X-Git-Url: https://git.gag.com/?a=blobdiff_plain;f=gr-utils%2Fsrc%2Fpython%2Fusrp_siggen.py;fp=gr-utils%2Fsrc%2Fpython%2Fusrp_siggen.py;h=da83da770d43429457dc2316f442abb77c34cda1;hb=35e43e8d8c271e6842191cac3fc3f2f88a861183;hp=8ae2fbfbfd93ade4518cff28311ab3ba946108d6;hpb=ea29b08aeb54227e6628f655ccfdb96fe4d8c378;p=debian%2Fgnuradio diff --git a/gr-utils/src/python/usrp_siggen.py b/gr-utils/src/python/usrp_siggen.py index 8ae2fbfb..da83da77 100755 --- a/gr-utils/src/python/usrp_siggen.py +++ b/gr-utils/src/python/usrp_siggen.py @@ -1,6 +1,6 @@ #!/usr/bin/env python # -# Copyright 2004,2005,2007,2008 Free Software Foundation, Inc. +# Copyright 2008,2009 Free Software Foundation, Inc. # # This file is part of GNU Radio # @@ -20,200 +20,312 @@ # Boston, MA 02110-1301, USA. # -from gnuradio import gr, gru -from gnuradio import usrp +DESC_KEY = 'desc' +SAMP_RATE_KEY = 'samp_rate' +LINK_RATE_KEY = 'link_rate' +DAC_RATE_KEY = 'dac_rate' +INTERP_KEY = 'interp' +GAIN_KEY = 'gain' +TX_FREQ_KEY = 'tx_freq' +DDC_FREQ_KEY = 'ddc_freq' +BB_FREQ_KEY = 'bb_freq' +AMPLITUDE_KEY = 'amplitude' +AMPL_RANGE_KEY = 'ampl_range' +WAVEFORM_FREQ_KEY = 'waveform_freq' +WAVEFORM_OFFSET_KEY = 'waveform_offset' +WAVEFORM2_FREQ_KEY = 'waveform2_freq' +FREQ_RANGE_KEY = 'freq_range' +GAIN_RANGE_KEY = 'gain_range' +TYPE_KEY = 'type' + +def setter(ps, key, val): ps[key] = val + +from gnuradio import gr, eng_notation +from gnuradio.gr.pubsub import pubsub from gnuradio.eng_option import eng_option -from gnuradio import eng_notation +from gnuradio import usrp_options from optparse import OptionParser import sys +import math +n2s = eng_notation.num_to_str -class my_top_block(gr.top_block): - def __init__ (self, nsamples): +waveforms = { gr.GR_SIN_WAVE : "Complex Sinusoid", + gr.GR_CONST_WAVE : "Constant", + gr.GR_GAUSSIAN : "Gaussian Noise", + gr.GR_UNIFORM : "Uniform Noise", + "2tone" : "Two Tone", + "sweep" : "Sweep" } + +# +# GUI-unaware GNU Radio flowgraph. This may be used either with command +# line applications or GUI applications. +# +class top_block(gr.top_block, pubsub): + def __init__(self, options, args): gr.top_block.__init__(self) + pubsub.__init__(self) + self._verbose = options.verbose + #initialize values from options + self._setup_usrpx(options) + self.subscribe(INTERP_KEY, lambda i: setter(self, SAMP_RATE_KEY, self[DAC_RATE_KEY]/i)) + self.subscribe(SAMP_RATE_KEY, lambda e: setter(self, LINK_RATE_KEY, e*32)) + self[INTERP_KEY] = options.interp or 16 + self[TX_FREQ_KEY] = options.tx_freq + self[AMPLITUDE_KEY] = options.amplitude + self[WAVEFORM_FREQ_KEY] = options.waveform_freq + self[WAVEFORM_OFFSET_KEY] = options.offset + self[WAVEFORM2_FREQ_KEY] = options.waveform2_freq + self[BB_FREQ_KEY] = 0 + self[DDC_FREQ_KEY] = 0 + #subscribe set methods + self.subscribe(INTERP_KEY, self.set_interp) + self.subscribe(GAIN_KEY, self.set_gain) + self.subscribe(TX_FREQ_KEY, self.set_freq) + self.subscribe(AMPLITUDE_KEY, self.set_amplitude) + self.subscribe(WAVEFORM_FREQ_KEY, self.set_waveform_freq) + self.subscribe(WAVEFORM2_FREQ_KEY, self.set_waveform2_freq) + self.subscribe(TYPE_KEY, self.set_waveform) + #force update on pubsub keys + for key in (INTERP_KEY, GAIN_KEY, TX_FREQ_KEY, + AMPLITUDE_KEY, WAVEFORM_FREQ_KEY, WAVEFORM_OFFSET_KEY, WAVEFORM2_FREQ_KEY): + self[key] = self[key] + self[TYPE_KEY] = options.type #set type last + + def _setup_usrpx(self, options): + self._u = usrp_options.create_usrp_sink(options) + self.publish(DESC_KEY, lambda: