse(gzlvl5, gt5); delay(1.0e-4); } else { delay(bigTN + tau3 - kappa - PRG_STOP_DELAY - pwHd - 2.0e-6 - POWER_DELAY - PWRF_DELAY); h1waltzoff("WALTZ16", widthHd, 0.0); delay(kappa - tau3 - pwS4 - WFG_START_DELAY - 2.0*POWER_DELAY - 2.0*PWRF_DELAY - 2.0e-6 - gt5 - 2.0*GRADIENT_DELAY - 1.0e-4); zgradpulse(gzlvl5, gt5); /* 2.0*GRADIENT_DELAY */ delay(1.0e-4); c13pulse("co", "ca", "sinc", 180.0, zero, 0.0, 0.0); delay(tau3); } sim3pulse(pw,0.0,pwN,zero,zero,t3,0.0,0.0); delay(0.2e-6); zgradpulse(gzlvl6, gt6); delay(2.0e-6); dec2phase(zero); delay(taub - gt6 - 2.2e-6); sim3pulse(2*pw,0.0,2*pwN,zero,zero,zero,0.0,0.0); delay(0.2e-6); zgradpulse(gzlvl6, gt6); delay(200.0e-6); delay(taub - gt6 - 200.2e-6); txphase(one); dec2phase(one); sim3pulse(pw,0.0,pwN,one,zero,one,0.0,0.0); delay(0.2e-6); zgradpulse(gzlvl7, gt7); delay(2.0e-6); txphase(zero); dec2phase(zero); delay(taub - gt7 - 2.2e-6); sim3pulse(2*pw,0.0,2*pwN,zero,zero,zero,0.0,0.0); delay(0.2e-6); zgradpulse(gzlvl7, gt7); delay(200.0e-6); delay(taub - gt7 - 200.2e-6); rgpulse(pw, zero, 0.0, 0.0); delay(gt8 + 1.0e-4 + 50.2e-6 - 0.3*pw + 2.0*GRADIENT_DELAY + POWER_DELAY); rgpulse(2*pw,zero,0.0,0.0); dec2power(dpwr2); decpower(dpwr); zgradpulse(icosel*gzlvl8, gt8); delay(50.2e-6); /* rcvron(); */ /* Turn on receiver to warm up before acq */ /* BEGIN ACQUISITION */ status(C); setreceiver(t6); }
pulsesequence() { /* DECLARE AND LOAD VARIABLES; parameters used in the last half of the */ /* sequence are declared and initialized as 0.0 in bionmr.h, and */ /* reinitialized below */ char f1180[MAXSTR], /* Flag to start t1 @ halfdwell */ f2180[MAXSTR], /* Flag to start t2 @ halfdwell */ COrefoc[MAXSTR], TROSY[MAXSTR]; /* do TROSY on N15 and H1 */ int t1_counter, /* used for states tppi in t1 */ t2_counter, /* used for states tppi in t2 */ ni2 = getval("ni2"); double d2_init=0.0, /* used for states tppi in t1 */ d3_init=0.0, /* used for states tppi in t2 */ tau1, /* t1 delay */ timeTN = getval("timeTN"), /* constant time for 15N evolution */ timeNCA = getval("timeNCA"), timeC = getval("timeC"), lambda = 1.0/(4.0*getval("JNH")), pwClvl = getval("pwClvl"), /* coarse power for C13 pulse */ pwC = getval("pwC"), /* C13 90 degree pulse length at pwClvl */ pwS1, /* length of square 90 on Ca */ phshift, /* phase shift induced on Ca by 180 on CO in middle of t1 */ pwS2, /* length of 180 on CO */ pwS = getval("pwS"), /* used to change 180 on CO in t1 for 1D calibrations */ pwZ, /* the largest of pwS2 and 2.0*pwN */ pwZ1, /* the largest of pwS2 and 2.0*pwN for 1D experiments */ pwNlvl = getval("pwNlvl"), /* power for N15 pulses */ pwN = getval("pwN"), /* N15 90 degree pulse length at pwNlvl */ sw1 = getval("sw1"), sw2 = getval("sw2"), gt0 = getval("gt0"), /* other gradients */ gt3 = getval("gt3"), gzlvl0 = getval("gzlvl0"), gzlvl3 = getval("gzlvl3"); getstr("f1180",f1180); getstr("f2180",f2180); getstr("COrefoc",COrefoc); getstr("TROSY",TROSY); /* LOAD PHASE TABLE */ settable(t3,2,phi3); settable(t4,1,phx); settable(t5,4,phi5); if (TROSY[A]=='y') {settable(t8,1,phy); settable(t9,1,phx); settable(t10,1,phy); settable(t11,1,phx); settable(t12,4,recT);} else {settable(t8,1,phx); settable(t9,8,phi9); settable(t10,1,phx); settable(t11,1,phy); settable(t12,4,rec);} /* INITIALIZE VARIABLES */ kappa = 5.4e-3; pwHs = 1.7e-3*500.0/sfrq; /* length of H2O flipback, 1.7ms at 500 MHz*/ widthHd = 34.0; /* bandwidth of H1 WALTZ16 decoupling, 7.3 kHz at 600 MHz */ pwHd = h1dec90pw("WALTZ16", widthHd, 0.0); /* H1 90 length for WALTZ16 */ /* get calculated pulse lengths of shaped C13 pulses */ pwS1 = c13pulsepw("co", "ca", "sinc", 90.0); pwS2 = c13pulsepw("ca", "co", "square", 180.0); /* get calculated pulse lengths of shaped C13 pulses pwS1 = c13pulsepw("ca", "co", "square", 90.0); pwS2 = c13pulsepw("co", "ca", "sinc", 180.0); */ /* the 180 pulse on CO at the middle of t1 */ if ((ni2 > 0.0) && (ni == 1.0)) ni = 0.0; if (pwS2 > 2.0*pwN) pwZ = pwS2; else pwZ = 2.0*pwN; if ((pwS==0.0) && (pwS2>2.0*pwN)) pwZ1=pwS2-2.0*pwN; else pwZ1=0.0; if ( ni > 1 ) pwS = 180.0; if ( pwS > 0 ) phshift = 130.0; else phshift = 130.0; /* CHECK VALIDITY OF PARAMETER RANGES */ if ( 0.5*ni2*1/(sw2) > timeTN - WFG3_START_DELAY) { printf(" ni2 is too big. Make ni2 equal to %d or less.\n", ((int)((timeTN - WFG3_START_DELAY)*2.0*sw2))); psg_abort(1);} if ( dm[A] == 'y' || dm[B] == 'y' || dm[C] == 'y' ) { printf("incorrect dec1 decoupler flags! Should be 'nnn' "); psg_abort(1);} if ( dm2[A] == 'y' || dm2[B] == 'y' ) { printf("incorrect dec2 decoupler flags! Should be 'nny' "); psg_abort(1);} if ( dm3[A] == 'y' || dm3[C] == 'y' ) { printf("incorrect dec3 decoupler flags! Should be 'nyn' or 'nnn' "); psg_abort(1);} if ( dpwr2 > 46 ) { printf("dpwr2 too large! recheck value "); psg_abort(1);} if ( pw > 20.0e-6 ) { printf(" pw too long ! recheck value "); psg_abort(1);} if ( pwN > 100.0e-6 ) { printf(" pwN too long! recheck value "); psg_abort(1);} if ( TROSY[A]=='y' && dm2[C] == 'y') { text_error("Choose either TROSY='n' or dm2='n' ! "); psg_abort(1);} /* PHASES AND INCREMENTED TIMES */ /* Phase incrementation for hypercomplex 2D data, States-Haberkorn element */ if (phase1 == 2) tsadd(t3,1,4); if (TROSY[A]=='y') { if (phase2 == 2) icosel = +1; else {tsadd(t4,2,4); tsadd(t10,2,4); icosel = -1;} } else { if (phase2 == 2) {tsadd(t10,2,4); icosel = +1;} else icosel = -1; } /* Set up f1180 */ tau1 = d2; if((f1180[A] == 'y') && (ni > 1.0)) { tau1 += ( 1.0 / (2.0*sw1) ); if(tau1 < 0.2e-6) tau1 = 0.0; } tau1 = tau1/2.0; /* Set up f2180 */ tau2 = d3; if((f2180[A] == 'y') && (ni2 > 1.0)) { tau2 += ( 1.0 / (2.0*sw2) ); if(tau2 < 0.2e-6) tau2 = 0.0; } tau2 = tau2/2.0; /* Calculate modifications to phases for States-TPPI acquisition */ if( ix == 1) d2_init = d2; t1_counter = (int) ( (d2-d2_init)*sw1 + 0.5 ); if(t1_counter % 2) { tsadd(t3,2,4); tsadd(t12,2,4); } if( ix == 1) d3_init = d3; t2_counter = (int) ( (d3-d3_init)*sw2 + 0.5 ); if(t2_counter % 2) { tsadd(t8,2,4); tsadd(t12,2,4); } /* BEGIN PULSE SEQUENCE */ status(A); delay(d1); if (dm3[B]=='y') lk_hold(); rcvroff(); set_c13offset("co"); obsoffset(tof); obspower(tpwr); obspwrf(4095.0); decpower(pwClvl); decpwrf(4095.0); dec2power(pwNlvl); txphase(zero); delay(1.0e-5); dec2rgpulse(pwN, zero, 0.0, 0.0); /*destroy N15 and C13 magnetization*/ decrgpulse(pwC, zero, 0.0, 0.0); zgradpulse(gzlvl0, 0.5e-3); delay(1.0e-4); dec2rgpulse(pwN, one, 0.0, 0.0); decrgpulse(pwC, zero, 0.0, 0.0); zgradpulse(0.7*gzlvl0, 0.5e-3); delay(5.0e-4); rgpulse(pw,zero,0.0,0.0); /* 1H pulse excitation */ dec2phase(zero); zgradpulse(gzlvl0, gt0); delay(lambda - gt0); sim3pulse(2.0*pw, 0.0, 2.0*pwN, zero, zero, zero, 0.0, 0.0); txphase(one); zgradpulse(gzlvl0, gt0); delay(lambda - gt0); rgpulse(pw, one, 0.0, 0.0); if (TROSY[A]=='y') {txphase(two); shiftedpulse("sinc", pwHs, 90.0, 0.0, two, 2.0e-6, 0.0); zgradpulse(gzlvl3, gt3); delay(2.0e-4); dec2rgpulse(pwN, zero, 0.0, 0.0); delay(0.5*kappa - 2.0*pw); rgpulse(2.0*pw, two, 0.0, 0.0); decphase(zero); dec2phase(zero); delay(timeTN - 0.5*kappa - WFG3_START_DELAY); } else {txphase(zero); shiftedpulse("sinc", pwHs, 90.0, 0.0, zero, 2.0e-6, 0.0); zgradpulse(gzlvl3, gt3); delay(2.0e-4); dec2rgpulse(pwN, zero, 0.0, 0.0); delay(kappa - POWER_DELAY - PWRF_DELAY - pwHd - 4.0e-6 - PRG_START_DELAY); /* delays for h1waltzon subtracted */ h1waltzon("WALTZ16", widthHd, 0.0); decphase(zero); dec2phase(zero); delay(timeTN - kappa - WFG3_START_DELAY); } c13pulse("co", "ca", "sinc", 180.0, zero, 0.0, 0.0); /* pwS2 */ delay(timeNCA - timeTN - timeC); dec2rgpulse(2.0*pwN,zero,0.0,0.0); c13pulse("ca", "co", "sinc", 180.0, zero, 0.0, 0.0); decphase(zero); delay(timeNCA - timeC + 1.3*pwN); c13pulse("co", "ca", "sinc", 90.0, zero, 0.0, 0.0); /* pwS1 */ delay(timeC); c13pulse("ca", "co", "square", 180.0, zero, 2.0e-6, 2.0e-6); sim3_c13pulse("", "co", "ca", "sinc", "", 0.0, 180.0, 2.0*pwN, zero, zero, zero, 0.0, 0.0); /* pwS2 */ delay(timeC); c13pulse("ca", "co", "square", 180.0, zero, 2.0e-6, 2.0e-6); c13pulse("co", "ca", "sinc", 90.0, one, 0.0, 0.0); /* pwS1 */ dec2rgpulse(pwN, zero, 0.0, 0.0); if (TROSY[A]=='n') h1waltzoff("WALTZ16", widthHd, 0.0); zgradpulse(gzlvl3, gt3); delay(2.0e-4); if(dm3[B] == 'y') /*optional 2H decoupling on */ {dec3unblank(); dec3rgpulse(1/dmf3, one, 0.0, 0.0); dec3unblank(); setstatus(DEC3ch, TRUE, 