laserfire = laserfire[1] def setdelay(delay): delay = laserfire - delay/pb.s # Convert to SI from PB units for d in ddgs: d.setDelay('A', 'T0', delay) setdelay(decelSeq.off+offset + 0.008/decelSeq.fvel*pb.s) pb.build() print decelSeq.off+offset # After this point, files are created and the script is saved. raw_input('Final Check! Enter when done.') # Bunching Stages numbers = yeutil.frange(0,320,32) # Define output files, together with the tag that labels them. files = {(n,'SF'):'SF Mode l=%d' %(333-n) for n in numbers} files.update({(n,'S=1'):'S=1 Mode l=%d' %(333-n) for n in numbers}) o = output.output(files) f = yeutil.yeopen('Decel-offtimes') # Saves a copy of the script to the Data folder yeutil.saveScript() # Loop through speeds and measure peak heights for n in numbers: for mode in ['S=1','SF']: print mode print n
files = {(v,'SF'):'SF Mode vf=%d' %(v) for v in vf} files.update({(v,'S=1'):'S=1 Mode vf=%d' %(v) for v in vf}) o = output.output(files) f = yeutil.yeopen('Decel-offtimes') # Saves a copy of the script to the Data folder yeutil.saveScript() # Loop through speeds and measure peak heights for v in vf: for mode in ['S=1','SF']: decelProg(810,v,mode) f.write('vi=%d\tvf=%d\tmode=%s\tdelay=%f\n'\ %(810,v,mode,decelSeq.off+offset)) full = 8e-3/v delay = yeutil.frange(-full,full,full/7) delay=full for d in delay: peak = (decelSeq.off+offset + 0.008/decelSeq.fvel)*pb.s if mode == 'S=1': peak += ((180 - 2*decelSeq.phi)*5e-3/180/decelSeq.fvel*pb.s) print peak setdelay(peak + d*pb.s) for ii in xrange(1): o.take(counter,'%.2f' %(d*1e6),(v,mode)) f.close() print 'DONE!\a'
pb.add(1, [0], [2800 * pb.us]) pb.add(2, [0], [2800 * pb.us]) pb.add(3, [0], [2800 * pb.us]) pb.add(4, [0], [2800 * pb.us]) pb.build() pb.build() #raw_input('Final Check!') # Saves a copy of the script to the Data folder yeutil.saveScript() #delays = yeutil.frange(2760,3240,40) for Argon delays333 = yeutil.frange(2200, 2450, 25) # for neon #delays=linspace(2200,2450,6) delays333 = linspace(2200, 2400, 6) #delays=[2350] delays40 = yeutil.frange(472, 526, 20) delays40 = linspace(472, 504, 6) delays = empty((delays333.size + delays40.size), dtype=delays333.dtype) delays[0::2] = delays40 delays[1::2] = delays333 #voltages = yeutil.frange(2400,4200,600) voltages = [500, 2000, 4000, 8000] voltages = [12000] #task.write(100000*[9000/15000.0*10])
f = yeutil.yeopen('Decel-offtimes') # Saves a copy of the script to the Data folder yeutil.saveScript() # Loop through speeds and measure peak heights for v in vf: for mode in ['S=3', 'SF']: print mode decelSeq = decelProg(810, v, mode) f.write('vi=%d\tvf=%d\tmode=%s\tdelay=%f\n'\ %(810,v,mode,decelSeq.off+offset)) f.flush() full = 3e-3 / v delay = yeutil.frange(-full, full, full / 7) delay = yeutil.frange(0, full * 2, full / 7) for d in delay: dist = 11e-3 - decelSeq.offPhi * 5e-3 / 180 peak = (decelSeq.off + offset + dist / decelSeq.fvel) * pb.s #print peak #if mode == 'S=1': # peak += ((180 - 2*decelSeq.phi)*5e-3/180/decelSeq.fvel*pb.s) setdelay(peak + d * pb.s) for ii in xrange(1): o.take(counter, '%.2f' % (d * 1e6), (v, mode)) f.close() print 'DONE!\a'
def setdelay(delay): delay = laserfire - delay / pb.s # Convert to SI from PB units for d in ddgs: d.setDelay('A', 'T0', delay) setdelay(decelSeq.off + offset + 0.008 / decelSeq.fvel * pb.s) pb.build() print decelSeq.off + offset # After this point, files are created and the script is saved. raw_input('Final Check! Enter when done.') # Bunching Stages numbers = yeutil.frange(0, 320, 32) # Define output files, together with the tag that labels them. files = {(n, 'SF'): 'SF Mode l=%d' % (333 - n) for n in numbers} files.update({(n, 'S=1'): 'S=1 Mode l=%d' % (333 - n) for n in numbers}) o = output.output(files) f = yeutil.yeopen('Decel-offtimes') # Saves a copy of the script to the Data folder yeutil.saveScript() # Loop through speeds and measure peak heights for n in numbers: for mode in ['S=1', 'SF']: print mode print n