Пример #1
0
def getDATA_hspike(folderName):
    print "********* Loading hspike data from '" + folderName + "' ***********"
    inputfile = InputFile(folderName + "/input.txt")
    inputfile.calcBasicParams()

    convFactor1 = inputfile.N_sp / inputfile.dT  #superpartices/timestep -> particles/sec
    convFactor2 = 1.60217657e-19 * inputfile.N_sp / inputfile.dT  # superparticles/timestep -> Amps
    convFactor3 = (inputfile.dz / inputfile.Omega_pe
                   )**2 * inputfile.T_ref  #dimless potential -> Volts

    (ts, emit, sigma,
     incident) = np.loadtxt(folderName + "/arcbounds_original.dat",
                            usecols=(0, 10, 11, 12),
                            unpack=True)
    useIdxs = np.arange(0, len(ts), 5)
    ts = ts[useIdxs]
    emit = emit[useIdxs]
    sigma = sigma[useIdxs]
    incident = incident[useIdxs]

    t = ts * inputfile.dT * 1e9  #ns
    emit *= convFactor1 / 5.0  #particles/sec
    sigma *= inputfile.dZ  #cm
    incident *= convFactor1 / 5.0  #particles/sec

    return (t, emit, sigma, incident)
Пример #2
0
def getData_IV(folderName):
    print "********* Loading IV data from '" + folderName + "' ***********"
    inputfile = InputFile(folderName + "/input.txt")
    inputfile.calcBasicParams()
    
    convFactor1 = inputfile.N_sp/inputfile.dT #superpartices/timestep -> particles/sec
    convFactor2 = 1.60217657e-19*inputfile.N_sp/inputfile.dT # superparticles/timestep -> Amps
    convFactor3 = (inputfile.dz/inputfile.Omega_pe)**2*inputfile.T_ref #dimless potential -> Volts
    
    #Load circuit data
    if inputfile.CircuitName == "FixedVoltage_resistorCapacitor":
        (circ_ts, circ_deltaQ, circ_U, circuitCurrent) = \
            np.loadtxt(folderName + "/circuit.dat", usecols=(0,1,2,3), unpack=True)
        
        t = circ_ts*inputfile.dT*1e9         #ns
        I = circ_deltaQ*convFactor2          #Amps
        U = circ_U*convFactor3               #Volts
        I_circ = circuitCurrent*convFactor2  #Amps
        
        print "done."
        return (t,I,U,I_circ)
    
    else:
        (circ_ts, circ_deltaQ, circ_U) = np.loadtxt(folderName + "/circuit.dat", usecols=(0,1,2), unpack=True)
        circuitCurrent=np.zeros_like(circ_ts)

        t = circ_ts*inputfile.dT*1e9         #ns
        I = circ_deltaQ*convFactor2          #Amps
        U = circ_U*convFactor3               #Volts
    
        print "done."
        return (t,I,U)
Пример #3
0
def getDATA_nParticles(folderName):
    print "********* Loading nParticles data from '" + folderName + "' ***********"
    inputfile = InputFile(folderName + "/input.txt")
    inputfile.calcBasicParams()

    (t, e,i,n) = np.loadtxt(folderName + "/mainStats.dat", usecols=(1,3,4,5), unpack=True)
    
    e*=inputfile.N_sp
    i*=inputfile.N_sp
    n*=inputfile.N_sp
    
    return (t,e,i,n)
Пример #4
0
def getDATA_nParticles(folderName):
    print "********* Loading nParticles data from '" + folderName + "' ***********"
    inputfile = InputFile(folderName + "/input.txt")
    inputfile.calcBasicParams()

    (t, e, i, n) = np.loadtxt(folderName + "/mainStats.dat",
                              usecols=(1, 3, 4, 5),
                              unpack=True)

    e *= inputfile.N_sp
    i *= inputfile.N_sp
    n *= inputfile.N_sp

    return (t, e, i, n)
Пример #5
0
def getDATA_hspike(folderName):
    print "********* Loading hspike data from '" + folderName + "' ***********"
    inputfile = InputFile(folderName + "/input.txt")
    inputfile.calcBasicParams()

    convFactor1 = inputfile.N_sp/inputfile.dT #superpartices/timestep -> particles/sec
    convFactor2 = 1.60217657e-19*inputfile.N_sp/inputfile.dT # superparticles/timestep -> Amps
    convFactor3 = (inputfile.dz/inputfile.Omega_pe)**2*inputfile.T_ref #dimless potential -> Volts
    
