Example #1
0
    def __init__(self, options):
        gr.flow_graph.__init__(self)
        self.normal_gain = 8000

        self.u = usrp.sink_c()
        dac_rate = self.u.dac_rate()
        self._data_rate = 2000000
        self._spb = 2
        self._interp = int(128e6 / self._spb / self._data_rate)
        self.fs = 128e6 / self._interp

        self.u.set_interp_rate(self._interp)

        # determine the daughterboard subdevice we're using
        if options.tx_subdev_spec is None:
            options.tx_subdev_spec = usrp.pick_tx_subdevice(self.u)
        self.u.set_mux(
            usrp.determine_tx_mux_value(self.u, options.tx_subdev_spec))
        self.subdev = usrp.selected_subdev(self.u, options.tx_subdev_spec)
        print "Using TX d'board %s" % (self.subdev.side_and_name(), )

        self.u.tune(self.subdev._which, self.subdev, options.cordic_freq_tx)
        self.u.set_pga(0, options.gain)
        self.u.set_pga(1, options.gain)

        # transmitter
        self.packet_transmitter = ieee802_15_4_pkt.ieee802_15_4_mod_pkts(
            self, spb=self._spb, msgq_limit=2)
        self.gain = gr.multiply_const_cc(self.normal_gain)

        self.connect(self.packet_transmitter, self.gain, self.u)

        self.set_gain(self.subdev.gain_range()[1])  # set max Tx gain
        self.set_auto_tr(True)  # enable Auto Transmit/Receive switching
Example #2
0
    def _setup_usrp_sink(self):
        """
        Creates a USRP sink, determines the settings for best bitrate,
        and attaches to the transmitter's subdevice.
        """
        self.u = usrp.sink_c(fusb_block_size=self._fusb_block_size,
                             fusb_nblocks=self._fusb_nblocks)

        self.u.set_interp_rate(self._interp)

        # determine the daughterboard subdevice we're using
        if self._tx_subdev_spec is None:
            self._tx_subdev_spec = usrp.pick_tx_subdevice(self.u)
        self.u.set_mux(
            usrp.determine_tx_mux_value(self.u, self._tx_subdev_spec))
        self.subdev = usrp.selected_subdev(self.u, self._tx_subdev_spec)

        # Set center frequency of USRP
        ok = self.set_freq(self._tx_freq)
        if not ok:
            print "Failed to set Tx frequency to %s" % (
                eng_notation.num_to_str(self._tx_freq), )
            raise ValueError

        # Set the USRP for maximum transmit gain
        # (Note that on the RFX cards this is a nop.)
        self.set_gain(self.subdev.gain_range()[1])

        # enable Auto Transmit/Receive switching
        self.set_auto_tr(True)
Example #3
0
def detect_usrp1():
	for i in range(3):
		try:
			u = usrp.source_c(i)
			print "\033[1;31mUSRP found, serial:", u.serial_number(), "\033[1;m"
			a = usrp.selected_subdev(u, (0,0))
			if(a.dbid()!=-1):
				print "\033[1;33mSide A, RX:", a.name(), "(dbid: 0x%04X)" % (a.dbid()), "\033[1;m"
				print "freq range: (", a.freq_min()/1e6, "MHz, ", a.freq_max()/1e6, "MHz )"
				print "gain rainge: (", a.gain_min(), "dB, ", a.gain_max(), "dB )"
			b = usrp.selected_subdev(u, (1,0))
			if(b.dbid()!=-1):
				print "\033[1;33mSide B, RX:", b.name(), "(dbid: 0x%04X)" % (b.dbid()), "\033[1;m"
				print "freq range: (", b.freq_min()/1e6, "MHz, ", b.freq_max()/1e6, "MHz )"
				print "gain rainge: (", b.gain_min(), "dB, ", b.gain_max(), "dB )"
			u = usrp.sink_c(i)
			a = usrp.selected_subdev(u, (0,0))
			if(a.dbid()!=-1):
				print "\033[1;33mSide A, TX:", a.name(), "(dbid: 0x%04X)" % (a.dbid()), "\033[1;m"
				print "freq range: (", a.freq_min()/1e6, "MHz, ", a.freq_max()/1e6, "MHz )"
				print "gain rainge: (", a.gain_min(), "dB, ", a.gain_max(), "dB )"
			b = usrp.selected_subdev(u, (1,0))
			if(b.dbid()!=-1):
				print "\033[1;33mSide B, TX:", b.name(), "(dbid: 0x%04X)" % (b.dbid()), "\033[1;m"
				print "freq range: (", b.freq_min()/1e6, "MHz, ", b.freq_max()/1e6, "MHz )"
				print "gain rainge: (", b.gain_min(), "dB, ", b.gain_max(), "dB )"
		except:
			if(i==0): print "\033[1;31mno USRPs found"
			break
    def __init__(self, fg, subdev_spec, interp, spb, use_barker):

        self.normal_gain = 28000

        self.u = usrp.sink_c()
        dac_rate = self.u.dac_rate();

        self._spb = spb
        self._interp=int(interp)
        self.u.set_interp_rate(self._interp)

        # determine the daughterboard subdevice we're using
        if subdev_spec is None:
            subdev_spec = usrp.pick_tx_subdevice(self.u)

        self.u.set_mux(usrp.determine_tx_mux_value(self.u, subdev_spec))
        self.subdev = usrp.selected_subdev(self.u, subdev_spec)
        print "Using TX d'board %s" % (self.subdev.side_and_name(),)

        # transmitter
        self.packet_transmitter = bbn_80211b_mod_pkts(fg, spb=spb,
                                                      alpha=0.5,
                                                      gain=self.normal_gain,
                                                      use_barker=use_barker)
        fg.connect(self.packet_transmitter, self.u)
        gr.hier_block.__init__(self, fg, None, None)

        self.set_gain(self.subdev.gain_range()[1])  # set max Tx gain
        self.set_auto_tr(True)    # enable Auto Transmit/Receive switching
Example #5
0
    def __init__(self):
        gr.top_block.__init__(self)
        self.normal_gain = 8000

        self.u = usrp.sink_c()
        dac_rate = self.u.dac_rate()
        self._data_rate = 2000000
        self._spb = 2
        self._interp = int(128e6 / self._spb / self._data_rate)
        self.fs = 128e6 / self._interp

        self.u.set_interp_rate(self._interp)

        self.picksubdev = pick_subdevice(self.u)
        #self.u.set_mux(usrp.determine_rx_mux_value(self.u, self.picksubdev))
        self.subdev = usrp.selected_subdev(self.u, pick_subdevice(self.u))
        print "Using TX d'board %s" % (self.subdev.side_and_name())

        #self.u.tune(0, self.subdev, 2475000000)
        #self.u.tune(0, self.subdev, 2480000000)
        self.u.tune(0, self.subdev, 2425000000)
        self.u.set_pga(0, 0)
        self.u.set_pga(1, 0)

        # transmitter
        self.packet_transmitter = ieee802_15_4_pkt.ieee802_15_4_mod_pkts(self, spb=self._spb, msgq_limit=2)

        self.gain = gr.multiply_const_cc (self.normal_gain)

        self.connect(self.packet_transmitter, self.gain, self.u)

        self.set_gain(self.subdev.gain_range()[1])  # set max Tx gain
        self.set_auto_tr(True)                      # enable Auto Transmit/Receive switching
Example #6
0
    def _setup_usrp_sink(self):
        """
        Creates a USRP sink, determines the settings for best bitrate,
        and attaches to the transmitter's subdevice.
        """
        self.tx_u = usrp.sink_c(fusb_block_size=self._fusb_block_size,
                                fusb_nblocks=self._fusb_nblocks)

        self.tx_u.set_interp_rate(self._interp)

        # determine the daughterboard subdevice we're using
        if self._tx_subdev_spec is None:
            print 'tx subdev not set'
            self._tx_subdev_spec = usrp.pick_tx_subdevice(self.tx_u)
        self.tx_u.set_mux(
            usrp.determine_tx_mux_value(self.tx_u, self._tx_subdev_spec))
        self.tx_subdev = usrp.selected_subdev(self.tx_u, self._tx_subdev_spec)

        # Set center frequency of USRP
        ok = self.tx_u.tune(1, self.tx_subdev, self._tx_freq)
        if not ok:
            print "Failed to set Tx frequency to %s" % (
                eng_notation.num_to_str(self._tx_freq), )
            raise ValueError

        # enable Auto Transmit/Receive switching
        self.tx_subdev.set_auto_tr(True)
Example #7
0
    def _setup_usrp_sink(self):
        """
        Creates a USRP sink, determines the settings for best bitrate,
        and attaches to the transmitter's subdevice.
        """
        self.tx_u = usrp.sink_c(fusb_block_size=self._fusb_block_size,
                             fusb_nblocks=self._fusb_nblocks)

        self.tx_u.set_interp_rate(self._interp)

        # determine the daughterboard subdevice we're using
        if self._tx_subdev_spec is None:
            print 'tx subdev not set'
            self._tx_subdev_spec = usrp.pick_tx_subdevice(self.tx_u)
        self.tx_u.set_mux(usrp.determine_tx_mux_value(self.tx_u, self._tx_subdev_spec))
        self.tx_subdev = usrp.selected_subdev(self.tx_u, self._tx_subdev_spec)

        # Set center frequency of USRP
        ok = self.tx_u.tune(1, self.tx_subdev, self._tx_freq)
        if not ok:
            print "Failed to set Tx frequency to %s" % (eng_notation.num_to_str(self._tx_freq),)
            raise ValueError


        # enable Auto Transmit/Receive switching
        self.tx_subdev.set_auto_tr(True)
Example #8
0
    def __init__(self, options, usrp_rate, usrp_interp, tari_rate):
        gr.hier_block2.__init__(self, "downlink_usrp_sink",
                                gr.io_signature(1, 1, gr.sizeof_gr_complex),
                                gr.io_signature(0, 0, 0))

        self.u = usrp.sink_c()

        #setup daughter boards
        #subdev_spec = usrp.pick_tx_subdevice(self.u)
        subdev_spec = (1, 0)
        self.subdev = usrp.selected_subdev(self.u, subdev_spec)
        self.u.set_mux(usrp.determine_tx_mux_value(self.u, subdev_spec))
        print "Using TX d'board %s" % (self.subdev.side_and_name(), )

        #set interp rate
        self.u.set_interp_rate(usrp_interp)
        self.subdev.set_gain(self.subdev.gain_range()[2])

        #setup frequency
        if not self.set_freq(options.freq):
            freq_range = self.subdev.freq_range()
            print "Failed to set frequency to %s.  Daughterboard supports %s to %s" % (
                eng_notation.num_to_str(
                    options.freq), eng_notation.num_to_str(
                        freq_range[0]), eng_notation.num_to_str(freq_range[1]))
            raise SystemExit

        self.subdev.set_enable(True)

        self.connect(self, self.u)
Example #9
0
    def __init__(self):
        gr.top_block.__init__(self)

        self.frequency = 13.56e6
        self.gain = 100
        self.usrp_interpol = 32

        # USRP settings
        self.u_tx = usrp.sink_c() #create the USRP sink for TX
        #try and set the LF_RX for this
        self.tx_subdev_spec = usrp.pick_subdev(self.u_tx, (usrp_dbid.LF_RX, usrp_dbid.LF_TX))
        #set the interpolation rate to match the USRP's 128 MS/s
        self.u_tx.set_interp_rate(self.usrp_interpol)

        #Configure the MUX for the daughterboard
        self.u_tx.set_mux(usrp.determine_tx_mux_value(self.u_tx, self.tx_subdev_spec))
        #Tell it to use the LF_TX
        self.subdev_tx = usrp.selected_subdev(self.u_tx, self.tx_subdev_spec)
        #Make sure it worked 
        print "Using TX dboard %s" % (self.subdev_tx.side_and_name(),)             

        #Set gain.. duh
        self.subdev_tx.set_gain(self.gain)

        #Tune the center frequency
        self.u_tx.tune(0, self.subdev_tx, self.frequency)

        self.src = gr.wavfile_source("RFID_command_52_4M_1610.wav", False)
        self.conv = gr.float_to_complex()
        self.amp = gr.multiply_const_cc(10.0 ** (self.gain / 20.0))
        
        self.connect(self.src, self.conv, self.amp, self.u_tx)
Example #10
0
    def __init__(self):
        gr.top_block.__init__(self)

        self.frequency = 13.56e6
        self.gain = 100
        # for 4 MS/s, 32
        # 
        self.usrp_interpol = 32

        # USRP settings
        self.u_tx = usrp.sink_c() #create the USRP sink for TX
        #try and set the LF_RX for this
        self.tx_subdev_spec = usrp.pick_subdev(self.u_tx, (usrp_dbid.LF_RX, usrp_dbid.LF_TX))
        #set the interpolation rate to match the USRP's 128 MS/s
        self.u_tx.set_interp_rate(self.usrp_interpol)

        #Configure the MUX for the daughterboard
        self.u_tx.set_mux(usrp.determine_tx_mux_value(self.u_tx, self.tx_subdev_spec))
        #Tell it to use the LF_TX
        self.subdev_tx = usrp.selected_subdev(self.u_tx, self.tx_subdev_spec)
        #Make sure it worked 
        print "Using TX dboard %s" % (self.subdev_tx.side_and_name(),)             

        #Set gain.. duh
        self.subdev_tx.set_gain(self.gain)

        #Tune the center frequency
        self.u_tx.tune(0, self.subdev_tx, self.frequency)

#        self.src = gr.wavfile_source("RFID_command_52_4M_1610.wav", True)
        self.src = gr.wavfile_source("wave52.wav", True)
        self.conv = gr.float_to_complex()
        self.amp = gr.multiply_const_cc(10.0 ** (self.gain / 20.0))
        
        self.connect(self.src, self.conv, self.amp, self.u_tx)
Example #11
0
    def __init__(self):
        gr.top_block.__init__(self)
        self.normal_gain = 8000

        self.u = usrp.sink_c()
        dac_rate = self.u.dac_rate()
        self._data_rate = 2000000
        self._spb = 2
        self._interp = int(128e6 / self._spb / self._data_rate)
        self.fs = 128e6 / self._interp

        self.u.set_interp_rate(self._interp)

        self.picksubdev = pick_subdevice(self.u)
        #self.u.set_mux(usrp.determine_rx_mux_value(self.u, self.picksubdev))
        self.subdev = usrp.selected_subdev(self.u, pick_subdevice(self.u))
        print "Using TX d'board %s" % (self.subdev.side_and_name())

        #self.u.tune(0, self.subdev, 2475000000)
        #self.u.tune(0, self.subdev, 2480000000)
        self.u.tune(0, self.subdev, 2425000000)
        self.u.set_pga(0, 0)
        self.u.set_pga(1, 0)

        # transmitter
        self.packet_transmitter = ieee802_15_4_pkt.ieee802_15_4_mod_pkts(
            self, spb=self._spb, msgq_limit=2)

        self.gain = gr.multiply_const_cc(self.normal_gain)

        self.connect(self.packet_transmitter, self.gain, self.u)

        self.set_gain(self.subdev.gain_range()[1])  # set max Tx gain
        self.set_auto_tr(True)  # enable Auto Transmit/Receive switching
Example #12
0
def build_block (tx_enable, rx_enable):
    max_usb_rate = 8e6                  # 8 MS/sec
    dac_freq = 128e6
    adc_freq =  64e6
    
    tx_nchan = 2
    tx_mux = 0x0000ba98
    tx_interp =  int (dac_freq / (max_usb_rate/2 * tx_nchan)) # 16
    
    rx_nchan = 2
    rx_mux = 0x00003210
    rx_decim = int ((adc_freq * rx_nchan) / (max_usb_rate/2)) # 32
    
    tb = gr.top_block ()

    if tx_enable:
        tx_src0 = gr.sig_source_c (dac_freq/tx_interp, gr.GR_CONST_WAVE, 0, 16e3, 0)
        usrp_tx = usrp.sink_c (0, tx_interp, tx_nchan, tx_mux)
        usrp_tx.set_tx_freq (0, 10e6)
        usrp_tx.set_tx_freq (1,  9e6)
        tb.connect (tx_src0, usrp_tx)

    if rx_enable:
        usrp_rx = usrp.source_c (0, rx_decim, rx_nchan, rx_mux)
        usrp_rx.set_rx_freq (0, 5.5e6)
        usrp_rx.set_rx_freq (1, 6.5e6)
        rx_dst0 = gr.null_sink (gr.sizeof_gr_complex)
        tb.connect (usrp_rx, rx_dst0)

    return tb
    def _setup_usrp_sink(self):
        """
        Creates a USRP sink, determines the settings for best bitrate,
        and attaches to the transmitter's subdevice.
        """
        self.u = usrp.sink_c(fusb_block_size=self._fusb_block_size,
                             fusb_nblocks=self._fusb_nblocks)

        self.u.set_interp_rate(self._interp)