'w', FALSE, dmf3);} h1waltzon("WALTZ16", widthHd, 0.0); /* xxxxxxxxxxxxxxxxxxxxxx 13Ca EVOLUTION xxxxxxxxxxxxxxxxxx */ set_c13offset("ca"); c13pulse("ca", "co", "square", 90.0, t3, 2.0e-6, 0.0); /* pwS1 */ decphase(zero); if ((ni>1.0) && (tau1>0.0)) /* total 13C evolution equals d2 exactly */ { /* 2.0*pwS1/PI compensates for evolution at 64% rate during 90 */ if (tau1 - 2.0*pwS1/PI - WFG3_START_DELAY - 0.5*pwZ - 2.0e-6 - 2.0*PWRF_DELAY - 2.0*POWER_DELAY > 0.0) { delay(tau1 - 2.0*pwS1/PI - WFG3_START_DELAY - 0.5*pwZ - 2.0e-6 - 2.0*PWRF_DELAY - 2.0*POWER_DELAY); sim3_c13pulse("", "co", "ca", "sinc", "", 0.0, 180.0, 2.0*pwN,zero, zero, zero, 2.0e-6, 0.0); initval(phshift, v3); decstepsize(1.0); dcplrphase(v3); delay(tau1 - 2.0*pwS1/PI - SAPS_DELAY - 0.5*pwZ - WFG_START_DELAY - 2.0e-6 - 2.0*PWRF_DELAY - 2.0*POWER_DELAY); } else { initval(180.0, v3); decstepsize(1.0); dcplrphase(v3); delay(2.0*tau1 - 4.0*pwS1/PI - SAPS_DELAY - WFG_START_DELAY - 2.0e-6 - PWRF_DELAY - POWER_DELAY); } /* delay(tau1); sim3_c13pulse("", "co", "ca", "sinc", "", 0.0, 180.0, 2.0*pwN,zero, zero, zero, 2.0e-6, 0.0); delay(tau1); c13pulse("ca", "co", "square", 180.0, zero, 2.0e-6, 0.0); sim3_c13pulse("", "co", "ca", "sinc", "", 0.0, 180.0, 2.0*pwN,zero, zero, zero, 2.0e-6, 0.0);*/ } else if (ni==1.0) { delay(10.0e-6 + SAPS_DELAY + 0.5*pwZ1 + WFG_START_DELAY); sim3_c13pulse("", "co", "ca", "sinc", "", 0.0, pwS, 2.0*pwN, zero, zero, zero, 2.0e-6, 0.0); initval(phshift, v3); decstepsize(1.0); dcplrphase(v3); delay(10.0e-6 + WFG3_START_DELAY + 0.5*pwZ1); } else { delay(10.0e-6); c13pulse("ca", "co", "square", 180.0, zero, 2.0e-6, 0.0); delay(10.0e-6); /* delay(tau1); sim3_c13pulse("", "co", "ca", "sinc", "", 0.0, 180.0, 2.0*pwN,zero, zero, zero, 2.0e-6, 0.0); delay(tau1); c13pulse("ca", "co", "square", 180.0, zero, 2.0e-6, 0.0); sim3_c13pulse("", "co", "ca", "sinc", "", 0.0, 180.0, 2.0*pwN,zero, zero, zero, 2.0e-6, 0.0); */ } decphase(t5); c13pulse("ca", "co", "square", 90.0, t5, 2.0e-6, 0.0); /* pwS1 */ h1waltzoff("WALTZ16", widthHd, 0.0); if(dm3[B] == 'y') /*optional 2H decoupling off */ {dec3rgpulse(1/dmf3, three, 0.0, 0.0); dec3blank(); setstatus(DEC3ch, FALSE, 'w', FALSE, dmf3); dec3blank();} set_c13offset("co"); /* xxxxxxxxxxxxxxxxxxxx N15 EVOLUTION & SE TRAIN xxxxxxxxxxxxxxxxxxxxxxx */ ihn_evol_se_train("co", "ca"); /* common part of sequence in bionmr.h */ if (dm3[B] == 'y') lk_sample(); }
pulsesequence() { char sel_flg[MAXSTR], autocal[MAXSTR], glyshp[MAXSTR]; int icosel, t1_counter, ni = getval("ni"); double d2_init=0.0, tau1, tau2, tau3, glypwr,glypwrf, /* Power levels for Cgly selective 90 */ pwgly, /* Pulse width for Cgly selective 90 */ waltzB1 = getval("waltzB1"), /* 1H decoupling strength (in Hz) */ timeTN = getval("timeTN"), /* constant time for 15N evolution */ tauCaCb = getval("tauCaCb"), tauNCa = getval("tauNCa"), tauNCo = getval("tauNCo"), tauCaCo = getval("tauCaCo"), compH = getval("compH"), /* adjustment for H1 amplifier compression */ tpwrs, /* power for the pwHs ("H2Osinc") pulse */ bw,ppm, pwClvl = getval("pwClvl"), /* coarse power for C13 pulse */ compC = getval("compC"), /* amplifier compression for C13 pulse */ pwC = getval("pwC"), /* C13 90 degree pulse length at pwClvl */ pwNlvl = getval("pwNlvl"), /* power for N15 pulses */ pwN = getval("pwN"), /* N15 90 degree pulse length at pwNlvl */ dpwr2 = getval("dpwr2"), /* power for N15 decoupling */ pwCa90, /* length of square 90 on Ca */ pwCa180, pwCab90, pwCab180, phshift, /* phase shift induced on Ca by 180 on CO in middle of t1 */ pwCO180, /* length of 180 on CO */ pwS = getval("pwS"), /* used to change 180 on CO in t1 for 1D calibrations */ pwZ, /* the largest of pwCO180 and 2.0*pwN */ pwZ1, /* the largest of pwCO180 and 2.0*pwN for 1D experiments */ sw1 = getval("sw1"), swCb = getval("swCb"), swCa = getval("swCa"), swN = getval("swN"), swTilt, /* This is the sweep width of the tilt vector */ cos_N, cos_Ca, cos_Cb, angle_N, angle_Ca, angle_Cb, /* angle_N is calculated automatically */ gstab = getval("gstab"), gt0 = getval("gt0"), gzlvl0 = getval("gzlvl0"), gt1 = getval("gt1"), gzlvl1 = getval("gzlvl1"), gzlvl2 = getval("gzlvl2"), gt3 = getval("gt3"), gzlvl3 = getval("gzlvl3"), gt4 = getval("gt4"), gzlvl4 = getval("gzlvl4"), gt5 = getval("gt5"), gzlvl5 = getval("gzlvl5"), gt6 = getval("gt6"), gzlvl6 = getval("gzlvl6"), gt7 = getval("gt7"), gzlvl7 = getval("gzlvl7"), gt10= getval("gt10"), gzlvl10= getval("gzlvl10"), gt11= getval("gt11"), gzlvl11= getval("gzlvl11"), gt12= getval("gt12"), gzlvl12= getval("gzlvl12"); angle_N = 0; glypwr = getval("glypwr"); pwgly = getval("pwgly"); tau1 = 0; tau2 = 0; tau3 = 0; cos_N = 0; cos_Cb = 0; cos_Ca = 0; getstr("autocal", autocal); getstr("glyshp", glyshp); getstr("sel_flg",sel_flg); pwHs = getval("pwHs"); /* H1 90 degree pulse length at tpwrs */ /* LOAD PHASE TABLE */ settable(t2,1,phy); settable(t3,2,phi3); settable(t4,1,phx); settable(t5,4,phi5); settable(t8,1,phy); settable(t9,8,phi9); settable(t10,1,phx); settable(t11,1,phy); settable(t12,4,rec); /* INITIALIZE VARIABLES */ kappa = 5.4e-3; lambda = 2.4e-3; /* selective H20 one-lobe sinc pulse */ tpwrs = tpwr - 20.0*log10(pwHs/(compH*pw*1.69)); /*needs 1.69 times more*/ tpwrs = (int) (tpwrs); /*power than a square pulse */ pwHs = 1.7e-3*500.0/sfrq; widthHd = 2.861*(waltzB1/sfrq); /* bandwidth of H1 WALTZ16 decoupling in ppm */ pwHd = h1dec90pw("WALTZ16", widthHd, 0.0); /* H1 90 length for WALTZ16 */ /* get calculated pulse lengths of shaped C13 pulses */ pwCa90 = c13pulsepw("ca", "co", "square", 90.0); pwCa180 = c13pulsepw("ca", "co", "square", 180.0); pwCO180 = c13pulsepw("co", "cab", "sinc", 180.0); pwCab90 = c13pulsepw("cab","co", "square", 90.0); pwCab180= c13pulsepw("cab","co", "square", 180.0); /* the 180 pulse on CO at the middle of t1 */ if (pwCO180 > 2.0*pwN) pwZ = pwCO180; else pwZ = 2.0*pwN; if ((pwS==0.0) && (pwCO180>2.0*pwN)) pwZ1=pwCO180-2.0*pwN; else pwZ1=0.0; if ( ni > 1 ) pwS = 180.0; if ( pwS > 0 ) phshift = 320.0; else phshift = 0.0; /* CHECK VALIDITY OF PARAMETER RANGES */ if ( dm[A] == 'y' || dm[B] == 'y' || dm[C] == 'y' ) { printf("incorrect dec1 decoupler flags! Should be 'nnn' "); psg_abort(1);} if ( dm2[A] == 'y' || dm2[B] == 'y' ) { printf("incorrect dec2 decoupler flags! Should be 'nny' "); psg_abort(1);} if ( dm3[A] == 'y' || dm3[C] == 'y' ) { printf("incorrect dec3 decoupler flags! Should be 'nyn' or 'nnn' "); psg_abort(1);} if ( dpwr2 > 46 ) { printf("dpwr2 too large! recheck value "); psg_abort(1);} if ( pw > 20.0e-6 ) { printf(" pw too long ! recheck value "); psg_abort(1);} if ( pwN > 100.0e-6 ) { printf(" pwN too long! recheck value "); psg_abort(1);} /* PHASES AND INCREMENTED TIMES */ /* Set up angles and phases */ angle_Cb=getval("angle_Cb"); cos_Cb=cos(PI*angle_Cb/180.0); angle_Ca=getval("angle_Ca"); cos_Ca=cos(PI*angle_Ca/180.0); if ( (angle_Cb < 0) || (angle_Cb > 90) ) { printf ("angle_Cb must be between 0 and 90 degree.\n"); psg_abort(1); } if ( (angle_Ca < 0) || (angle_Ca > 90) ) { printf ("angle_Ca must be between 0 and 90 degree.\n"); psg_abort(1); } if ( 1.0 < (cos_Cb*cos_Cb + cos_Ca*cos_Ca) ) { printf ("Impossible angles.\n"); psg_abort(1); } else { cos_N=sqrt(1.0- (cos_Cb*cos_Cb + cos_Ca*cos_Ca)); angle_N = 180.0*acos(cos_N)/PI; } swTilt=swCb*cos_Cb + swCa*cos_Ca + swN*cos_N; if (ix ==1) { printf("\n\nn\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n"); printf ("Maximum Sweep Width: \t\t %f Hz\n", swTilt); printf ("Angle_Cb:\t%6.2f\n", angle_Cb); printf ("Angle_Ca:\t%6.2f\n", angle_Ca); printf ("Angle_N :\t%6.2f\n", angle_N ); } /* Set up hyper complex */ /* sw1 is used as symbolic index */ if ( sw1 < 1000 ) { printf ("Please set sw1 to some value larger than 1000.\n"); psg_abort(1); } if (ix == 1) d2_init = d2; t1_counter = (int) ( (d2-d2_init)*sw1 + 0.5 ); if (t1_counter % 2) { tsadd(t8,2,4); tsadd(t12,2,4); } if (phase1 == 1) { ;} /* CC */ else if (phase1 == 2) { tsadd(t3,3,4); tsadd(t2,3,4);} /* SC */ else if (phase1 == 3) { tsadd(t5,1,4); } /* CS */ else if (phase1 == 4) { tsadd(t3,3,4); tsadd(t2,3,4); tsadd(t5,1,4);} /* SS */ else { printf ("phase1 can only be 1,2,3,4. \n"); psg_abort(1); } if (phase2 == 2) { tsadd(t10,2,4); icosel = +1; } /* N */ else icosel = -1; tau1 = 1.0*t1_counter*cos_Cb/swTilt; tau2 = 1.0*t1_counter*cos_Ca/swTilt; tau3 = 1.0*t1_counter*cos_N/swTilt; tau1 = tau1/2.0; tau2 = tau2/2.0; tau3 = tau3/2.0; /* CHECK VALIDITY OF PARAMETER RANGES */ if (0.5*ni*(cos_N/swTilt) > timeTN - WFG3_START_DELAY) { printf(" ni is too big. Make ni equal to %d or less.