str(self._u)) + self.publish(DAC_RATE_KEY, self._u.dac_rate) + self.publish(FREQ_RANGE_KEY, self._u.freq_range) + self.publish(GAIN_RANGE_KEY, self._u.gain_range) + self.publish(GAIN_KEY, self._u.gain) + if self._verbose: print str(self._u) + + def _set_tx_amplitude(self, ampl): + """ + Sets the transmit amplitude sent to the USRP + @param ampl the amplitude or None for automatic + """ + ampl_range = self[AMPL_RANGE_KEY] + if ampl is None: ampl = (ampl_range[1] - ampl_range[0])*0.15 + ampl_range[0] + self[AMPLITUDE_KEY] = max(ampl_range[0], min(ampl, ampl_range[1])) + + def set_interp(self, interp): + if not self._u.set_interp(interp): + raise RuntimeError("Failed to set interpolation rate %i" % (interp,)) + + if self._verbose: + print "USRP interpolation rate:", interp + print "USRP IF bandwidth: %sHz" % (n2s(self[SAMP_RATE_KEY]),) + + if self[TYPE_KEY] in (gr.GR_SIN_WAVE, gr.GR_CONST_WAVE): + self._src.set_sampling_freq(self[SAMP_RATE_KEY]) + elif self[TYPE_KEY] == "2tone": + self._src1.set_sampling_freq(self[SAMP_RATE_KEY]) + self._src2.set_sampling_freq(self[SAMP_RATE_KEY]) + elif self[TYPE_KEY] == "sweep": + self._src1.set_sampling_freq(self[SAMP_RATE_KEY]) + self._src2.set_sampling_freq(self[WAVEFORM_FREQ_KEY]*2*math.pi/self[SAMP_RATE_KEY]) + else: + return True # Waveform not yet set - # controllable values - self.interp = 64 - self.waveform_type = gr.GR_SIN_WAVE - self.waveform_ampl = 16000 - self.waveform_freq = 100.12345e3 - self.waveform_offset = 0 - self.nsamples = nsamples - self._instantiate_blocks () - self.set_waveform_type (self.waveform_type) - - def usb_freq (self): - return self.u.dac_freq() / self.interp - - def usb_throughput (self): - return self.usb_freq () * 4 - - def set_waveform_type (self, type): - ''' - valid waveform types are: gr.GR_SIN_WAVE, gr.GR_CONST_WAVE, - gr.GR_UNIFORM and gr.GR_GAUSSIAN - ''' - self._configure_graph (type) - self.waveform_type = type - - def set_waveform_ampl (self, ampl): - self.waveform_ampl = ampl - self.siggen.set_amplitude (ampl) - self.noisegen.set_amplitude (ampl) - - def set_waveform_freq (self, freq): - self.waveform_freq = freq - self.siggen.set_frequency (freq) - - def set_waveform_offset (self, offset): - self.waveform_offset = offset - self.siggen.set_offset (offset) - - def set_interpolator (self, interp): - self.interp = interp - self.siggen.set_sampling_freq (self.usb_freq ()) - self.u.set_interp_rate (interp) - - def _instantiate_blocks (self): - self.src = None - self.u = usrp.sink_c (0, self.interp) - - self.siggen = gr.sig_source_c (self.usb_freq (), - gr.GR_SIN_WAVE, - self.waveform_freq, - self.waveform_ampl, - self.waveform_offset) - - self.noisegen = gr.noise_source_c (gr.GR_UNIFORM, - self.waveform_ampl) - - self.head = None - if self.nsamples > 0: - self.head = gr.head(gr.sizeof_gr_complex, int(self.nsamples)) - - # self.file_sink = gr.file_sink (gr.sizeof_gr_complex, "siggen.dat") - - def _configure_graph (self, type): - try: - self.lock() - self.disconnect_all () - - if self.head: - self.connect(self.head, self.u) - tail = self.head - else: - tail = self.u - - if type == gr.GR_SIN_WAVE or type == gr.GR_CONST_WAVE: - self.connect (self.siggen, tail) - # self.connect (self.siggen, self.file_sink) - self.siggen.set_waveform (type) - self.src = self.siggen - elif type == gr.GR_UNIFORM or type == gr.GR_GAUSSIAN: - self.connect (self.noisegen, tail) - self.noisegen.set_type (type) - self.src = self.noisegen - else: - raise ValueError, type - finally: - self.unlock() + if self._verbose: print "Set interpolation rate to:", interp + return True + + def set_gain(self, gain): + if gain is None: + g = self[GAIN_RANGE_KEY] + gain = float(g[0]+g[1])/2 + if self._verbose: + print "Using auto-calculated mid-point TX gain" + self[GAIN_KEY] = gain + return + self._u.set_gain(gain) + if self._verbose: + print "Set TX gain to:", gain def set_freq(self, target_freq): - """ - Set the center frequency we're interested in. - - @param target_freq: frequency in Hz - @rypte: bool - Tuning is a two step process. First we ask the front-end to - tune as close to the desired frequency as it can. Then we use - the result of that operation and our target_frequency to - determine the value for the digital up converter. - """ - r = self.u.tune(self.subdev.which(), self.subdev, target_freq) - if r: - #print "r.baseband_freq =", eng_notation.num_to_str(r.baseband_freq) - #print "r.dxc_freq =", eng_notation.num_to_str(r.dxc_freq) - #print "r.residual_freq =", eng_notation.num_to_str(r.residual_freq) - #print "r.inverted =", r.inverted - return True - - return False - - - -def main (): - parser = OptionParser (option_class=eng_option) - parser.add_option ("-T", "--tx-subdev-spec", type="subdev", default=(0, 0), - help="select USRP Tx side A or B") - parser.add_option ("-f", "--rf-freq", type="eng_float", default=None, - help="set RF center frequency to FREQ") - parser.add_option ("-i", "--interp", type="int", default=64, - help="set fgpa interpolation rate to INTERP [default=%default]") - - parser.add_option ("--sine", dest="type", action="store_const", const=gr.GR_SIN_WAVE, - help="generate a complex sinusoid [default]", default=gr.GR_SIN_WAVE) - parser.add_option ("--const", dest="type", action="store_const", const=gr.GR_CONST_WAVE, - help="generate a constant output") - parser.add_option ("--gaussian", dest="type", action="store_const", const=gr.GR_GAUSSIAN, - help="generate Gaussian random output") - parser.add_option ("--uniform", dest="type", action="store_const", const=gr.GR_UNIFORM, - help="generate Uniform random output") - - parser.add_option ("-w", "--waveform-freq", type="eng_float", default=0, - help="set waveform frequency to FREQ [default=%default]") - parser.add_option ("-a", "--amplitude", type="eng_float", default=16e3, - help="set waveform amplitude to AMPLITUDE [default=%default]", metavar="AMPL") - parser.add_option ("-g", "--gain", type="eng_float", default=None, - help="set output gain to GAIN [default=%default]") - parser.add_option ("-o", "--offset", type="eng_float", default=0, - help="set waveform offset to OFFSET [default=%default]") - parser.add_option ("-N", "--nsamples", type="eng_float", default=0, - help="set number of samples to transmit [default=+inf]") - (options, args) = parser.parse_args () - - if len(args) != 0: - parser.print_help() - raise SystemExit - - if options.rf_freq is None: - sys.stderr.write("usrp_siggen: must specify RF center frequency with -f RF_FREQ\n") - parser.print_help() - raise SystemExit - - tb = my_top_block(options.nsamples) - tb.set_interpolator (options.interp) - tb.set_waveform_type (options.type) - tb.set_waveform_freq (options.waveform_freq) - tb.set_waveform_ampl (options.amplitude) - tb.set_waveform_offset (options.offset) - - # determine the daughterboard subdevice we're using - if options.tx_subdev_spec is None: - options.tx_subdev_spec = usrp.pick_tx_subdevice(tb.u) - - m = usrp.determine_tx_mux_value(tb.u, options.tx_subdev_spec) - #print "mux = %#04x" % (m,) - tb.u.set_mux(m) - tb.subdev = usrp.selected_subdev(tb.u, options.tx_subdev_spec) - print "Using TX d'board %s" % (tb.subdev.side_and_name(),) - - if options.gain is None: - tb.subdev.set_gain(tb.subdev.gain_range()[1]) # set max Tx