        # determine the daughterboard subdevice we're using
        if self._tx_subdev_spec is None:
            self._tx_subdev_spec = usrp.pick_tx_subdevice(self.u)
        self.u.set_mux(usrp.determine_tx_mux_value(self.u, self._tx_subdev_spec))
        self.subdev = usrp.selected_subdev(self.u, self._tx_subdev_spec)

        # Set center frequency of USRP
        ok = self.set_freq(self._tx_freq)
        if not ok:
            print "Failed to set Tx frequency to %s" % (eng_notation.num_to_str(self._tx_freq),)
            raise ValueError

        # Set the USRP for maximum transmit gain
        # (Note that on the RFX cards this is a nop.)
        self.set_gain(self.subdev.gain_range()[1])

        # enable Auto Transmit/Receive switching
        self.set_auto_tr(True)
    def __init__(self, options):
        gr.flow_graph.__init__(self)
        self.normal_gain = 8000

        self.u = usrp.sink_c()
        dac_rate = self.u.dac_rate();
        self._data_rate = 2000000
        self._spb = 2
        self._interp = int(128e6 / self._spb / self._data_rate)
        self.fs = 128e6 / self._interp

        self.u.set_interp_rate(self._interp)

        # determine the daughterboard subdevice we're using
        if options.tx_subdev_spec is None:
            options.tx_subdev_spec = usrp.pick_tx_subdevice(self.u)
        self.u.set_mux(usrp.determine_tx_mux_value(self.u, options.tx_subdev_spec))
        self.subdev = usrp.selected_subdev(self.u, options.tx_subdev_spec)
        print "Using TX d'board %s" % (self.subdev.side_and_name(),)

        self.u.tune(self.subdev._which, self.subdev, options.cordic_freq_tx)
        self.u.set_pga(0, options.gain)
        self.u.set_pga(1, options.gain)

        # transmitter
        self.packet_transmitter = ieee802_15_4_pkt.ieee802_15_4_mod_pkts(self, spb=self._spb, msgq_limit=2)
        self.gain = gr.multiply_const_cc (self.normal_gain)
        
        self.connect(self.packet_transmitter, self.gain, self.u)

        self.set_gain(self.subdev.gain_range()[1])  # set max Tx gain
        self.set_auto_tr(True)                      # enable Auto Transmit/Receive switching
Example #15
0
  def __init__(self,options,usrp_rate,usrp_interp,tari_rate):
    gr.hier_block2.__init__(self,"downlink_usrp_sink",
                            gr.io_signature(1,1,gr.sizeof_gr_complex),
                            gr.io_signature(0,0,0))

    self.u = usrp.sink_c()

    #setup daughter boards
    #subdev_spec = usrp.pick_tx_subdevice(self.u)
    subdev_spec = (1, 0)
    self.subdev = usrp.selected_subdev(self.u,subdev_spec)
    self.u.set_mux(usrp.determine_tx_mux_value(self.u,subdev_spec))
    print "Using TX d'board %s" % (self.subdev.side_and_name(),)

    #set interp rate
    self.u.set_interp_rate(usrp_interp)
    self.subdev.set_gain(self.subdev.gain_range()[2])
    
    #setup frequency
    if not self.set_freq(options.freq):
      freq_range = self.subdev.freq_range()
      print "Failed to set frequency to %s.  Daughterboard supports %s to %s" % (
            eng_notation.num_to_str(options.freq),
            eng_notation.num_to_str(freq_range[0]),
            eng_notation.num_to_str(freq_range[1]))
      raise SystemExit
    
    self.subdev.set_enable(True)

    self.connect(self,self.u)
Example #16
0
    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)
Example #17
0
    def __init__(self, subdev_spec, freq, subdev_gain, filename, delay):

        gr.top_block.__init__(self)

        # data sink and sink rate
        u = usrp.sink_c()

        # important vars (to be calculated from USRP when available
        dac_rate = u.dac_rate()
        usrp_rate = 320e3
        usrp_interp = int(dac_rate // usrp_rate)
        channel_rate = 32e3
        interp_factor = int(usrp_rate // channel_rate)

        # open the pcap source
        pcap = op25.pcap_source_b(filename, delay)
        #        pcap = gr.glfsr_source_b(16)

        # convert octets into dibits
        bits_per_symbol = 2
        unpack = gr.packed_to_unpacked_bb(bits_per_symbol, gr.GR_MSB_FIRST)

        # modulator
        c4fm = p25_mod_bf(output_rate=channel_rate)

        # setup low pass filter + interpolator
        low_pass = 2.88e3
        interp_taps = gr.firdes.low_pass(1.0, channel_rate, low_pass,
                                         low_pass * 0.1, gr.firdes.WIN_HANN)
        interpolator = gr.interp_fir_filter_fff(int(interp_factor),
                                                interp_taps)

        # frequency modulator
        max_dev = 12.5e3
        k = 2 * math.pi * max_dev / usrp_rate
        adjustment = 1.5  # adjust for proper c4fm deviation level
        fm = gr.frequency_modulator_fc(k * adjustment)

        # signal gain
        gain = gr.multiply_const_cc(4000)

        # configure USRP
        if subdev_spec is None:
            subdev_spec = usrp.pick_tx_subdevice(u)
        u.set_mux(usrp.determine_tx_mux_value(u, subdev_spec))
        self.db = usrp.selected_subdev(u, subdev_spec)
        print "Using TX d'board %s" % (self.db.side_and_name(), )
        u.set_interp_rate(usrp_interp)

        if gain is None:
            g = self.db.gain_range()
            gain = float(g[0] + g[1]) / 2
        self.db.set_gain(self.db.gain_range()[0])
        u.tune(self.db.which(), self.db, freq)
        self.db.set_enable(True)

        self.connect(pcap, unpack, c4fm, interpolator, fm, gain, u)
Example #18
0
    def __init__(self, subdev_spec, audio_input):
        gr.hier_block2.__init__(
            self,
            "transmit_path",
            gr.io_signature(0, 0, 0),  # Input signature
            gr.io_signature(0, 0, 0))  # Output signature

        self.u = usrp.sink_c()

        dac_rate = self.u.dac_rate()
        self.if_rate = 320e3  # 320 kS/s
        self.usrp_interp = int(dac_rate // self.if_rate)
        self.u.set_interp_rate(self.usrp_interp)
        self.sw_interp = 10
        self.audio_rate = self.if_rate // self.sw_interp  #  32 kS/s

        self.audio_gain = 10
        self.normal_gain = 32000

        self.audio = audio.source(int(self.audio_rate), audio_input)
        self.audio_amp = gr.multiply_const_ff(self.audio_gain)

        lpf = gr.firdes.low_pass(
            1,  # gain
            self.audio_rate,  # sampling rate
            3800,  # low pass cutoff freq
            300,  # width of trans. band
            gr.firdes.WIN_HANN)  # filter type

        hpf = gr.firdes.high_pass(
            1,  # gain
            self.audio_rate,  # sampling rate
            325,  # low pass cutoff freq
            50,  # width of trans. band
            gr.firdes.WIN_HANN)  # filter type

        audio_taps = convolve(array(lpf), array(hpf))
        self.audio_filt = gr.fir_filter_fff(1, audio_taps)

        self.pl = blks2.ctcss_gen_f(self.audio_rate, 123.0)
        self.add_pl = gr.add_ff()
        self.connect(self.pl, (self.add_pl, 1))

        self.fmtx = blks2.nbfm_tx(self.audio_rate, self.if_rate)
        self.amp = gr.multiply_const_cc(self.normal_gain)

        # determine the daughterboard subdevice we're using
        if subdev_spec is None:
            subdev_spec = usrp.pick_tx_subdevice(self.u)
        self.u.set_mux(usrp.determine_tx_mux_value(self.u, subdev_spec))
        self.subdev = usrp.selected_subdev(self.u, subdev_spec)
        print "TX using", self.subdev.name()

        self.connect(self.audio, self.audio_amp, self.audio_filt,
                     (self.add_pl, 0), self.fmtx, self.amp, self.u)

        self.set_gain(self.subdev.gain_range()[1])  # set max Tx gain
Example #19
0
    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)
Example #20
0
    def __init__(self, subdev_spec, audio_input):
        gr.hier_block2.__init__(
            self, "transmit_path", gr.io_signature(0, 0, 0), gr.io_signature(0, 0, 0)  # Input signature
        )  # Output signature

        self.u = usrp.sink_c()

        dac_rate = self.u.dac_rate()
        self.if_rate = 320e3  # 320 kS/s
        self.usrp_interp = int(dac_rate // self.if_rate)
        self.u.set_interp_rate(self.usrp_interp)
        self.sw_interp = 10
        self.audio_rate = self.if_rate // self.sw_interp  #  32 kS/s

        self.audio_gain = 10
        self.normal_gain = 32000

        self.audio = audio.source(int(self.audio_rate), audio_input)
        self.audio_amp = gr.multiply_const_ff(self.audio_gain)

        lpf = gr.firdes.low_pass(
            1,  # gain
            self.audio_rate,  # sampling rate
            3800,  # low pass cutoff freq
            300,  # width of trans. band
            gr.firdes.WIN_HANN,
        )  # filter type

        hpf = gr.firdes.high_pass(
            1,  # gain
            self.audio_rate,  # sampling rate
            325,  # low pass cutoff freq
            50,  # width of trans. band
            gr.firdes.WIN_HANN,
        )  # filter type

        audio_taps = convolve(array(lpf), array(hpf))
        self.audio_filt = gr.fir_filter_fff(1, audio_taps)

        self.pl = blks2.ctcss_gen_f(self.audio_rate, 123.0)
        self.add_pl = gr.add_ff()
        self.connect(self.pl, (self.add_pl, 1))

        self.fmtx = blks2.nbfm_tx(self.audio_rate, self.if_rate)
        self.amp = gr.multiply_const_cc(self.normal_gain)

        # determine the daughterboard subdevice we're using
        if subdev_spec is None:
            subdev_spec = usrp.pick_tx_subdevice(self.u)
        self.u.set_mux(usrp.determine_tx_mux_value(self.u, subdev_spec))
        self.subdev = usrp.selected_subdev(self.u, subdev_spec)
        print "TX using", self.subdev.name()

        self.connect(self.audio, self.audio_amp, self.audio_filt, (self.add_pl, 0), self.fmtx, self.amp, self.u)

        self.set_gain(self.subdev.gain_range()[1])  # set max Tx gain
Example #21
0
 def _setup_usrp1(self):
     self._u = usrp.sink_c (self._which,
                             fusb_block_size=self._fusb_block_size,
                             fusb_nblocks=self._fusb_nblocks)
     # determine the daughterboard subdevice we're using
     if self._subdev_spec is None:
         self._subdev_spec = usrp.pick_tx_subdevice(self._u)
     self._subdev = usrp.selected_subdev(self._u, self._subdev_spec)
     self._u.set_mux(usrp.determine_tx_mux_value(self._u, self._subdev_spec))
     self._dxc = self._subdev.which()
Example #22
0
    def __init__(self, subdev_spec, freq, subdev_gain, filename, delay):

        gr.top_block.__init__ (self)

        # data sink and sink rate
        u = usrp.sink_c()

        # important vars (to be calculated from USRP when available
        dac_rate = u.dac_rate()
        usrp_rate = 320e3
        usrp_interp = int(dac_rate // usrp_rate)
        channel_rate = 32e3
        interp_factor = int(usrp_rate // channel_rate)

        # open the pcap source
        pcap = op25.pcap_source_b(filename, delay)
#        pcap = gr.glfsr_source_b(16)

        # convert octets into dibits
        bits_per_symbol = 2
        unpack = gr.packed_to_unpacked_bb(bits_per_symbol, gr.GR_MSB_FIRST)

        # modulator
        c4fm = p25_mod_bf(output_rate=channel_rate)

        # setup low pass filter + interpolator
        low_pass = 2.88e3
        interp_taps = gr.firdes.low_pass(1.0, channel_rate, low_pass, low_pass * 0.1, gr.firdes.WIN_HANN)
        interpolator = gr.interp_fir_filter_fff (int(interp_factor), interp_taps)

        # frequency modulator
        max_dev = 12.5e3
        k = 2 * math.pi * max_dev / usrp_rate
        adjustment = 1.5   # adjust for proper c4fm deviation level
        fm = gr.frequency_modulator_fc(k * adjustment)

        # signal gain
        gain = gr.multiply_const_cc(4000)

        # configure USRP
        if subdev_spec is None:
            subdev_spec = usrp.pick_tx_subdevice(u)
        u.set_mux(usrp.determine_tx_mux_value(u, subdev_spec))
        self.db = usrp.selected_subdev(u, subdev_spec)
        print "Using TX d'board %s" % (self.db.side_and_name(),)
        u.set_interp_rate(usrp_interp)

        if gain is None:
            g = self.db.gain_range()
            gain = float(g[0] + g[1]) / 2
        self.db.set_gain(self.db.gain_range()[0])
        u.tune(self.db.which(), self.db, freq)
        self.db.set_enable(True)

        self.connect(pcap, unpack, c4fm, interpolator, fm, gain, u)
Example #23
0
 def _setup_usrp1(self):
     self._u = usrp.sink_c(self._which,
                           fusb_block_size=self._fusb_block_size,
                           fusb_nblocks=self._fusb_nblocks)
     # determine the daughterboard subdevice we're using
     if self._subdev_spec is None:
         self._subdev_spec = usrp.pick_tx_subdevice(self._u)
     self._subdev = usrp.selected_subdev(self._u, self._subdev_spec)
     self._u.set_mux(usrp.determine_tx_mux_value(self._u,
                                                 self._subdev_spec))
     self._dxc = self._subdev.which()
Example #24
0
	def __init__(self):
		gr.top_block.__init__(self)
        
		
		parser = OptionParser(option_class=eng_option, usage="%prog: [options] input-filename")
		parser.add_option("-T", "--tx-subdev-spec", type="subdev", default=(0, 0),
		     help="select USRP Tx side A or B [default=A]")
		parser.add_option("-f", "--freq", type="eng_float", default=227.36e6,
		     help="set frequency to FREQ [default=%default]")
		parser.add_option("-g", "--tx-gain", type="eng_float", default=None,
		     help="set transmit gain in dB (default is midpoint)")
		parser.add_option('-v', '--verbose', action="store_true", default=False,
		     help="verbose output")

        	(options, args) = parser.parse_args ()
		if len(args)!=1:
			parser.print_help()
			sys.exit(1)
		else:
			self.filename = args[0]

		# if gr.enable_realtime_scheduling() != gr.RT_OK:
		#       print "-> failed to enable realtime scheduling"

		interp = 64
		self.dab_params = dab.parameters.dab_parameters(mode=1, sample_rate=2000000, verbose=options.verbose)

		self.src = gr.file_source(gr.sizeof_char, self.filename)
		self.trigsrc = gr.vector_source_b([1]+[0]*(self.dab_params.symbols_per_frame-1),True)
		
		self.s2v = gr.stream_to_vector(gr.sizeof_char, 384)
		
		self.mod = dab.ofdm_mod(self.dab_params, verbose=options.verbose) 

		self.sink = usrp.sink_c(interp_rate = interp)
        	self.sink.set_mux(usrp.determine_tx_mux_value(self.sink, options.tx_subdev_spec))
        	self.subdev = usrp.selected_subdev(self.sink, options.tx_subdev_spec)
		self.sample_rate = self.sink.dac_rate()/interp
		
		print "--> using sample rate: " + str(self.sample_rate)


		self.connect(self.src, self.s2v, self.mod, self.sink)
		self.connect(self.trigsrc, (self.mod,1))