\n", ((int)((timeTN - WFG3_START_DELAY)*2.0*swTilt/cos_N))); psg_abort(1);} /* BEGIN PULSE SEQUENCE */ status(A); delay(d1); if ( dm3[B] == 'y' ) lk_hold(); rcvroff(); obsoffset(tof); obspower(tpwr); obspwrf(4095.0); set_c13offset("cab"); decpower(pwClvl); decpwrf(4095.0); dec2power(pwNlvl); txphase(zero); delay(1.0e-5); decrgpulse(pwC, zero, 0.0, 0.0); zgradpulse(gzlvl0, gt0); delay(gstab); decrgpulse(pwC, one, 0.0, 0.0); zgradpulse(0.7*gzlvl0, gt0); delay(gstab); txphase(one); delay(1.0e-5); shiftedpulse("sinc", pwHs, 90.0, 0.0, one, 2.0e-6, 0.0); txphase(zero); decphase(zero); dec2phase(zero); delay(2.0e-6); /* pulse sequence starts */ rgpulse(pw,zero,0.0,0.0); /* 1H pulse excitation */ dec2phase(zero); zgradpulse(gzlvl3, gt3); delay(lambda - gt3); sim3pulse(2.0*pw, 0.0, 2.0*pwN, zero, zero, zero, 0.0, 0.0); if (sel_flg[A] == 'n') txphase(three); else txphase(one); zgradpulse(gzlvl3, gt3); delay(lambda - gt3); if (sel_flg[A] == 'n') { rgpulse(pw, three, 0.0, 0.0); txphase(zero); zgradpulse(gzlvl4, gt4); /* Crush gradient G4 */ delay(gstab); /* Begin of N to Ca transfer */ dec2rgpulse(pwN, one, 0.0, 0.0); decphase(zero); dec2phase(zero); delay(tauNCo - pwCO180/2 - 2.0e-6 - WFG3_START_DELAY); } else /* active suppresion */ { rgpulse(pw,one,2.0e-6,0.0); initval(1.0,v6); dec2stepsize(45.0); dcplr2phase(v6); zgradpulse(gzlvl4, gt4); /* Crush gradient G4 */ delay(gstab); /* Begin of N to Ca transfer */ dec2rgpulse(pwN,one,0.0,0.0); dcplr2phase(zero); /* SAPS_DELAY */ delay(1.34e-3 - SAPS_DELAY - 2.0*pw); rgpulse(pw,one,0.0,0.0); rgpulse(2.0*pw,zero,0.0,0.0); rgpulse(pw,one,0.0,0.0); delay(tauNCo - pwCO180/2 - 1.34e-3 - 2.0*pw - WFG3_START_DELAY); } /* Begin transfer from HzNz to N(i)zC'(i-1)zCa(i)zCa(i-1)z */ c13pulse("co", "cab", "sinc", 180.0, zero, 2.0e-6, 0.0); delay(tauNCa - tauNCo - pwCO180/2 - WFG3_START_DELAY - WFG3_STOP_DELAY - 2.0e-6); /* WFG3_START_DELAY */ sim3_c13pulse("", "cab", "co", "square", "", 0.0, 180.0, 2.0*pwN, zero, zero, zero, 2.0e-6, 2.0e-6); delay(tauNCa - 2.0e-6 - WFG3_STOP_DELAY); dec2rgpulse(pwN, zero, 0.0, 0.0); /* End transfer from HzNz to N(i)zC'(i-1)zCa(i)zCa(i-1)z */ zgradpulse(gzlvl5, gt5); delay(gstab); /* Begin removal of Ca(i-1) */ c13pulse("co", "cab", "sinc", 90.0, zero, 2.0e-6, 2.0e-6); zgradpulse(gzlvl6, gt6); delay(tauCaCo - gt6 - pwCab180 - pwCO180/2 - 6.0e-6); c13pulse("cab","co", "square", 180.0, zero, 2.0e-6, 2.0e-6); c13pulse("co","cab", "sinc", 180.0, zero, 2.0e-6, 2.0e-6); zgradpulse(gzlvl6, gt6); delay(tauCaCo - gt6 - pwCab180 - pwCO180/2 - 6.0e-6); c13pulse("cab","co", "square", 180.0, zero, 2.0e-6, 2.0e-6); c13pulse("co", "cab", "sinc", 90.0, one, 2.0e-6, 2.0e-6); /* End removal of Ca(i-1) */ /* xx Selective glycine pulse xx */ set_c13offset("gly"); setautocal(); if (autocal[A] == 'y') { if(FIRST_FID) { ppm = getval("dfrq"); bw=9*ppm; gly90 = pbox_make("gly90","eburp1",bw,0.0,compC*pwC,pwClvl); /* Gly selective 90 with null at 50ppm */ } pwgly=gly90.pw; glypwr=gly90.pwr; glypwrf=gly90.pwrf; decpwrf(glypwrf); decpower(glypwr); decshaped_pulse("gly90",pwgly,zero,2.0e-6,0.0); } else { decpwrf(4095.0); decpower(glypwr); decshaped_pulse(glyshp,pwgly,zero,2.0e-6,0.0); } /* xx End of glycine selecton xx */ zgradpulse(gzlvl7, gt7); set_c13offset("cab"); delay(gstab); decphase(t3); if ( dm3[B] == 'y' ) /* begins optional 2H decoupling */ { dec3unblank(); dec3rgpulse(1/dmf3,one,10.0e-6,2.0e-6); dec3unblank(); dec3phase(zero); delay(2.0e-6); setstatus(DEC3ch, TRUE, 'w', FALSE, dmf3); } /* ========== Ca to Cb transfer =========== */ c13pulse("cab", "co", "square", 90.0, t3, 2.0e-6, 2.0e-6); decphase(zero); delay(tauCaCb - 4.0e-6); c13pulse("cab", "co", "square", 180.0, zero, 2.0e-6, 2.0e-6); decphase(t2); delay(tauCaCb - 4.0e-6 ); /* xxxxxxxxxxxxxxxxxxxxxx 13Cb EVOLUTION xxxxxxxxxxxxxxxxxx */ c13pulse("cab", "co", "square", 90.0, t2, 2.0e-6, 0.0); /* pwCa90 */ decphase(zero); if ((ni>1.0) && (tau1>0.0)) { if (tau1 - 2.0*pwCab90/PI - WFG_START_DELAY - pwN - 2.0e-6 - PWRF_DELAY - POWER_DELAY > 0.0) { delay(tau1 - 2.0*pwCab90/PI - pwN - 2.0e-6 ); dec2rgpulse(2.0*pwN, zero, 2.0e-6, 0.0); delay(tau1 - 2.0*pwCab90/PI - pwN - WFG_START_DELAY - 2.0e-6 - PWRF_DELAY - POWER_DELAY); } else { tsadd(t12,2,4); delay(2.0*tau1); delay(10.0e-6); /* WFG_START_DELAY */ sim3_c13pulse("", "cab", "co", "square", "", 0.0, 180.0, 2.0*pwN, zero, zero, zero, 2.0e-6, 0.0); delay(10.0e-6); } } else { tsadd(t12,2,4); delay(10.0e-6); /* WFG_START_DELAY */ sim3_c13pulse("", "cab", "co", "square", "", 0.0, 180.0, 2.0*pwN, zero, zero, zero, 2.0e-6, 0.0); delay(10.0e-6); } decphase(one); c13pulse("cab", "co", "square", 90.0, one, 2.0e-6, 0.0); /* pwCa90 */ /* xxxxxxxxxxx End of 13Cb EVOLUTION - Start 13Ca EVOLUTION xxxxxxxxxxxx */ decphase(zero); delay(tau2); sim3_c13pulse("", "co", "cab", "sinc", "", 0.0, 180.0, 2.0*pwN, zero, zero, zero, 2.0e-6, 0.0); decphase(zero); delay(tauCaCb - 2*pwN - pwCab180/2 - WFG2_START_DELAY - 2.0*PWRF_DELAY - 2.0*POWER_DELAY - WFG2_STOP_DELAY - 4.0e-6 ); c13pulse("cab", "co", "square", 180.0, zero, 2.0e-6, 0.0); delay(tauCaCb- tau2 - pwCO180 - pwCab180/2 - WFG2_START_DELAY - 2.0*PWRF_DELAY -2.0*POWER_DELAY - WFG2_STOP_DELAY - 4.0e-6); c13pulse("co", "cab", "sinc", 180.0, zero, 2.0e-6, 0.0); decphase(t5); c13pulse("cab", "co", "square", 90.0, t5, 2.0e-6, 0.0); /* xxxxxxxxxxxxxxxxxxx End of 13Ca EVOLUTION xxxxxxxxxxxxxxxxxx */ if ( dm3[B] == 'y' ) /* turns off 2H decoupling */ { dec3rgpulse(1/dmf3,three,2.0e-6,2.0e-6); dec3blank(); setstatus(DEC3ch, FALSE, 'c', FALSE, dmf3); dec3blank(); } /* xxxxxxxxxxxxxxxxxxxx N15 EVOLUTION & SE TRAIN xxxxxxxxxxxxxxxxxxxxxxx */ dcplrphase(zero); dec2phase(t8); zgradpulse(gzlvl10, gt10); delay(gstab); dec2rgpulse(pwN, t8, 2.0e-6, 0.0); c13pulse("co", "cab", "sinc", 180.0, zero, 2.0e-6, 0.0); /*pwCO180*/ decphase(zero); dec2phase(t9); delay(timeTN - pwCO180 - WFG3_START_DELAY - tau3 - 4.0e-6); /* WFG3_START_DELAY */ sim3_c13pulse("", "cab", "co", "square", "", 0.0, 180.0, 2.0*pwN, zero, zero, t9, 2.0e-6, 2.0e-6); c13pulse("co", "cab", "sinc", 180.0, zero, 2.0e-6, 0.0); /*pwCO180*/ dec2phase(t10); txphase(t4); delay(timeTN - pwCO180 + tau3 - 500.0e-6 - gt1 - 2.0*GRADIENT_DELAY- WFG_START_DELAY - WFG_STOP_DELAY ); delay(0.2e-6); zgradpulse(gzlvl1, gt1); delay(gstab); sim3pulse(pw, 0.0, pwN, t4, zero, t10, 0.0, 0.0); txphase(zero); dec2phase(zero); zgradpulse(gzlvl11, gt11); delay(lambda - 1.3*pwN - gt11); sim3pulse(2.0*pw, 0.0, 2.0*pwN, zero, zero, zero, 0.0, 0.0); zgradpulse(gzlvl11, gt11); txphase(one); dec2phase(t11); delay(lambda - 1.3*pwN - gt11); sim3pulse(pw, 0.0, pwN, one, zero, t11, 0.0, 0.0); txphase(zero); dec2phase(zero); zgradpulse(gzlvl12, gt12); delay(lambda - 1.3*pwN - gt12); sim3pulse(2.0*pw, 0.0, 2.0*pwN, zero, zero, zero, 0.0, 0.0); dec2phase(zero); zgradpulse(gzlvl12, gt12); delay(lambda - 1.3*pwN - gt12); sim3pulse(pw, 0.0, pwN, zero, zero, zero, 0.0, 0.0); delay((gt1/10.0) + 1.0e-4 + 2.0*GRADIENT_DELAY + POWER_DELAY); rgpulse(2.0*pw, zero, 0.0, 0.0); dec2power(dpwr2); /* POWER_DELAY */ zgradpulse(icosel*gzlvl2, gt1/10.0); /* 2.0*GRADIENT_DELAY */ statusdelay(C, 1.0e-4 ); setreceiver(t12); if (dm3[B]=='y') lk_sample(); }
