示例#1
0
 def test_001_diff_phasor_vcc(self):
     a = [1 + 2j, 2 + 3.5j, 3.5 + 4j, 4 + 5j, 5 + 6j]
     b = [1j, 1j, 1j, 1j, 1j]
     c = [-1j + 3, 1j, -7 + 0j, 2.5j + 0.333, 3.2j]
     d = [(0.35979271051026462 + 0.89414454782483865j),
          (0.19421665709046287 + 0.024219594550527801j),
          (0.12445564785882557 + 0.40766238899138718j),
          (0.041869638845043688 + 0.97860437393366329j),
          (0.068927762235083234 + 0.16649764877365247j)]
     e = [(0.16207552830286298 + 0.435385030608331j),
          (0.47195779613669675 + 0.37824764113272558j),
          (0.13911998015446148 + 0.6585095669811617j),
          (0.093510743358783954 + 0.98446560079828938j),
          (0.86036393297704694 + 0.72043005342024602j)]
     multconj = lambda x, y: x.conjugate() * y
     src_data = a + b + c + d + e
     expected_result = [0j, 0j, 0j, 0j, 0j] + map(multconj, a, b) + map(
         multconj, b, c) + map(multconj, c, d) + map(multconj, d, e)
     src = blocks.vector_source_c(src_data)
     s2v = blocks.stream_to_vector(gr.sizeof_gr_complex, 5)
     diff_phasor_vcc = dab.diff_phasor_vcc(5)
     v2s = blocks.vector_to_stream(gr.sizeof_gr_complex, 5)
     dst = blocks.vector_sink_c()
     self.tb.connect(src, s2v, diff_phasor_vcc, v2s, dst)
     self.tb.run()
     result_data = dst.data()
     # print expected_result
     # print result_data
     self.assertComplexTuplesAlmostEqual(expected_result, result_data, 6)
示例#2
0
	def test_001_diff_phasor_vcc(self):
		a = [1+2j,2+3.5j,3.5+4j,4+5j,5+6j]
		b = [1j,1j,1j,1j,1j]
		c = [-1j+3,1j,-7+0j,2.5j+0.333,3.2j]
		d = [(0.35979271051026462+0.89414454782483865j),
		     (0.19421665709046287+0.024219594550527801j),
		     (0.12445564785882557+0.40766238899138718j),
		     (0.041869638845043688+0.97860437393366329j),
		     (0.068927762235083234+0.16649764877365247j)]
		e = [(0.16207552830286298+0.435385030608331j),
		     (0.47195779613669675+0.37824764113272558j),
		     (0.13911998015446148+0.6585095669811617j),
		     (0.093510743358783954+0.98446560079828938j),
		     (0.86036393297704694+0.72043005342024602j)]
		multconj = lambda x,y: x.conjugate()*y
		src_data        = a+b+c+d+e
		expected_result = [0j,0j,0j,0j,0j]+map(multconj,a,b)+map(multconj,b,c)+map(multconj,c,d)+map(multconj,d,e)
		src = blocks.vector_source_c(src_data)
		s2v = blocks.stream_to_vector(gr.sizeof_gr_complex, 5)
		diff_phasor_vcc = dab.diff_phasor_vcc(5)
		v2s = blocks.vector_to_stream(gr.sizeof_gr_complex, 5)
		dst = blocks.vector_sink_c()
		self.tb.connect(src, s2v, diff_phasor_vcc, v2s, dst)
		self.tb.run()
		result_data = dst.data()
		# print expected_result
		# print result_data
		self.assertComplexTuplesAlmostEqual(expected_result, result_data, 6)
示例#3
0
文件: ofdm.py 项目: FLYKingdom/gr-dab
	def __init__(self, dab_params, rx_params, verbose=False, debug=False):
		"""
		Hierarchical block for OFDM demodulation

		@param dab_params DAB parameter object (dab.parameters.dab_parameters)
		@param rx_params RX parameter object (dab.parameters.receiver_parameters)
		@param debug enables debug output to files
		@param verbose whether to produce verbose messages
		"""

		self.dp = dp = dab_params
		self.rp = rp = rx_params
		self.verbose = verbose

		if self.rp.softbits:
			gr.hier_block2.__init__(self,"ofdm_demod",
						gr.io_signature (1, 1, gr.sizeof_gr_complex), # input signature
						gr.io_signature2(2, 2, gr.sizeof_float*self.dp.num_carriers*2, gr.sizeof_char)) # output signature
		else:
			gr.hier_block2.__init__(self,"ofdm_demod",
						gr.io_signature (1, 1, gr.sizeof_gr_complex), # input signature
						gr.io_signature2(2, 2, gr.sizeof_char*self.dp.num_carriers/4, gr.sizeof_char)) # output signature