		# tune frequency
		self.sink.tune(0, self.subdev, options.freq)

		# set gain      
		if options.tx_gain is None:
			# if no gain was specified, use the mid-point in dB
			g = self.subdev.gain_range()
			options.tx_gain = float(g[0]+g[1])/2
		self.subdev.set_gain(options.tx_gain)
    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)
Example #26
0
    def _instantiate_blocks (self):
        self.src = None
        self.u = usrp.sink_c (0, self.interp,fpga_filename=gpio.fpga_filename)
        
        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.vecgen = gr.vector_source_c ([complex(1.0,0.0),complex(0.0,0.0),complex(1.0,1.0),complex(0.0,1.0)],True)
Example #27
0
    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))
Example #28
0
 def __init__(self):
     gr.top_block.__init__(self)
     self.source = gr.file_source(
         gr.sizeof_char,  #samples size
         "mensagem.wav",
         repeat=False)
     mod = blks2.qam8_mod()  #QAM modulator
     self.target = u = usrp.sink_c(0)
     #set intermediate frequency (IF)
     res = u.tune(
         tx[0],  #DUC channel
         flexboard,  #daughterboard
         2.5e9)  #IF value
     self.connect(self.source, mod, self.target)  #connect blocks
Example #29
0
    def _setup_usrp(self, which, interp, subdev_spec, freq):
        self._usrp = usrp.sink_c(which=which, interp_rate=interp)
	if subdev_spec is None:
	    subdev_spec = usrp.pick_tx_subdevice(self._usrp)
	self._usrp.set_mux(usrp.determine_tx_mux_value(self._usrp, subdev_spec))
	self._subdev = usrp.selected_subdev(self._usrp, subdev_spec)
	tr = usrp.tune(self._usrp, self._subdev.which(), self._subdev, freq)
        if not (tr):
            print "Failed to tune to center frequency!"
        else:
            print "Center frequency:", n2s(freq)
        gain = float(self._subdev.gain_range()[1]) # Max TX gain
	self._subdev.set_gain(gain)
	self._subdev.set_enable(True)
        print "TX d'board:", self._subdev.side_and_name()
Example #30
0
    def _setup_usrp_sink(self):
        self.u_snk = usrp.sink_c(which = self._usrp,
                                 fusb_block_size = self._fusb_block_size,
                                 fusb_nblocks = self._fusb_nblocks)
        self.u_snk.set_verbose(self._verbose)

        self.u_snk.set_interp_rate(int(self.u_snk.converter_rate() / self._sample_rate))

        # determine the daughterboard subdevice we're using
        if self._tx_subdev_spec is None:
            self._tx_subdev_spec = usrp.pick_tx_subdevice(self.u_snk)

        self.u_snk.set_mux(usrp.determine_tx_mux_value(self.u_snk, self._tx_subdev_spec))
        self.tx_subdev = usrp.selected_subdev(self.u_snk, self._tx_subdev_spec)
        self.tx_subdev.set_auto_tr(True)
        self.tx_subdev.set_gain(self.tx_subdev.gain_range()[1])
def setup_usrp(freq):

  # Constants
  interp = 128
  decim = 64
  
  # Make USRP instances to TX and RX
  utx = usrp.sink_c(fpga_filename="local_rssi5.rbf")
  urx = usrp.source_c(fpga_filename="local_rssi5.rbf")

  # Set decim and interp rates
  utx.set_interp_rate(interp)
  urx.set_decim_rate(decim)

  # Pick subdevice
  subdev_spec_tx = usrp.pick_tx_subdevice(utx)
  subdev_spec_rx = usrp.pick_rx_subdevice(urx)

  # Set up mux
  mux_tx = usrp.determine_tx_mux_value(utx, subdev_spec_tx)
  mux_rx = usrp.determine_rx_mux_value(urx, subdev_spec_rx)
  utx.set_mux(mux_tx)
  urx.set_mux(mux_rx)

  # pick d'board
  subdev_tx = usrp.selected_subdev(utx, subdev_spec_tx)
  subdev_rx = usrp.selected_subdev(urx, subdev_spec_rx)
  print "Using TX d'board %s" %(subdev_tx.side_and_name())
  print "Using RX d'board %s" %(subdev_rx.side_and_name())

  # Gain
  subdev_tx.set_gain((subdev_tx.gain_range()[0] + subdev_tx.gain_range()[1]) / 2)
  subdev_rx.set_gain((subdev_rx.gain_range()[0] + subdev_rx.gain_range()[1]) / 2)

  # Tune
  if not utx.tune(subdev_tx._which, subdev_tx, freq):
      DEBUG( "error tuning TX")
  if not urx.tune(subdev_rx._which, subdev_rx, freq):
      DEBUG( "error tuning RX")

  # Power on
  subdev_tx.set_enable(True)
  subdev_rx.set_enable(True)
  sys.stdout.flush()

  return utx, urx
    def _setup_usrp_sink(self, options):
        """
        Creates a USRP sink, determines the settings for best bitrate,
        and attaches to the transmitter's subdevice.
        """
        #self.u = usrp_options.create_usrp_sink(options)
        self.rs_rate = options.rate    # Store requested bit rate
        
        if_rate = options.rate*options.sps
        self._interp = int(_dac_rate/if_rate)
        options.interp = self._interp
        
        self.u = usrp.sink_c(which = options.which, interp_rate = options.interp)
        if options.tx_subdev_spec is None: 
            options.tx_subdev_spec = usrp.pick_tx_subdevice(self.u)
        self.u.set_mux(usrp.determine_tx_mux_value(self.u, options.tx_subdev_spec))
        
        self._subdev = usrp.selected_subdev(self.u, options.tx_subdev_spec)
        
        tr = usrp.tune(self.u, self._subdev.which(), self._subdev, options.freq)
        if not (tr):
            print "Failed to tune to center frequency!"
        else:
            print "Center frequency:", n2s(options.freq)
            
        gain = float(self._subdev.gain_range()[1]) # Max TX gain
        self._subdev.set_gain(gain)
        self._subdev.set_enable(True)
        print "TX d'board:", self._subdev.side_and_name()
        
        #initiate hardly the value of bits per symbol to 1
        self.bits_per_symbol = 1
            
#        (self._bitrate, self._samples_per_symbol, self._interp) = \
#                        pick_bitrate.pick_tx_bitrate(options.bitrate, self.bits_per_symbol,
#                                        options.samples_per_symbol, options.interp,
#                                        dac_rate, self.u.get_interp_rates())
        

        if options.verbose:
            print 'USRP Sink:', self.u
            print "Interpolation Rate: ", self._interp
Example #33
0
def listUsrp(option, opt, value, parser):
    id = 0
    while (true) :
        try:
            version = usrp._look_for_usrp(id)
            print "USRP #%i" % id
            print " Rev: %i" % version
            dst = usrp.sink_c(id)
            src = usrp.source_c(id)
            print " Tx"
            for db in dst.db:
                if (db[0].dbid() != -1):
                    print "  %s" % db[0].side_and_name()
                    (min, max, offset) = db[0].freq_range()
                    print "   Frequency"
                    print "    Min:    %sHz" % num_to_str(min)
                    print "    Max:    %sHz" % num_to_str(max)
                    print "    Offset: %sHz" % num_to_str(offset)
                    (min, max, offset) = db[0].gain_range()
                    print "   Gain"
                    print "    Min:    %sdB" % num_to_str(min)
                    print "    Max:    %sdB" % num_to_str(max)
                    print "    Offset: %sdB" % num_to_str(offset)
            print " Rx"
            for db in src.db:
                if (db[0].dbid() != -1):
                    print "  %s" % db[0].side_and_name()
                    (min, max, offset) = db[0].freq_range()
                    print "   Frequency"
                    print "    Min:    %sHz" % num_to_str(min)
                    print "    Max:    %sHz" % num_to_str(max)
                    print "    Offset: %sHz" % num_to_str(offset)
                    (min, max, offset) = db[0].gain_range()
                    print "   Gain"
                    print "    Min:    %sdB" % num_to_str(min)
                    print "    Max:    %sdB" % num_to_str(max)
                    print "    Offset: %sdB" % num_to_str(offset)
        except RuntimeError:
            break
        id += 1

    raise SystemExit
Example #34
0
def detect_usrp1():
    for i in range(3):
        try:
            u = usrp.source_c(i)
            print "\033[1;31mUSRP found, serial:", u.serial_number(
            ), "\033[1;m"
            a = usrp.selected_subdev(u, (0, 0))
            if (a.dbid() != -1):
                print "\033[1;33mSide A, RX:", a.name(), "(dbid: 0x%04X)" % (
                    a.dbid()), "\033[1;m"
                print "freq range: (", a.freq_min() / 1e6, "MHz, ", a.freq_max(
                ) / 1e6, "MHz )"
                print "gain rainge: (", a.gain_min(), "dB, ", a.gain_max(
                ), "dB )"
            b = usrp.selected_subdev(u, (1, 0))
            if (b.dbid() != -1):
                print "\033[1;33mSide B, RX:", b.name(), "(dbid: 0x%04X)" % (
                    b.dbid()), "\033[1;m"
                print "freq range: (", b.freq_min() / 1e6, "MHz, ", b.freq_max(
                ) / 1e6, "MHz )"
                print "gain rainge: (", b.gain_min(), "dB, ", b.gain_max(
                ), "dB )"
            u = usrp.sink_c(i)
            a = usrp.selected_subdev(u, (0, 0))
            if (a.dbid() != -1):
                print "\033[1;33mSide A, TX:", a.name(), "(dbid: 0x%04X)" % (
                    a.dbid()), "\033[1;m"
                print "freq range: (", a.freq_min() / 1e6, "MHz, ", a.freq_max(
                ) / 1e6, "MHz )"
                print "gain rainge: (", a.gain_min(), "dB, ", a.gain_max(
                ), "dB )"
            b = usrp.selected_subdev(u, (1, 0))
            if (b.dbid() != -1):
                print "\033[1;33mSide B, TX:", b.name(), "(dbid: 0x%04X)" % (
                    b.dbid()), "\033[1;m"
                print "freq range: (", b.freq_min() / 1e6, "MHz, ", b.freq_max(
                ) / 1e6, "MHz )"
                print "gain rainge: (", b.gain_min(), "dB, ", b.gain_max(
                ), "dB )"
        except:
            if (i == 0): print "\033[1;31mno USRPs found"
            break
    def _setup_usrp_sink(self):
        """
        Creates a USRP sink, determines the settings for best bitrate,
        and attaches to the transmitter's subdevice.
        """
        self.u = usrp.sink_c(fusb_block_size=self._fusb_block_size,fusb_nblocks=self._fusb_nblocks)
        dac_rate = self.u.dac_rate();

        # derive values of bitrate, samples_per_symbol, and interp from desired info
        (self._bitrate, self._samples_per_symbol, self._interp) = \
            pick_tx_bitrate(self._bitrate, self._modulator_class.bits_per_symbol(),
                            self._samples_per_symbol, self._interp, dac_rate)
        
        self.u.set_interp_rate(self._interp)

        # determine the daughterboard subdevice we're using
        if self._tx_subdev_spec is None:
            self._tx_subdev_spec = usrp.pick_tx_subdevice(self.u)
        self.u.set_mux(usrp.determine_tx_mux_value(self.u, self._tx_subdev_spec))
        self.subdev = usrp.selected_subdev(self.u, self._tx_subdev_spec)
Example #36
0
    def _setup_usrp_sink(self):
        """
        Creates a USRP sink, determines the settings for best bitrate,
        and attaches to the transmitter's subdevice.
        """
        self.u_snk = usrp.sink_c(fusb_block_size=self._fusb_block_size,
                                 fusb_nblocks=self._fusb_nblocks)

        self.u_snk.set_interp_rate(self._interp)

        # determine the daughterboard subdevice we're using
        if self._tx_subdev_spec is None:
            self._tx_subdev_spec = usrp.pick_tx_subdevice(self.u_snk)
        self.u_snk.set_mux(usrp.determine_tx_mux_value(self.u_snk, self._tx_subdev_spec))
        self.subdev = usrp.selected_subdev(self.u_snk, self._tx_subdev_spec)

        # Set the USRP for maximum transmit gain
        # (Note that on the RFX cards this is a nop.)
        self.set_gain(self.subdev.gain_range()[1])

        # enable Auto Transmit/Receive switching
        self.set_auto_tr(True)
Example #37
0
    def _setup_usrp_sink(self):
        """
        Creates a USRP sink, determines the settings for best bitrate,
        and attaches to the transmitter's subdevice.
        """
        self.u_snk = usrp.sink_c(fusb_block_size=self._fusb_block_size,
                                 fusb_nblocks=self._fusb_nblocks)

        self.u_snk.set_interp_rate(self._interp)

        # determine the daughterboard subdevice we're using
        if self._tx_subdev_spec is None:
            self._tx_subdev_spec = usrp.pick_tx_subdevice(self.u_snk)
        self.u_snk.set_mux(
            usrp.determine_tx_mux_value(self.u_snk, self._tx_subdev_spec))
        self.subdev = usrp.selected_subdev(self.u_snk, self._tx_subdev_spec)

        # Set the USRP for maximum transmit gain
        # (Note that on the RFX cards this is a nop.)
        self.set_gain(self.subdev.gain_range()[1])

        # enable Auto Transmit/Receive switching
        self.set_auto_tr(True)
Example #38
0
    def __init__(self):
        gr.hier_block2.__init__(self, "tx_path", gr.io_signature(0, 0, 0),
                                gr.io_signature(0, 0, 0))

        self.frequency = 13.56e6
        self.normal_gain = 100
        self.k = 0
        self.usrp_interpol = int(128 / (SAMPLERATE / 1e6))
        print "[+] Using interpolation rate of", self.usrp_interpol

        # USRP settings
        self.u_tx = usrp.sink_c()  #create the USRP sink for TX
        #try and set the LF_RX for this
        self.tx_subdev_spec = usrp.pick_subdev(
            self.u_tx, (usrp_dbid.LF_RX, usrp_dbid.LF_TX))
        #set the interpolation rate to match the USRP's 128 MS/s
        self.u_tx.set_interp_rate(self.usrp_interpol)

        #Configure the MUX for the daughterboard
        self.u_tx.set_mux(
            usrp.determine_tx_mux_value(self.u_tx, self.tx_subdev_spec))
        #Tell it to use the LF_TX
        self.subdev_tx = usrp.selected_subdev(self.u_tx, self.tx_subdev_spec)
        #Make sure it worked
        print "Using TX dboard %s" % (self.subdev_tx.side_and_name(), )

        #Set gain.. duh
        self.subdev_tx.set_gain(self.normal_gain)

        #Tune the center frequency
        self.u_tx.tune(0, self.subdev_tx, self.frequency)

        self.src = gr.wavfile_source("wave52.wav", True)
        self.conv = gr.float_to_complex()
        self.amp = gr.multiply_const_cc(10.0**(self.normal_gain / 20.0))

        self.connect(self.src, self.conv, self.amp, self.u_tx)
Example #39
0
    def __init__(self):
        gr.hier_block2.__init__(self, "tx_path", 
                                gr.io_signature(0, 0, 0),
                                gr.io_signature(0, 0, 0))

        self.frequency = 13.56e6
        self.normal_gain = 100
        self.k = 0
        self.usrp_interpol = int(128/(SAMPLERATE/1e6))
        print "[+] Using interpolation rate of",self.usrp_interpol

        # USRP settings
        self.u_tx = usrp.sink_c() #create the USRP sink for TX
        #try and set the LF_RX for this
        self.tx_subdev_spec = usrp.pick_subdev(self.u_tx, (usrp_dbid.LF_RX, usrp_dbid.LF_TX))
        #set the interpolation rate to match the USRP's 128 MS/s
        self.u_tx.set_interp_rate(self.usrp_interpol)

