def re_measure(cycle=1):
Temp = Uc = Uc_m = Ic = Ue = Ue_m = Ib = 0.0
if ag.temperature() >= 50.0:
print "High temperature! Cooler!!!!"
ag.stop_output("all")
ag.state_output()
while ag.temperature() >= 40.0:
print "Current Temperature: %.2f, Delay: %d sec" % (ag.temperature(), 60 * DELAY_MEASURE)
print "Delay"
for sec in xrange(12 * DELAY_MEASURE):
print "%d, " % (sec * 5),
time.sleep(5)
ag.start_output("all")
for i in xrange(cycle):
time.sleep(DELAY_MEASURE)
Temp += ag.temperature()
Uc += ag.source_value(2, "volt")
Uc_m += ag.measure(2, "volt")
Ic += ag.measure(2, "cur")
Ue += ag.source_value(1, "volt")
Ue_m += ag.measure(1, "volt")
Ib += ag.measure(1, "cur")
cycle = float(cycle)
Measurements["Temp"] = Temp / cycle
Measurements["Uc"] = Uc / cycle
Measurements["Uc_m"] = Uc_m / cycle
Measurements["Ic"] = Ic / cycle
Measurements["Ue"] = Ue / cycle
Measurements["Ue_m"] = Ue_m / cycle
Measurements["Ib"] = Ib / cycle
def re_measure(cycle=1):
Temp = Ud = Ud_m = Id = 0.
if ag.temperature() >= 50.0:
print "Hi, temperature! Cool!"
ag.stop_output("all")
ag.state_output()
while ag.temperature() >= 40.0:
print "Current Temperature: %.2f, Delay: %d sec" % ( ag.temperature(),60 * MEASURE_DELAY )
print "Delay"
for sec in xrange( 12 * MEASURE_DELAY ):
print "%d, " % (sec*5),
time.sleep(5)
ag.start_output("all")
for i in xrange(cycle):
time.sleep( MEASURE_DELAY )
Temp += ag.temperature()
Ud += ag.source_value(1,"volt")
Ud_m += ag.measure(1,"volt")
Id += ag.measure(1,"cur")
cycle = float(cycle)
Measurements["Temp"] = Temp / cycle
Measurements["Ud"] = Ud / cycle
Measurements["Ud_m"] = Ud_m / cycle
Measurements["Id"] = Id / cycle
def re_measure(cycle=1):
Temp = Uc = Uc_m = Ic = Ue = Ib = Ib_m = 0.
if ag.temperature() >= 50.0:
ag.cooler(36.0)
for i in xrange(cycle):
time.sleep( DELAY_MEASURE )
Temp += ag.temperature()
Uc += ag.source_value(2,"volt")
Uc_m += ag.measure(2,"volt")
Ic += ag.measure(2,"cur")
Ue += ag.measure(1,"volt")
Ib += ag.source_value(1,"c")
Ib_m += ag.measure(1,"cur")
cycle = float(cycle)
Measurements["Temp"] = Temp / cycle
Measurements["Uc"] = Uc / cycle
Measurements["Uc_m"] = Uc_m / cycle
Measurements["Ic"] = Ic / cycle
Measurements["Ue"] = Ue / cycle
Measurements["Ib_m"] = Ib_m / cycle
Measurements["Ib"] = Ib / cycle
def re_measure(cycle=1):
global Measurements
if ag.temperature() >= 50.0:
print "High temperature! Cooler!!!!"
ag.stop_output("all")
ag.state_output()
while ag.temperature() >= 40.0:
print "Current Temperature: %.2f, Delay: %d sec" % ( ag.temperature(),60 * MEASURE_DELAY )
print "Delay"
for sec in xrange( 12 * MEASURE_DELAY ):
print "%d, " % (sec*5),
time.sleep(5)
ag.start_output("all")
Ids = Uds = Uds_m = Ugs = Ugs_m = Ubs = Ubs_m = Temp = 0.0
for i in xrange(cycle):
# Impulse measure
time.sleep( MEASURE_DELAY )
_measures = deepcopy(ag.measure_all())
Ids += _measures['ch1']['curr']['meas']
Uds += _measures['ch1']['volt']['sour']
Uds_m += _measures['ch1']['volt']['meas']
Ugs += _measures['ch2']['volt']['sour']
Ugs_m += _measures['ch2']['volt']['meas']
Ubs += _measures['ch3']['volt']['sour']
Ubs_m += _measures['ch3']['volt']['meas']
Temp += _measures['temp']
Measurements['Ids'] = Ids / float(cycle)
Measurements['Uds'] = Uds / float(cycle)
Measurements['Uds_m'] = Uds_m / float(cycle)
Measurements['Ugs'] = Ugs / float(cycle)
Measurements['Ugs_m'] = Ugs_m / float(cycle)
Measurements['Ubs'] = Ubs / float(cycle)
Measurements['Ubs_m'] = Ubs_m / float(cycle)
Measurements['Temp'] = Temp / float(cycle)
return True
finally:
pass
#ag.debug()
return True
if INCLUDE_GRAPHICS:
plt.figure(1,figsize=(18, 9), dpi=80, facecolor='w', edgecolor='k')
print "Current temperature: %.2f" % ( ag.temperature() )
write2file( fmeasure,"@COLS:Ue,Ib,Uc,Ic" ) # Записываем как будут располагаться колонки
style = 0
for Uc in Uc_RANGES:
style+=1;
label_uc = "Uc=%.2f" % (Uc)
GRAPH_2_Y = []