pulsesequence() { /* DECLARE VARIABLES */ char satmode[MAXSTR], fscuba[MAXSTR], cbdecseq[MAXSTR], chirp_shp[MAXSTR], /* name of variable containing name of Pbox shape */ fco180[MAXSTR], /* Flag for checking sequence */ fca180[MAXSTR], /* Flag for checking sequence */ sel_flg[MAXSTR]; int icosel, ni = getval("ni"), t1_counter; /* used for states tppi in t1 */ double d2_init=0.0, /* used for states tppi in t1 */ tau1, /* t1 delay */ tau2, /* t2 delay */ tau3, /* t2 delay */ taua, /* ~ 1/4JNH = 2.25 ms */ taub, /* ~ 1/4JNH = 2.25 ms */ zeta, /* time for C'-N to refocuss set to 0.5*24.0 ms */ bigTN, /* nitrogen T period */ BigT1, /* delay to compensate for gradient gt5 */ satpwr, /* low level 1H trans.power for presat */ sw1, /* sweep width in f1 */ sw2, /* sweep width in f2 */ cophase, /* phase correction for CO evolution */ caphase, /* phase correction for Ca evolution */ cbpwr, /* power level for selective CB decoupling */ cbdmf, /* pulse width for selective CB decoupling */ cbres, /* decoupling resolution of CB decoupling */ pwS1, /* length of 90 on Ca */ pwS2, /* length of 90 on CO */ pwS3, /* length of 180 on Ca */ pwS4, /* length of 180 on CO */ pwS5, /* CHIRP inversion pulse on CO and CA */ pwrS5=0.0, /* power of CHIRP pulse */ gt1, gt2, gt3, gt4, gt5, gt6, gt7, gt8, gt9, gstab, gzlvl1, gzlvl2, gzlvl3, gzlvl4, gzlvl5, gzlvl6, gzlvl7, gzlvl8, gzlvl9, compH = getval("compH"), /* adjustment for amplifier compression */ pwHs = getval ("pwHs"), /* H1 90 degree pulse at tpwrs */ tpwrs, /* power for pwHs ("H2osinc") pulse */ waltzB1 = getval("waltzB1"), pwClvl = getval("pwClvl"), /* coarse power for C13 pulse */ pwC = getval("pwC"), /* C13 90 degree pulse length at pwClvl */ compC = getval("compC"), /* ampl. compression */ pwNlvl = getval("pwNlvl"), /* power for N15 pulses */ pwN = getval("pwN"), /* N15 90 degree pulse length at pwNlvl */ swCa = getval("swCa"), swCO = getval("swCO"), swN = getval("swN"), swTilt, /* This is the sweep width of the tilt vector */ cos_N, cos_CO, cos_Ca, angle_N, angle_CO, angle_Ca; angle_N=0.0; /* LOAD VARIABLES */ getstr("satmode",satmode); getstr("fco180",fco180); getstr("fca180",fca180); getstr("fscuba",fscuba); getstr("sel_flg",sel_flg); taua = getval("taua"); taub = getval("taub"); zeta = getval("zeta"); bigTN = getval("bigTN"); BigT1 = getval("BigT1"); tpwr = getval("tpwr"); satpwr = getval("tsatpwr"); dpwr = getval("dpwr"); sw1 = getval("sw1"); sw2 = getval("sw2"); cophase = getval("cophase"); caphase = getval("caphase"); gt1 = getval("gt1"); gt2 = getval("gt2"); gt3 = getval("gt3"); gt4 = getval("gt4"); gt5 = getval("gt5"); gt6 = getval("gt6"); gt7 = getval("gt7"); gt8 = getval("gt8"); gt9 = getval("gt9"); gstab = getval("gstab"); gzlvl1 = getval("gzlvl1"); gzlvl2 = getval("gzlvl2"); gzlvl3 = getval("gzlvl3"); gzlvl4 = getval("gzlvl4"); gzlvl5 = getval("gzlvl5"); gzlvl6 = getval("gzlvl6"); gzlvl7 = getval("gzlvl7"); gzlvl8 = getval("gzlvl8"); gzlvl9 = getval("gzlvl9"); /* Load variable */ cbpwr = getval("cbpwr"); cbdmf = getval("cbdmf"); cbres = getval("cbres"); tau1 = 0; tau2 = 0; tau3 = 0; cos_N = 0; cos_CO = 0; cos_Ca = 0; getstr("cbdecseq", cbdecseq); /* LOAD PHASE TABLE */ settable(t1,2,phi1); settable(t2,2,phi2); settable(t3,1,phi3); settable(t4,8,phi4); settable(t5,4,phi5); settable(t6,8,rec); /* get calculated pulse lengths of shaped C13 pulses */ pwS1 = c13pulsepw("ca", "co", "square", 90.0); pwS2 = c13pulsepw("co", "ca", "sinc", 90.0); pwS3 = c13pulsepw("ca","co","square",180.0); pwS4 = c13pulsepw("co","ca","sinc",180.0); /*this section creates the chirp pulse inverting both co and ca*/ /*Pcoca180 is the name of the shapelib file created */ /*chirp180 is a file produced by Pbox psg containing parameter values from shape*/ strcpy(chirp_shp,"Pcoca180"); if (FIRST_FID) /* make shape once */ chirp180 = pbox(chirp_shp, CHIRP180, CHIRP180ps, dfrq, compC*pwC, pwClvl); pwrS5 = chirp180.pwr; /* get pulse power from file */ pwS5 = chirp180.pw; /* get pulse width from file */ tpwrs = tpwr - 20.0*log10(pwHs/(compH*pw*1.69)); /*needs 1.69 times more*/ tpwrs = (int) (tpwrs); /*power than a square pulse */ widthHd = 2.681*waltzB1/sfrq; /* bandwidth of H1 WALTZ16 decoupling */ pwHd = h1dec90pw("WALTZ16", widthHd, 0.0); /* H1 90 length for WALTZ16 */ /* CHECK VALIDITY OF PARAMETER RANGES */ if((dm[A] == 'y' || dm[B] == 'y' || dm[C] == 'y' )) { printf("incorrect dec1 decoupler flags! "); psg_abort(1); } if((dm2[A] == 'y' || dm2[B] == 'y' || dm2[C] == 'y' )) { printf("incorrect dec2 decoupler flags! Should be 'nnn' "); psg_abort(1); } if( satpwr > 6 ) { printf("SATPWR too large !!! "); psg_abort(1); } if( dpwr > 46 ) { printf("don't fry the probe, DPWR too large! "); psg_abort(1); } if( dpwr2 > 46 ) { printf("don't fry the probe, DPWR2 too large! "); psg_abort(1); } if( pwClvl > 62 ) { printf("don't fry the probe, pwClvl too large! "); psg_abort(1); } if( pw > 200.0e-6 ) { printf("dont fry the probe, pw too high ! "); psg_abort(1); } if( pwN > 200.0e-6 ) { printf("dont fry the probe, pwN too high ! "); psg_abort(1); } if( pwC > 200.0e-6 ) { printf("dont fry the probe, pwC too high ! "); psg_abort(1); } if( gt3 > 2.5e-3 ) { printf("gt3 is too long\n"); psg_abort(1); } if( gt1 > 10.0e-3 || gt2 > 10.0e-3 || gt4 > 10.0e-3 || gt5 > 10.0e-3 || gt6 > 10.0e-3 || gt7 > 10.0e-3 || gt8 > 10.0e-3 || gt9 > 10.0e-3) { printf("gt values are too long. Must be < 10.0e-3 or gt11=50us\n"); psg_abort(1); } /* PHASES AND INCREMENTED TIMES */ /* Set up angles and phases */ angle_CO=getval("angle_CO"); cos_CO=cos(PI*angle_CO/180.0); angle_Ca=getval("angle_Ca"); cos_Ca=cos(PI*angle_Ca/180.0); if ( (angle_CO < 0) || (angle_CO > 90) ) { printf ("angle_CO must be between 0 and 90 degree.\n"); psg_abort(1); } if ( (angle_Ca < 0) || (angle_Ca > 90) ) { printf ("angle_Ca must be between 0 and 90 degree.\n"); psg_abort(1); } if ( 1.0 < (cos_CO*cos_CO + cos_Ca*cos_Ca) ) { printf ("Impossible angles.\n"); psg_abort(1); } else { cos_N=sqrt(1.0- (cos_CO*cos_CO + cos_Ca*cos_Ca)); angle_N = 180.0*acos(cos_N)/PI; } swTilt=swCO*cos_CO + swCa*cos_Ca + swN*cos_N; if (ix ==1) { printf("\n\nn\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n"); printf ("Maximum Sweep Width: \t\t %f Hz\n", swTilt); printf ("Anlge_CO:\t%6.2f\n", angle_CO); printf ("Anlge_Ca:\t%6.2f\n", angle_Ca); printf ("Anlge_N :\t%6.2f\n", angle_N ); } /* Set up hyper complex */ /* sw1 is used as symbolic index */ if ( sw1 < 1000 ) { printf ("Please set sw1 to some value larger than 1000.\n"); psg_abort(1); } if (ix == 1) d2_init = d2; t1_counter = (int) ( (d2-d2_init)*sw1 + 0.5 ); if (t1_counter % 2) { tsadd(t2,2,4); tsadd(t6,2,4); } if (phase1 == 1) { ;} /* CC */ else if (phase1 == 2) { tsadd(t1,1,4);} /* SC */ else if (phase1 == 3) { tsadd(t5,1,4); } /* CS */ else if (phase1 == 4) { tsadd(t1,1,4); tsadd(t5,1,4); } /* SS */ else { printf ("phase1 can only be 1,2,3,4. \n"); psg_abort(1); } if (phase2 == 2) { tsadd(t4,2,4); icosel = +1; } /* N */ else icosel = -1; tau1 = 1.0*t1_counter*cos_CO/swTilt; tau2 = 1.0*t1_counter*cos_Ca/swTilt; tau3 = 1.0*t1_counter*cos_N/swTilt; tau1 = tau1/2.0; tau2 = tau2/2.0; tau3 = tau3/2.0; /* CHECK VALIDITY OF PARAMETER RANGES */ if (bigTN - 0.5*ni*(cos_N/swTilt) < 0.2e-6) { printf(" ni is too big. Make ni equal to %d or less.\n", ((int)((bigTN )*2.0*swTilt/cos_N))); psg_abort(1);} /* BEGIN ACTUAL PULSE SEQUENCE */ status(A); set_c13offset("co"); /* set Dec1 carrier at Co */ obspower(satpwr); /* Set transmitter power for 1H presaturation */ obspwrf(4095.0); decpower(pwClvl); /* Set Dec1 power for hard 13C pulses */ decpwrf(4095.0); dec2power(pwNlvl); /* Set Dec2 power for 15N hard pulses */ dec2pwrf(4095.0); /* Presaturation Period */ if (satmode[0] == 'y') { delay(2.0e-5); rgpulse(d1,zero,2.0e-6,2.0e-6); /* presaturation */ obspower(tpwr); /* Set transmitter power for hard 1H pulses */ delay(2.0e-5); if(fscuba[0] == 'y') { delay(2.2e-2); rgpulse(pw,zero,2.0e-6,0.0); rgpulse(2*pw,one,2.0e-6,0.0); rgpulse(pw,zero,2.0e-6,0.0); delay(2.2e-2); } } else { delay(d1); } obspower(tpwr); /* Set transmitter power for hard 1H pulses */ txphase(one); dec2phase(zero); delay(1.0e-5); /* Begin Pulses */ status(B); rcvroff(); lk_hold(); delay(20.0e-6); shiftedpulse("sinc", pwHs, 90.0, 0.0, one, 2.0e-6, 2.0e-6); txphase(zero); rgpulse(pw,zero,0.0,0.0); /* 90 deg 1H pulse */ delay(0.2e-6); zgradpulse(gzlvl1, gt1); delay(2.0e-6); delay(taua - gt1 - 2.2e-6); /* taua <= 1/4JNH */ sim3pulse(2*pw,0.0,2*pwN,zero,zero,zero,0.0,0.0); txphase(three); dec2phase(zero); decphase(zero); delay(0.2e-6); zgradpulse(gzlvl1, gt1); delay(gstab); delay(taua - gt1 - gstab - 2.0e-6); if(sel_flg[A] == 'n') { rgpulse(pw,three,2.0e-6,0.0); delay(0.2e-6); zgradpulse(gzlvl2, gt2); delay(gstab); dec2rgpulse(pwN,zero,0.0,0.0); decpower(pwrS5); delay( zeta -POWER_DELAY); dec2rgpulse(2.0*pwN,zero,0.0,0.0); decshapedpulse(chirp_shp, pwS5, zero, 0.0, 0.0); decpower(pwClvl); delay(zeta - pwS5 - POWER_DELAY - 2.0e-6); dec2rgpulse(pwN,zero,2.0e-6,0.0); } else { rgpulse(pw,one,2.0e-6,0.0); initval(1.0,v3); dec2stepsize(45.0); dcplr2phase(v3); delay(0.2e-6); zgradpulse(gzlvl2, gt2); delay(gstab); dec2rgpulse(pwN,zero,0.0,0.0); dcplr2phase(zero); delay(1.34e-3 - SAPS_DELAY - 