    (ts, emit, sigma, incident) = np.loadtxt(folderName + "/arcbounds_original.dat", usecols=(0,10,11,12), unpack=True)
    useIdxs = np.arange(0,len(ts),5)
    ts = ts[useIdxs]
    emit = emit[useIdxs]
    sigma = sigma[useIdxs]
    incident = incident[useIdxs]
    
    t = ts*inputfile.dT*1e9 #ns    
    emit *= convFactor1/5.0 #particles/sec
    sigma *= inputfile.dZ #cm
    incident *= convFactor1/5.0 #particles/sec
    
    return (t,emit,sigma,incident)
Пример #6
0
def getData_IV(folderName):
    print "********* Loading IV data from '" + folderName + "' ***********"
    inputfile = InputFile(folderName + "/input.txt")
    inputfile.calcBasicParams()

    convFactor1 = inputfile.N_sp / inputfile.dT  #superpartices/timestep -> particles/sec
    convFactor2 = 1.60217657e-19 * inputfile.N_sp / inputfile.dT  # superparticles/timestep -> Amps
    convFactor3 = (inputfile.dz / inputfile.Omega_pe
                   )**2 * inputfile.T_ref  #dimless potential -> Volts

    #Load circuit data
    if inputfile.CircuitName == "FixedVoltage_resistorCapacitor":
        (circ_ts, circ_deltaQ, circ_U, circuitCurrent) = \
            np.loadtxt(folderName + "/circuit.dat", usecols=(0,1,2,3), unpack=True)

        t = circ_ts * inputfile.dT * 1e9  #ns
        I = circ_deltaQ * convFactor2  #Amps
        U = circ_U * convFactor3  #Volts
        I_circ = circuitCurrent * convFactor2  #Amps

        print "done."
        return (t, I, U, I_circ)

    else:
        (circ_ts, circ_deltaQ,
         circ_U) = np.loadtxt(folderName + "/circuit.dat",
                              usecols=(0, 1, 2),
                              unpack=True)
        circuitCurrent = np.zeros_like(circ_ts)

        t = circ_ts * inputfile.dT * 1e9  #ns
        I = circ_deltaQ * convFactor2  #Amps
        U = circ_U * convFactor3  #Volts

        print "done."
        return (t, I, U)
Пример #7
0
if not (species == "e" or species == "Cu" or species == "Cup"):
    print "species must be one of 'e', 'Cu', 'Cup'"
    exit(1)

speed = float(sys.argv[9])

tempunit = sys.argv[10]
if not (tempunit == "K" or tempunit == "eV"):
    print "tempunit must be one of 'K' or 'eV'"
    exit(1)

#Get the scaling setup
MODLOAD_parentdir = os.path.dirname(os.path.dirname(os.path.abspath(__file__)))
sys.path.insert(0,MODLOAD_parentdir) 
from calcScaling import InputFile
inputfile = InputFile("../input.txt")
inputfile.calcBasicParams()

nr      = inputfile.nr  #system size [grids]
nz      = inputfile.nz  #system size [grids]

N_sp  = inputfile.N_sp  #Particle/superparticle ratio
dZ    = inputfile.dZ    #um/grid
dz    = inputfile.dz    #Ldb/grid (typically 0.5)

Ldb   = inputfile.Ldb   #Debye length [cm]
O_pe  = inputfile.O_pe  #Plasma angular frequency [s^-1]

if max_r > inputfile.R*1e4:
    print
    print "************************************************************************************************"
print "Got options:"
print " - mintime = ", mintime
print " - maxtime = ", maxtime
print
print " - species = ", species
print " - edge    = ", edg
print
print " - nbinsX  = ", nbinsX
print " - nbinsY  = ", nbinsY
print

#Get the scaling setup
MODLOAD_parentdir = os.path.dirname(os.path.dirname(os.path.abspath(__file__)))
sys.path.insert(0, MODLOAD_parentdir)
from calcScaling import InputFile
inputfile = InputFile("../input.txt")
inputfile.calcBasicParams()
print
print "Time window =", mintime * inputfile.dT * 1e9, "--", maxtime * inputfile.dT * 1e9, "ns"
print

# if minR == maxR and minR == None:
#     minR = 0.0
#     maxR = inputfile.nr

step = []
z = []
r = []
vz = []
vr = []
vt = []