diff options
Diffstat (limited to 'gnuradio-examples/python/usrp')
-rw-r--r-- | gnuradio-examples/python/usrp/Makefile.am | 2 | ||||
-rwxr-xr-x | gnuradio-examples/python/usrp/fm_tx_2_daughterboards.py | 183 | ||||
-rwxr-xr-x | gnuradio-examples/python/usrp/test_dft_analysis.py | 72 | ||||
-rwxr-xr-x | gnuradio-examples/python/usrp/test_dft_synth.py | 78 | ||||
-rwxr-xr-x | gnuradio-examples/python/usrp/usrp_spectrum_sense.py | 261 |
5 files changed, 0 insertions, 596 deletions
diff --git a/gnuradio-examples/python/usrp/Makefile.am b/gnuradio-examples/python/usrp/Makefile.am index 8033b2a7a..addee0d40 100644 --- a/gnuradio-examples/python/usrp/Makefile.am +++ b/gnuradio-examples/python/usrp/Makefile.am @@ -25,6 +25,4 @@ ourdatadir = $(exampledir)/usrp dist_ourdata_SCRIPTS = \ fm_tx_2_daughterboards.py \ - test_dft_analysis.py \ - test_dft_synth.py \ usrp_spectrum_sense.py diff --git a/gnuradio-examples/python/usrp/fm_tx_2_daughterboards.py b/gnuradio-examples/python/usrp/fm_tx_2_daughterboards.py deleted file mode 100755 index 15fdf2831..000000000 --- a/gnuradio-examples/python/usrp/fm_tx_2_daughterboards.py +++ /dev/null @@ -1,183 +0,0 @@ -#!/usr/bin/env python -# -# Copyright 2005,2006,2007 Free Software Foundation, Inc. -# -# This file is part of GNU Radio -# -# GNU Radio is free software; you can redistribute it and/or modify -# it under the terms of the GNU General Public License as published by -# the Free Software Foundation; either version 3, or (at your option) -# any later version. -# -# GNU Radio is distributed in the hope that it will be useful, -# but WITHOUT ANY WARRANTY; without even the implied warranty of -# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -# GNU General Public License for more details. -# -# You should have received a copy of the GNU General Public License -# along with GNU Radio; see the file COPYING. If not, write to -# the Free Software Foundation, Inc., 51 Franklin Street, -# Boston, MA 02110-1301, USA. -# - -""" -Transmit 2 signals, one out each daughterboard. - -Outputs SSB (USB) signals on side A and side B at frequencies -specified on command line. - -Side A is 600 Hz tone. -Side B is 350 + 440 Hz tones. -""" - -from gnuradio import gr -from gnuradio.eng_notation import num_to_str, str_to_num -from gnuradio import usrp -from gnuradio import audio -from gnuradio import blks2 -from gnuradio.eng_option import eng_option -from optparse import OptionParser -from usrpm import usrp_dbid -import math -import sys - - -class example_signal_0(gr.hier_block2): - """ - Sinusoid at 600 Hz. - """ - def __init__(self, sample_rate): - gr.hier_block2.__init__(self, "example_signal_0", - gr.io_signature(0, 0, 0), # Input signature - gr.io_signature(1, 1, gr.sizeof_gr_complex)) # Output signature - - src = gr.sig_source_c (sample_rate, # sample rate - gr.GR_SIN_WAVE, # waveform type - 600, # frequency - 1.0, # amplitude - 0) # DC Offset - - self.connect(src, self) - - -class example_signal_1(gr.hier_block2): - """ - North American dial tone (350 + 440 Hz). - """ - def __init__(self, sample_rate): - gr.hier_block2.__init__(self, "example_signal_1", - gr.io_signature(0, 0, 0), # Input signature - gr.io_signature(1, 1, gr.sizeof_gr_complex)) # Output signature - - src0 = gr.sig_source_c (sample_rate, # sample rate - gr.GR_SIN_WAVE, # waveform type - 350, # frequency - 1.0, # amplitude - 0) # DC Offset - - src1 = gr.sig_source_c (sample_rate, # sample rate - gr.GR_SIN_WAVE, # waveform type - 440, # frequency - 1.0, # amplitude - 0) # DC Offset - sum = gr.add_cc() - self.connect(src0, (sum, 0)) - self.connect(src1, (sum, 1)) - self.connect(sum, self) - -class my_top_block(gr.top_block): - - def __init__(self): - gr.top_block.