2.0*pw); rgpulse(pw,one,0.0,0.0); rgpulse(2.0*pw,zero,0.0,0.0); rgpulse(pw,one,0.0,0.0); decpower(pwrS5); delay( zeta - 1.34e-3 - 2.0*pw -POWER_DELAY); dec2rgpulse(2.0*pwN,zero,0.0,0.0); decshapedpulse(chirp_shp, pwS5, zero, 0.0, 0.0); decpower(pwClvl); delay(zeta - pwS5 - POWER_DELAY - 2.0e-6); dec2rgpulse(pwN,zero,2.0e-6,0.0); } dec2phase(zero); decphase(t1); delay(0.2e-6); zgradpulse(gzlvl3, gt3); delay(gstab); /* t1 period for CO evolution */ c13pulse("co", "ca", "sinc", 90.0, t1, 0.0, 0.0); if (!strcmp(fco180, "y")) { delay(10.0e-6); sim3_c13pulse("", "ca", "co", "square", "", 0.0, 180.0, 2.0*pwN, zero, zero, zero, 2.0e-6, 2.0e-6); decstepsize(1.0); initval(cophase,v4); dcplrphase(v4); delay(10.0e-6); } else { if (tau1-2.0*pwS2/PI-pwN-WFG3_START_DELAY-POWER_DELAY-2.0e-6 > 0.0) { delay(tau1-2.0*pwS2/PI-pwN-WFG3_START_DELAY-POWER_DELAY-2.0e-6); sim3_c13pulse("", "ca", "co", "square", "", 0.0, 180.0, 2.0*pwN, zero, zero, zero, 2.0e-6, 2.0e-6); decstepsize(1.0); initval(cophase,v4); dcplrphase(v4); delay(tau1-2.0*pwS2/PI-pwN-SAPS_DELAY-WFG3_STOP_DELAY-POWER_DELAY-2.0e-6); } else { c13pulse("co", "ca", "sinc", 180.0, zero, 0.0, 0.0); } } c13pulse("co", "ca", "sinc", 90.0, zero, 4.0e-6, 0.0); dcplrphase(zero); set_c13offset("ca"); /* change Dec1 carrier to Ca (55 ppm) */ delay(0.2e-6); zgradpulse(gzlvl4, gt4); delay(gstab); /* t2 period for Ca evolution*/ /* Turn on D decoupling using the third decoupler */ dec3unblank(); dec3rgpulse(1/dmf3, one, 0.0, 0.0); dec3unblank(); setstatus(DEC3ch, TRUE, 'w', FALSE, dmf3); /* Turn on D decoupling */ c13pulse("ca", "co", "square", 90.0, t5, 0.0, 0.0); if (!strcmp(fca180, "y")) { delay(10.0e-6); sim3_c13pulse("", "co", "ca", "sinc", "", 0.0, 180.0, 2.0*pwN, zero, zero, zero, 2.0e-6, 2.0e-6); decstepsize(1.0); initval(caphase,v5); dcplrphase(v5); delay(10.0e-6); } else { if (tau2-pwN-2.0*pwS1/PI-WFG3_START_DELAY-2*POWER_DELAY- -WFG_STOP_DELAY-WFG_START_DELAY-2.0e-6 > 0.0) { decpower(cbpwr); decphase(zero); decprgon(cbdecseq,1/cbdmf,cbres); decon(); delay(tau2-pwN-2.0*pwS1/PI-WFG3_START_DELAY-2*POWER_DELAY- WFG_STOP_DELAY-WFG_START_DELAY-2.0e-6); decoff(); decprgoff(); decphase(zero); dec2phase(zero); decpower(pwClvl); sim3_c13pulse("", "co", "ca", "sinc", "", 0.0, 180.0, 2.0*pwN, zero, zero, zero, 2.0e-6, 2.0e-6); decpower(cbpwr); decphase(zero); decprgon(cbdecseq,1/cbdmf,cbres); decon(); delay(tau2-pwN-2.0*pwS1/PI-SAPS_DELAY-WFG3_STOP_DELAY-2*POWER_DELAY- WFG_STOP_DELAY-WFG_START_DELAY-2.0e-6); decoff(); decprgoff(); decstepsize(1.0); initval(caphase,v5); dcplrphase(v5); decpower(pwClvl); } else { c13pulse("ca", "co", "square", 180.0, zero, 0.0, 0.0); } } c13pulse("ca", "co", "square", 90.0, zero, 4.0e-6, 0.0); dcplrphase(zero); /* Turn off D decoupling */ dec3rgpulse(1/dmf3, three, 0.0, 0.0); dec3blank(); setstatus(DEC3ch, FALSE, 'w', FALSE, dmf3); dec3blank(); /* Turn off D decoupling */ set_c13offset("co"); /* set carrier back to Co */ delay(0.2e-6); zgradpulse(gzlvl9, gt9); delay(gstab); /* t3 period */ dec2rgpulse(pwN,t2,2.0e-6,0.0); dec2phase(t3); decpower(pwrS5); delay(bigTN - tau3 -POWER_DELAY); dec2rgpulse(2.0*pwN,t3,0.0,0.0); decshapedpulse(chirp_shp, pwS5, zero, 0.0, 0.0); decpower(pwClvl); txphase(zero); dec2phase(t4); delay(0.2e-6); zgradpulse(icosel*gzlvl5, gt5); delay(gstab); delay(bigTN - WFG_START_DELAY - pwS5 - WFG_STOP_DELAY - gt5 - gstab - 2.0*GRADIENT_DELAY); delay(tau3); sim3pulse(pw,0.0,pwN,zero,zero,t4,0.0,0.0); c13pulse("co", "ca", "sinc", 90.0, zero, 4.0e-6, 0.0); set_c13offset("ca"); c13pulse("ca", "co", "square", 90.0, zero, 20.0e-6, 0.0); delay(0.2e-6); zgradpulse(gzlvl6, gt6); delay(2.0e-6); dec2phase(zero); delay(taub - POWER_DELAY - 4.0e-6 - pwS1 - 20.0e-6 - pwS2 - gt6 - 2.2e-6); sim3pulse(2*pw,0.0,2*pwN,zero,zero,zero,0.0,0.0); set_c13offset("co"); delay(0.2e-6); zgradpulse(gzlvl6, gt6); delay(gstab); txphase(one); dec2phase(one); delay(taub - gt6 - gstab); sim3pulse(pw,0.0,pwN,one,zero,one,0.0,0.0); delay(0.2e-6); zgradpulse(gzlvl7, gt7); delay(2.0e-6); txphase(zero); dec2phase(zero); delay(taub - gt7 - 2.2e-6); sim3pulse(2*pw,0.0,2*pwN,zero,zero,zero,0.0,0.0); delay(0.2e-6); zgradpulse(gzlvl7, gt7); delay(gstab); delay(taub - gt7 - gstab); sim3pulse(pw,0.0,pwN,zero,zero,zero,0.0,0.0); delay(0.2e-6); zgradpulse(-gzlvl8, gt8/2.0); delay(gstab); delay(BigT1 - gt8/2.0 - gstab - 0.5*(pwN - pw) - 2.0*pw/PI); rgpulse(2*pw,zero,0.0,0.0); delay(0.2e-6); zgradpulse(gzlvl8, gt8/2.0); delay(gstab); dec2power(dpwr2); decpower(dpwr); delay(BigT1 - gt8/2.0 - gstab - 2.0*POWER_DELAY); lk_sample(); status(C); setreceiver(t6); }
pulsesequence() { /* DECLARE AND LOAD VARIABLES; parameters used in the last half of the */ /* sequence are declared and initialized as 0.0 in bionmr.h, and */ /* reinitialized below */ char sel_flg[MAXSTR], autocal[MAXSTR], glyshp[MAXSTR]; int t1_counter, /* used for states tppi in t1 */ ni = getval("ni"); double d2_init=0.0, /* used for states tppi in t1 */ tau1, tau2, tau3, glypwr,glypwrf, /* Power levels for Cgly selective 90 */ pwgly, /* Pulse width for Cgly selective 90 */ bw,ppm, /* Used for autocal Cgly selective 90*/ tauCC = getval("tauCC"), /* delay for Ca to Cb cosy */ timeTN = getval("timeTN"), /* constant time for 15N evolution */ waltzB1 = getval("waltzB1"), pwC = getval("pwC"), /* C13 pulse at pwClvl */ pwClvl = getval("pwClvl"), /* coarse power for C13 pulse */ compC = getval("compC"), /* correction for amplifier compression*/ pwCa180, pwCO180, pwCab90, pwCab180, pwS1, /* length of square 90 on Cab */ phshift = getval("phshift"), /* phase shift on Cab by 180 on CO in t1 */ pwS2, /* length of 180 on CO */ pwS3, pwS = getval("pwS"), /*used to change 180 on CO in t1 for 1D calibration */ pwZ, /* the largest of pwS2 and 2.0*pwN */ pwZ1, /* the largest of pwS2 and 2.0*pwN for 1D experiments */ pwNlvl = getval("pwNlvl"), /* power for N15 pulses */ pwN = getval("pwN"), /* N15 90 degree pulse length at pwNlvl */ sw1 = getval("sw1"), swCb = getval("swCb"), swCa = getval("swCa"), swN = getval("swN"), swTilt, /* This is the sweep width of the tilt vector */ cos_N, cos_Ca, cos_Cb, angle_N, angle_Ca, angle_Cb, /* angle_N is calculated automatically */ gstab = getval("gstab"), gt1 = getval("gt1"), gzlvl1 = getval("gzlvl1"), gzlvl2 = getval("gzlvl2"), gt3 = getval("gt3"), gzlvl3 = getval("gzlvl3"), gt4 = getval("gt4"), gzlvl4 = getval("gzlvl4"), gt5 = getval("gt5"), gzlvl5 = getval("gzlvl5"), gt6 = getval("gt6"), gzlvl6 = getval("gzlvl6"), gt7 = getval("gt7"), gzlvl7 = getval("gzlvl7"), gt8 = getval("gt8"), gzlvl8 = getval("gzlvl8"); angle_N=0.0; /* Load variables */ glypwrf = getval("glypwrf"); glypwr = getval("glypwr"); pwgly = getval("pwgly"); tau1 = 0; tau2 = 0; tau3 = 0; cos_N = 0; cos_Ca = 0; cos_Cb = 0; getstr("autocal", autocal); getstr("glyshp", glyshp); getstr("sel_flg",sel_flg); /* LOAD PHASE TABLE */ settable(t2,1,phy); settable(t3,2,phi3); settable(t5,4,phi5); settable(t6,8,phi6); settable(t8,1,phy); settable(t9,1,phx); settable(t10,1,phx); settable(t11,1,phx); settable(t12,8,recT); /* INITIALIZE VARIABLES */ lambda = 2.4e-3; pwCa180=c13pulsepw("ca", "co", "square", 180.0); pwCO180=c13pulsepw("co", "ca", "sinc", 180.0); pwCab90=c13pulsepw("cab","co","square",90.0); pwCab180=c13pulsepw("cab","co","square",180.0); pwHs = 1.7e-3*500.0/sfrq; /* length of H2O flipback, 1.7ms at 500 MHz*/ widthHd = 2.861*(waltzB1/sfrq); /* bw of H1 WALTZ16 decoupling */ pwHd = h1dec90pw("WALTZ16", widthHd, 0.0); /* H1 90 length for WALTZ16 */ /* get calculated pulse lengths of shaped C13 pulses */ pwS1 = c13pulsepw("cab", "co", "square", 90.0); pwS2 = c13pulsepw("co", "cab", "sinc", 180.0); pwS3 = c13pulsepw("cab", "co", "square", 180.0); /* the 180 pulse on CO at the middle of t1 */ if (pwS2 > 2.0*pwN) pwZ = pwS2; else pwZ = 2.0*pwN; if ((pwS==0.0) && (pwS2>2.0*pwN)) pwZ1=pwS2-2.0*pwN; else pwZ1=0.0; if ( ni > 1 ) pwS = 180.0; if ( pwS > 0 ) phshift = 140.0; else phshift = 0.0; /* CHECK VALIDITY OF PARAMETER RANGES */ if ( dm[A] == 'y' || dm[B] == 'y' || dm[C] == 'y' ) { printf("incorrect dec1 decoupler flags! Should be 'nnn' "); psg_abort(1);} if ( dm2[A] == 'y' || dm2[B] == 'y' || dm3[C] == 'y' ) { printf("incorrect dec2 decoupler flags! Should be 'nnn' "); psg_abort(1);} if ( dm3[A] == 'y' || dm3[C] == 'y' ) { printf("incorrect dec3 decoupler flags! Should be 'nyn' or 'nnn' "); psg_abort(1);} if ( dpwr2 > 46 ) { printf("dpwr2 too large! recheck value "); psg_abort(1);} if ( pw > 20.0e-6 ) { printf(" pw too long ! recheck value "); psg_abort(1);} if ( pwN > 100.0e-6 ) { printf(" pwN too long! recheck value "); psg_abort(1);} /* PHASES AND INCREMENTED TIMES */ /* Set up angles and phases */ angle_Cb=getval("angle_Cb"); cos_Cb=cos(PI*angle_Cb/180.0); angle_Ca=getval("angle_Ca"); cos_Ca=cos(PI*angle_Ca/180.0); if ( (angle_Cb < 0) || (angle_Cb > 90) ) { printf ("angle_Cb must be between 0 and 90 degree.