Mon, 10 Dec 2007 21:28:14 +0100
ported 'dump_trace' to gpib API
# -*- coding: utf-8 -*- import struct def decode_float(s): assert len(s) in [4,8] # exponential term e = ord(s[-1]) if e & 0x80: e = e - 256 # mantissa m = [ord(x) for x in s[:-1]] M = 0. for i in range(len(s)-1): #M += m[i]<<(i*8) M += float(m[i])/2**((i+1)*8) #if m[0] & 0x80: # M = M - 2^(len(s)) return M * 2**(e+1) mm = str(M) mm = '0.'+mm + 'e' + str(e) if len(s) == 8: print "mm = ", mm return eval(mm) def decode_string(s): nb = ord(s[0]) s = s[1:nb+2] r = "" for c in s: if ord(c)>128: c = chr(ord(c)-128) r += c return r EDSP = {0: "No data", 1: "Frequency response", 2: "Power spectrum 1", 3: "Power spectrum 2", 4: "Coherence", 5: "Cross spectrum", 6: "Input time 1", 7: "Input time 2", 8: "Input linear spectrum 1", 9: "Input linear spectrum 2", 10: "Impulse response", 11: "Cross correlation", 12: "Auto correlation 1", 13: "Auto correlation 2", 14: "Histogram 1", 15: "Histogram 2", 16: "Cumulative density function 1", 17: "Cumulative density function 2", 18: "Probability density function 1", 19: "Probability density function 2", 20: "Average linear spectrum 1", 21: "Average linear spectrum 2", 22: "Average time record 1", 23: "Average time record 2", 24: "Synthesis pole-zeros", 25: "Synthesis pole-residue", 26: "Synthesis polynomial", 27: "Synthesis constant", 28: "Windowed time record 1", 29: "Windowed time record 2", 30: "Windowed linear spectrum 1", 31: "Windowed linear spectrum 2", 32: "Filtered time record 1", 33: "Filtered time record 2", 34: "Filtered linear spectrum 1", 35: "Filtered linear spectrum 2", 36: "Time capture buffer", 37: "Captured linear spectrum", 38: "Captured time record", 39: "Throughput time record 1", 40: "Throughput time record 2", 41: "Curve fit", 42: "Weighted function", 43: "Not used", 44: "Orbits", 45: "Demodulation polar", 46: "Preview demod record 1", 47: "Preview demod record 2", 48: "Preview demod linear spectrum 1", 49: "Preview demod linear spectrum 2", } ECH = {0: "Channel 1", 1: "Channel 2", 2: "Channel 1&2", 3: "No channel", } EOVR = ECH EDOM = {0: 'Time', 1: 'Frequency', 2: 'Voltage (amplitude)', } EVLT = {0: "Peak", 1: "RMS", 2: "Volt (indicates peak only)", } EAMP = {0: "Volts", 1: "Volts squared", 2: "PSD (V²/Hz)", 3: "ESD (V²s/Hz)", 4: "PSD¹² (V/Hz¹²)", 5: "No unit", 6: "Unit volts", 7: "Unit volts²", } EXAXIS= {0: "No units", 1: "Hertz", 2: "RPM", 3: "Orders", 4: "Seconds", 5: "Revs", 6: "Degrees", 7: "dB", 8: "dBV", 9: "Volts", 10: "V Hz¹²", 11: "Hz/s", 12: "V/EU", 13: "Vrms", 14: "V²/Hz", 15: "%", 16: "Points", 17: "Records", 18: "Ohms", 19: "Hertz/octave", 20: "Pulse/Rev", 21: "Decades", 22: "Minutes", 23: "V²s/Hz", 24: "Octave", 25: "Seconds/Decade", 26: "Seconds/Octave", #... } EMEAS = {0: "Linear resolution", 1: "Log resolution", 2: "Swept sine", 3: "Time capture", 4: "Linear resolution throughput", } EDEMOD1 = {45: "AM", 46: "FM", 47: "PM", } EDEMOD2 = EDEMOD1 EAVG = {0: "No data", 1: "Not averaged", 2: "Averaged",} EWIN = {0: "N/A", 1: "Hann", 2: "Flat top", #... } HEADER = [ ("Display function", EDSP, 'h', 2), ('Number of elements', int, 'h', 2), ('Displayed elements', int, 'h', 2), ('Number of averages', int, 'h', 2), ('Channel selection', ECH, 'h', 2), ('Overflow status', EOVR, 'h', 2), ('Overlap percentage', int, 'h', 2), ('Domain', EDOM, 'h', 2), ('Volts peak/rms', EVLT, 'h', 2), ('Amplitude units', EAMP, 'h', 2), ('X axis units', EXAXIS, 'h', 2), ('Auto math label', str, 's', 14), ('Trace label', str, 's', 22), ('EU label 1', str, 's', 6), ('EU label 2', str, 's', 6), ('Float/Interger', bool, 'h', 2), ('Complex/Real', bool, 'h', 2), ('Live/Recalled', bool, 'h', 2), ('Math result', bool, 'h', 2), ('Real/Complex input', bool, 'h', 2), ('Log/Linear data', bool, 'h', 2), ('Auto math', bool, 'h', 2), ('Real time status', bool, 'h', 2), ('Measurement mode', EMEAS, 'h', 2), ('Window', EWIN, 'h', 2), ('Demod type channel 1', EDEMOD1, 'h', 2), ('Demod type channel 2', EDEMOD2, 'h', 2), ('Demod active channel 1', bool, 'h', 2), ('Demod active channel 2', bool, 'h', 2), ('Average status', EAVG, 'h', 2), ('Not used', int, 'hh', 4), ('Samp freq/2 (real)', decode_float, None, 4), ('Samp freq/2 (imag)', decode_float, None, 4), ('Not used', decode_float, None, 4), ('Delta X-axis', decode_float, None, 4), ('Max range', decode_float, None, 4), ('Start time value', decode_float, None, 4), ('Expon wind const 1', decode_float, None, 4), ('Expon wind const 2', decode_float, None, 4), ('EU value chan 1', decode_float, None, 4), ('EU value chan 2', decode_float, None, 4), ('Trig delay chan 1', decode_float, None, 4), ('Trig delay chan 2', decode_float, None, 4), ('Start freq value', decode_float, None, 8), ('Start data value', decode_float, None, 8), ] def decode_file(filename): d = open(filename).read() typ = d[:2] assert typ == "#A" totlen = struct.unpack('>h', d[2:4])[0] idx = 4 tt=0 header = {} for i, (nam, dtype, fmt, nbytes) in enumerate(HEADER): if dtype == str: val = decode_string(d[idx:]) else: if fmt: v = struct.unpack('>'+fmt, d[idx: idx+nbytes])[0] if isinstance(dtype, dict): val = dtype.get(int(v), "N/A") else: val = dtype(v) else: val = dtype(d[idx: idx+nbytes]) print idx, hex(idx), nam, ":", val header[nam] = val idx += nbytes resu = [] for i in range(header["Number of elements"]): resu.append(decode_float(d[idx: idx+4])) idx += 4 #print "resu = ", resu #return import pylab import numpy resu = numpy.array(resu, dtype=float) print "max = ", max(resu) #xr = numpy.linspace(0, header['Delta X-axis'], len(resu)) sf = header['Start freq value'] xr = numpy.linspace(sf, sf+20000, len(resu)) mn = min(resu[resu>0]) resu[resu==0] = mn pylab.plot(xr, 10*numpy.log10(resu)) pylab.show() # tt=0 # for i, (nam, dtype, nbytes) in enumerate(HEADER): # if dtype == str: # nb = ord(struct.unpack('c', d[idx])[0]) # val = d[idx+1:idx+1+nb] # else: # v = struct.unpack('>d', d[idx: idx+(nbytes*4)])[0] # if isinstance(dtype, dict): # val = dtype.get(int(v), "N/A") # else: # val = dtype(v) # print idx, nam, ":", val # idx += nbytes*4 if __name__ == "__main__": import sys decode_file(sys.argv[1])