__init__(self) - - usage="%prog: [options] side-A-tx-freq side-B-tx-freq" - parser = OptionParser (option_class=eng_option, usage=usage) - (options, args) = parser.parse_args () - - if len(args) != 2: - parser.print_help() - raise SystemExit - else: - freq0 = str_to_num(args[0]) - freq1 = str_to_num(args[1]) - - # ---------------------------------------------------------------- - # Set up USRP to transmit on both daughterboards - - self.u = usrp.sink_c(nchan=2) # say we want two channels - - self.dac_rate = self.u.dac_rate() # 128 MS/s - self.usrp_interp = 400 - self.u.set_interp_rate(self.usrp_interp) - self.usrp_rate = self.dac_rate / self.usrp_interp # 320 kS/s - - # we're using both daughterboard slots, thus subdev is a 2-tuple - self.subdev = (self.u.db(0, 0), self.u.db(1, 0)) - print "Using TX d'board %s" % (self.subdev[0].side_and_name(),) - print "Using TX d'board %s" % (self.subdev[1].side_and_name(),) - - # set up the Tx mux so that - # channel 0 goes to Slot A I&Q and channel 1 to Slot B I&Q - self.u.set_mux(0xba98) - - self.subdev[0].set_gain(self.subdev[0].gain_range()[1]) # set max Tx gain - self.subdev[1].set_gain(self.subdev[1].gain_range()[1]) # set max Tx gain - - self.set_freq(0, freq0) - self.set_freq(1, freq1) - self.subdev[0].set_enable(True) # enable transmitter - self.subdev[1].set_enable(True) # enable transmitter - - # ---------------------------------------------------------------- - # build two signal sources, interleave them, amplify and connect them to usrp - - sig0 = example_signal_0(self.usrp_rate) - sig1 = example_signal_1(self.usrp_rate) - - intl = gr.interleave(gr.sizeof_gr_complex) - self.connect(sig0, (intl, 0)) - self.connect(sig1, (intl, 1)) - - # apply some gain - if_gain = 10000 - ifamp = gr.multiply_const_cc(if_gain) - - # and wire them up - self.connect(intl, ifamp, self.u) - - - def set_freq(self, side, target_freq): - """ - Set the center frequency we're interested in. - - @param side: 0 = side A, 1 = side B - @param target_freq: frequency in Hz - @rtype: 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. - """ - - print "Tuning side %s to %sHz" % (("A", "B")[side], num_to_str(target_freq)) - r = self.u.tune(self.subdev[side].which(), self.subdev[side], target_freq) - if r: - print " r.baseband_freq =", num_to_str(r.baseband_freq) - print " r.dxc_freq =", num_to_str(r.dxc_freq) - print " r.residual_freq =", num_to_str(r.residual_freq) - print " r.inverted =", r.inverted - print " OK" - return True - - else: - print " Failed!" - - return False - - -if __name__ == '__main__': - try: - my_top_block().run() - except KeyboardInterrupt: - pass diff --git a/gnuradio-examples/python/usrp/test_dft_analysis.py b/gnuradio-examples/python/usrp/test_dft_analysis.py deleted file mode 100755 index 49db6bf2a..000000000 --- a/gnuradio-examples/python/usrp/test_dft_analysis.py +++ /dev/null @@ -1,72 +0,0 @@ -#!/usr/bin/env python - -from gnuradio import gr, gru, blks2 -from gnuradio.wxgui import stdgui2, fftsink2, slider -from gnuradio.eng_option import eng_option -from optparse import OptionParser -import wx - -class test_graph (stdgui2.std_top_block): - def __init__(self, frame, panel, vbox, argv): - stdgui2.std_top_block.__init__(self, frame, panel, vbox, argv) - - parser = OptionParser (option_class=eng_option) - (options, args) = parser.parse_args () - - sample_rate = 16e3 - mpoints = 4 - ampl = 1000 - freq = 0 - - lo_freq = 1e6 - lo_ampl = 1 - - vbox.Add(slider.slider(panel, - -sample_rate/2, sample_rate/2, - self.set_lo_freq), 0, wx.ALIGN_CENTER) - - - src = gr.sig_source_c(sample_rate, gr.GR_CONST_WAVE, - freq, ampl, 0) - - self.lo = gr.sig_source_c(sample_rate, gr.GR_SIN_WAVE, - lo_freq, lo_ampl, 0) - - mixer = gr.multiply_cc() - self.connect(src, (mixer, 0)) - self.connect(self.lo, (mixer, 1)) - - # We add these throttle blocks so that this demo doesn't - # suck down all the CPU available. Normally you wouldn't use these. - thr = gr.throttle(gr.sizeof_gr_complex, sample_rate) - - taps = gr.firdes.low_pass(1, # gain - 1, # rate - 1.0/mpoints * 0.4, # cutoff - 1.0/mpoints * 0.1, # trans width - gr.firdes.WIN_HANN) - print len(taps) - analysis = blks2.analysis_filterbank(mpoints, taps) - - self.connect(mixer, thr) - self.connect(thr, analysis) - - for i in range(mpoints): - fft = fftsink2.fft_sink_c(frame, fft_size=128, - sample_rate=sample_rate/mpoints, - fft_rate=5, - title="Ch %d" % (i,)) - self.connect((analysis, i), fft) - vbox.Add(fft.win, 1, wx.EXPAND) - - def set_lo_freq(self, freq): - self.lo.set_frequency(freq) - - - -def main (): - app = stdgui2.stdapp (test_graph, "Test DFT filterbank") - app.MainLoop () - -if __name__ == '__main__': - main () diff --git a/gnuradio-examples/python/usrp/test_dft_synth.py b/gnuradio-examples/python/usrp/test_dft_synth.py deleted file mode 100755 index 99b1c4923..000000000 --- a/gnuradio-examples/python/usrp/test_dft_synth.py +++ /dev/null @@ -1,78 +0,0 @@ -#!/usr/bin/env python - -from gnuradio import gr, gru, blks2 -from gnuradio.wxgui import stdgui2, fftsink2 -from gnuradio.eng_option import eng_option -from optparse import OptionParser -import wx -import random - - -def make_random_complex_tuple(L, gain=1): - result = [] - for x in range(L): - result.append(gain * complex(random.gauss(0, 1),random.gauss(0, 1))) - - return tuple(result) - -def random_noise_c(gain=1): - src = gr.vector_source_c(make_random_complex_tuple(32*1024, gain), True) - return src - - -class test_graph (stdgui2.std_top_block): - def __init__(self, frame, panel, vbox, argv): - stdgui2.std_top_block.__init__(self, frame, panel, vbox, argv) - - parser = OptionParser (option_class=eng_option) - (options, args) = parser.parse_args () - - sample_rate = 16e6 - mpoints = 16 - ampl = 1000 - - enable = mpoints/2 * [1, 0] - enable[0] = 1 - - taps = gr.firdes.low_pass(1, # gain - 1, # rate - 1.0/mpoints * 0.4, # cutoff - 1.0/mpoints * 0.1, # trans width - gr.firdes.WIN_HANN) - - synth = blks2.synthesis_filterbank(mpoints, taps) - - null_source = gr.null_source(gr.sizeof_gr_complex) - - if 1: - for i in range(mpoints): - s = gr.sig_source_c(sample_rate/mpoints, gr.GR_SIN_WAVE, - 300e3, ampl * enable[i], 0) - self.connect(s, (synth, i)) - - else: - for i in range(mpoints): - if i == 1: - #s = gr.sig_source_c(sample_rate/mpoints, gr.GR_SIN_WAVE, - # 300e3, ampl * enable[i], 0) - s = random_noise_c(ampl) - self.connect(s, (synth, i)) - else: - self.connect(null_source, (synth, i)) - - - # We add these throttle blocks so that this demo doesn't - # suck down all the CPU available. Normally you wouldn't use these. - thr = gr.throttle(gr.sizeof_gr_complex, sample_rate) - fft = fftsink2.fft_sink_c(frame, fft_size=1024,sample_rate=sample_rate) - vbox.Add(fft.win, 1, wx.EXPAND) - - self.connect(synth, thr, fft) - - -def main (): - app = stdgui2.stdapp (test_graph, "Test DFT filterbank") - app.MainLoop () - -if __name__ == '__main__': - main () diff --git a/gnuradio-examples/python/usrp/usrp_spectrum_sense.py b/gnuradio-examples/python/usrp/usrp_spectrum_sense.py deleted file mode 100755 index 90adf1671..000000000 --- a/gnuradio-examples/python/usrp/usrp_spectrum_sense.py +++ /dev/null @@ -1,261 +0,0 @@ -#!/usr/bin/env python -# -# Copyright 2005,2007 Free Software Foundation, Inc. -# -# This file is part of GNU Radio -# -# GNU Radio is free software; you can redistribute it and/or modify -# it under the terms of the GNU General Public License as published by -# the Free Software Foundation; either version 3, or (at your option) -# any later version. -# -# GNU Radio is distributed in the hope that it will be useful, -# but WITHOUT ANY WARRANTY; without even the implied warranty of -# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -# GNU General Public License for more details. -# -# You should have received a copy of the GNU