		

		# workaround for a problem that prevents connecting more than one block directly (see trac ticket #161)
		#self.input = gr.kludge_copy(gr.sizeof_gr_complex)
		self.input = blocks.multiply_const_cc(1.0) # FIXME
		self.connect(self, self.input)
		
		# input filtering
		if self.rp.input_fft_filter: 
			if verbose: print "--> RX filter enabled"
			lowpass_taps = filter.firdes_low_pass(1.0,                     # gain
							  dp.sample_rate,          # sampling rate
							  rp.filt_bw,              # cutoff frequency
							  rp.filt_tb,              # width of transition band
							  filter.firdes.WIN_HAMMING)   # Hamming window
			self.fft_filter = filter.fft_filter_ccc(1, lowpass_taps)
		

		# correct sample rate offset, if enabled
		if self.rp.autocorrect_sample_rate:
			if verbose: print "--> dynamic sample rate correction enabled"
			self.rate_detect_ns = dab.detect_null(dp.ns_length, False)
			self.rate_estimator = dab.estimate_sample_rate_bf(dp.sample_rate, dp.frame_length)
			self.rate_prober = blocks.probe_signal_f()
			self.connect(self.input, self.rate_detect_ns, self.rate_estimator, self.rate_prober)
			# self.resample = gr.fractional_interpolator_cc(0, 1)
			self.resample = dab.fractional_interpolator_triggered_update_cc(0,1)
			self.connect(self.rate_detect_ns, (self.resample,1))
			self.updater = Timer(0.1,self.update_correction)
			# self.updater = threading.Thread(target=self.update_correction)
			self.run_interpolater_update_thread = True
			self.updater.setDaemon(True)
			self.updater.start()
		else:
			self.run_interpolater_update_thread = False
			if self.rp.sample_rate_correction_factor != 1:
				if verbose: print "--> static sample rate correction enabled"
				self.resample = gr.fractional_interpolator_cc(0, self.rp.sample_rate_correction_factor)

		# timing and fine frequency synchronisation
		self.sync = dab.ofdm_sync_dab2(self.dp, self.rp, debug)

		# ofdm symbol sampler
		self.sampler = dab.ofdm_sampler(dp.fft_length, dp.cp_length, dp.symbols_per_frame, rp.cp_gap)
		
		# fft for symbol vectors
		self.fft = fft.fft_vcc(dp.fft_length, True, [], True)

		# coarse frequency synchronisation
		self.cfs = dab.ofdm_coarse_frequency_correct(dp.fft_length, dp.num_carriers, dp.cp_length)

		# diff phasor
		self.phase_diff = dab.diff_phasor_vcc(dp.num_carriers)

		# remove pilot symbol
		self.remove_pilot = dab.ofdm_remove_first_symbol_vcc(dp.num_carriers)

		# magnitude equalisation
		if self.rp.equalize_magnitude:
			if verbose: print "--> magnitude equalization enabled"
			self.equalizer = dab.magnitude_equalizer_vcc(dp.num_carriers, rp.symbols_for_magnitude_equalization)

		# frequency deinterleaving
		self.deinterleave = dab.frequency_interleaver_vcc(dp.frequency_deinterleaving_sequence_array)
		
		# symbol demapping
		self.demapper = dab.qpsk_demapper_vcb(dp.num_carriers)

		#
		# connect everything
		#

		if self.rp.autocorrect_sample_rate or self.rp.sample_rate_correction_factor != 1:
			self.connect(self.input, self.resample)
			self.input2 = self.resample
		else:
			self.input2 = self.input
		if self.rp.input_fft_filter:
			self.connect(self.input2, self.fft_filter, self.sync)
		else:
			self.connect(self.input2, self.sync)

