def __init__(self): gr.top_block.__init__(self, "OPS-SAT UHF demodulator/decoder") Qt.QWidget.__init__(self) self.setWindowTitle("OPS-SAT UHF demodulator/decoder") qtgui.util.check_set_qss() 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", "os_demod_decode") self.restoreGeometry(self.settings.value("geometry").toByteArray()) ################################################## # Variables ################################################## self.samp_rate = samp_rate = 57600 self.baud_rate = baud_rate = 9600 self.gaussian_taps = gaussian_taps = firdes.gaussian( 1.5, 2 * (samp_rate / baud_rate), 0.5, 12) self.gain_mu = gain_mu = 0.175 ################################################## # Blocks ################################################## self.zeromq_sub_source_0 = zeromq.sub_source(gr.sizeof_gr_complex, 1, 'tcp://127.0.0.1:5555', 100, False, -1) self.zeromq_pub_sink_0 = zeromq.pub_sink(gr.sizeof_char, 1, 'tcp://127.0.0.1:38211', 100, False, -1) self.satellites_strip_ax25_header_0 = satellites.strip_ax25_header() self.satellites_nrzi_decode_0 = satellites.nrzi_decode() self.satellites_hdlc_deframer_0_0 = satellites.hdlc_deframer( check_fcs=True, max_length=1000) self.satellites_decode_rs_0 = satellites.decode_rs(True, 0) self.satellites_check_address_0 = satellites.check_address( 'DP0OPS', "from") self.qtgui_waterfall_sink_x_0 = qtgui.waterfall_sink_c( 512, #size firdes.WIN_HAMMING, #wintype 0, #fc samp_rate, #bw "OPS-SAT UHF BEACON", #name 1 #number of inputs ) self.qtgui_waterfall_sink_x_0.set_update_time(0.03) self.qtgui_waterfall_sink_x_0.enable_grid(False) self.qtgui_waterfall_sink_x_0.enable_axis_labels(True) if not True: self.qtgui_waterfall_sink_x_0.disable_legend() if "complex" == "float" or "complex" == "msg_float": self.qtgui_waterfall_sink_x_0.set_plot_pos_half(not True) labels = ['', '', '', '', '', '', '', '', '', ''] colors = [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_waterfall_sink_x_0.set_line_label( i, "Data {0}".format(i)) else: self.qtgui_waterfall_sink_x_0.set_line_label(i, labels[i]) self.qtgui_waterfall_sink_x_0.set_color_map(i, colors[i]) self.qtgui_waterfall_sink_x_0.set_line_alpha(i, alphas[i]) self.qtgui_waterfall_sink_x_0.set_intensity_range(-140, 10) self._qtgui_waterfall_sink_x_0_win = sip.wrapinstance( self.qtgui_waterfall_sink_x_0.pyqwidget(), Qt.QWidget) self.top_grid_layout.addWidget(self._qtgui_waterfall_sink_x_0_win) self.qtgui_freq_sink_x_0 = qtgui.freq_sink_c( 512, #size firdes.WIN_BLACKMAN_hARRIS, #wintype 0, #fc samp_rate, #bw "", #name 1 #number of inputs ) self.qtgui_freq_sink_x_0.set_update_time(0.10) self.qtgui_freq_sink_x_0.set_y_axis(-140, 10) self.qtgui_freq_sink_x_0.set_y_label('Relative Gain', 'dB') self.qtgui_freq_sink_x_0.set_trigger_mode(qtgui.TRIG_MODE_FREE, 0.0, 0, "") self.qtgui_freq_sink_x_0.enable_autoscale(False) self.qtgui_freq_sink_x_0.enable_grid(False) self.qtgui_freq_sink_x_0.set_fft_average(0.1) self.qtgui_freq_sink_x_0.enable_axis_labels(True) self.qtgui_freq_sink_x_0.enable_control_panel(False) if not True: self.qtgui_freq_sink_x_0.disable_legend() if "complex" == "float" or "complex" == "msg_float": self.qtgui_freq_sink_x_0.set_plot_pos_half(not True) labels = ['', '', '', '', '', '', '', '', '', ''] widths = [1, 1, 1, 1, 1, 1, 1, 1, 1, 1] colors = [ "blue", "red", "green", "black", "cyan", "magenta", "yellow", "dark red", "dark green", "dark blue" ] 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_freq_sink_x_0.set_line_label( i, "Data {0}".format(i)) else: self.qtgui_freq_sink_x_0.set_line_label(i, labels[i]) self.qtgui_freq_sink_x_0.set_line_width(i, widths[i]) self.qtgui_freq_sink_x_0.set_line_color(i, colors[i]) self.qtgui_freq_sink_x_0.set_line_alpha(i, alphas[i]) self._qtgui_freq_sink_x_0_win = sip.wrapinstance( self.qtgui_freq_sink_x_0.pyqwidget(), Qt.QWidget) self.top_grid_layout.addWidget(self._qtgui_freq_sink_x_0_win) self.fir_filter_xxx_0 = filter.fir_filter_fff(1, (gaussian_taps)) self.fir_filter_xxx_0.declare_sample_delay(0) self.digital_descrambler_bb_0_0 = digital.descrambler_bb(0x21, 0, 16) self.digital_clock_recovery_mm_xx_0 = digital.clock_recovery_mm_ff( (samp_rate / baud_rate) * (1 + 0.0), 0.25 * gain_mu * gain_mu, 0.5, gain_mu, 0.005) self.digital_binary_slicer_fb_0 = digital.binary_slicer_fb() self.digital_additive_scrambler_bb_0_0 = digital.additive_scrambler_bb( 0xA9, 0xFF, 7, count=0, bits_per_byte=1, reset_tag_key="packet_len") self.blocks_unpacked_to_packed_xx_0_0_0_0 = blocks.unpacked_to_packed_bb( 1, gr.GR_MSB_FIRST) self.blocks_tagged_stream_to_pdu_0_0_0_0_0 = blocks.tagged_stream_to_pdu( blocks.byte_t, 'packet_len') self.blocks_pdu_to_tagged_stream_1 = blocks.pdu_to_tagged_stream( blocks.byte_t, 'packet_len') self.blocks_pdu_to_tagged_stream_0 = blocks.pdu_to_tagged_stream( blocks.byte_t, 'packet_len') self.blocks_packed_to_unpacked_xx_0 = blocks.packed_to_unpacked_bb( 1, gr.GR_MSB_FIRST) self.blocks_message_debug_0 = blocks.message_debug() self.analog_quadrature_demod_cf_0 = analog.quadrature_demod_cf( 2 * (samp_rate / baud_rate) / (math.pi)) ################################################## # Connections ################################################## self.msg_connect((self.blocks_tagged_stream_to_pdu_0_0_0_0_0, 'pdus'), (self.satellites_decode_rs_0, 'in')) self.msg_connect((self.satellites_check_address_0, 'ok'), (self.satellites_strip_ax25_header_0, 'in')) self.msg_connect((self.satellites_decode_rs_0, 'out'), (self.blocks_message_debug_0, 'print_pdu')) self.msg_connect((self.satellites_decode_rs_0, 'out'), (self.blocks_pdu_to_tagged_stream_1, 'pdus')) self.msg_connect((self.satellites_hdlc_deframer_0_0, 'out'), (self.satellites_check_address_0, 'in')) self.msg_connect((self.satellites_strip_ax25_header_0, 'out'), (self.blocks_pdu_to_tagged_stream_0, 'pdus')) self.connect((self.analog_quadrature_demod_cf_0, 0), (self.fir_filter_xxx_0, 0)) self.connect((self.blocks_packed_to_unpacked_xx_0, 0), (self.digital_additive_scrambler_bb_0_0, 0)) self.connect((self.blocks_pdu_to_tagged_stream_0, 0), (self.blocks_packed_to_unpacked_xx_0, 0)) self.connect((self.blocks_pdu_to_tagged_stream_1, 0), (self.zeromq_pub_sink_0, 0)) self.connect((self.blocks_unpacked_to_packed_xx_0_0_0_0, 0), (self.blocks_tagged_stream_to_pdu_0_0_0_0_0, 0)) self.connect((self.digital_additive_scrambler_bb_0_0, 0), (self.blocks_unpacked_to_packed_xx_0_0_0_0, 0)) self.connect((self.digital_binary_slicer_fb_0, 0), (self.satellites_nrzi_decode_0, 0)) self.connect((self.digital_clock_recovery_mm_xx_0, 0), (self.digital_binary_slicer_fb_0, 0)) self.connect((self.digital_descrambler_bb_0_0, 0), (self.satellites_hdlc_deframer_0_0, 0)) self.connect((self.fir_filter_xxx_0, 0), (self.digital_clock_recovery_mm_xx_0, 0)) self.connect((self.satellites_nrzi_decode_0, 0), (self.digital_descrambler_bb_0_0, 0)) self.connect((self.zeromq_sub_source_0, 0), (self.analog_quadrature_demod_cf_0, 0)) self.connect((self.zeromq_sub_source_0, 0), (self.qtgui_freq_sink_x_0, 0)) self.connect((self.zeromq_sub_source_0, 0), (self.qtgui_waterfall_sink_x_0, 0))
def test_custom_rs(self): self.encode = encode_rs(8, 0x11d, 1, 1, 16, 1) self.decode = decode_rs(8, 0x11d, 1, 1, 16, 1) self.data = np.random.randint(0, 256, 255 - 16, dtype='uint8')
def test_interleave(self): interleave = 5 self.encode = encode_rs(False, interleave) self.decode = decode_rs(False, interleave) self.data = np.random.randint(0, 256, 150 * interleave, dtype='uint8')
def test_shortened(self): self.encode = encode_rs(False, 1) self.decode = decode_rs(False, 1) self.data = np.random.randint(0, 256, 100, dtype='uint8')
def test_dual(self): self.encode = encode_rs(True, 1) self.decode = decode_rs(True, 1) self.data = np.random.randint(0, 256, 223, dtype='uint8')
def test_conventional(self): self.encode = encode_rs(False, 1) self.decode = decode_rs(False, 1) self.data = np.random.randint(0, 256, 223, dtype='uint8')