        #Configure the MUX for the daughterboard
        self.u_tx.set_mux(usrp.determine_tx_mux_value(self.u_tx, self.tx_subdev_spec))
        #Tell it to use the LF_TX
        self.subdev_tx = usrp.selected_subdev(self.u_tx, self.tx_subdev_spec)
        #Make sure it worked 
        print "Using TX dboard %s" % (self.subdev_tx.side_and_name(),)

        #Set gain.. duh
        self.subdev_tx.set_gain(self.normal_gain)

        #Tune the center frequency
        self.u_tx.tune(0, self.subdev_tx, self.frequency)

        self.src = gr.wavfile_source("wave52.wav", True)
        self.conv = gr.float_to_complex()
        self.amp = gr.multiply_const_cc(10.0 ** (self.normal_gain / 20.0))
        
        self.connect(self.src, self.conv, self.amp, self.u_tx)
    def __init__(self):
        gr.flow_graph.__init__(self)

        self.u = usrp.sink_c()
    def __init__(self):

        parser = OptionParser (option_class=eng_option)
        parser.add_option("-T", "--tx-subdev-spec", type="subdev", default=None,
                          help="select USRP Tx side A or B (default=first one with a daughterboard)")
        parser.add_option ("-c", "--cordic-freq1", type="eng_float", default=434845200,
                           help="set Tx cordic frequency to FREQ", metavar="FREQ")
        parser.add_option ("-d", "--cordic-freq2", type="eng_float", default=434318512,
                           help="set rx cordic frequency for channel 2 to FREQ", metavar="FREQ")
        parser.add_option ("-g", "--gain", type="eng_float", default=0,
                           help="set Rx PGA gain in dB [0,20]")

        (options, args) = parser.parse_args ()
        print "cordic_freq1 = %s" % (eng_notation.num_to_str (options.cordic_freq1))
        print "cordic_freq2 = %s" % (eng_notation.num_to_str (options.cordic_freq2))

        # ----------------------------------------------------------------

        self.data_rate = 38400
        self.samples_per_symbol = 8
        self.channel_fs = self.data_rate * self.samples_per_symbol
        self.fs = 4e6
        payload_size = 128             # bytes

        print "data_rate = ", eng_notation.num_to_str(self.data_rate)
        print "samples_per_symbol = ", self.samples_per_symbol
        print "fs = ", eng_notation.num_to_str(self.fs)
        
        gr.flow_graph.__init__(self)
        self.normal_gain = 8000

        self.u = usrp.sink_c()
        dac_rate = self.u.dac_rate();

        self.interp = int(dac_rate / self.fs )
        print "usrp interp = ", self.interp

        self.u.set_interp_rate(self.interp)

        # determine the daughterboard subdevice we're using
        if options.tx_subdev_spec is None:
            options.tx_subdev_spec = usrp.pick_tx_subdevice(self.u)
        self.u.set_mux(usrp.determine_tx_mux_value(self.u, options.tx_subdev_spec))
        self.subdev = usrp.selected_subdev(self.u, options.tx_subdev_spec)
        print "Using TX d'board %s" % (self.subdev.side_and_name(),)

        if options.cordic_freq1 < options.cordic_freq2:
            self.usrp_freq = options.cordic_freq1
            self.freq_diff = options.cordic_freq2 - options.cordic_freq1
        else:
            self.usrp_freq = options.cordic_freq2
            self.freq_diff = options.cordic_freq1 - options.cordic_freq2
        print "freq_diff = ", eng_notation.num_to_str(self.freq_diff)

        self.u.tune(self.subdev._which, self.subdev, self.usrp_freq)
        print "tune USRP to = ", eng_notation.num_to_str(self.usrp_freq)
        self.u.set_pga(0, options.gain)
        self.u.set_pga(1, options.gain)

        interp_factor = int(self.fs / self.channel_fs)
        quad_rate = self.fs
        print "interp_factor = ", interp_factor
        
        # Create filter for the interpolation
        interp_taps = gr.firdes.low_pass (interp_factor,   # gain
                                          self.channel_fs*interp_factor,       # Fs
                                          self.channel_fs/2, # low pass cutoff freq
                                          self.channel_fs*0.1,# width of trans. band
                                          gr.firdes.WIN_HANN) #filter type

        print "len(interp_taps) =", len(interp_taps)

        self.interpolator1 = gr.interp_fir_filter_ccc(interp_factor, interp_taps)
        self.interpolator2 = gr.interp_fir_filter_ccc(interp_factor, interp_taps)

        self.multiplicator = gr.multiply_cc()

        self.adder = gr.add_cc()
        
        self.sin = gr.sig_source_c(self.channel_fs * interp_factor, gr.GR_SIN_WAVE, self.freq_diff, 1, complex(0, 0))

        # transmitter
        self.packet_transmitter1 = cc1k_sos_pkt.cc1k_mod_pkts(self, spb=self.samples_per_symbol, msgq_limit=2)
        #self.packet_transmitter2 = cc1k_sos_pkt.cc1k_mod_pkts(self, spb=self.samples_per_symbol, msgq_limit=2)

        self.amp = gr.multiply_const_cc (self.normal_gain)
        self.filesink = gr.file_sink(gr.sizeof_gr_complex, 'tx_test.dat')
        self.filesink2 = gr.file_sink(gr.sizeof_gr_complex, 'tx_test2.dat')
        self.filesink3 = gr.file_sink(gr.sizeof_gr_complex, 'tx_test3.dat')

        # interpolate the two transmitters
        self.connect(self.packet_transmitter1, self.interpolator1)
        #self.connect(self.packet_transmitter2, self.interpolator2)
        # upconvert the first transmitter)
        self.connect(self.interpolator1, (self.multiplicator, 1))
        self.connect(self.sin, (self.multiplicator, 0))
        # add the two signals
        #self.connect(self.multiplicator, (self.adder, 0))
        #self.connect(self.interpolator2, (self.adder, 1))
        # send the signal to the USRP
        self.connect(self.interpolator1, self.amp, self.filesink)
        self.connect(self.multiplicator, self.filesink2)
        self.connect(self.sin, self.filesink3)
        
        self.set_gain(self.subdev.gain_range()[1])  # set max Tx gain
        self.set_auto_tr(True)                      # enable Auto Transmit/Receive switching
Example #42
0
    def __init__(self, frame, panel, vbox, argv):
        MAX_CHANNELS = 7
        stdgui2.std_top_block.__init__ (self, frame, panel, vbox, argv)

        parser = OptionParser (option_class=eng_option)
        parser.add_option("-T", "--tx-subdev-spec", type="subdev", default=None,
                          help="select USRP Tx side A or B")
        parser.add_option("-f", "--freq", type="eng_float", default=None,
                           help="set Tx frequency to FREQ [required]", metavar="FREQ")
        parser.add_option("-n", "--nchannels", type="int", default=4,
                           help="number of Tx channels [1,4]")
        #parser.add_option("","--debug", action="store_true", default=False,
        #                  help="Launch Tx debugger")
        (options, args) = parser.parse_args ()

        if len(args) != 0:
            parser.print_help()
            sys.exit(1)

        if options.nchannels < 1 or options.nchannels > MAX_CHANNELS:
            sys.stderr.write ("fm_tx4: nchannels out of range.  Must be in [1,%d]\n" % MAX_CHANNELS)
            sys.exit(1)
        
        if options.freq is None:
            sys.stderr.write("fm_tx4: must specify frequency with -f FREQ\n")
            parser.print_help()
            sys.exit(1)

        # ----------------------------------------------------------------
        # Set up constants and parameters

        self.u = usrp.sink_c ()       # the USRP sink (consumes samples)

        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
        self.sw_interp = 10
        self.audio_rate = self.usrp_rate / self.sw_interp    # 32 kS/s

        # determine the daughterboard subdevice we're using
        if options.tx_subdev_spec is None:
            options.tx_subdev_spec = usrp.pick_tx_subdevice(self.u)

        m = usrp.determine_tx_mux_value(self.u, options.tx_subdev_spec)
        #print "mux = %#04x" % (m,)
        self.u.set_mux(m)
        self.subdev = usrp.selected_subdev(self.u, options.tx_subdev_spec)
        print "Using TX d'board %s" % (self.subdev.side_and_name(),)

        self.subdev.set_gain(self.subdev.gain_range()[1])    # set max Tx gain
        if not self.set_freq(options.freq):
            freq_range = self.subdev.freq_range()
            print "Failed to set frequency to %s.  Daughterboard supports %s to %s" % (
                eng_notation.num_to_str(options.freq),
                eng_notation.num_to_str(freq_range[0]),
                eng_notation.num_to_str(freq_range[1]))
            raise SystemExit
        self.subdev.set_enable(True)                         # enable transmitter

        sum = gr.add_cc ()

        # Instantiate N NBFM channels
        step = 25e3
        offset = (0 * step, 1 * step, -1 * step, 2 * step, -2 * step, 3 * step, -3 * step)
        for i in range (options.nchannels):
            t = pipeline("audio-%d.dat" % (i % 4), offset[i],
                         self.audio_rate, self.usrp_rate)
            self.connect(t, (sum, i))

        gain = gr.multiply_const_cc (4000.0 / options.nchannels)

        # connect it all
        self.connect (sum, gain)
        self.connect (gain, self.u)

        # plot an FFT to verify we are sending what we want
        if 1:
            post_mod = fftsink2.fft_sink_c(panel, title="Post Modulation",
                                           fft_size=512, sample_rate=self.usrp_rate,
                                           y_per_div=20, ref_level=40)
            self.connect (sum, post_mod)
            vbox.Add (post_mod.win, 1, wx.EXPAND)
Example #43
0
	def __init__(self, frame, panel, vbox, argv):
		stdgui2.std_top_block.__init__ (self, frame, panel, vbox, argv)

		parser = OptionParser (option_class=eng_option)
		parser.add_option("-T", "--tx-subdev-spec", type="subdev", default=None,
						help="select USRP Tx side A or B")
		parser.add_option("-f", "--freq", type="eng_float", default=107.2e6,
						help="set Tx frequency to FREQ [required]", metavar="FREQ")
		parser.add_option("-i", "--filename", type="string", default="",
						help="read input from FILE")
		(options, args) = parser.parse_args()
		if len(args) != 0:
			parser.print_help()
			sys.exit(1)

		self.u = usrp.sink_c ()

		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
		self.sw_interp = 10
		self.audio_rate = self.usrp_rate / self.sw_interp	# 32 kS/s

		# determine the daughterboard subdevice we're using
		if options.tx_subdev_spec is None:
			options.tx_subdev_spec = usrp.pick_tx_subdevice(self.u)
		self.u.set_mux(usrp.determine_tx_mux_value(self.u, options.tx_subdev_spec))
		self.subdev = usrp.selected_subdev(self.u, options.tx_subdev_spec)
		print "Using TX d'board %s" % (self.subdev.side_and_name(),)

		# set max Tx gain, tune frequency and enable transmitter
		self.subdev.set_gain(self.subdev.gain_range()[1])
		self.u.tune(self.subdev._which, self.subdev, options.freq)
		self.subdev.set_enable(True)

		# open file containing floats in the [-1, 1] range, repeat
		self.src = gr.wavfile_source (options.filename, True)
		nchans = self.src.channels()
		sample_rate = self.src.sample_rate()
		bits_per_sample = self.src.bits_per_sample()
		print nchans, "channels,", sample_rate, "kS/s,", bits_per_sample, "bits/sample"

		# resample to 32kS/s
		if sample_rate == 44100:
			self.resample = blks2.rational_resampler_fff(8,11)
		elif sample_rate == 48000:
			self.resample == blks2.rational_resampler_fff(2,3)
		else:
			print sample_rate, "is an unsupported sample rate"
			exit()

		# interpolation, preemphasis, fm modulation & gain
		self.fmtx = blks2.wfm_tx (self.audio_rate, self.usrp_rate, tau=75e-6, max_dev=15e3)
		self.gain = gr.multiply_const_cc (4e3)

		# connect it all
		self.connect (self.src, self.resample, self.fmtx, self.gain, self.u)

		# plot an FFT to verify we are sending what we want
		pre_mod = fftsink2.fft_sink_f(panel, title="Pre-Modulation",
			fft_size=512, sample_rate=self.usrp_rate, y_per_div=10, ref_level=0)
		self.connect (self.emph, pre_mod)
		vbox.Add (pre_mod.win, 1, wx.EXPAND)
Example #44
0
    def __init__(self, frame, panel, vbox, argv):
        stdgui2.std_top_block.__init__(self, frame, panel, vbox, argv)

        parser = OptionParser(option_class=eng_option)
        parser.add_option("-T",
                          "--tx-subdev-spec",
                          type="subdev",
                          default=None,
                          help="select USRP Tx side A or B")
        parser.add_option("-f",
                          "--freq",
                          type="eng_float",
                          default=107.2e6,
                          help="set Tx frequency to FREQ [required]",
                          metavar="FREQ")
        parser.add_option("--wavfile",
                          type="string",
                          default="",
                          help="read input from FILE")
        (options, args) = parser.parse_args()
        if len(args) != 0:
            parser.print_help()
            sys.exit(1)

        self.usrp_interp = 200
        self.u = usrp.sink_c(0, self.usrp_interp)
        print "USRP Serial: ", self.u.serial_number()
        self.dac_rate = self.u.dac_rate()  # 128 MS/s
        self.usrp_rate = self.dac_rate / self.usrp_interp  # 640 kS/s
        self.sw_interp = 5
        self.audio_rate = self.usrp_rate / self.sw_interp  # 128 kS/s

        # determine the daughterboard subdevice we're using
        if options.tx_subdev_spec is None:
            options.tx_subdev_spec = usrp.pick_tx_subdevice(self.u)
        self.u.set_mux(
            usrp.determine_tx_mux_value(self.u, options.tx_subdev_spec))
        self.subdev = usrp.selected_subdev(self.u, options.tx_subdev_spec)
        print "Using d'board: ", self.subdev.side_and_name()

        # set max Tx gain, tune frequency and enable transmitter
        self.subdev.set_gain(self.subdev.gain_range()[1])
        if self.u.tune(self.subdev.which(), self.subdev, options.freq):
            print "Tuned to", options.freq / 1e6, "MHz"
        else:
            sys.exit(1)
        self.subdev.set_enable(True)

        # open wav file containing floats in the [-1, 1] range, repeat
        if options.wavfile is None:
            print "Please provide a wavfile to transmit! Exiting\n"
            sys.exit(1)
        self.src = gr.wavfile_source(options.wavfile, True)
        nchans = self.src.channels()
        sample_rate = self.src.sample_rate()
        bits_per_sample = self.src.bits_per_sample()
        print nchans, "channels,", sample_rate, "kS/s,", bits_per_sample, "bits/sample"

        # resample to 128kS/s
        if sample_rate == 44100:
            self.resample_left = blks2.rational_resampler_fff(32, 11)
            self.resample_right = blks2.rational_resampler_fff(32, 11)
        elif sample_rate == 48000:
            self.resample_left == blks2.rational_resampler_fff(8, 3)
            self.resample_right == blks2.rational_resampler_fff(8, 3)
        elif sample_rate == 8000:
            self.resample_left == blks2.rational_resampler_fff(16, 1)
            self.resample_right == blks2.rational_resampler_fff(16, 1)
        else:
            print sample_rate, "is an unsupported sample rate"
            sys.exit(1)
        self.connect((self.src, 0), self.resample_left)
        self.connect((self.src, 1), self.resample_right)

        # create L+R (mono) and L-R (stereo)
        self.audio_lpr = gr.add_ff()
        self.audio_lmr = gr.sub_ff()
        self.connect(self.resample_left, (self.audio_lpr, 0))
        self.connect(self.resample_left, (self.audio_lmr, 0))
        self.connect(self.resample_right, (self.audio_lpr, 1))
        self.connect(self.resample_right, (self.audio_lmr, 1))

