def test_001_t(self): N = 1000 # number of samples to use fs = 1000 # baseband sampling rate freq = 100 # frequency of source signal signal = analog.sig_source_c(fs, analog.GR_SIN_WAVE, freq, 1) head = blocks.head(gr.sizeof_gr_complex, N) op = snr.channel_model_snr( 0.0, 0.0, 1.0, [ 1, ], 0 ) # noise_voltage, frequency_offset, epsilon, taps, noise_seed, block_tags snk = blocks.vector_sink_c() snk1 = blocks.vector_sink_c() op.set_noise_voltage(0.1) op.set_frequency_offset(0.0) op.set_taps([ 1, ]) op.set_timing_offset(1.0) self.tb.connect(signal, head, op, snk) self.tb.connect(op, snk1) self.tb.run() dst_data = snk.data() exp_data = snk1.data() self.assertComplexTuplesAlmostEqual(exp_data, dst_data, 5)
def simulate_other_est(SNR_range, est_type): """ Create flow graph, run, read out estimated SNR with usage of gnuradio implemented estimator :param SNR_range: range of SNR for which noise voltage will be calculated """ est_snr = [] for SNR in SNR_range: noise_volt = noise_voltage(SNR) src = blocks.vector_source_c(bits.tolist(), False) chn = snr.channel_model_snr(0.0, 0.0, 1.0, [1, ], 0) # noise_voltage, frequency_offset, epsilon, taps, noise_seed, block_tags est = digital.mpsk_snr_est_cc(est_type, ntag, alpha) sink = blocks.null_sink(gr.sizeof_gr_complex) chn.set_noise_voltage(noise_volt) tb = gr.top_block() tb.connect(src, chn, est, sink) tb.run() est_snr.append(est.snr()) return est_snr
def simulate_general_est(SNR_range): """ All the work's done here: create flow graph, run, read out estimated SNR :param SNR_range: range of SNR for which noise voltage will be calculated """ est_snr = [] for SNR in SNR_range: noise_volt = noise_voltage(SNR) src = blocks.vector_source_c(bits.tolist(), False) chn = snr.channel_model_snr(0.0, 0.0, 1.0, [1, ], 0) # noise_voltage, frequency_offset, epsilon, taps, noise_seed, block_tags chn.set_noise_voltage(noise_volt) est = snr.mpsk_receiver_snr_est_cc(ntag, alpha) sink = blocks.null_sink(gr.sizeof_gr_complex) tb = gr.top_block() tb.connect(src, chn, est, sink) tb.run() est_snr.append(est.snr()) return est_snr
def test_001_t (self): N = 1000 # number of samples to use fs = 1000 # baseband sampling rate freq = 100 # frequency of source signal noise_volt = 0.18 # noise voltage [V] signal = analog.sig_source_c(fs, analog.GR_SIN_WAVE, freq, 1) head = blocks.head(gr.sizeof_gr_complex, N) op = snr.channel_model_snr(0.0, 0.0, 1.0, [1,], 0) # noise_voltage, frequency_offset, epsilon, taps, noise_seed, block_tags est = snr.mpsk_receiver_snr_est_cc(1000, 0.001) # ntag, alpha snk = blocks.vector_sink_c() op.set_noise_voltage(0.18) op.set_frequency_offset(0.0) op.set_taps([1,]) op.set_timing_offset(1.0) self.tb.connect(signal, head, op, est, snk) self.tb.run() est_snr = est.snr() exp_snr = 20*math.log10(1/noise_volt)