\n"); psg_abort(1); } if ( (angle_Ca < 0) || (angle_Ca > 90) ) { printf ("angle_Ca must be between 0 and 90 degree.\n"); psg_abort(1); } if ( 1.0 < (cos_Cb*cos_Cb + cos_Ca*cos_Ca) ) { printf ("Impossible angles.\n"); psg_abort(1); } else { cos_N=sqrt(1.0- (cos_Cb*cos_Cb + cos_Ca*cos_Ca)); angle_N = 180.0*acos(cos_N)/PI; } swTilt=swCb*cos_Cb + swCa*cos_Ca + swN*cos_N; if (ix ==1) { if ( 0.5*ni*(cos_N/swTilt) > timeTN - WFG3_START_DELAY) { printf(" ni is too big. Make ni equal to %d or less.\n", ((int)((timeTN - WFG3_START_DELAY)*2.0*swTilt/cos_N))); psg_abort(1);} if ( (0.5*ni*cos_Ca/swTilt) > (tauCC - pwCO180 - pwCab180/2 - WFG2_START_DELAY - 2.0*PWRF_DELAY - 2.0*POWER_DELAY - WFG2_STOP_DELAY - 4.0e-6)) { printf (" ni is too big. Make ni equal to %d or less. \n", (int) ((tauCC - pwCO180 - pwCab180/2 - WFG2_START_DELAY - 2.0*PWRF_DELAY -2.0*POWER_DELAY - WFG2_STOP_DELAY -14.0e-6)/(0.5*cos_Ca/swTilt))); psg_abort(1); } printf("\n\nn\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n"); printf ("Maximum Sweep Width: \t\t %f Hz\n", swTilt); printf ("Angle_Cb:\t%6.2f\n", angle_Cb); printf ("Angle_Ca:\t%6.2f\n", angle_Ca); printf ("Angle_N :\t%6.2f\n", angle_N ); } /* Set up hyper complex */ /* sw1 is used as symbolic index */ if ( sw1 < 1000 ) { printf ("Please set sw1 to some value larger than 1000.\n"); psg_abort(1); } if (ix == 1) d2_init = d2; t1_counter = (int) ( (d2-d2_init)*sw1 + 0.5 ); if (t1_counter % 2) { tsadd(t8,2,4); tsadd(t12,2,4); } if (phase1 == 1) { ;} /* CC */ else if (phase1 == 2) { tsadd(t3,3,4); tsadd(t2,3,4);} /* SC */ else if (phase1 == 3) { tsadd(t5,1,4); } /* CS */ else if (phase1 == 4) { tsadd(t3,3,4); tsadd(t2,3,4); tsadd(t5,1,4); } /* SS */ else { printf ("phase1 can only be 1,2,3,4. \n"); psg_abort(1); } if (phase2 == 2) { tsadd(t10,2,4); icosel = +1; } /* N */ else icosel = -1; tau1 = 1.0*t1_counter*cos_Cb/swTilt; tau2 = 1.0*t1_counter*cos_Ca/swTilt; tau3 = 1.0*t1_counter*cos_N/swTilt; tau1 = tau1/2.0; tau2 = tau2/2.0; tau3 = tau3/2.0; /* BEGIN PULSE SEQUENCE */ status(A); delay(d1); if (dm3[B] == 'y') lk_hold(); rcvroff(); obsoffset(tof); obspower(tpwr); obspwrf(4095.0); set_c13offset("cab"); decpower(pwClvl); decpwrf(4095.0); dec2power(pwNlvl); txphase(one); delay(1.0e-5); shiftedpulse("sinc", pwHs, 90.0, 0.0, one, 2.0e-6, 0.0); txphase(zero); decphase(zero); dec2phase(zero); delay(2.0e-6); /* xxxxxxxxxxxxxxxxxxxxxx HN to N to Ca TRANSFER xxxxxxxxxxxxxxxxxx */ rgpulse(pw, zero, 0.0, 0.0); /* 1H pulse excitation */ dec2phase(zero); zgradpulse(gzlvl3, gt3); /* G3 */ delay(lambda - gt3); sim3pulse(2.0*pw, 0.0, 2.0*pwN, zero, zero, zero, 0.0, 0.0); if (sel_flg[A] == 'n') txphase(three); else txphase(one); zgradpulse(gzlvl3, gt3); /* G3 */ delay(lambda - gt3); if (sel_flg[A] == 'n') { rgpulse(pw, three, 0.0, 0.0); zgradpulse(gzlvl4, gt4); /* Crush gradient G4 */ delay(gstab); /* Begin of N to Ca transfer */ dec2rgpulse(pwN, zero, 0.0, 0.0); delay(timeTN - WFG3_START_DELAY); } else /* active suppresion */ { rgpulse(pw,one,2.0e-6,0.0); initval(1.0,v6); dec2stepsize(45.0); dcplr2phase(v6); zgradpulse(gzlvl4, gt4); /* Crush gradient G4 */ delay(gstab); /* Begin of N to Ca transfer */ dec2rgpulse(pwN,zero,0.0,0.0); dcplr2phase(zero); /* SAPS_DELAY */ delay(1.34e-3 - SAPS_DELAY - 2.0*pw); rgpulse(pw,one,0.0,0.0); rgpulse(2.0*pw,zero,0.0,0.0); rgpulse(pw,one,0.0,0.0); delay(timeTN -1.34e-3 - 2.0*pw - WFG3_START_DELAY); } sim3_c13pulse("", "ca", "co", "square", "", 0.0, 180.0, 2.0*pwN, zero, zero, zero, 2.0e-6, 2.0e-6); dec2phase(one); delay(timeTN); dec2rgpulse(pwN, one, 0.0, 0.0); /* xxxxxxxxxxxxxxxxxxxxxxxx END of N to CA TRANSFER xxxxxxxxxxxxxxxxxxxx */ setautocal(); set_c13offset("gly"); if (autocal[A] == 'n') { decpower(glypwr); decpwrf(4095.0); decphase(zero); decshaped_pulse(glyshp,pwgly,zero,2.0e-6,0.0); } else { if(FIRST_FID) { ppm = getval("dfrq"); bw=9*ppm; gly90 = pbox_make("gly90","eburp1",bw,0.0,compC*pwC,pwClvl); /* Gly selective 90 with null at 50ppm */ } pwgly=gly90.pw; glypwr=gly90.pwr; glypwrf=gly90.pwrf; decpwrf(glypwrf); decpower(glypwr); decshaped_pulse("gly90",pwgly,zero,2.0e-6,0.0); } zgradpulse(gzlvl5, gt5); /* Crush gradient G5 */ set_c13offset("cab"); decphase(t3); delay(gstab); if (dm3[B] == 'y') /*optional 2H decoupling on */ { dec3unblank(); dec3rgpulse(1/dmf3, one, 0.0, 0.0); dec3unblank(); setstatus(DEC3ch, TRUE, 'w', FALSE, dmf3); } /* xxxxxxxxxxxxxxxxxxxxxx 13CA to 13CB TRANSFER xxxxxxxxxxxxxxxxxx */ c13pulse("cab", "co", "square", 90.0, t3, 2.0e-6, 0.0); decphase(zero); delay(tauCC); c13pulse("cab", "co", "square", 180.0, zero, 2.0e-6, 0.0); decphase(t2); delay(tauCC - POWER_DELAY - PWRF_DELAY - PRG_START_DELAY); /* xxxxxxxxxxxxxxxxxxxxxx 13CB EVOLUTION xxxxxxxxxxxxxxxxxx */ c13pulse("cab", "co", "square", 90.0, t2, 2.0e-6, 0.0); /* pwS1 */ decphase(zero); if ((ni>1.0) && (tau1>0.0)) { if (tau1 - 2.0*pwCab90/PI - WFG_START_DELAY - pwN - 2.0e-6 - PWRF_DELAY - POWER_DELAY > 0.0) { delay(tau1 - 2.0*pwCab90/PI - pwN - 2.0e-6 ); dec2rgpulse(2.0*pwN, zero, 2.0e-6, 0.0); delay(tau1 - 2.0*pwS1/PI - pwN - WFG_START_DELAY - 2.0e-6 - PWRF_DELAY - POWER_DELAY); } else { tsadd(t12,2,4); delay(2.0*tau1); delay(10.0e-6); /* WFG_START_DELAY */ sim3_c13pulse("", "cab", "co", "square", "", 0.0, 180.0, 2.0*pwN, zero, zero, zero, 2.0e-6, 0.0); delay(10.0e-6); } } else { tsadd(t12,2,4); delay(10.0e-6); /* WFG_START_DELAY */ sim3_c13pulse("", "cab", "co", "square", "", 0.0, 180.0, 2.0*pwN, zero, zero, zero, 2.0e-6, 0.0); delay(10.0e-6); } decphase(t6); c13pulse("cab", "co", "square", 90.0, t6, 2.0e-6, 0.0); /* pwS1 */ /* xxxxxxxxxxxx 13CB to 13CA BACK TRANSFER - CA EVOLUTION xxxxxxxxxxxxxx */ decphase(zero); delay(tau2); sim3_c13pulse("", "co", "ca", "sinc", "", 0.0, 180.0, 2.0*pwN, zero, zero, zero, 2.0e-6, 0.0); decphase(zero); delay(tauCC- 2*pwN - pwCab180/2 - WFG2_START_DELAY - 2.0*PWRF_DELAY - 2.0*POWER_DELAY - WFG2_STOP_DELAY - 4.0e-6 ); c13pulse("cab", "co", "square", 180.0, zero, 2.0e-6, 0.0); delay(tauCC - tau2 - pwCO180 - pwCab180/2 - WFG2_START_DELAY - 2.0*PWRF_DELAY -2.0*POWER_DELAY - WFG2_STOP_DELAY - 4.0e-6 ); c13pulse("co", "ca", "sinc", 180.0, zero, 2.0e-6, 0.0); decphase(t5); c13pulse("cab", "co", "square", 90.0, t5, 2.0e-6, 0.0); /* pwS1 */ /* xxxxxxxxxxx END of 13CB to 13CA BACK TRANSFER - CA EVOLUTION xxxxxxxxxxxx */ if (dm3[B] == 'y') /*optional 2H decoupling off */ { dec3rgpulse(1/dmf3, three, 0.0, 0.0); dec3blank(); setstatus(DEC3ch, FALSE, 'w', FALSE, dmf3); dec3blank(); } dec2phase(t8); zgradpulse(gzlvl6, gt6); /* Crush gradient G6 */ delay(gstab); /* xxxxxxxxxxxxxxxx 13CA to 15N BACK TRANSFER - 15N EVOLUTION xxxxxxxxxxxxxx */ dec2rgpulse(pwN, t8, 2.0e-6, 2.0e-6); decphase(zero); dec2phase(t9); delay(timeTN - WFG3_START_DELAY - tau3); /* WFG3_START_DELAY */ sim3_c13pulse("", "ca", "co", "square", "", 0.0, 180.0, 2.0*pwN, zero, zero, t9, 2.0e-6, 2.0e-6); dec2phase(t10); delay (timeTN - pwCO180 - WFG_START_DELAY - 2.0*POWER_DELAY - 2.0*PWRF_DELAY - 2.0e-6 - gt1 - 2.0*GRADIENT_DELAY - gstab); zgradpulse(gzlvl1, gt1); /* 2.0*GRADIENT_DELAY */ delay(gstab - POWER_DELAY - PWRF_DELAY); c13pulse("co", "ca", "sinc", 180.0, zero, 2.0e-6, 0.0); /*pwCO180*/ delay(tau3); sim3pulse(pw, 0.0, pwN, zero, zero, t10, 0.0, 0.0); /* t4??*/ zgradpulse(gzlvl7, gt7); /* G7 */ txphase(zero); dec2phase(zero); delay (lambda - 1.3*pwN - gt7); sim3pulse(2.0*pw, 0.0, 2.0*pwN, zero, zero, zero, 0.0, 0.0); zgradpulse(gzlvl7, gt7); /* G7 */ txphase(one); dec2phase(one); delay (lambda - 1.3*pwN - gt7); sim3pulse(pw, 0.0, pwN, one, zero, one, 0.0, 0.0); zgradpulse(gzlvl8, gt8); /* G8 */ txphase(zero); dec2phase(zero); delay (lambda - 1.3*pwN - gt8); sim3pulse(2.0*pw, 0.0, 2.0*pwN, zero, zero, zero, 0.0, 0.0); zgradpulse(gzlvl8, gt8); /* G8 */ delay (lambda - 1.3*pwN - gt8); sim3pulse(pw, 0.0, pwN, zero, zero, zero, 0.0, 0.0); dec2power(dpwr2); decpower(dpwr); delay ( (gt1/10.0) + 1.0e-4 + 2.0*GRADIENT_DELAY + POWER_DELAY); rgpulse(2.0*pw, zero, 0.0, 0.0); zgradpulse(icosel*gzlvl2, gt1/10.0); /* 2.0*GRADIENT_DELAY */ statusdelay(C, 1.0e-4); setreceiver(t12); if (dm3[B] == 'y') lk_sample(); }