        # low-pass filter for L+R
        audio_lpr_taps = gr.firdes.low_pass(
            0.3,  # gain
            self.audio_rate,  # sampling rate
            15e3,  # passband cutoff
            2e3,  # transition width
            gr.firdes.WIN_HANN)
        self.audio_lpr_filter = gr.fir_filter_fff(1, audio_lpr_taps)
        self.connect(self.audio_lpr, self.audio_lpr_filter)

        # create pilot tone at 19 kHz
        self.pilot = gr.sig_source_f(
            self.audio_rate,  # sampling freq
            gr.GR_SIN_WAVE,  # waveform
            19e3,  # frequency
            3e-2)  # amplitude

        # create the L-R signal carrier at 38 kHz, high-pass to remove 0Hz tone
        self.stereo_carrier = gr.multiply_ff()
        self.connect(self.pilot, (self.stereo_carrier, 0))
        self.connect(self.pilot, (self.stereo_carrier, 1))
        stereo_carrier_taps = gr.firdes.high_pass(
            1,  # gain
            self.audio_rate,  # sampling rate
            1e4,  # cutoff freq
            2e3,  # transition width
            gr.firdes.WIN_HANN)
        self.stereo_carrier_filter = gr.fir_filter_fff(1, stereo_carrier_taps)
        self.connect(self.stereo_carrier, self.stereo_carrier_filter)

        # upconvert L-R to 23-53 kHz and band-pass
        self.mix_stereo = gr.multiply_ff()
        audio_lmr_taps = gr.firdes.band_pass(
            3e3,  # gain
            self.audio_rate,  # sampling rate
            23e3,  # low cutoff
            53e3,  # high cuttof
            2e3,  # transition width
            gr.firdes.WIN_HANN)
        self.audio_lmr_filter = gr.fir_filter_fff(1, audio_lmr_taps)
        self.connect(self.audio_lmr, (self.mix_stereo, 0))
        self.connect(self.stereo_carrier_filter, (self.mix_stereo, 1))
        self.connect(self.mix_stereo, self.audio_lmr_filter)

        # mix L+R, pilot and L-R
        self.mixer = gr.add_ff()
        self.connect(self.audio_lpr_filter, (self.mixer, 0))
        self.connect(self.pilot, (self.mixer, 1))
        self.connect(self.audio_lmr_filter, (self.mixer, 2))

        # interpolation & pre-emphasis
        interp_taps = gr.firdes.low_pass(
            self.sw_interp,  # gain
            self.audio_rate,  # Fs
            60e3,  # cutoff freq
            5e3,  # transition width
            gr.firdes.WIN_HAMMING)
        self.interpolator = gr.interp_fir_filter_fff(self.sw_interp,
                                                     interp_taps)
        self.pre_emph = blks2.fm_preemph(self.usrp_rate, tau=50e-6)
        self.connect(self.mixer, self.interpolator, self.pre_emph)

        # fm modulation, gain & TX
        max_dev = 100e3
        k = 2 * math.pi * max_dev / self.usrp_rate  # modulator sensitivity
        self.modulator = gr.frequency_modulator_fc(k)
        self.gain = gr.multiply_const_cc(1e3)
        self.connect(self.pre_emph, self.modulator, self.gain, self.u)

        # plot an FFT to verify we are sending what we want
        pre_mod = fftsink2.fft_sink_f(panel,
                                      title="Before Interpolation",
                                      fft_size=512,
                                      sample_rate=self.audio_rate,
                                      y_per_div=20,
                                      ref_level=20)
        self.connect(self.mixer, pre_mod)
        vbox.Add(pre_mod.win, 1, wx.EXPAND)
def main():

    # Parsing command line parameter
    parser = OptionParser(option_class=eng_option)
    parser.add_option(
        "-f",
        "--freq",
        type="eng_float",
        dest="freq",
        default=866.5,
        help="set USRP center frequency (provide frequency in MHz)")
    parser.add_option("-m",
                      "--miller",
                      type="int",
                      dest="miller",
                      default=2,
                      help="set number of Miller subcarriers (2,4 or 8)")
    (options, args) = parser.parse_args()

    which_usrp = 0
    fpga = "gen2_reader_2ch_mod_pwr.rbf"  # Modified firmware --> you can set TX amplitude directly from Python (see below)
    freq = options.freq  # Default value = 866.5 --> center frequency of 2 MHz European RFID Band
    freq = freq * 1e6
    miller = options.miller
    deviation_corr = 1  # Maximum deviation for Early/Late gate correlator in Buettner's reader
    amplitude = 30000  # Amplitude of READER TX signal. 30000 is the maximum allowed.
    rx_gain = 20
    us_per_sample = float(1 / (64.0 / (dec_rate * sw_dec)))
    samp_freq = (64 / dec_rate) * 1e6

    # BUETTNER'S READER HARDWARE SUB-SYSTEM for TX SIDE
    tx = usrp.sink_c(which_usrp,
                     fusb_block_size=1024,
                     fusb_nblocks=4,
                     fpga_filename=fpga)
    tx.set_interp_rate(interp)
    tx_subdev = (0, 0)  # TX/RX port of RFX900 daugtherboard on SIDE A
    tx.set_mux(usrp.determine_tx_mux_value(tx, tx_subdev))
    subdev = usrp.selected_subdev(tx, tx_subdev)
    subdev.set_enable(True)
    subdev.set_gain(subdev.gain_range()[2])

    t = tx.tune(subdev.which(), subdev,
                freq)  # Tuning TX Daughterboard @ Center Frequency
    if not t:
        print "Couldn't set READER TX frequency"

    tx._write_fpga_reg(usrp.FR_USER_1, int(
        amplitude))  # SET FPGA register value with the desired tx amplitude
    # END BUETTNER'S READER HARDWARE SUB-SYSTEM for TX SIDE

    # BUETTNER'S READER HARDWARE SUB-SYSTEM for RX SIDE
    rx = usrp.source_c(
        which_usrp,
        dec_rate,
        nchan=2,
        fusb_block_size=512,
        fusb_nblocks=16,
        fpga_filename=fpga)  # USRP source: 2 channels (reader + listener)
    rx.set_mux(rx.determine_rx_mux_value(
        (0, 0), (1, 0)
    ))  # 2 channel mux --> rx from (0,0) to reader - rx from (1,0) to listener
    rx_reader_subdev_spec = (0, 0)  # Reader RFX900 daugtherboard on SIDE A
    rx_reader_subdev = rx.selected_subdev(rx_reader_subdev_spec)
    rx_reader_subdev.set_gain(rx_gain)
    rx_reader_subdev.set_auto_tr(False)
    rx_reader_subdev.set_enable(True)
    rx_reader_subdev.select_rx_antenna(
        'RX2'
    )  # RX2 port of RFX900 on side A --> RX antenna of Buettner's reader

    r = usrp.tune(rx, 0, rx_reader_subdev,
                  freq)  # Tuning READER RX Daughterboard @ Center Frequency
    if not r:
        print "Couldn't set READER RX frequency"
    # END BUETTNER'S READER HARDWARE SUB-SYSTEM for TX SIDE

    # LISTENER HARDWARE SUB-SYSTEM
    rx_listener_subdev_spec = (1, 0)  # Listener DB RFX900 on side B
    rx_listener_subdev = rx.selected_subdev(rx_listener_subdev_spec)
    rx_listener_subdev.set_gain(rx_gain)
    rx_listener_subdev.set_auto_tr(False)
    rx_listener_subdev.set_enable(True)
    rx_listener_subdev.select_rx_antenna(
        'RX2'
    )  # RX Antenna on RX2 Connector of side B RFX900 (comment this line if you want TX/RX connector)

    r = usrp.tune(rx, 1, rx_listener_subdev,
                  freq)  # Tuning Listener Daughterboard @ Center Frequency
    if not r:
        print "Couldn't set LISTENER RX frequency"
    # END LISTENER HARDWARE SUB-SYSTEM

    print ""
    print "********************************************************"
    print "************ Gen2 RFID Monitoring Platform *************"
    print "********* Reader and Listener on the same USRP *********"
    print "********************************************************\n"

    print "USRP center frequency: %s MHz" % str(freq / 1e6)
    print "Sampling Frequency: " + str(
        samp_freq /
        1e6) + " MHz" + " --- microsec. per Sample: " + str(us_per_sample)

    # BUETTNER's READER SOFTWARE SUB-SYSTEM (GNU-Radio flow-graph)
    gen2_reader = rfid.gen2_reader(dec_rate * sw_dec * samples_per_pulse,
                                   interp, int(miller), True,
                                   int(deviation_corr))
    zc = rfid.clock_recovery_zc_ff(samples_per_pulse, 1, float(us_per_sample),
                                   float(up_link_freq), True)
    # END BUETTNER's READER SOFTWARE SUB-SYSTEM (GNU-Radio flow-graph)

    # LISTENER SOFTWARE SUB-SYSTEM (GNU-Radio flow-graph)
    # MATCHED FILTER
    num_taps = int(
        64000 / (dec_rate * up_link_freq * 4))  #Matched filter for 1/4 cycle
    taps = [complex(1, 1)] * num_taps
    matched_filter = gr.fir_filter_ccc(sw_dec, taps)
    # Tag Decoding Block --> the boolean value in input indicate if real-time output of EPC is enabled or not
    tag_monitor = listener.tag_monitor(True, int(miller), float(up_link_freq))
    # Clock recovery
    cr = listener.clock_recovery(samples_per_pulse, us_per_sample,
                                 tag_monitor.STATE_PTR, float(up_link_freq))
    # Reader Decoding Block and Command gate--> the boolean value indicate if real-time output of reader commands is enabled or not
    reader_monitor_cmd_gate = listener.reader_monitor_cmd_gate(
        False, us_per_sample, tag_monitor.STATE_PTR, float(up_link_freq),
        float(rtcal))
    # END LISTENER SOFTWARE SUB-SYSTEM (GNU-Radio flow-graph)

    # Create GNU-Radio flow-graph
    tb = my_top_block(tx, zc, gen2_reader, rx, matched_filter,
                      reader_monitor_cmd_gate, cr, tag_monitor, amplitude)

    # Start application
    tb.start()

    # GETTING LOGs from BUETTNER's READER
    video_output = False  # Set as True if you want real time video output of Buettner's reader logs
    log_reader_buettner_file = open("log_reader_buettner.log", "w")
    finish = 0
    succ_reads = 0
    epc_errors = 0

    while 1:
        log_reader_buettner = gen2_reader.get_log()
        i = log_reader_buettner.count()
        for k in range(0, i):
            msg = log_reader_buettner.delete_head_nowait()
            print_msg(msg, log_reader_buettner_file, video_output)
            if msg.type() == 99:  # All cycles are terminated
                finish = 1
            if msg.type() == LOG_EPC:  # EPC
                if msg.arg2() == LOG_ERROR:
                    epc_errors = epc_errors + 1
                    # CRC Error on EPC
                else:
                    succ_reads = succ_reads + 1
                    # Successful EPc
        if finish:
            break

    # Stop application
    tb.stop()
    log_reader_buettner_file.close()
    rec_frames = succ_reads + epc_errors
    print "\nReader --> Total Received Frames: " + str(rec_frames)
    print "Reader --> Successful reads: " + str(succ_reads)
    print "Reader --> CRC error frames: " + str(epc_errors)
    print ""

    # GETTING LOGs from LISTENER
    log_READER = reader_monitor_cmd_gate.get_reader_log()
    log_TAG = tag_monitor.get_tag_log()
    print "Listener collected %s Entries for READER LOG" % str(
        log_READER.count())
    print "Listener collected %s Entries for TAG LOG" % str(log_TAG.count())

    c = raw_input("PRESS 'f' to write LOG files, 'q' to QUIT\n")
    if c == "q":
        print "\n Shutting Down...\n"
        return
    if c == "f":
        print "\n Writing READER LOG on file...\n\n"
        reader_file = open("reader_log.out", "w")
        reader_file.close()
        reader_file = open("reader_log.out", "a")
        i = log_READER.count()
        for k in range(0, i):
            decode_reader_log_msg(log_READER.delete_head_nowait(), reader_file)
            k = k + 1
        reader_file.close()

        print "\n Writing TAG LOG on file...\n"
        tag_file = open("tag_log.out", "w")
        tag_file.close()
        tag_file = open("tag_log.out", "a")
        i = log_TAG.count()
        for k in range(0, i):
            decode_tag_log_msg(log_TAG.delete_head_nowait(), tag_file)
            k = k + 1
        tag_file.close()
def main():

    #TX
    which_usrp = 0
    fpga = "gen2_reader.rbf"

    freq = 915e6
    rx_gain = 20

    samp_freq = (64 / dec_rate) * 1e6

    tx = usrp.sink_c(which_usrp,
                     fusb_block_size=1024,
                     fusb_nblocks=4,
                     fpga_filename=fpga)
    tx.set_interp_rate(interp)
    tx_subdev = (0, 0)
    tx.set_mux(usrp.determine_tx_mux_value(tx, tx_subdev))
    subdev = usrp.selected_subdev(tx, tx_subdev)
    subdev.set_enable(True)
    subdev.set_gain(subdev.gain_range()[2])

    t = tx.tune(subdev.which(), subdev, freq)
    if not t:
        print "Couldn't set tx freq"
#End TX

#RX

    rx = usrp.source_c(which_usrp,
                       dec_rate,
                       fusb_block_size=512,
                       fusb_nblocks=16,
                       fpga_filename=fpga)
    rx_subdev_spec = (1, 0)
    rx.set_mux(usrp.determine_rx_mux_value(rx, rx_subdev_spec))
    rx_subdev = usrp.selected_subdev(rx, rx_subdev_spec)
    rx_subdev.set_gain(rx_gain)
    rx_subdev.set_auto_tr(False)
    rx_subdev.set_enable(True)

    us_per_sample = 1 / (64.0 / dec_rate / sw_dec)
    print "Sample Frequency: " + str(samp_freq) + " us Per Sample: " + str(
        us_per_sample)
    r = usrp.tune(rx, 0, rx_subdev, freq)
    if not r:
        print "Couldn't set rx freq"


#End RX

    gen2_reader = rfid.gen2_reader(dec_rate * sw_dec * samples_per_pulse,
                                   interp)

    tb = my_top_block(rx, gen2_reader, tx)
    tb.start()

    log_file = open("log_out.log", "w")

    while 1:

        c = raw_input("'Q' to quit\n")
        if c == "q":
            break

        if c == "A" or c == "a":
            log_file.write("T,CMD,ERROR,BITS,SNR\n")
            log = gen2_reader.get_log()
            print "Log has %s Entries" % (str(log.count()))
            i = log.count()

            for k in range(0, i):
                msg = log.delete_head_nowait()
                print_log_msg(msg, log_file)

    tb.stop()

    log_file.close()
def main():
    

    #TX
    which_usrp = 0
    fpga = "gen2_reader.rbf"

    freq = 915e6
    rx_gain = 20
    
    samp_freq = (64 / dec_rate) * 1e6

    

    tx = usrp.sink_c(which_usrp,fusb_block_size = 1024, fusb_nblocks=4, fpga_filename=fpga)
    tx.set_interp_rate(interp)
    tx_subdev = (0,0)
    tx.set_mux(usrp.determine_tx_mux_value(tx, tx_subdev))
    subdev = usrp.selected_subdev(tx, tx_subdev)
    subdev.set_enable(True)
    subdev.set_gain(subdev.gain_range()[2])
    
    t = tx.tune(subdev.which(), subdev, freq)
    if not t:
        print "Couldn't set tx freq"
#End TX

#RX
            

    rx = usrp.source_c(which_usrp, dec_rate, fusb_block_size = 512, fusb_nblocks = 16, fpga_filename=fpga)
    rx_subdev_spec = (1,0)
    rx.set_mux(usrp.determine_rx_mux_value(rx, rx_subdev_spec))
    rx_subdev = usrp.selected_subdev(rx, rx_subdev_spec)
    rx_subdev.set_gain(rx_gain)
    rx_subdev.set_auto_tr(False)
    rx_subdev.set_enable(True)
    
    us_per_sample = 1 / (64.0 / dec_rate / sw_dec)
    print "Sample Frequency: "+ str(samp_freq) + " us Per Sample: " + str(us_per_sample)
    r = usrp.tune(rx, 0, rx_subdev, freq)
    if not r:
        print "Couldn't set rx freq"