		# data stream
		self.connect((self.sync, 0), (self.sampler, 0), self.fft, (self.cfs, 0), self.phase_diff, (self.remove_pilot,0))
		if self.rp.equalize_magnitude:
			self.connect((self.remove_pilot,0), (self.equalizer,0), self.deinterleave)
		else:
			self.connect((self.remove_pilot,0), self.deinterleave)
		if self.rp.softbits:
			if verbose: print "--> using soft bits"
			self.softbit_interleaver = dab.complex_to_interleaved_float_vcf(self.dp.num_carriers)
			self.connect(self.deinterleave, self.softbit_interleaver, (self,0))
		else:
			self.connect(self.deinterleave, self.demapper, (self,0))

		# control stream
		self.connect((self.sync, 1), (self.sampler, 1), (self.cfs, 1), (self.remove_pilot,1))
		if self.rp.equalize_magnitude:
			self.connect((self.remove_pilot,1), (self.equalizer,1), (self,1))
		else:
			self.connect((self.remove_pilot,1), (self,1))
			
		# calculate an estimate of the SNR
		self.phase_var_decim   = blocks.keep_one_in_n(gr.sizeof_gr_complex*self.dp.num_carriers, self.rp.phase_var_estimate_downsample)
		self.phase_var_arg     = blocks.complex_to_arg(dp.num_carriers)
		self.phase_var_v2s     = blocks.vector_to_stream(gr.sizeof_float, dp.num_carriers)
		self.phase_var_mod     = dab.modulo_ff(pi/2)
		self.phase_var_avg_mod = filter.iir_filter_ffd([rp.phase_var_estimate_alpha], [0,1-rp.phase_var_estimate_alpha]) 
		self.phase_var_sub_avg = blocks.sub_ff()
		self.phase_var_sqr     = blocks.multiply_ff()
		self.phase_var_avg     = filter.iir_filter_ffd([rp.phase_var_estimate_alpha], [0,1-rp.phase_var_estimate_alpha]) 
		self.probe_phase_var   = blocks.probe_signal_f()
		self.connect((self.remove_pilot,0), self.phase_var_decim, self.phase_var_arg, self.phase_var_v2s, self.phase_var_mod, (self.phase_var_sub_avg,0), (self.phase_var_sqr,0))
		self.connect(self.phase_var_mod, self.phase_var_avg_mod, (self.phase_var_sub_avg,1))
		self.connect(self.phase_var_sub_avg, (self.phase_var_sqr,1))
		self.connect(self.phase_var_sqr, self.phase_var_avg, self.probe_phase_var)

		# measure processing rate
		self.measure_rate = dab.measure_processing_rate(gr.sizeof_gr_complex, 2000000) 
		self.connect(self.input, self.measure_rate)

		# debugging
		if debug:
			self.connect(self.fft, blocks.file_sink(gr.sizeof_gr_complex*dp.fft_length, "debug/ofdm_after_fft.dat"))
			self.connect((self.cfs,0), blocks.file_sink(gr.sizeof_gr_complex*dp.num_carriers, "debug/ofdm_after_cfs.dat"))
			self.connect(self.phase_diff, blocks.file_sink(gr.sizeof_gr_complex*dp.num_carriers, "debug/ofdm_diff_phasor.dat"))
			self.connect((self.remove_pilot,0), blocks.file_sink(gr.sizeof_gr_complex*dp.num_carriers, "debug/ofdm_pilot_removed.dat"))
			self.connect((self.remove_pilot,1), blocks.file_sink(gr.sizeof_char, "debug/ofdm_after_cfs_trigger.dat"))
			self.connect(self.deinterleave, blocks.file_sink(gr.sizeof_gr_complex*dp.num_carriers, "debug/ofdm_deinterleaved.dat"))
			if self.rp.equalize_magnitude:
				self.connect(self.equalizer, blocks.file_sink(gr.sizeof_gr_complex*dp.num_carriers, "debug/ofdm_equalizer.dat"))
			if self.rp.softbits:
				self.connect(self.softbit_interleaver, blocks.file_sink(gr.sizeof_float*dp.num_carriers*2, "debug/softbits.dat"))
示例#4
0
文件: ofdm.py 项目: noc0lour/gr-dab
	def __init__(self, dab_params, rx_params, verbose=False, debug=False):
		"""
		Hierarchical block for OFDM demodulation