pulsesequence() { /* DECLARE VARIABLES */ char satmode[MAXSTR], fscuba[MAXSTR], fc180[MAXSTR], /* Flag for checking sequence */ cbdecseq[MAXSTR]; int icosel, ni = getval("ni"), t1_counter; /* used for states tppi in t1 */ double tau1, /* t1 delay */ tau2, /* t2 delay */ tau3, /* t2 delay */ taua, /* ~ 1/4JNH = 2.25 ms */ taub, /* ~ 1/4JNH = 2.25 ms */ tauc, /* ~ 1/4JCaC' = 4 ms */ taud, /* ~ 1/4JCaC' = 4.5 ms if bigTCo can be set to be less than 4.5ms and then taud can be smaller*/ zeta, /* time for C'-N to refocuss set to 0.5*24.0 ms */ bigTCa, /* Ca T period */ bigTCo, /* Co T period */ bigTN, /* nitrogen T period */ BigT1, /* delay to compensate for gradient gt5 */ satpwr, /* low level 1H trans.power for presat */ sw1, /* sweep width in f1 */ sw2, /* sweep width in f2 */ sphase, /* small angle phase shift */ cbpwr, /* power level for selective CB decoupling */ cbdmf, /* pulse width for selective CB decoupling */ cbres, /* decoupling resolution of CB decoupling */ pwS1, /* length of square 90 on Ca */ phshift, /* phase shift induced on Ca by 180 on CO in middle of t1 */ pwS2, /* length of 180 on CO */ pwS3, /* length of 180 on Ca */ pwS4, /* length of 90 on CO */ pwS = getval("pwS"), /* used to change 180 on CO in t1 for 1D calibrations */ pwZ, /* the largest of pwS2 and 2.0*pwN */ pwZ1, /* the largest of pwS2 and 2.0*pwN for 1D experiments */ gt1, gt2, gt3, gt4, gt5, gt6, gt7, gt8, gt9, gt10, gt11, gt12, gstab, gzlvl1, gzlvl2, gzlvl3, gzlvl4, gzlvl5, gzlvl6, gzlvl7, gzlvl8, gzlvl9, gzlvl10, gzlvl11, gzlvl12, compH = getval("compH"), /* adjustment for amplifier compression */ pwHs = getval ("pwHs"), /* H1 90 degree pulse at tpwrs */ tpwrs, /* power for pwHs ("H2osinc") pulse */ waltzB1 = getval("waltzB1"), pwClvl = getval("pwClvl"), /* coarse power for C13 pulse */ pwC = getval("pwC"), /* C13 90 degree pulse length at pwClvl */ pwNlvl = getval("pwNlvl"), /* power for N15 pulses */ pwN = getval("pwN"), /* N15 90 degree pulse length at pwNlvl */ swCa = getval("swCa"), swCO = getval("swCO"), swN = getval("swN"), swTilt, /* This is the sweep width of the tilt vector */ cos_N, cos_CO, cos_Ca, angle_N, angle_CO, angle_Ca; angle_N=0.0; /*initialize variable*/ /* LOAD VARIABLES */ getstr("satmode",satmode); getstr("fc180",fc180); getstr("fscuba",fscuba); taua = getval("taua"); taub = getval("taub"); tauc = getval("tauc"); taud = getval("taud"); zeta = getval("zeta"); bigTCa = getval("bigTCa"); bigTCo = getval("bigTCo"); bigTN = getval("bigTN"); BigT1 = getval("BigT1"); tpwr = getval("tpwr"); satpwr = getval("satpwr"); dpwr = getval("dpwr"); sw1 = getval("sw1"); sw2 = getval("sw2"); sphase = getval("sphase"); gt1 = getval("gt1"); gt2 = getval("gt2"); gt3 = getval("gt3"); gt4 = getval("gt4"); gt5 = getval("gt5"); gt6 = getval("gt6"); gt7 = getval("gt7"); gt8 = getval("gt8"); gt9 = getval("gt9"); gt10 = getval("gt10"); gt11 = getval("gt11"); gt12 = getval("gt12"); gstab = getval("gstab"); gzlvl1 = getval("gzlvl1"); gzlvl2 = getval("gzlvl2"); gzlvl3 = getval("gzlvl3"); gzlvl4 = getval("gzlvl4"); gzlvl5 = getval("gzlvl5"); gzlvl6 = getval("gzlvl6"); gzlvl7 = getval("gzlvl7"); gzlvl8 = getval("gzlvl8"); gzlvl9 = getval("gzlvl9"); gzlvl10 = getval("gzlvl10"); gzlvl11 = getval("gzlvl11"); gzlvl12 = getval("gzlvl12"); /* Load variable */ cbpwr = getval("cbpwr"); cbdmf = getval("cbdmf"); cbres = getval("cbres"); tau1 = 0; tau2 = 0; tau3 = 0; cos_N = 0; cos_CO = 0; cos_Ca = 0; getstr("cbdecseq", cbdecseq); /* LOAD PHASE TABLE */ settable(t1,1,phi1); settable(t2,1,phi2); settable(t3,4,phi3); settable(t4,1,phi4); settable(t5,1,phi5); settable(t7,4,phi7); settable(t8,4,phi8); settable(t6,4,rec); kappa = 5.4e-3; /* get calculated pulse lengths of shaped C13 pulses */ pwS1 = c13pulsepw("ca", "co", "square", 90.0); pwS2 = c13pulsepw("co", "ca", "sinc", 180.0); pwS3 = c13pulsepw("ca","co","square",180.0); pwS4 = c13pulsepw("co", "ca", "sinc", 90.0); /* the 180 pulse on CO at the middle of t1 */ if (pwS2 > 2.0*pwN) pwZ = pwS2; else pwZ = 2.0*pwN; if ((pwS==0.0) && (pwS2>2.0*pwN)) pwZ1=pwS2-2.0*pwN; else pwZ1=0.0; if ( ni > 1 ) pwS = 180.0; if ( pwS > 0 ) phshift = 140.0; else phshift = 0.0; tpwrs = tpwr - 20.0*log10(pwHs/(compH*pw*1.69)); /*needs 1.69 times more*/ tpwrs = (int) (tpwrs); /*power than a square pulse */ widthHd = 2.681*waltzB1/sfrq; /* bandwidth of H1 WALTZ16 decoupling */ pwHd = h1dec90pw("WALTZ16", widthHd, 0.0); /* H1 90 length for WALTZ16 */ /* CHECK VALIDITY OF PARAMETER RANGES */ if((dm[A] == 'y' || dm[B] == 'y' || dm[C] == 'y' )) { printf("incorrect dec1 decoupler flags! "); psg_abort(1); } if((dm2[A] == 'y' || dm2[B] == 'y' )) { printf("incorrect dec2 decoupler flags! Should be 'nny' "); psg_abort(1); } if( satpwr > 6 ) { printf("TSATPWR too large !!! "); psg_abort(1); } if( dpwr > 46 ) { printf("don't fry the probe, DPWR too large! "); psg_abort(1); } if( dpwr2 > 46 ) { printf("don't fry the probe, DPWR2 too large! "); psg_abort(1); } if( pwClvl > 62 ) { printf("don't fry the probe, pwClvl too large! "); psg_abort(1); } if( pw > 200.0e-6 ) { printf("dont fry the probe, pw too high ! "); psg_abort(1); } if( pwN > 200.0e-6 ) { printf("dont fry the probe, pwN too high ! "); psg_abort(1); } if( pwC > 200.0e-6 ) { printf("dont fry the probe, pwC too high ! "); psg_abort(1); } if( pwS3 > 200.0e-6 ) { printf("dont fry the probe, pwS3 too high ! "); psg_abort(1); } if( gt3 > 2.5e-3 ) { printf("gt3 is too long\n"); psg_abort(1); } if( gt1 > 10.0e-3 || gt2 > 10.0e-3 || gt4 > 10.0e-3 || gt5 > 10.0e-3 || gt6 > 10.0e-3 || gt7 > 10.0e-3 || gt8 > 10.0e-3 || gt9 > 10.0e-3 || gt10 > 10.0e-3 || gt11 > 50.0e-6) { printf("gt values are too long. Must be < 10.0e-3 or gt11=50us\n"); psg_abort(1); } /* PHASES AND INCREMENTED TIMES */ /* Set up angles and phases */ angle_CO=getval("angle_CO"); cos_CO=cos(PI*angle_CO/180.0); angle_Ca=getval("angle_Ca"); cos_Ca=cos(PI*angle_Ca/180.0); if ( (angle_CO < 0) || (angle_CO > 90) ) { printf ("angle_CO must be between 0 and 90 degree.\n"); psg_abort(1); } if ( (angle_Ca < 0) || (angle_Ca > 90) ) { printf ("angle_Ca must be between 0 and 90 degree.\n"); psg_abort(1); } if ( 1.0 < (cos_CO*cos_CO + cos_Ca*cos_Ca) ) { printf ("Impossible angles.\n"); psg_abort(1); } else { cos_N=sqrt(1.0- (cos_CO*cos_CO + cos_Ca*cos_Ca)); angle_N = 180.0*acos(cos_N)/PI; } swTilt=swCO*cos_CO + swCa*cos_Ca + swN*cos_N; if (ix ==1) { printf("\n\nn\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n"); printf ("Maximum Sweep Width: \t\t %f Hz\n", swTilt); printf ("Angle_CO:\t%6.2f\n", angle_CO); printf ("Angle_Ca:\t%6.2f\n", angle_Ca); printf ("Angle_N :\t%6.2f\n", angle_N ); } /* Set up hyper complex */ /* sw1 is used as symbolic index */ if ( sw1 < 1000 ) { printf ("Please set sw1 to some value larger than 1000.\n"); psg_abort(1); } if (ix == 1) d2_init = d2; t1_counter = (int) ( (d2-d2_init)*sw1 + 0.5 ); if (t1_counter % 2) { tsadd(t2,2,4); tsadd(t6,2,4); } if (phase1 == 1) { ;} /* CC */ else if (phase1 == 2) { tsadd(t5,1,4);} /* SC */ else if (phase1 == 3) { tsadd(t1,1,4); } /* CS */ else if (phase1 == 4) { tsadd(t5,1,4); tsadd(t1,1,4); } /* SS */ else { printf ("phase1 can only be 1,2,3,4. \n"); psg_abort(1); } if (phase2 == 2) { tsadd(t4,2,4); icosel = 1; } /* N */ else icosel = -1; tau1 = 1.0*t1_counter*cos_Ca/swTilt; tau2 = 1.0*t1_counter*cos_CO/swTilt; tau3 = 1.0*t1_counter*cos_N/swTilt; tau1 = tau1/2.0; tau2 = tau2/2.0; tau3 = tau3/2.0; /* CHECK VALIDITY OF PARAMETER RANGES */ if (bigTN - 0.5*ni*(cos_N/swTilt) + pwS2 < 0.2e-6) { printf(" ni is too big. Make ni equal to %d or less.\n", ((int)((bigTN + pwS2)*2.0*swTilt/cos_N))); psg_abort(1);} if (bigTCo - 0.5*ni*(cos_CO/swTilt) - 4.0e-6 - POWER_DELAY < 0.2e-6) { printf(" ni is too big for CO. Make ni equal to %d or less.