#End RX

    
    gen2_reader = rfid.gen2_reader(dec_rate * sw_dec * samples_per_pulse, interp)

    tb = my_top_block(rx, gen2_reader, tx)
    tb.start()
    

    log_file = open("log_out.log", "w")
    

    
    while 1:
            
        c = raw_input("'Q' to quit\n")
        if c == "q":
            break

        if c == "A" or c == "a":
            log_file.write("T,CMD,ERROR,BITS,SNR\n")
            log = gen2_reader.get_log()
            print "Log has %s Entries"% (str(log.count()))
            i = log.count();
                             
            
            for k in range(0, i):
                msg = log.delete_head_nowait()
                print_log_msg(msg, log_file)

    
    
        
    tb.stop()
   
    log_file.close()
Example #48
0
    def __init__(self, frame, panel, vbox, argv):
        MAX_CHANNELS = 7
        stdgui2.std_top_block.__init__(self, frame, panel, vbox, argv)

        parser = OptionParser(option_class=eng_option)
        parser.add_option("-T",
                          "--tx-subdev-spec",
                          type="subdev",
                          default=None,
                          help="select USRP Tx side A or B")
        parser.add_option("-e",
                          "--enable-fft",
                          action="store_true",
                          default=False,
                          help="enable spectrum plot (and use more CPU)")
        parser.add_option("-f",
                          "--freq",
                          type="eng_float",
                          default=None,
                          help="set Tx frequency to FREQ [required]",
                          metavar="FREQ")
        parser.add_option("-i",
                          "--file-input",
                          action="store_true",
                          default=False,
                          help="input from baseband-0.dat, baseband-1.dat ...")
        parser.add_option("-g",
                          "--audio-gain",
                          type="eng_float",
                          default=1.0,
                          help="input audio gain multiplier")
        parser.add_option("-n",
                          "--nchannels",
                          type="int",
                          default=2,
                          help="number of Tx channels [1,4]")
        parser.add_option("-a",
                          "--udp-addr",
                          type="string",
                          default="127.0.0.1",
                          help="UDP host IP address")
        parser.add_option("-p",
                          "--udp-port",
                          type="int",
                          default=0,
                          help="UDP port number")
        parser.add_option("-r",
                          "--repeat",
                          action="store_true",
                          default=False,
                          help="continuously replay input file")
        parser.add_option("-S",
                          "--stretch",
                          type="int",
                          default=0,
                          help="elastic buffer trigger value")
        parser.add_option("-v",
                          "--verbose",
                          action="store_true",
                          default=False,
                          help="print out stats")
        parser.add_option(
            "-I",
            "--audio-input",
            type="string",
            default="",
            help="pcm input device name.  E.g., hw:0,0 or /dev/dsp")
        (options, args) = parser.parse_args()

        if len(args) != 0:
            parser.print_help()
            sys.exit(1)

        if options.nchannels < 1 or options.nchannels > MAX_CHANNELS:
            sys.stderr.write(
                "op25_tx: nchannels out of range.  Must be in [1,%d]\n" %
                MAX_CHANNELS)
            sys.exit(1)

        if options.freq is None:
            sys.stderr.write("op25_tx: must specify frequency with -f FREQ\n")
            parser.print_help()
            sys.exit(1)

        # ----------------------------------------------------------------
        # Set up constants and parameters

        self.u = usrp.sink_c()  # the USRP sink (consumes samples)

        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
        self.sw_interp = 10
        self.audio_rate = self.usrp_rate / self.sw_interp  # 32 kS/s

        # determine the daughterboard subdevice we're using
        if options.tx_subdev_spec is None:
            options.tx_subdev_spec = usrp.pick_tx_subdevice(self.u)

        m = usrp.determine_tx_mux_value(self.u, options.tx_subdev_spec)
        #print "mux = %#04x" % (m,)
        self.u.set_mux(m)
        self.subdev = usrp.selected_subdev(self.u, options.tx_subdev_spec)
        print "Using TX d'board %s" % (self.subdev.side_and_name(), )

        self.subdev.set_gain(self.subdev.gain_range()[0])  # set min Tx gain
        if not self.set_freq(options.freq):
            freq_range = self.subdev.freq_range()
            print "Failed to set frequency to %s.  Daughterboard supports %s to %s" % (
                eng_notation.num_to_str(
                    options.freq), eng_notation.num_to_str(
                        freq_range[0]), eng_notation.num_to_str(freq_range[1]))
            raise SystemExit
        self.subdev.set_enable(True)  # enable transmitter

        # instantiate vocoders
        self.vocoders = []
        if options.file_input:
            for i in range(options.nchannels):
                t = gr.file_source(gr.sizeof_char, "baseband-%d.dat" % i,
                                   options.repeat)
                self.vocoders.append(t)

        elif options.udp_port > 0:
            self.udp_sources = []
            for i in range(options.nchannels):
                t = gr.udp_source(1, options.udp_addr, options.udp_port + i,
                                  216)
                self.udp_sources.append(t)
                arity = 2
                t = gr.packed_to_unpacked_bb(arity, gr.GR_MSB_FIRST)
                self.vocoders.append(t)
                self.connect(self.udp_sources[i], self.vocoders[i])

        else:
            self.audio_amps = []
            self.converters = []
            input_audio_rate = 8000
            self.audio_input = audio.source(input_audio_rate,
                                            options.audio_input)
            for i in range(options.nchannels):
                t = gr.multiply_const_ff(32767 * options.audio_gain)
                self.audio_amps.append(t)
                t = gr.float_to_short()
                self.converters.append(t)
                t = repeater.vocoder(
                    True,  # 0=Decode,True=Encode
                    options.verbose,  # Verbose flag
                    options.stretch,  # flex amount
                    "",  # udp ip address
                    0,  # udp port
                    False)  # dump raw u vectors
                self.vocoders.append(t)
                self.connect((self.audio_input, i), self.audio_amps[i],
                             self.converters[i], self.vocoders[i])

        sum = gr.add_cc()

        # Instantiate N NBFM channels
        step = 25e3
        offset = (0 * step, 1 * step, -1 * step, 2 * step, -2 * step, 3 * step,
                  -3 * step)
        for i in range(options.nchannels):
            t = pipeline(self.vocoders[i], offset[i], self.audio_rate,
                         self.usrp_rate)
            self.connect(t, (sum, i))

        gain = gr.multiply_const_cc(4000.0 / options.nchannels)

        # connect it all
        self.connect(sum, gain)
        self.connect(gain, self.u)

        # plot an FFT to verify we are sending what we want
        if options.enable_fft:
            post_mod = fftsink2.fft_sink_c(panel,
                                           title="Post Modulation",
                                           fft_size=512,
                                           sample_rate=self.usrp_rate,
                                           y_per_div=20,
                                           ref_level=40)
            self.connect(sum, post_mod)
            vbox.Add(post_mod.win, 1, wx.EXPAND)
Example #49
0
    def __init__(self, frame, panel, vbox, argv):
        MAX_CHANNELS = 7
        stdgui2.std_top_block.__init__(self, frame, panel, vbox, argv)

        parser = OptionParser(option_class=eng_option)
        parser.add_option("-T",
                          "--tx-subdev-spec",
                          type="subdev",
                          default=None,
                          help="select USRP Tx side A or B")
        parser.add_option("-d", "--debug", action="store_true", default=False)
        parser.add_option("-e",
                          "--enable-fft",
                          action="store_true",
                          default=False,
                          help="enable spectrum plot (and use more CPU)")
        parser.add_option("-f",
                          "--freq",
                          type="eng_float",
                          default=None,
                          help="set Tx frequency to FREQ [required]",
                          metavar="FREQ")
        parser.add_option("-n",
                          "--nchannels",
                          type="int",
                          default=2,
                          help="number of Tx channels [1,4]")
        parser.add_option("-p",
                          "--udp-port",
                          type="int",
                          default=32001,
                          help="initial UDP port number")
        (options, args) = parser.parse_args()

        if len(args) != 0:
            parser.print_help()
            sys.exit(1)

        if options.nchannels < 1 or options.nchannels > MAX_CHANNELS:
            sys.stderr.write(
                "op25_tx: nchannels out of range.  Must be in [1,%d]\n" %
                MAX_CHANNELS)
            sys.exit(1)

        if options.freq is None:
            sys.stderr.write("op25_tx: must specify frequency with -f FREQ\n")
            parser.print_help()
            sys.exit(1)

        # ----------------------------------------------------------------
        # Set up constants and parameters

        self.u = usrp.sink_c()  # the USRP sink (consumes samples)

        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

        # determine the daughterboard subdevice we're using
        if options.tx_subdev_spec is None:
            options.tx_subdev_spec = usrp.pick_tx_subdevice(self.u)

        m = usrp.determine_tx_mux_value(self.u, options.tx_subdev_spec)
        #print "mux = %#04x" % (m,)
        self.u.set_mux(m)
        self.subdev = usrp.selected_subdev(self.u, options.tx_subdev_spec)
        print "Using TX d'board %s" % (self.subdev.side_and_name(), )

        self.subdev.set_gain(self.subdev.gain_range()[0])  # set min Tx gain
        if not self.set_freq(options.freq):
            freq_range = self.subdev.freq_range()
            print "Failed to set frequency to %s.  Daughterboard supports %s to %s" % (
                eng_notation.num_to_str(
                    options.freq), eng_notation.num_to_str(
                        freq_range[0]), eng_notation.num_to_str(freq_range[1]))
            raise SystemExit
        self.subdev.set_enable(True)  # enable transmitter

        self.sum = gr.add_cc()

        step = 25e3
        offset = (0 * step, 1 * step, -1 * step, 2 * step, -2 * step, 3 * step,
                  -3 * step)

        # Instantiate N TX channels
        for i in range(options.nchannels):
            t = tx_channel_usrp(options.udp_port + i,
                                MAX_GAIN / options.nchannels, self.usrp_rate,
                                offset[i])
            self.connect(t, (self.sum, i))
        self.connect(self.sum, self.u)

        # plot an FFT to verify we are sending what we want
        if options.enable_fft:
            post_mod = fftsink2.fft_sink_c(panel,
                                           title="Post Modulation",
                                           fft_size=512,
                                           sample_rate=self.usrp_rate,
                                           y_per_div=20,
                                           ref_level=40)
            self.connect(self.sum, post_mod)
            vbox.Add(post_mod.win, 1, wx.EXPAND)

        if options.debug:
            #    self.debugger = tx_debug_gui.tx_debug_gui(self.subdev)
            #    self.debugger.Show(True)
            print "attach pid %d" % os.getpid()
            raw_input("press enter")
Example #50
0
    def __init__(self):

        parser = OptionParser(option_class=eng_option)
        parser.add_option(
            "-T",
            "--tx-subdev-spec",
            type="subdev",
            default=None,
            help=
            "select USRP Tx side A or B (default=first one with a daughterboard)"
        )
        parser.add_option("-c",
                          "--cordic-freq1",
                          type="eng_float",
                          default=434845200,
                          help="set Tx cordic frequency to FREQ",
                          metavar="FREQ")
        parser.add_option("-d",
                          "--cordic-freq2",
                          type="eng_float",
                          default=434318512,
                          help="set rx cordic frequency for channel 2 to FREQ",
                          metavar="FREQ")
        parser.add_option("-g",
                          "--gain",
                          type="eng_float",
                          default=0,
                          help="set Rx PGA gain in dB [0,20]")

        (options, args) = parser.parse_args()
        print "cordic_freq1 = %s" % (eng_notation.num_to_str(
            options.cordic_freq1))
        print "cordic_freq2 = %s" % (eng_notation.num_to_str(
            options.cordic_freq2))

        # ----------------------------------------------------------------

        self.data_rate = 38400
        self.samples_per_symbol = 8
        self.channel_fs = self.data_rate * self.samples_per_symbol
        self.fs = 4e6
        payload_size = 128  # bytes

        print "data_rate = ", eng_notation.num_to_str(self.data_rate)
        print "samples_per_symbol = ", self.samples_per_symbol
        print "fs = ", eng_notation.num_to_str(self.fs)

        gr.flow_graph.__init__(self)
        self.normal_gain = 8000

        self.u = usrp.sink_c()
        dac_rate = self.u.dac_rate()

        self.interp = int(dac_rate / self.fs)
        print "usrp interp = ", self.interp

        self.u.set_interp_rate(self.interp)

        # determine the daughterboard subdevice we're using
        if options.tx_subdev_spec is None:
            options.tx_subdev_spec = usrp.pick_tx_subdevice(self.u)
        self.u.set_mux(
            usrp.determine_tx_mux_value(self.u, options.tx_subdev_spec))
        self.subdev = usrp.selected_subdev(self.u, options.tx_subdev_spec)
        print "Using TX d'board %s" % (self.subdev.side_and_name(), )

        if options.cordic_freq1 < options.cordic_freq2:
            self.usrp_freq = options.cordic_freq1
            self.freq_diff = options.cordic_freq2 - options.cordic_freq1
        else:
            self.usrp_freq = options.cordic_freq2
            self.freq_diff = options.cordic_freq1 - options.cordic_freq2
        print "freq_diff = ", eng_notation.num_to_str(self.freq_diff)

        self.u.tune(self.subdev._which, self.subdev, self.usrp_freq)
        print "tune USRP to = ", eng_notation.num_to_str(self.usrp_freq)
        self.u.set_pga(0, options.gain)
        self.u.set_pga(1, options.gain)

        interp_factor = int(self.fs / self.channel_fs)
        quad_rate = self.fs
        print "interp_factor = ", interp_factor

        # Create filter for the interpolation
        interp_taps = gr.firdes.low_pass(
            interp_factor,  # gain
            self.channel_fs * interp_factor,  # Fs
            self.channel_fs / 2,  # low pass cutoff freq
            self.channel_fs * 0.1,  # width of trans. band
            gr.firdes.WIN_HANN)  #filter type

        print "len(interp_taps) =", len(interp_taps)

        self.interpolator1 = gr.interp_fir_filter_ccc(interp_factor,
                                                      interp_taps)
        self.interpolator2 = gr.interp_fir_filter_ccc(interp_factor,
                                                      interp_taps)

        self.multiplicator = gr.multiply_cc()

        self.adder = gr.add_cc()

        self.sin = gr.sig_source_c(self.channel_fs * interp_factor,
                                   gr.GR_SIN_WAVE, self.freq_diff, 1,
                                   complex(0, 0))

        # transmitter
        self.packet_transmitter1 = cc1k_sos_pkt.cc1k_mod_pkts(
            self, spb=self.samples_per_symbol, msgq_limit=2)
        #self.packet_transmitter2 = cc1k_sos_pkt.cc1k_mod_pkts(self, spb=self.samples_per_symbol, msgq_limit=2)

        self.amp = gr.multiply_const_cc(self.normal_gain)
        self.filesink = gr.file_sink(gr.sizeof_gr_complex, 'tx_test.dat')
        self.filesink2 = gr.file_sink(gr.sizeof_gr_complex, 'tx_test2.dat')
        self.filesink3 = gr.file_sink(gr.sizeof_gr_complex, 'tx_test3.dat')