gain - else: - tb.subdev.set_gain(options.gain) # set max Tx gain - - if not tb.set_freq(options.rf_freq): - sys.stderr.write('Failed to set RF frequency\n') - raise SystemExit + if target_freq is None: + f = self[FREQ_RANGE_KEY] + target_freq = float(f[0]+f[1])/2.0 + if self._verbose: + print "Using auto-calculated mid-point frequency" + self[TX_FREQ_KEY] = target_freq + return + + tr = self._u.set_center_freq(target_freq) + fs = "%sHz" % (n2s(target_freq),) + if tr is not None: + self._freq = target_freq + self[DDC_FREQ_KEY] = tr.dxc_freq + self[BB_FREQ_KEY] = tr.baseband_freq + if self._verbose: + print "Set center frequency to", fs + print "Tx baseband frequency: %sHz" % (n2s(tr.baseband_freq),) + print "Tx DDC frequency: %sHz" % (n2s(tr.dxc_freq),) + print "Tx residual frequency: %sHz" % (n2s(tr.residual_freq),) + elif self._verbose: print "Failed to set freq." + return tr + + def set_waveform_freq(self, freq): + if self[TYPE_KEY] == gr.GR_SIN_WAVE: + self._src.set_frequency(freq) + elif self[TYPE_KEY] == "2tone": + self._src1.set_frequency(freq) + elif self[TYPE_KEY] == 'sweep': + #there is no set sensitivity, redo fg + self[TYPE_KEY] = self[TYPE_KEY] + return True + + def set_waveform2_freq(self, freq): + if freq is None: + self[WAVEFORM2_FREQ_KEY] = -self[WAVEFORM_FREQ_KEY] + return + if self[TYPE_KEY] == "2tone": + self._src2.set_frequency(freq) + elif self[TYPE_KEY] == "sweep": + self._src1.set_frequency(freq) + return True + + def set_waveform(self, type): + self.lock() + self.disconnect_all() + if type == gr.GR_SIN_WAVE or type == gr.GR_CONST_WAVE: + self._src = gr.sig_source_c(self[SAMP_RATE_KEY], # Sample rate + type, # Waveform type + self[WAVEFORM_FREQ_KEY], # Waveform frequency + self[AMPLITUDE_KEY], # Waveform amplitude + self[WAVEFORM_OFFSET_KEY]) # Waveform offset + elif type == gr.GR_GAUSSIAN or type == gr.GR_UNIFORM: + self._src = gr.noise_source_c(type, self[AMPLITUDE_KEY]) + elif type == "2tone": + self._src1 = gr.sig_source_c(self[SAMP_RATE_KEY], + gr.GR_SIN_WAVE, + self[WAVEFORM_FREQ_KEY], + self[AMPLITUDE_KEY]/2.0, + 0) + if(self[WAVEFORM2_FREQ_KEY] is None): + self[WAVEFORM2_FREQ_KEY] = -self[WAVEFORM_FREQ_KEY] + + self._src2 = gr.sig_source_c(self[SAMP_RATE_KEY], + gr.GR_SIN_WAVE, + self[WAVEFORM2_FREQ_KEY], + self[AMPLITUDE_KEY]/2.0, + 0) + self._src = gr.add_cc() + self.connect(self._src1,(self._src,0)) + self.connect(self._src2,(self._src,1)) + elif type == "sweep": + # rf freq is center frequency + # waveform_freq is total swept width + # waveform2_freq is sweep rate + # will sweep from (rf_freq-waveform_freq/2) to (rf_freq+waveform_freq/2) + if self[WAVEFORM2_FREQ_KEY] is None: + self[WAVEFORM2_FREQ_KEY] = 0.1 + + self._src1 = gr.sig_source_f(self[SAMP_RATE_KEY], + gr.GR_TRI_WAVE, + self[WAVEFORM2_FREQ_KEY], + 1.0, + -0.5) + self._src2 = gr.frequency_modulator_fc(self[WAVEFORM_FREQ_KEY]*2*math.pi/self[SAMP_RATE_KEY]) + self._src = gr.multiply_const_cc(self[AMPLITUDE_KEY]) + self.connect(self._src1,self._src2,self._src) + else: + raise RuntimeError("Unknown waveform type") + + self.connect(self._src, self._u) + self.unlock() + + if self._verbose: + print "Set baseband modulation to:", waveforms[type] + if type == gr.GR_SIN_WAVE: + print "Modulation frequency: %sHz" % (n2s(self[WAVEFORM_FREQ_KEY]),) + print "Initial phase:", self[WAVEFORM_OFFSET_KEY] + elif type == "2tone": + print "Tone 1: %sHz" % (n2s(self[WAVEFORM_FREQ_KEY]),) + print "Tone 2: %sHz" % (n2s(self[WAVEFORM2_FREQ_KEY]),) + elif type == "sweep": + print "Sweeping across %sHz to %sHz" % (n2s(-self[WAVEFORM_FREQ_KEY]/2.0),n2s(self[WAVEFORM_FREQ_KEY]/2.0)) + print "Sweep rate: %sHz" % (n2s(self[WAVEFORM2_FREQ_KEY]),) + print "TX amplitude:", self[AMPLITUDE_KEY] + + + def set_amplitude(self, amplitude): + if amplitude < 0.0 or amplitude > 1.0: + if self._verbose: print "Amplitude out of range:", amplitude + return False + + if self[TYPE_KEY] in (gr.GR_SIN_WAVE, gr.GR_CONST_WAVE, gr.GR_GAUSSIAN, gr.GR_UNIFORM): + self._src.set_amplitude(amplitude) + elif self[TYPE_KEY] == "2tone": + self._src1.set_amplitude(amplitude/2.0) + self._src2.set_amplitude(amplitude/2.0) + elif self[TYPE_KEY] == "sweep": + self._src.set_k(amplitude) + else: + return True # Waveform not yet set + + if self._verbose: print "Set amplitude to:", amplitude + return True + +def get_options(): + usage="%prog: [options]" + + parser = OptionParser(option_class=eng_option, usage=usage) + usrp_options.add_tx_options(parser) + parser.add_option("-f", "--tx-freq", type="eng_float", default=None, + help="Set carrier frequency to FREQ [default=mid-point]", metavar="FREQ") + parser.add_option("-x", "--waveform-freq", type="eng_float", default=0, + help="Set baseband waveform frequency to FREQ [default=%default]") + parser.add_option("-y", "--waveform2-freq", type="eng_float", default=None, + help="Set 2nd waveform frequency to FREQ [default=%default]") + parser.add_option("--sine", dest="type", action="store_const", const=gr.GR_SIN_WAVE, + help="Generate a carrier modulated by a complex sine wave", default=gr.GR_SIN_WAVE) + parser.add_option("--const", dest="type", action="store_const", const=gr.GR_CONST_WAVE, + help="Generate a constant carrier") + parser.add_option("--offset", type="eng_float", default=0, + help="Set waveform phase offset to OFFSET [default=%default]") + parser.add_option("--gaussian", dest="type", action="store_const", const=gr.GR_GAUSSIAN, + help="Generate Gaussian random output") + parser.add_option("--uniform", dest="type", action="store_const", const=gr.GR_UNIFORM, + help="Generate Uniform random output") + parser.add_option("--2tone", dest="type", action="store_const", const="2tone", + help="Generate Two Tone signal for IMD testing") + parser.add_option("--sweep", dest="type", action="store_const", const="sweep", + help="Generate a swept sine wave") + parser.add_option("-A", "--amplitude", type="eng_float", default=0.15, + help="Set output amplitude to AMPL (0.0-1.0) [default=%default]", metavar="AMPL") + parser.add_option("-v", "--verbose", action="store_true", default=False, + help="Use verbose console output [default=%default]") + + (options, args) = parser.parse_args() + + return (options, args) + +# If this script is executed, the following runs. If it is imported, the below does not run. +def main(): + if gr.enable_realtime_scheduling() != gr.RT_OK: + print "Note: failed to enable realtime scheduling, continuing" - tb.subdev.set_enable(True) # enable transmitter - + # Grab command line options and create top block try: - tb.run() - except KeyboardInterrupt: - pass - - -if __name__ == '__main__': - main () + (options, args) = get_options() + tb = top_block(options, args) + + except RuntimeError, e: + print e + sys.exit(1) + + tb.start() + raw_input('Press Enter to quit: ') + tb.stop() + tb.wait() + +# Make sure to create the top block (tb) within a function: +# That code in main will allow tb to go out of scope on return, +# which will call the decontructor on usrp and stop transmit. +# Whats odd is that grc works fine with tb in the __main__, +# perhaps its because the try/except clauses around tb. +if __name__ == "__main__": main()