General Public License -# along with GNU Radio; see the file COPYING. If not, write to -# the Free Software Foundation, Inc., 51 Franklin Street, -# Boston, MA 02110-1301, USA. -# - -from gnuradio import gr, gru, eng_notation, optfir, window -from gnuradio import audio -from gnuradio import usrp -from gnuradio.eng_option import eng_option -from optparse import OptionParser -from usrpm import usrp_dbid -import sys -import math -import struct - - -class tune(gr.feval_dd): - """ - This class allows C++ code to callback into python. - """ - def __init__(self, tb): - gr.feval_dd.__init__(self) - self.tb = tb - - def eval(self, ignore): - """ - This method is called from gr.bin_statistics_f when it wants to change - the center frequency. This method tunes the front end to the new center - frequency, and returns the new frequency as its result. - """ - try: - # We use this try block so that if something goes wrong from here - # down, at least we'll have a prayer of knowing what went wrong. - # Without this, you get a very mysterious: - # - # terminate called after throwing an instance of 'Swig::DirectorMethodException' - # Aborted - # - # message on stderr. Not exactly helpful ;) - - new_freq = self.tb.set_next_freq() - return new_freq - - except Exception, e: - print "tune: Exception: ", e - - -class parse_msg(object): - def __init__(self, msg): - self.center_freq = msg.arg1() - self.vlen = int(msg.arg2()) - assert(msg.length() == self.vlen * gr.sizeof_float) - - # FIXME consider using Numarray or NumPy vector - t = msg.to_string() - self.raw_data = t - self.data = struct.unpack('%df' % (self.vlen,), t) - - -class my_top_block(gr.top_block): - - def __init__(self): - gr.top_block.__init__(self) - - usage = "usage: %prog [options] min_freq max_freq" - parser = OptionParser(option_class=eng_option, usage=usage) - parser.add_option("-R", "--rx-subdev-spec", type="subdev", default=(0,0), - help="select USRP Rx side A or B (default=A)") - parser.add_option("-g", "--gain", type="eng_float", default=None, - help="set gain in dB (default is midpoint)") - parser.add_option("", "--tune-delay", type="eng_float", default=1e-3, metavar="SECS", - help="time to delay (in seconds) after changing frequency [default=%default]") - parser.add_option("", "--dwell-delay", type="eng_float", default=10e-3, metavar="SECS", - help="time to dwell (in seconds) at a given frequncy [default=%default]") - parser.add_option("-F", "--fft-size", type="int", default=256, - help="specify number of FFT bins [default=%default]") - parser.add_option("-d", "--decim", type="intx", default=16, - help="set decimation to DECIM [default=%default]") - parser.add_option("", "--real-time", action="store_true", default=False, - help="Attempt to enable real-time scheduling") - parser.add_option("-B", "--fusb-block-size", type="int", default=0, - help="specify fast usb block size [default=%default]") - parser.add_option("-N", "--fusb-nblocks", type="int", default=0, - help="specify number of fast usb blocks [default=%default]") - - (options, args) = parser.parse_args() - if len(args) != 2: - parser.print_help() - sys.exit(1) - - self.min_freq = eng_notation.str_to_num(args[0]) - self.max_freq = eng_notation.str_to_num(args[1]) - - if self.min_freq > self.max_freq: - self.min_freq, self.max_freq = self.max_freq, self.min_freq # swap them - - self.fft_size = options.fft_size - - - if not options.real_time: - realtime = False - else: - # Attempt to enable realtime scheduling - r = gr.enable_realtime_scheduling() - if r == gr.RT_OK: - realtime = True - else: - realtime = False - print "Note: failed to enable realtime scheduling" - - # If the user hasn't set the fusb_* parameters on the command line, - # pick some values that will reduce latency. - - if 1: - if options.fusb_block_size == 0 and options.fusb_nblocks == 0: - if realtime: # be more aggressive - options.fusb_block_size = gr.prefs().get_long('fusb', 'rt_block_size', 1024) - options.fusb_nblocks = gr.prefs().get_long('fusb', 'rt_nblocks', 16) - else: - options.fusb_block_size = gr.prefs().get_long('fusb', 'block_size', 4096) - options.fusb_nblocks = gr.prefs().get_long('fusb', 'nblocks', 16) - - #print "fusb_block_size =", options.fusb_block_size - #print "fusb_nblocks =", options.fusb_nblocks - - # build graph - - self.u = usrp.source_c(fusb_block_size=options.fusb_block_size, - fusb_nblocks=options.fusb_nblocks) - - - adc_rate = self.u.adc_rate() # 64 MS/s - usrp_decim = options.decim - self.u.set_decim_rate(usrp_decim) - usrp_rate = adc_rate / usrp_decim - - self.u.set_mux(usrp.determine_rx_mux_value(self.u, options.rx_subdev_spec)) - self.subdev = usrp.selected_subdev(self.u, options.rx_subdev_spec) - print "Using RX d'board %s" % (self.subdev.side_and_name(),) - - - s2v = gr.stream_to_vector(gr.sizeof_gr_complex, self.fft_size) - - mywindow = window.blackmanharris(self.fft_size) - fft = gr.fft_vcc(self.fft_size, True, mywindow) - power = 0 - for tap in mywindow: - power += tap*tap - - c2mag = gr.complex_to_mag_squared(self.fft_size) - - # FIXME the log10 primitive is dog slow - log = gr.nlog10_ff(10, self.fft_size, - -20*math.log10(self.fft_size)-10*math.log10(power/self.fft_size)) - - # Set the freq_step to 75% of the actual data throughput. - # This allows us to discard the bins on both ends of the spectrum. - - self.freq_step = 0.75 * usrp_rate - self.min_center_freq = self.min_freq + self.freq_step/2 - nsteps = math.ceil((self.max_freq - self.min_freq) / self.freq_step) - self.max_center_freq = self.min_center_freq + (nsteps * self.freq_step) - - self.next_freq = self.min_center_freq - - tune_delay = max(0, int(round(options.tune_delay * usrp_rate / self.fft_size))) # in fft_frames - dwell_delay = max(1, int(round(options.dwell_delay * usrp_rate / self.fft_size))) # in fft_frames - - self.msgq = gr.msg_queue(16) - self._tune_callback = tune(self) # hang on to this to keep it from being GC'd - stats = gr.bin_statistics_f(self.fft_size, self.msgq, - self._tune_callback, tune_delay, dwell_delay) - - # FIXME leave out the log10 until we speed it up - #self.connect(self.u, s2v, fft, c2mag, log, stats) - self.connect(self.u, s2v, fft, c2mag, stats) - - if options.gain is None: - # if no gain was specified, use the mid-point in dB - g = self.subdev.gain_range() - options.gain = float(g[0]+g[1])/2 - - self.set_gain(options.gain) - print "gain =", options.gain - - - def set_next_freq(self): - target_freq = self.next_freq - self.next_freq = self.next_freq + self.freq_step - if self.next_freq >= self.max_center_freq: - self.next_freq = self.min_center_freq - - if not self.set_freq(target_freq): - print "Failed to set frequency to", target_freq - - return target_freq - - - 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 down converter. - """ - return self.u.tune(0, self.subdev, target_freq) - - - def set_gain(self, gain): - self.subdev.set_gain(gain) - - -def main_loop(tb): - while 1: - - # Get the next message sent from the C++ code (blocking call). - # It contains the center frequency and the mag squared of the fft - m = parse_msg(tb.msgq.delete_head()) - - # Print center freq so we know that something is happening... - print m.center_freq - - # FIXME do something useful with the data... - - # m.data are the mag_squared of the fft output (they are in the - # standard order. I.e., bin 0 == DC.) - # You'll probably want to do the equivalent of "fftshift" on them - # m.raw_data is a string that contains the binary floats. - # You could write this as binary to a file. - - -if __name__ == '__main__': - tb = my_top_block() - try: - tb.start() # start executing flow graph in another thread... - main_loop(tb) - - except KeyboardInterrupt: - pass |