        # interpolate the two transmitters
        self.connect(self.packet_transmitter1, self.interpolator1)
        #self.connect(self.packet_transmitter2, self.interpolator2)
        # upconvert the first transmitter)
        self.connect(self.interpolator1, (self.multiplicator, 1))
        self.connect(self.sin, (self.multiplicator, 0))
        # add the two signals
        #self.connect(self.multiplicator, (self.adder, 0))
        #self.connect(self.interpolator2, (self.adder, 1))
        # send the signal to the USRP
        self.connect(self.interpolator1, self.amp, self.filesink)
        self.connect(self.multiplicator, self.filesink2)
        self.connect(self.sin, self.filesink3)

        self.set_gain(self.subdev.gain_range()[1])  # set max Tx gain
        self.set_auto_tr(True)  # enable Auto Transmit/Receive switching
Example #51
0
def main():
    parser = OptionParser(option_class=eng_option)
    parser.add_option("-f",
                      "--freq",
                      type="eng_float",
                      default=144.800e6,
                      help="set frequency to FREQ",
                      metavar="FREQ")
    parser.add_option("-m",
                      "--message",
                      type="string",
                      default=":ALL      :this is a test",
                      help="message to send",
                      metavar="MESSAGE")
    parser.add_option("-c",
                      "--mycall",
                      type="string",
                      default="MYCALL",
                      help="source callsign",
                      metavar="CALL")
    parser.add_option("-t",
                      "--tocall",
                      type="string",
                      default="CQ",
                      help="recipient callsign",
                      metavar="CALL")
    parser.add_option("-v",
                      "--via",
                      type="string",
                      default="RELAY",
                      help="digipeater callsign",
                      metavar="CALL")
    parser.add_option("-d",
                      "--do-logging",
                      action="store_true",
                      default=False,
                      help="enable logging on datafiles")
    parser.add_option("-s",
                      "--use-datafile",
                      action="store_true",
                      default=False,
                      help="use usrp.dat (256kbps) as output")
    (options, args) = parser.parse_args()
    if len(args) != 0:
        parser.print_help()
        sys.exit(1)

    bitrate = 9600
    dac_rate = 128e6
    usrp_interp = 500
    cordic_freq = options.freq - dac_rate
    sf = 153600
    syminterp = sf / bitrate  #16
    nbfmdev = 3e3
    fmsens = 2 * pi * nbfmdev / (sf * 5 / 3)
    bit_oversampling = 8
    sw_interp = int(sf / bitrate / bit_oversampling)  #2

    fg = gr.flow_graph()

    p = buildpacket(options.mycall, 0, options.tocall, 0, options.via, 0, 0x03,
                    0xf0, options.message)
    if options.do_logging:
        dumppackettofile(p, "packet.dat")
    v = bits2syms(nrziencode(scrambler(hdlcpacket(p, 100, 1000))))
    src = gr.vector_source_f(v)
    gaussian_taps = gr.firdes.gaussian(
        1,  # gain
        bit_oversampling,  # symbol_rate
        0.3,  # bandwidth * symbol time
        4 * bit_oversampling  # number of taps
    )
    sqwave = (1, ) * syminterp  #rectangular window
    taps = Numeric.convolve(Numeric.array(gaussian_taps),
                            Numeric.array(sqwave))
    gaussian = gr.interp_fir_filter_fff(syminterp, taps)  #9600*16=153600

    res_taps = blks.design_filter(5, 3, 0.4)
    res = blks.rational_resampler_fff(fg, 5, 3, res_taps)  #153600*5/3=256000
    fmmod = gr.frequency_modulator_fc(fmsens)
    amp = gr.multiply_const_cc(32000)

    if options.use_datafile:
        dst = gr.file_sink(gr.sizeof_gr_complex, "usrp.dat")
    else:
        u = usrp.sink_c(0, usrp_interp)  #256000*500=128000000
        tx_subdev_spec = usrp.pick_tx_subdevice(u)
        m = usrp.determine_tx_mux_value(u, tx_subdev_spec)
        print "mux = %#04x" % (m, )
        u.set_mux(m)
        subdev = usrp.selected_subdev(u, tx_subdev_spec)
        print "Using TX d'board %s" % (subdev.side_and_name(), )
        u.set_tx_freq(0, cordic_freq)
        u.set_pga(0, 0)
        print "Actual frequency: ", u.tx_freq(0)
        dst = u

    fg.connect(src, gaussian, res, fmmod, amp, dst)

    fg.start()
    fg.wait()
Example #52
0
    def __init__(self, frame, panel, vbox, argv):
        MAX_CHANNELS = 7
        stdgui2.std_top_block.__init__ (self, frame, panel, vbox, argv)

        parser = OptionParser (option_class=eng_option)
        parser.add_option("-T", "--tx-subdev-spec", type="subdev", default=None,
                          help="select USRP Tx side A or B")
        parser.add_option("-d","--debug", action="store_true", default=False)
        parser.add_option("-e","--enable-fft", action="store_true", default=False,
                          help="enable spectrum plot (and use more CPU)")
        parser.add_option("-f", "--freq", type="eng_float", default=None,
                           help="set Tx frequency to FREQ [required]", metavar="FREQ")
        parser.add_option("-n", "--nchannels", type="int", default=2,
                           help="number of Tx channels [1,4]")
        parser.add_option("-p", "--udp-port", type="int", default=32001,
                           help="initial UDP port number")
        (options, args) = parser.parse_args ()

        if len(args) != 0:
            parser.print_help()
            sys.exit(1)

        if options.nchannels < 1 or options.nchannels > MAX_CHANNELS:
            sys.stderr.write ("op25_tx: nchannels out of range.  Must be in [1,%d]\n" % MAX_CHANNELS)
            sys.exit(1)
        
        if options.freq is None:
            sys.stderr.write("op25_tx: must specify frequency with -f FREQ\n")
            parser.print_help()
            sys.exit(1)

        # ----------------------------------------------------------------
        # Set up constants and parameters

        self.u = usrp.sink_c ()       # the USRP sink (consumes samples)

        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

        # determine the daughterboard subdevice we're using
        if options.tx_subdev_spec is None:
            options.tx_subdev_spec = usrp.pick_tx_subdevice(self.u)

        m = usrp.determine_tx_mux_value(self.u, options.tx_subdev_spec)
        #print "mux = %#04x" % (m,)
        self.u.set_mux(m)
        self.subdev = usrp.selected_subdev(self.u, options.tx_subdev_spec)
        print "Using TX d'board %s" % (self.subdev.side_and_name(),)

        self.subdev.set_gain(self.subdev.gain_range()[0])    # set min Tx gain
        if not self.set_freq(options.freq):
            freq_range = self.subdev.freq_range()
            print "Failed to set frequency to %s.  Daughterboard supports %s to %s" % (
                eng_notation.num_to_str(options.freq),
                eng_notation.num_to_str(freq_range[0]),
                eng_notation.num_to_str(freq_range[1]))
            raise SystemExit
        self.subdev.set_enable(True)                         # enable transmitter

        self.sum = gr.add_cc()

        step = 25e3
        offset = (0 * step, 1 * step, -1 * step, 2 * step, -2 * step, 3 * step, -3 * step)

        # Instantiate N TX channels
	for i in range(options.nchannels):
            t = tx_channel_usrp(options.udp_port + i, MAX_GAIN / options.nchannels, self.usrp_rate, offset[i])
            self.connect (t, (self.sum, i))
        self.connect (self.sum, self.u)

        # plot an FFT to verify we are sending what we want
        if options.enable_fft:
            post_mod = fftsink2.fft_sink_c(panel, title="Post Modulation",
                                           fft_size=512, sample_rate=self.usrp_rate,
                                           y_per_div=20, ref_level=40)
            self.connect (self.sum, post_mod)
            vbox.Add (post_mod.win, 1, wx.EXPAND)
            

        if options.debug:
        #    self.debugger = tx_debug_gui.tx_debug_gui(self.subdev)
        #    self.debugger.Show(True)
          print "attach pid %d" % os.getpid()
          raw_input("press enter")
Example #53
0
# 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.
# 

#!/usr/bin/env python

from gnuradio import gr
from gnuradio import usrp
from optparse import OptionParser
from usrpm import usrp_dbid

u_source = usrp.source_c()
u_sink = usrp.sink_c()

subdev_Ar = usrp.selected_subdev(u_source, (0,0))
subdev_Br = usrp.selected_subdev(u_source, (1,0))
subdev_At = usrp.selected_subdev(u_sink, (0,0))
subdev_Bt = usrp.selected_subdev(u_sink, (1,0))

print "RX d'board %s" % (subdev_Ar.side_and_name(),)
print "RX d'board %s" % (subdev_Br.side_and_name(),)
print "TX d'board %s" % (subdev_At.side_and_name(),)
print "TX d'board %s" % (subdev_Bt.side_and_name(),)

    def __init__(self):
        gr.flow_graph.__init__(self)

        self.u = usrp.sink_c()
Example #55
0
    def __init__(self, frame, panel, vbox, argv):
        # Graphical part
        stdgui2.std_top_block.__init__(self, frame, panel, vbox, argv)

        # Config_____
        tx_frequency = 14085000
        usrp_interpolation = 400
        usrp_tx_rate = 128000000
        tx_side = 0
        tx_dev = 0
        audio_rate = 32000

        tx_subdev = (tx_side, tx_dev)
        usrp_tx_sample_rate = usrp_tx_rate / usrp_interpolation

        def rtty_gen_f(samplerate, speed, textdata):
            bitsamples = samplerate / speed
            mark = 900
            shift = 170
            space = mark + shift

            wavedata = []

            letters = "_E\nA SIU\rDRJNFCKTZLWHYPQOBG_MXV_"
            figures = "_3\n- '87\r_4_,!:(5+)2$6019?&_./;_"
            keyshift = 0

            for c in textdata:
                chartable = letters
                baudotdata = ''
                shiftdata = ''

                if ((c >= '!') and (c <= '9')):
                    if (not keyshift):
                        shiftdata = '[MMSMM]'
                    keyshift = 1
                else:
                    if (keyshift):
                        shiftdata = '[MMMMM]'
                    keyshift = 0

                baudotdata = ']' + baudotdata
                if (keyshift):
                    chartable = figures
                baudotval = chartable.find(c)
                for b in (16, 8, 4, 2, 1):
                    if (baudotval >= b):
                        baudotdata = 'M' + baudotdata
                        baudotval = baudotval - b
                    else:
                        baudotdata = 'S' + baudotdata
                baudotdata = shiftdata + '[' + baudotdata

                for bit in baudotdata:
                    if (bit == 'M'):
                        bitval = mark
                        bitlen = 1
                    if (bit == 'S'):
                        bitval = space
                        bitlen = 1
                    if (bit == '['):
                        bitval = space
                        bitlen = 1
                    if (bit == ']'):
                        bitval = mark
                        bitlen = 1.5

                    for s in range(0, bitlen * bitsamples):
                        wavedata.append(bitval)

            return gr.vector_source_f(wavedata, True)

        ryry = "RYRYRYRYRYRYRYRYRYRYRYRYRYRYRYRYRYRYRYRYRYRYRYRYRY\r\n"
        callsign = "ZCZC DE PA3FKM PA3FKM -- RUNNING GNURADIO -- \r\n"
        fox = "+-- THE QUICK BROWN FOX JUMPED OVER THE LAZY DOG --+\r\n "
        rttymsg = ryry + ryry + callsign + fox + "(0123456789)\r\n"

        callgever = rtty_gen_f(audio_rate, 45, rttymsg)

        lpf_coeffs = gr.firdes.low_pass(1, audio_rate, 5000, 200)

        lpf = gr.fir_filter_fff(1, lpf_coeffs)

        fsk_f = gr.vco_f(audio_rate, 2 * pi, 0.5)

        fsk_c = gr.hilbert_fc(audio_rate / 300)

        # IF low pass filter
        lpf_tx_coeffs = gr.firdes.low_pass(32000, audio_rate, 2000, 1000)

        # Interpolation to usrp sample frequency
        fsk_resample = blks2.rational_resampler_ccc(usrp_tx_sample_rate /
                                                    audio_rate,
                                                    1,
                                                    taps=lpf_tx_coeffs)

        usrp_tx = usrp.sink_c(0, usrp_interpolation)
        self.usrp_tx = usrp_tx

        speaker = audio.sink(audio_rate, "plughw:0,0")

        self.connect(callgever, lpf, fsk_f)
        self.connect(fsk_f, fsk_c, fsk_resample, usrp_tx)
        #self.connect(fsk_f, speaker)

        # Set Multiplexer
        mux = usrp.determine_tx_mux_value(usrp_tx, tx_subdev)
        usrp_tx.set_mux(mux)

        # Select subdevice
        usrp_tx_subdev = usrp.selected_subdev(usrp_tx, tx_subdev)

        # Tune subdevice
        usrp_tx.tune(usrp_tx_subdev._which, usrp_tx_subdev, tx_frequency)

        # Enable Transmitter (Required if using one of the Flex boards)
        usrp_tx_subdev.set_enable(True)
Example #56
0
    def __init__(self):
        gr.top_block.__init__(self)
           
        amplitude = 30000

        filt_out = gr.file_sink(gr.sizeof_gr_complex, "./filt.out")
        filt2_out = gr.file_sink(gr.sizeof_gr_complex, "./filt2.out")
        ffilt_out = gr.file_sink(gr.sizeof_float, "./ffilt.out")
        ffilt2_out = gr.file_sink(gr.sizeof_float, "./ffilt2.out")

        interp_rate = 128
        dec_rate = 8
        sw_dec = 4

        num_taps = int(64000 / ( (dec_rate * 4) * 256 )) #Filter matched to 1/4 of the 256 kHz tag cycle
        taps = [complex(1,1)] * num_taps
        
        matched_filt = gr.fir_filter_ccc(sw_dec, taps);  
          
        agc = gr.agc2_cc(0.3, 1e-3, 1, 1, 100) 
     
        to_mag = gr.complex_to_mag()

        center = rfid.center_ff(4)

        omega = 2
        mu = 0.25
        gain_mu = 0.25
        gain_omega = .25 * gain_mu * gain_mu
        omega_relative_limit = .05

        mm = gr.clock_recovery_mm_ff(omega, gain_omega, mu, gain_mu, omega_relative_limit)


        self.reader = rfid.reader_f(int(128e6/interp_rate)); 
        
        tag_decoder = rfid.tag_decoder_f()
        
        command_gate = rfid.command_gate_cc(12, 60, 64000000 / dec_rate / sw_dec)
        

       
       
        to_complex = gr.float_to_complex()
        amp = gr.multiply_const_ff(amplitude)
        
        f_sink = gr.file_sink(gr.sizeof_gr_complex, 'f_sink.out');
        f_sink2 = gr.file_sink(gr.sizeof_gr_complex, 'f_sink2.out');


            #TX
      


        freq = 915e6
        rx_gain = 20  
    
        tx = usrp.sink_c(fusb_block_size = 1024, fusb_nblocks=8)
        tx.set_interp_rate(interp_rate)
        tx_subdev = (0,0)
        tx.set_mux(usrp.determine_tx_mux_value(tx, tx_subdev))
        subdev = usrp.selected_subdev(tx, tx_subdev)
        subdev.set_enable(True)
        subdev.set_gain(subdev.gain_range()[2])
        t = tx.tune(subdev.which(), subdev, freq)
        if not t:
            print "Couldn't set tx freq"
#End TX
             
#RX
        rx = usrp.source_c(0, dec_rate, fusb_block_size = 512 * 4, fusb_nblocks = 16)
        rx_subdev_spec = (1,0)
        rx.set_mux(usrp.determine_rx_mux_value(rx, rx_subdev_spec))
        rx_subdev = usrp.selected_subdev(rx, rx_subdev_spec)
        rx_subdev.set_gain(rx_gain)
        rx_subdev.set_auto_tr(False)
        rx_subdev.set_enable(True)
        
        r = usrp.tune(rx, 0, rx_subdev, freq)

        self.rx = rx
        if not r:
            print "Couldn't set rx freq"

#End RX

        command_gate.set_ctrl_out(self.reader.ctrl_q())
        tag_decoder.set_ctrl_out(self.reader.ctrl_q())
        agc2 = gr.agc2_ff(0.3, 1e-3, 1, 1, 100) 


#########Build Graph
        self.connect(rx, matched_filt)
        self.connect(matched_filt, command_gate)
        self.connect(command_gate, agc)
        self.connect(agc, to_mag) 
        self.connect(to_mag, center, agc2, mm, tag_decoder)
        self.connect(tag_decoder, self.reader, amp, to_complex, tx);
#################

        
        self.connect(matched_filt, filt_out)
Example #57
0
    def __init__(self, parent, ID, title):
        wxFrame.__init__(self, parent, ID, title,
                wxDefaultPosition)

        self.pga = 0
        self.pgaMin = -20
        self.pgaMax = 0
        self.pgaStep = 0.25

# Parsing options
        parser = OptionParser(option_class=eng_option,
                usage="usage: %prog [options] filename1" \
                " [-f frequency2 filename2 [...]]")
        parser.add_option("-a", "--agc", action="store_true",
                help="enable agc")
        parser.add_option("-c", "--clockrate", type="eng_float", default=128e6,
                help="set USRP clock rate (128e6)")
        parser.add_option("--copy", action="store_true",
                help="enable real to imag data copy when in real mode")
        parser.add_option("-e", "--encoding", type="choice", choices=["s", "f"],
                default="f", help="choose data encoding: [s]igned or [f]loat.")
        parser.add_option("-f", "--frequency", type="eng_float",
                action="callback", callback=appendFrequency,
                help="set output frequency (222.064e6)")
        parser.add_option("-g", "--gain", type="float",
                help="set output pga gain")
        parser.add_option("-l", "--list", action="callback", callback=listUsrp,
                help="list USRPs and daugtherboards")
        parser.add_option("-m", "--mode", type="eng_float", default=2,
                help="mode: 1: real, 2: complex (2)")
        parser.add_option("-o", "--osc", action="store_true",
                help="enable oscilloscope")
        parser.add_option("-r", "--samplingrate", type="eng_float",
                default=3.2e6,
                help="set input sampling rate (3200000)")
        parser.add_option("-s", "--spectrum", action="store_true",
                help="enable spectrum analyzer")
#        parser.add_option("-t", "--tx", type="choice", choices=["A", "B"],
#                default="A", help="choose USRP tx A|B output (A)")
        parser.add_option("-u", "--usrp", action="store_true",
                help="enable USRP output")

        (options, args) = parser.parse_args()
        if len(args) == 0 :
            options.filename = [ "/dev/stdin" ]
        else :
            options.filename = args
# Setting default frequency
        if options.frequency is None :
            options.frequency = [ 222.064e6 ]
        if len(options.filename) != len(options.frequency) :
            parser.error("Nb input file != nb frequency!")