def test_001_t (self): N = 1000 # number of samples to use fs = 1000 # baseband sampling rate freq = 100 # frequency of source signal signal = analog.sig_source_c(fs, analog.GR_SIN_WAVE, freq, 1) head = blocks.head(gr.sizeof_gr_complex, N) op = snr.channel_model_snr(0.0, 0.0, 1.0, [1,], 0) # noise_voltage, frequency_offset, epsilon, taps, noise_seed, block_tags snk = blocks.vector_sink_c() snk1 = blocks.vector_sink_c() op.set_noise_voltage(0.1) op.set_frequency_offset(0.0) op.set_taps([1,]) op.set_timing_offset(1.0) self.tb.connect(signal, head, op, snk) self.tb.connect(op, snk1) self.tb.run() dst_data = snk.data() exp_data = snk1.data() self.assertComplexTuplesAlmostEqual(exp_data, dst_data, 5)
def test_001_t(self): N = 1000 # number of samples to use fs = 1000 # baseband sampling rate freq = 100 # frequency of source signal noise_volt = 0.18 # noise voltage [V] signal = analog.sig_source_c(fs, analog.GR_SIN_WAVE, freq, 1) head = blocks.head(gr.sizeof_gr_complex, N) op = snr.channel_model_snr( 0.0, 0.0, 1.0, [1], 0 ) # noise_voltage, frequency_offset, epsilon, taps, noise_seed, block_tags est = snr.mpsk_receiver_snr_est_cc(1000, 0.001) # ntag, alpha snk = blocks.vector_sink_c() op.set_noise_voltage(0.18) op.set_frequency_offset(0.0) op.set_taps([1]) op.set_timing_offset(1.0) self.tb.connect(signal, head, op, est, snk) self.tb.run() est_snr = est.snr() exp_snr = 20 * math.log10(1 / noise_volt)
def __init__(self): gr.top_block.__init__(self, "Mpsk Simul") Qt.QWidget.__init__(self) self.setWindowTitle("Mpsk Simul") try: self.setWindowIcon(Qt.QIcon.fromTheme('gnuradio-grc')) except: pass self.top_scroll_layout = Qt.QVBoxLayout() self.setLayout(self.top_scroll_layout) self.top_scroll = Qt.QScrollArea() self.top_scroll.setFrameStyle(Qt.QFrame.NoFrame) self.top_scroll_layout.addWidget(self.top_scroll) self.top_scroll.setWidgetResizable(True) self.top_widget = Qt.QWidget() self.top_scroll.setWidget(self.top_widget) self.top_layout = Qt.QVBoxLayout(self.top_widget) self.top_grid_layout = Qt.QGridLayout() self.top_layout.addLayout(self.top_grid_layout) self.settings = Qt.QSettings("GNU Radio", "mpsk_simul") self.restoreGeometry(self.settings.value("geometry").toByteArray()) ################################################## # Variables ################################################## self.sps = sps = 8 self.nfilts = nfilts = 32 self.timing_loop_bw = timing_loop_bw = 6.28/100.0 self.time_offset = time_offset = 1.00 self.taps = taps = [1.0 + 0.0j, ] self.samp_rate = samp_rate = 32000 self.rrc_taps = rrc_taps = firdes.root_raised_cosine(nfilts, nfilts, 1.0/float(sps), 0.35, 11*sps*nfilts) self.phase_bw = phase_bw = 6.28/100.0 self.noise_volt = noise_volt = 0.001 self.freq_offset = freq_offset = 0 self.eq_gain = eq_gain = 0.01 self.arity = arity = 8 ################################################## # Blocks ################################################## self._timing_loop_bw_range = Range(0.0, 0.2, 0.01, 6.28/100.0, 200) self._timing_loop_bw_win = RangeWidget(self._timing_loop_bw_range, self.set_timing_loop_bw, "Time: BW", "slider", float) self.top_grid_layout.addWidget(self._timing_loop_bw_win, 3,1,1,1) self._time_offset_range = Range(0.999, 1.001, 0.0001, 1.00, 200) self._time_offset_win = RangeWidget(self._time_offset_range, self.set_time_offset, "Channel: Timing