		@param dab_params DAB parameter object (dab.parameters.dab_parameters)
		@param rx_params RX parameter object (dab.parameters.receiver_parameters)
		@param debug enables debug output to files
		@param verbose whether to produce verbose messages
		"""

		self.dp = dp = dab_params
		self.rp = rp = rx_params
		self.verbose = verbose

		if self.rp.softbits:
			gr.hier_block2.__init__(self,"ofdm_demod",
						gr.io_signature (1, 1, gr.sizeof_gr_complex), # input signature
						gr.io_signature2(2, 2, gr.sizeof_float*self.dp.num_carriers*2, gr.sizeof_char)) # output signature
		else:
			gr.hier_block2.__init__(self,"ofdm_demod",
						gr.io_signature (1, 1, gr.sizeof_gr_complex), # input signature
						gr.io_signature2(2, 2, gr.sizeof_char*self.dp.num_carriers/4, gr.sizeof_char)) # output signature

		

		# workaround for a problem that prevents connecting more than one block directly (see trac ticket #161)
		#self.input = gr.kludge_copy(gr.sizeof_gr_complex)
		self.input = blocks.multiply_const_cc(1.0) # FIXME
		self.connect(self, self.input)
		
		# input filtering
		if self.rp.input_fft_filter: 
			if verbose: print "--> RX filter enabled"
			lowpass_taps = filter.firdes_low_pass(1.0,                     # gain
							  dp.sample_rate,          # sampling rate
							  rp.filt_bw,              # cutoff frequency
							  rp.filt_tb,              # width of transition band
							  filter.firdes.WIN_HAMMING)   # Hamming window
			self.fft_filter = filter.fft_filter_ccc(1, lowpass_taps)
		

		# correct sample rate offset, if enabled
		if self.rp.autocorrect_sample_rate:
			if verbose: print "--> dynamic sample rate correction enabled"
			self.rate_detect_ns = dab.detect_null(dp.ns_length, False)
			self.rate_estimator = dab.estimate_sample_rate_bf(dp.sample_rate, dp.frame_length)
			self.rate_prober = blocks.probe_signal_f()
			self.connect(self.input, self.rate_detect_ns, self.rate_estimator, self.rate_prober)
			# self.resample = gr.fractional_interpolator_cc(0, 1)
			self.resample = dab.fractional_interpolator_triggered_update_cc(0,1)
			self.connect(self.rate_detect_ns, (self.resample,1))
			self.updater = Timer(0.1,self.update_correction)
			# self.updater = threading.Thread(target=self.update_correction)
			self.run_interpolater_update_thread = True
			self.updater.setDaemon(True)
			self.updater.start()
		else:
			self.run_interpolater_update_thread = False
			if self.rp.sample_rate_correction_factor != 1:
				if verbose: print "--> static sample rate correction enabled"
				self.resample = gr.fractional_interpolator_cc(0, self.rp.sample_rate_correction_factor)

		# timing and fine frequency synchronisation
		self.sync = dab.ofdm_sync_dab2(self.dp, self.rp, debug)

		# ofdm symbol sampler
		self.sampler = dab.ofdm_sampler(dp.fft_length, dp.cp_length, dp.symbols_per_frame, rp.cp_gap)
		
		# fft for symbol vectors
		self.fft = fft.fft_vcc(dp.fft_length, True, [], True)

		# coarse frequency synchronisation
		self.cfs = dab.ofdm_coarse_frequency_correct(dp.fft_length, dp.num_carriers, dp.cp_length)

		# diff phasor
		self.phase_diff = dab.diff_phasor_vcc(dp.num_carriers)

		# remove pilot symbol
		self.remove_pilot = dab.ofdm_remove_first_symbol_vcc(dp.num_carriers)

		# magnitude equalisation
		if self.rp.equalize_magnitude:
			if verbose: print "--> magnitude equalization enabled"
			self.equalizer = dab.magnitude_equalizer_vcc(dp.num_carriers, rp.symbols_for_magnitude_equalization)

		# frequency deinterleaving
		self.deinterleave = dab.frequency_interleaver_vcc(dp.frequency_deinterleaving_sequence_array)
		
		# symbol demapping
		self.demapper = dab.qpsk_demapper_vcb(dp.num_carriers)

		#
		# connect everything
		#

		if self.rp.autocorrect_sample_rate or self.rp.sample_rate_correction_factor != 1:
			self.connect(self.input, self.resample)
			self.input2 = self.resample
		else:
			self.input2 = self.input
		if self.rp.input_fft_filter:
			self.connect(self.input2, self.fft_filter, self.sync)
		else:
			self.connect(self.input2, self.sync)