# Status bar
#        self.CreateStatusBar(3, 0)
#        msg = "PGA: %.2f dB" % (self.pga * self.pgaStep)
#        self.SetStatusText(msg, 1)
#        msg = "Freq: %.3f mHz" % (options.frequency[0] / 1000000.0)
#        self.SetStatusText(msg, 2)

# Menu bar
        menu = wxMenu()
        menu.Append(ID_ABOUT, "&About",
                "More information about this program")
        menu.AppendSeparator()
        menu.Append(ID_EXIT, "E&xit", "Terminate the program")
        menuBar = wxMenuBar()
        menuBar.Append(menu, "&File")
        self.SetMenuBar(menuBar)
        

# Main windows
        mainSizer = wxFlexGridSizer(0, 1)
        sliderSizer = wxFlexGridSizer(0, 2)
        buttonSizer = wxBoxSizer(wxHORIZONTAL)

        if options.usrp :
            # TX d'board 0
            gainLabel = wxStaticText(self, -1, "PGA 0")
            gainSlider = wxSlider(self, ID_GAIN_SLIDER0, self.pga,
                    self.pgaMin / self.pgaStep, self.pgaMax / self.pgaStep,
                    style = wxSL_HORIZONTAL | wxSL_AUTOTICKS)
            gainSlider.SetSize((400, -1))
            sliderSizer.Add(gainLabel, 0,
                    wxALIGN_CENTER_VERTICAL | wxFIXED_MINSIZE, 0)
            sliderSizer.Add(gainSlider, 0,
                    wxALIGN_CENTER_VERTICAL | wxFIXED_MINSIZE, 0)

            freqLabel = wxStaticText(self, -1, "Frequency 0")
            freqSlider = wxSlider(self, ID_FREQ_SLIDER0,
                    options.frequency[0] / 16000, 0, 20e3,
                    style = wxSL_HORIZONTAL | wxSL_AUTOTICKS)
            freqSlider.SetSize((400, -1))
            sliderSizer.Add(freqLabel, 0,
                    wxALIGN_CENTER_VERTICAL | wxFIXED_MINSIZE, 0)
            sliderSizer.Add(freqSlider, 0,
                    wxALIGN_CENTER_VERTICAL | wxFIXED_MINSIZE, 0)

            if len(options.frequency) > 1 :
                # TX d'board 1
                gainLabel = wxStaticText(self, -1, "PGA 1")
                gainSlider = wxSlider(self, ID_GAIN_SLIDER1, self.pga,
                        self.pgaMin / self.pgaStep, self.pgaMax / self.pgaStep,
                        style = wxSL_HORIZONTAL | wxSL_AUTOTICKS)
                gainSlider.SetSize((400, -1))
                sliderSizer.Add(gainLabel, 0,
                        wxALIGN_CENTER_VERTICAL | wxFIXED_MINSIZE, 0)
                sliderSizer.Add(gainSlider, 0,
                        wxALIGN_CENTER_VERTICAL | wxFIXED_MINSIZE, 0)

                freqLabel = wxStaticText(self, -1, "Frequency 1")
                freqSlider = wxSlider(self, ID_FREQ_SLIDER1,
                        options.frequency[1] / 16000, 0, 20e3,
                        style = wxSL_HORIZONTAL | wxSL_AUTOTICKS)
                freqSlider.SetSize((400, -1))
                sliderSizer.Add(freqLabel, 0,
                        wxALIGN_CENTER_VERTICAL | wxFIXED_MINSIZE, 0)
                sliderSizer.Add(freqSlider, 0,
                        wxALIGN_CENTER_VERTICAL | wxFIXED_MINSIZE, 0)

            mainSizer.Add(sliderSizer, 1, wxEXPAND, 0)

        start = wxButton(self, ID_START, "Start")
        stop = wxButton(self, ID_STOP, "Stop")
        buttonSizer.Add(start, 1, wxALIGN_CENTER, 0)
        buttonSizer.Add(stop, 1, wxALIGN_CENTER, 0)
        mainSizer.Add(buttonSizer, 1, wxEXPAND, 0)
    
# GnuRadio
        self.fg = gr.flow_graph()
        if options.mode == 1 :
            print "Source: real"
            if (options.encoding == "s") :
                print "Source encoding: short"
                src = gr.file_source(gr.sizeof_short, options.filename[0], 1)
                if (options.copy) :
                    print "Imag: copy"
                    imag = src
                else :
                    print "Imag: null"
                    imag = gr.null_source(gr.sizeof_short)
                interleaver = gr.interleave(gr.sizeof_short)
                self.fg.connect(src, (interleaver, 0))
                self.fg.connect(imag, (interleaver, 1))
                tail = interleaver
            elif (options.encoding == "f") :
                print "Source encoding: float"
                src = gr.file_source(gr.sizeof_gr_complex,
                    options.filename[0], 1)
                tail = src
        elif (options.mode == 2) :
            print "Source: complex"
            if len(options.frequency) == 1 :
                if (options.encoding == "s") :
                    print "Source encoding: short"
                    src = gr.file_source(gr.sizeof_short,
                            options.filename[0], 1)
                elif (options.encoding == "f") :
                    print "Source encoding: float"
                    src = gr.file_source(gr.sizeof_gr_complex,
                            options.filename[0], 1)
                else :
                    parser.error("Invalid encoding type for complex data!")
                tail = src
                    
            elif (len(options.frequency) == 2) :
                src0 = gr.file_source(gr.sizeof_gr_complex,
                        options.filename[0], 1)
                src1 = gr.file_source(gr.sizeof_gr_complex,
                        options.filename[1], 1)
                interleaver = gr.interleave(gr.sizeof_gr_complex)
                self.fg.connect(src0, (interleaver, 0))
                self.fg.connect(src1, (interleaver, 1))
                tail = interleaver
            else :
                parser.error(
                        "Invalid number of source (> 2) with complex input!")
        else :
            parser.error("Invalid mode!")

# Interpolation
        dac_freq = options.clockrate
        interp = int(dac_freq / options.samplingrate)
        if interp == 0 :
            parser.error("Invalid sampling rate!")
        if options.mode == 2 :
            print "Input sampling rate: %s complex samples/s" % \
                num_to_str(options.samplingrate)
        else :
            print "Input sampling rate: %s samples/s" % \
                num_to_str(options.samplingrate)
        print "Interpolation rate: int(%s / %s) = %sx" % \
            (num_to_str(dac_freq), num_to_str(options.samplingrate), interp)
        if interp > 512 :
            factor = gcd(dac_freq / 512, options.samplingrate)
            num = int((dac_freq / 512) / factor)
            den = int(options.samplingrate / factor)
            print "Resampling by %i / %i" % (num, den)
            resampler = blks.rational_resampler_ccc(self.fg, num, den)
            self.fg.connect(tail, resampler)
            tail = resampler
            interp = 512
            options.samplingrate = dac_freq / 512

# AGC
        if options.agc :
            agc = gr.agc_cc()
            self.fg.connect(tail, agc)
            tail = agc
            
# USRP
        if options.usrp :
            nchan = len(options.frequency)
            if len(options.frequency) == 1 :
                if options.mode == 1 :
                    mux = 0x00000098
                elif options.mode == 2 :
                    mux = 0x00000098
                else :
                    parser.error("Unsupported mode for USRP mux!")
            elif len(options.frequency) == 2 :
                if options.mode == 1 :
                    mux = 0x0000ba98
                elif options.mode == 2 :
                    mux = 0x0000ba98
                else :
                    parser.error("Unsupported mode for USRP mux!")
            else :
                parser.error("Invalid number of frequency [0..2]!")
#            if options.tx == "A" :
#                mux = 0x00000098
#            else :
#                mux = 0x00009800
            print "Nb channels: ", nchan
            print "Mux: 0x%x" % mux
            if options.encoding == 's' :
                dst = usrp.sink_s(0, interp, nchan, mux)
            elif options.encoding == 'f' :
                dst = usrp.sink_c(0, interp, nchan, mux)
            else :
                parser.error("Unsupported data encoding for USRP!")
            
            dst.set_verbose(1)

            for i in range(len(options.frequency)) :
                if options.gain is None :
                    print "Setting gain to %f" % dst.pga_max()
                    dst.set_pga(i << 1, dst.pga_max())
                else :
                    print "Setting gain to %f" % options.gain
                    dst.set_pga(i << 1, options.gain)

                tune = false
                for dboard in dst.db:
                    if (dboard[0].dbid() != -1):
                        device = dboard[0]
                        print "Tuning TX d'board %s to %sHz" % \
                                (device.side_and_name(),
                                num_to_str(options.frequency[i]))
                        device.lo_offset = 38e6
                        (min, max, offset) = device.freq_range()
                        print " Frequency"
                        print "  Min:    %sHz" % num_to_str(min)
                        print "  Max:    %sHz" % num_to_str(max)
                        print "  Offset: %sHz" % num_to_str(offset)
#device.set_gain(device.gain_range()[1])
                        device.set_enable(True)
                        tune = \
                            dst.tune(device._which, device,
                                    options.frequency[i] * 128e6 / dac_freq)
                        if tune:
                            print "  Baseband frequency: %sHz" % \
                                num_to_str(tune.baseband_freq)
                            print "  DXC frequency: %sHz" % \
                                num_to_str(tune.dxc_freq)
                            print "  Residual Freqency: %sHz" % \
                                num_to_str(tune.residual_freq)
                            print "  Inverted: ", \
                                tune.inverted
                            mux = usrp.determine_tx_mux_value(dst,
                                    (device._which, 0))
                            dst.set_mux(mux)
                            break
                        else:
                            print "  Failed!"
                if not tune:
                    print "  Failed!"
                    raise SystemExit

# int nunderruns ()

            print "USRP"
            print " Rx halfband: ", dst.has_rx_halfband()
            print " Tx halfband: ", dst.has_tx_halfband()
            print " Nb DDC: ", dst.nddc()
            print " Nb DUC: ", dst.nduc()
#dst._write_9862(0, 14, 224)
            
            print " DAC frequency: %s samples/s" % num_to_str(dst.dac_freq())
            print " Fpga decimation rate: %s -> %s samples/s" % \
                (num_to_str(dst.interp_rate()),
                 num_to_str(dac_freq / dst.interp_rate()))
            print " Nb channels:",
            if hasattr(dst, "nchannels()") :
                print dst.nchannels()
            else:
                print "N/A"
            print " Mux:",
            if hasattr(dst, "mux()") :
                print "0x%x" % dst.mux()
            else :
                print "N/A"
            print " FPGA master clock frequency:",
            if hasattr(dst, "fpga_master_clock_freq()") :
                print "%sHz" % num_to_str(dst.fpga_master_clock_freq())
            else :
                print "N/A"
            print " Converter rate:",
            if hasattr(dst, "converter_rate()") :
                print "%s" % num_to_str(dst.converter_rate())
            else :
                print "N/A"
            print " DAC rate:",
            if hasattr(dst, "dac_rate()") :
                print "%s sample/s" % num_to_str(dst.dac_rate())
            else :
                print "N/A"
            print " Interp rate: %sx" % num_to_str(dst.interp_rate())
            print " DUC frequency 0: %sHz" % num_to_str(dst.tx_freq(0))
            print " DUC frequency 1: %sHz" % num_to_str(dst.tx_freq(1))
            print " Programmable Gain Amplifier 0: %s dB" % \
                num_to_str(dst.pga(0))
            print " Programmable Gain Amplifier 1: %s dB" % \
                num_to_str(dst.pga(2))

        else :
            dst = gr.null_sink(gr.sizeof_gr_complex)
            
# AGC
        if options.agc :
            agc = gr.agc_cc()
            self.fg.connect(tail, agc)
            tail = agc
            
        self.fg.connect(tail, dst)

# oscilloscope
        if options.osc :
            oscPanel = wxPanel(self, -1)
            if (options.encoding == "s") :
                converter = gr.interleaved_short_to_complex()
                self.fg.connect(tail, converter)
                signal = converter
            elif (options.encoding == "f") :
                signal = tail
            else :
                parser.error("Unsupported data encoding for oscilloscope!")

#block = scope_sink_f(fg, parent, title=label, sample_rate=input_rate)
#return (block, block.win)

            oscWin = scopesink.scope_sink_c(self.fg, oscPanel, "Signal",
                    options.samplingrate)
            self.fg.connect(signal, oscWin)
            mainSizer.Add(oscPanel, 1, wxEXPAND)

# spectrometer
        if options.spectrum :
            ymin = 0
            ymax = 160
            fftPanel = wxPanel(self, -1)
            if (options.encoding == "s") :
                converter = gr.interleaved_short_to_complex()
                self.fg.connect(tail, converter)
                signal = converter
            elif (options.encoding == "f") :
                signal = tail
            else :
                parser.error("Unsupported data encoding for oscilloscope!")

            fftWin = fftsink.fft_sink_c(self.fg, fftPanel,
                    title="Spectrum",
                    fft_size=2048,
                    sample_rate=options.samplingrate,
                    y_per_div=(ymax - ymin) / 8,
                    ref_level=ymax,
                    fft_rate=50,
                    average=True
                    )
            self.fg.connect(signal, fftWin)
            mainSizer.Add(fftPanel, 1, wxEXPAND)

# Events
        EVT_MENU(self, ID_ABOUT, self.OnAbout)
        EVT_MENU(self, ID_EXIT,  self.TimeToQuit)
        EVT_SLIDER(self, ID_GAIN_SLIDER0, self.slideEvent)
        EVT_SLIDER(self, ID_FREQ_SLIDER0, self.slideEvent)
        EVT_SLIDER(self, ID_GAIN_SLIDER1, self.slideEvent)
        EVT_SLIDER(self, ID_FREQ_SLIDER1, self.slideEvent)
        EVT_BUTTON(self, ID_START, self.onClick)
        EVT_BUTTON(self, ID_STOP, self.onClick)

#Layout sizers
        self.SetSizer(mainSizer)
        self.SetAutoLayout(1)
        mainSizer.Fit(self)

        self.fg.start()