Offset", "slider", float) self.top_grid_layout.addWidget(self._time_offset_win, 3,0,1,1) self._phase_bw_range = Range(0.0, 1.0, 0.01, 6.28/100.0, 200) self._phase_bw_win = RangeWidget(self._phase_bw_range, self.set_phase_bw, "Phase: Bandwidth", "slider", float) self.top_grid_layout.addWidget(self._phase_bw_win, 4,1,1,1) self._noise_volt_range = Range(0, 1, 0.01, 0.001, 200) self._noise_volt_win = RangeWidget(self._noise_volt_range, self.set_noise_volt, "Channel: Noise Voltage", "slider", float) self.top_grid_layout.addWidget(self._noise_volt_win, 2,0,1,1) self._freq_offset_range = Range(-0.1, 0.1, 0.001, 0, 200) self._freq_offset_win = RangeWidget(self._freq_offset_range, self.set_freq_offset, "Channel: Frequency Offset", "slider", float) self.top_grid_layout.addWidget(self._freq_offset_win, 2,1,1,1) self._eq_gain_range = Range(0.0, 0.1, 0.001, 0.01, 200) self._eq_gain_win = RangeWidget(self._eq_gain_range, self.set_eq_gain, "Equalizer: rate", "slider", float) self.top_grid_layout.addWidget(self._eq_gain_win, 4,0,1,1) self.snr_mpsk_receiver_snr_est_cc_0 = snr.mpsk_receiver_snr_est_cc(10000, 0.001) self.snr_channel_model_snr_0 = snr.channel_model_snr( noise_voltage=noise_volt, frequency_offset=freq_offset, epsilon=time_offset, taps=(taps), noise_seed=0, block_tags=False ) self.qtgui_time_sink_x_0 = qtgui.time_sink_f( 4000, #size samp_rate, #samp_rate "QT GUI Plot", #name 1 #number of inputs ) self.qtgui_time_sink_x_0.set_update_time(0.01) self.qtgui_time_sink_x_0.set_y_axis(-1, 1) self.qtgui_time_sink_x_0.set_y_label("Amplitude", "") self.qtgui_time_sink_x_0.enable_tags(-1, True) self.qtgui_time_sink_x_0.set_trigger_mode(qtgui.TRIG_MODE_FREE, qtgui.TRIG_SLOPE_POS, 0.0, 0, 0, "") self.qtgui_time_sink_x_0.enable_autoscale(False) self.qtgui_time_sink_x_0.enable_grid(False) self.qtgui_time_sink_x_0.enable_control_panel(False) if not True: self.qtgui_time_sink_x_0.disable_legend() labels = ["", "", "", "", "", "", "", "", "", ""] widths = [1, 1, 1, 1, 1, 1, 1, 1, 1, 1] colors = ["blue", "red", "green", "black", "cyan", "magenta", "yellow", "dark red", "dark green", "blue"] styles = [1, 1, 1, 1, 1, 1, 1, 1, 1, 1] markers = [-1, -1, -1, -1, -1, -1, -1, -1, -1, -1] alphas = [1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0] for i in xrange(1): if len(labels[i]) == 0: self.qtgui_time_sink_x_0.set_line_label(i, "Data {0}".format(i)) else: self.qtgui_time_sink_x_0.set_line_label(i, labels[i]) self.qtgui_time_sink_x_0.set_line_width(i, widths[i]) self.qtgui_time_sink_x_0.set_line_color(i, colors[i]) self.qtgui_time_sink_x_0.set_line_style(i, styles[i]) self.qtgui_time_sink_x_0.set_line_marker(i, markers[i]) self.qtgui_time_sink_x_0.set_line_alpha(i, alphas[i]) self._qtgui_time_sink_x_0_win = sip.wrapinstance(self.qtgui_time_sink_x_0.pyqwidget(), Qt.QWidget) self.top_grid_layout.addWidget(self._qtgui_time_sink_x_0_win, 0,0,1,1) self.qtgui_const_sink_x_0 = qtgui.const_sink_c( 1024, #size "QT GUI Plot", #name 1 #number of inputs ) self.qtgui_const_sink_x_0.set_update_time(0.10) self.qtgui_const_sink_x_0.set_y_axis(-2, 