		# data stream
		self.connect((self.sync, 0), (self.sampler, 0), self.fft, (self.cfs, 0), self.phase_diff, (self.remove_pilot,0))
		if self.rp.equalize_magnitude:
			self.connect((self.remove_pilot,0), (self.equalizer,0), self.deinterleave)
		else:
			self.connect((self.remove_pilot,0), self.deinterleave)
		if self.rp.softbits:
			if verbose: print "--> using soft bits"
			self.softbit_interleaver = dab.complex_to_interleaved_float_vcf(self.dp.num_carriers)
			self.connect(self.deinterleave, self.softbit_interleaver, (self,0))
		else:
			self.connect(self.deinterleave, self.demapper, (self,0))

		# control stream
		self.connect((self.sync, 1), (self.sampler, 1), (self.cfs, 1), (self.remove_pilot,1))
		if self.rp.equalize_magnitude:
			self.connect((self.remove_pilot,1), (self.equalizer,1), (self,1))
		else:
			self.connect((self.remove_pilot,1), (self,1))
			
		# calculate an estimate of the SNR
		self.phase_var_decim   = blocks.keep_one_in_n(gr.sizeof_gr_complex*self.dp.num_carriers, self.rp.phase_var_estimate_downsample)
		self.phase_var_arg     = blocks.complex_to_arg(dp.num_carriers)
		self.phase_var_v2s     = blocks.vector_to_stream(gr.sizeof_float, dp.num_carriers)
		self.phase_var_mod     = dab.modulo_ff(pi/2)
		self.phase_var_avg_mod = filter.iir_filter_ffd([rp.phase_var_estimate_alpha], [0,1-rp.phase_var_estimate_alpha]) 
		self.phase_var_sub_avg = blocks.sub_ff()
		self.phase_var_sqr     = blocks.multiply_ff()
		self.phase_var_avg     = filter.iir_filter_ffd([rp.phase_var_estimate_alpha], [0,1-rp.phase_var_estimate_alpha]) 
		self.probe_phase_var   = blocks.probe_signal_f()
		self.connect((self.remove_pilot,0), self.phase_var_decim, self.phase_var_arg, self.phase_var_v2s, self.phase_var_mod, (self.phase_var_sub_avg,0), (self.phase_var_sqr,0))
		self.connect(self.phase_var_mod, self.phase_var_avg_mod, (self.phase_var_sub_avg,1))
		self.connect(self.phase_var_sub_avg, (self.phase_var_sqr,1))
		self.connect(self.phase_var_sqr, self.phase_var_avg, self.probe_phase_var)

		# measure processing rate
		self.measure_rate = dab.measure_processing_rate(gr.sizeof_gr_complex, 2000000) 
		self.connect(self.input, self.measure_rate)

		# debugging
		if debug:
			self.connect(self.fft, blocks.file_sink(gr.sizeof_gr_complex*dp.fft_length, "debug/ofdm_after_fft.dat"))
			self.connect((self.cfs,0), blocks.file_sink(gr.sizeof_gr_complex*dp.num_carriers, "debug/ofdm_after_cfs.dat"))
			self.connect(self.phase_diff, blocks.file_sink(gr.sizeof_gr_complex*dp.num_carriers, "debug/ofdm_diff_phasor.dat"))
			self.connect((self.remove_pilot,0), blocks.file_sink(gr.sizeof_gr_complex*dp.num_carriers, "debug/ofdm_pilot_removed.dat"))
			self.connect((self.remove_pilot,1), blocks.file_sink(gr.sizeof_char, "debug/ofdm_after_cfs_trigger.dat"))
			self.connect(self.deinterleave, blocks.file_sink(gr.sizeof_gr_complex*dp.num_carriers, "debug/ofdm_deinterleaved.dat"))
			if self.rp.equalize_magnitude:
				self.connect(self.equalizer, blocks.file_sink(gr.sizeof_gr_complex*dp.num_carriers, "debug/ofdm_equalizer.dat"))
			if self.rp.softbits:
				self.connect(self.softbit_interleaver, blocks.file_sink(gr.sizeof_float*dp.num_carriers*2, "debug/softbits.dat"))