\n", (int) ((bigTCo - 4.0e-6 - POWER_DELAY) / (0.5*cos_CO/swTilt)) ); psg_abort(1); } /* BEGIN ACTUAL PULSE SEQUENCE */ status(A); obsoffset(tof); set_c13offset("ca"); /* set Dec1 carrier at Co */ obspower(satpwr); /* Set transmitter power for 1H presaturation */ obspwrf(4095.0); decpower(pwClvl); /* Set Dec1 power for hard 13C pulses */ decpwrf(4095.0); dec2power(pwNlvl); /* Set Dec2 power for hard 15N pulses */ dec2pwrf(4095.0); sim3_c13pulse("", "ca", "co", "sinc", "", 0.0, 180.0, 0.0, /* to produce shape */ zero, zero, zero, 2.0e-6, 2.0e-4); set_c13offset("co"); /* set Dec1 carrier at Co */ /* Presaturation Period */ if (satmode[0] == 'y') { delay(2.0e-5); rgpulse(d1,zero,2.0e-6,2.0e-6); /* presaturation */ obspower(tpwr); /* Set transmitter power for hard 1H pulses */ delay(2.0e-5); if(fscuba[0] == 'y') { delay(2.2e-2); rgpulse(pw,zero,2.0e-6,0.0); rgpulse(2*pw,one,2.0e-6,0.0); rgpulse(pw,zero,2.0e-6,0.0); delay(2.2e-2); } } else { delay(d1); } obspower(tpwr); /* Set transmitter power for hard 1H pulses */ txphase(three); dec2phase(zero); delay(1.0e-5); /* Begin Pulses */ status(B); rcvroff(); shiftedpulse("sinc", pwHs, 90.0, 0.0, three, 2.0e-6, 2.0e-6); txphase(zero); /* xxxxxxxxxxxxxxxxxxxxxx 1HN to 15N TRANSFER xxxxxxxxxxxxxxxxxx */ rgpulse(pw,zero,0.0,0.0); /* 90 deg 1H pulse */ delay(0.2e-6); zgradpulse(gzlvl1, gt1); delay(2.0e-6); delay(taua - gt1 - 2.2e-6); /* taua <= 1/4JNH */ sim3pulse(2*pw,0.0,2*pwN,zero,zero,zero,0.0,0.0); txphase(one); dec2phase(zero); decphase(zero); delay(taua - gt1 - gstab -0.2e-6 - 2.0e-6); delay(0.2e-6); zgradpulse(gzlvl1, gt1); delay(gstab); /* xxxxxxxxxxxxxxxxxxxxxx 15N to 13CO TRANSFER xxxxxxxxxxxxxxxxxx */ rgpulse(pw,one,2.0e-6,0.0); delay(0.2e-6); zgradpulse(gzlvl2, gt2); delay(gstab); dec2rgpulse(pwN,zero,0.0,0.0); delay(kappa - POWER_DELAY - PWRF_DELAY - pwHd - 4.0e-6 - PRG_START_DELAY); /* delays for h1waltzon subtracted */ h1waltzon("WALTZ16", widthHd, 0.0); decphase(zero); dec2phase(zero); delay(zeta - kappa - WFG3_START_DELAY); dec2rgpulse(2*pwN,zero,0.0,0.0); c13pulse("co", "ca", "sinc", 180.0, zero, 0.0, 0.0); dec2phase(zero); delay(zeta - 2.0e-6); dec2rgpulse(pwN,zero,2.0e-6,0.0); h1waltzoff("WALTZ16", widthHd, 0.0); dec2phase(zero); decphase(zero); delay(0.2e-6); /* CHECK Negative gradient */ zgradpulse(-gzlvl3, gt3); delay(gstab); /* xxxxxxxxxxxxxxxxxxxxx 13CO to 13CA TRANSFER xxxxxxxxxxxxxxxxxxxxxxx */ c13pulse("co", "ca", "sinc", 90.0, zero, 2.0e-6, 0.0); delay(2.0e-7); zgradpulse(gzlvl10, gt10); delay(tauc - gt10 - 0.2e-6 - (0.5*10.933*pwC)); decrgpulse(pwC*158.0/90.0, zero, 0.0, 0.0); decrgpulse(pwC*171.2/90.0, two, 0.0, 0.0); decrgpulse(pwC*342.8/90.0, zero, 0.0, 0.0); /* Shaka 6 composite */ decrgpulse(pwC*145.5/90.0, two, 0.0, 0.0); decrgpulse(pwC*81.2/90.0, zero, 0.0, 0.0); decrgpulse(pwC*85.3/90.0, two, 0.0, 0.0); delay(2.0e-7); zgradpulse(gzlvl10, gt10); delay(tauc - 4.0e-6 - gt10 - 0.2e-6 - (0.5*10.933*pwC)); c13pulse("co", "ca", "sinc", 90.0, one, 4.0e-6, 0.0); set_c13offset("ca"); /* change Dec1 carrier to Ca (55 ppm) */ delay(0.2e-6); zgradpulse(gzlvl9, gt9); decphase(t5); delay(gstab); /* xxxxxxxxxxxxxxxxxx 13CA EVOLUTION xxxxxxxxxxxxxxxxxxxxxx */ h1waltzon("WALTZ16", widthHd, 0.0); c13pulse("ca", "co", "square", 90.0, t5, 2.0e-6, 0.0); /* pwS1 */ if (fc180[A]=='n') { if ((ni>1.0) && (tau1>0.0)) { if (tau1 - 2.0*pwS1/PI - WFG3_START_DELAY - PRG_START_DELAY - 2*POWER_DELAY - PRG_STOP_DELAY - 2.0*PWRF_DELAY - 0.5*pwZ > 0.0) { decpower(cbpwr); decphase(zero); decprgon(cbdecseq,1/cbdmf,cbres); decon(); delay(tau1 - 2.0*pwS1/PI - WFG3_START_DELAY - PRG_START_DELAY - 2*POWER_DELAY - PRG_STOP_DELAY - 2.0*PWRF_DELAY - 0.5*pwZ); decoff(); decprgoff(); decpower(pwClvl); decphase(zero); dec2phase(zero); sim3_c13pulse("", "co", "ca", "sinc", "", 0.0, 180.0, 2.0*pwN, zero, zero, zero, 2.0e-6, 2.0e-6); decpower(cbpwr); decphase(zero); decprgon(cbdecseq,1/cbdmf,cbres); decon(); delay(tau1 - 2.0*pwS1/PI - PRG_START_DELAY - 2*POWER_DELAY - PRG_STOP_DELAY - WFG_START_DELAY - 2.0*PWRF_DELAY - 0.5*pwZ); decoff(); decprgoff(); decpower(pwClvl); initval(140.0, v9); decstepsize(1.0); dcplrphase(v9); } else { tsadd(t6,2,4); delay(2.0*tau1); delay(10.0e-6); sim3_c13pulse("", "ca", "co", "sinc", "", 0.0, 180.0, 2.0*pwN, zero, zero, zero, 2.0e-6, 2.0e-6); delay(10.0e-6); } } else { tsadd(t6,2,4); delay(10.0e-6); sim3_c13pulse("", "co", "ca", "sinc", "", 0.0, 180.0, 2.0*pwN, zero, zero, zero, 2.0e-6, 2.0e-6); delay(10.0e-6); } } else { /* for checking sequence */ c13pulse("ca", "co", "square", 180.0, zero, 2.0e-6, 0.0); } decphase(t7); c13pulse("ca", "co", "square", 90.0, t7, 4.0e-6, 0.0); /* pwS1 */ dcplrphase(zero); h1waltzoff("WALTZ16", widthHd, 0.0); set_c13offset("co"); /* set carrier back to Co */ delay(0.2e-6); zgradpulse(gzlvl12, gt12); delay(gstab); /* xxxxxxxxxxxxxxx 13CA to 13CO TRANSFER and CT 13CO EVOLUTION xxxxxxxxxxxxxxxxx */ c13pulse("co", "ca", "sinc", 90.0, t1, 2.0e-6, 0.0); delay(tau2); dec2rgpulse(pwN,one,0.0,0.0); dec2rgpulse(2*pwN,zero,0.0,0.0); dec2rgpulse(pwN,one,0.0,0.0); delay(taud - 4.0*pwN - POWER_DELAY - 0.5*(WFG_START_DELAY + pwS3 + WFG_STOP_DELAY)); c13pulse("ca", "co", "square", 180.0, zero, 2.0e-6, 0.0); decphase(t8); initval(1.0,v4); decstepsize(sphase); dcplrphase(v4); delay(bigTCo - taud - 0.5*(WFG_START_DELAY + pwS3 + WFG_STOP_DELAY) ); c13pulse("co", "ca", "sinc", 180.0, t8, 2.0e-6, 0.0); dcplrphase(zero); decphase(one); delay(bigTCo - tau2 - POWER_DELAY - 4.0e-6); c13pulse("co", "ca", "sinc", 90.0, one, 4.0e-6, 0.0); delay(0.2e-6); zgradpulse(gzlvl4, gt4); delay(gstab); h1waltzon("WALTZ16", widthHd, 0.0); /* t3 period */ dec2rgpulse(pwN,t2,2.0e-6,0.0); dec2phase(t3); delay(bigTN - tau3 + pwS2); dec2rgpulse(2*pwN,t3,0.0,0.0); c13pulse("co", "ca", "sinc", 180.0, zero, 0.0, 0.0); dec2phase(t4); if (tau3 > (kappa + PRG_STOP_DELAY + pwHd + 2.0e-6)) { delay(bigTN - pwS3 - WFG_START_DELAY - 2.0*POWER_DELAY - 2.0*PWRF_DELAY - 2.0e-6); c13pulse("ca", "co", "square", 180.0, zero, 2.0e-6, 0.0); delay(tau3 - kappa - PRG_STOP_DELAY - pwHd - 2.0e-6 - POWER_DELAY - PWRF_DELAY); h1waltzoff("WALTZ16", widthHd, 0.0); txphase(zero); delay(kappa - gt5 - 2.0*GRADIENT_DELAY - 1.0e-4); zgradpulse(gzlvl5, gt5); /* 2.0*GRADIENT_DELAY */ delay(1.0e-4); } else if (tau3 > (kappa - pwS3 - WFG_START_DELAY - 2.0*POWER_DELAY - 2.0*PWRF_DELAY - 2.0e-6)) { delay(bigTN + tau3 - kappa - PRG_STOP_DELAY - pwHd - 2.0e-6 - POWER_DELAY - PWRF_DELAY); h1waltzoff("WALTZ16", widthHd, 0.0); txphase(zero); c13pulse("ca", "co", "square", 180.0, zero, 2.0e-6, 0.0); delay(kappa - pwS3 - WFG_START_DELAY - 2.0*POWER_DELAY - 2.0*PWRF_DELAY - 2.0e-6 - gt5 - 2.0*GRADIENT_DELAY - 1.0e-4); zgradpulse(gzlvl5, gt5); /* 2.0*GRADIENT_DELAY */ delay(1.0e-4); } else if (tau3 > gt5 + 2.0*GRADIENT_DELAY + 1.0e-4) { delay(bigTN + tau3 - kappa - PRG_STOP_DELAY - pwHd - 2.0e-6 - POWER_DELAY - PWRF_DELAY); h1waltzoff("WALTZ16", widthHd, 0.0); txphase(zero); delay(kappa - tau3 - pwS3 - WFG_START_DELAY - 2.0*POWER_DELAY - 2.0*PWRF_DELAY - 2.0e-6); c13pulse("ca", "co", "square", 180.0, zero, 2.0e-6, 0.0); delay(tau3 - gt5 - 2.0*GRADIENT_DELAY - 1.0e-4); zgradpulse(gzlvl5, gt5); /* 2.0*GRADIENT_DELAY */ delay(1.0e-4); } else { delay(bigTN + tau3 - kappa - PRG_STOP_DELAY - pwHd - 2.0e-6 - POWER_DELAY - PWRF_DELAY); h1waltzoff("WALTZ16", widthHd, 0.0); txphase(zero); delay(kappa - tau3 - pwS3 - WFG_START_DELAY - 2.0*POWER_DELAY - 2.0*PWRF_DELAY - 2.0e-6 - gt5 - 2.0*GRADIENT_DELAY - 1.0e-4); zgradpulse(gzlvl5, gt5); /* 2.0*GRADIENT_DELAY */ delay(1.0e-4); c13pulse("ca", "co", "square", 180.0, zero, 2.0e-6, 0.0); delay(tau3); } sim3pulse(pw,0.0,pwN,zero,zero,t4,0.0,0.0); delay(0.2e-6); zgradpulse(gzlvl6, gt6); delay(2.0e-6); dec2phase(zero); delay(taub - gt6 - 2.2e-6); sim3pulse(2.0*pw,0.0,2.0*pwN,zero,zero,zero,0.0,0.0); delay(0.2e-6); zgradpulse(gzlvl6, gt6); delay(200.0e-6); txphase(one); dec2phase(one); delay(taub - gt6 - 200.2e-6); sim3pulse(pw,0.0,pwN,one,zero,one,0.0,0.0); delay(0.2e-6); zgradpulse(gzlvl7, gt7); delay(2.0e-6); txphase(zero); dec2phase(zero); delay(taub - gt7 - 2.2e-6); sim3pulse(2.0*pw,0.0,2.0*pwN,zero,zero,zero,0.0,0.0); delay(0.2e-6); zgradpulse(gzlvl7, gt7); delay(200.0e-6); delay(taub - gt7 - 200.2e-6); rgpulse(pw, zero, 0.0, 0.0); delay(gt8 + 1.0e-4 + 1.0e-4 - 0.3*pw + 2.0*GRADIENT_DELAY + POWER_DELAY); rgpulse(2*pw,zero,0.0,0.0); dec2power(dpwr2); decpower(dpwr); zgradpulse(icosel*gzlvl8, gt8); delay(1.0e-4); /* rcvron(); */ /* Turn on receiver to warm up before acq */ /* BEGIN ACQUISITION */ statusdelay(C, 1.0e-4); setreceiver(t6); }