2) self.qtgui_const_sink_x_0.set_x_axis(-2, 2) self.qtgui_const_sink_x_0.set_trigger_mode(qtgui.TRIG_MODE_FREE, qtgui.TRIG_SLOPE_POS, 0.0, 0, "") self.qtgui_const_sink_x_0.enable_autoscale(False) self.qtgui_const_sink_x_0.enable_grid(False) if not True: self.qtgui_const_sink_x_0.disable_legend() labels = ["", "", "", "", "", "", "", "", "", ""] widths = [1, 1, 1, 1, 1, 1, 1, 1, 1, 1] colors = ["blue", "red", "red", "red", "red", "red", "red", "red", "red", "red"] styles = [0, 0, 0, 0, 0, 0, 0, 0, 0, 0] markers = [0, 0, 0, 0, 0, 0, 0, 0, 0, 0] alphas = [1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0] for i in xrange(1): if len(labels[i]) == 0: self.qtgui_const_sink_x_0.set_line_label(i, "Data {0}".format(i)) else: self.qtgui_const_sink_x_0.set_line_label(i, labels[i]) self.qtgui_const_sink_x_0.set_line_width(i, widths[i]) self.qtgui_const_sink_x_0.set_line_color(i, colors[i]) self.qtgui_const_sink_x_0.set_line_style(i, styles[i]) self.qtgui_const_sink_x_0.set_line_marker(i, markers[i]) self.qtgui_const_sink_x_0.set_line_alpha(i, alphas[i]) self._qtgui_const_sink_x_0_win = sip.wrapinstance(self.qtgui_const_sink_x_0.pyqwidget(), Qt.QWidget) self.top_grid_layout.addWidget(self._qtgui_const_sink_x_0_win, 0,1,1,1) self.digital_psk_mod_0 = digital.psk.psk_mod( constellation_points=arity, mod_code="gray", differential=True, samples_per_symbol=sps, excess_bw=0.35, verbose=False, log=False, ) self.digital_pfb_clock_sync_xxx_0 = digital.pfb_clock_sync_ccf(sps, timing_loop_bw, (rrc_taps), nfilts, nfilts/2, 1.5, 2) self.digital_costas_loop_cc_0 = digital.costas_loop_cc(phase_bw, arity, False) self.digital_cma_equalizer_cc_0 = digital.cma_equalizer_cc(15, 1, eq_gain, 2) self.blocks_throttle_0 = blocks.throttle(gr.sizeof_gr_complex*1, samp_rate,True) self.blocks_multiply_const_vxx_0 = blocks.multiply_const_vcc((1+1j, )) self.blocks_message_debug_0 = blocks.message_debug() self.analog_random_source_x_0 = blocks.vector_source_b(map(int, numpy.random.randint(0, 256, 10000)), True) ################################################## # Connections ################################################## self.msg_connect((self.snr_channel_model_snr_0, 'snr_level_out'), (self.snr_mpsk_receiver_snr_est_cc_0, 'snr_level_in')) self.connect((self.analog_random_source_x_0, 0), (self.digital_psk_mod_0, 0)) self.connect((self.blocks_multiply_const_vxx_0, 0), (self.blocks_throttle_0, 0)) self.connect((self.blocks_throttle_0, 0), (self.snr_channel_model_snr_0, 0)) self.connect((self.digital_cma_equalizer_cc_0, 0), (self.digital_costas_loop_cc_0, 0)) self.connect((self.digital_costas_loop_cc_0, 0), (self.qtgui_const_sink_x_0, 0)) self.connect((self.digital_costas_loop_cc_0, 1), (self.qtgui_time_sink_x_0, 0)) self.connect((self.digital_pfb_clock_sync_xxx_0, 0), (self.digital_cma_equalizer_cc_0, 0)) self.connect((self.digital_psk_mod_0, 0), (self.blocks_multiply_const_vxx_0, 0)) self.connect((self.snr_channel_model_snr_0, 0), (self.snr_mpsk_receiver_snr_est_cc_0, 0)) self.connect((self.snr_mpsk_receiver_snr_est_cc_0, 0), (self.digital_pfb_clock_sync_xxx_0, 0))