// // Copyright 2010-2012 Ettus Research LLC // // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program. If not, see . // #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace po = boost::program_options; /*********************************************************************** * Signal handlers **********************************************************************/ static bool stop_signal_called = false; void sig_int_handler(int){stop_signal_called = true;} /*********************************************************************** * Waveform generators **********************************************************************/ static const size_t wave_table_len = 8192; class wave_table_class{ public: wave_table_class(const std::string &wave_type, const float ampl): _wave_table(wave_table_len) { //compute real wave table with 1.0 amplitude std::vector real_wave_table(wave_table_len); if (wave_type == "CONST"){ for (size_t i = 0; i < wave_table_len; i++) real_wave_table[i] = 1.0; } else if (wave_type == "SQUARE"){ for (size_t i = 0; i < wave_table_len; i++) real_wave_table[i] = (i < wave_table_len/2)? 0.0 : 1.0; } else if (wave_type == "RAMP"){ for (size_t i = 0; i < wave_table_len; i++) real_wave_table[i] = 2.0*i/(wave_table_len-1) - 1.0; } else if (wave_type == "SINE"){ static const double tau = 2*std::acos(-1.0); for (size_t i = 0; i < wave_table_len; i++) real_wave_table[i] = std::sin((tau*i)/wave_table_len); } else throw std::runtime_error("unknown waveform type: " + wave_type); //compute i and q pairs with 90% offset and scale to amplitude for (size_t i = 0; i < wave_table_len; i++){ const size_t q = (i+(3*wave_table_len)/4)%wave_table_len; _wave_table[i] = std::complex(ampl*real_wave_table[i], ampl*real_wave_table[q]); } } inline std::complex operator()(const size_t index) const{ return _wave_table[index % wave_table_len]; } private: std::vector > _wave_table; }; /*********************************************************************** * Main function **********************************************************************/ int UHD_SAFE_MAIN(int argc, char *argv[]){ uhd::set_thread_priority_safe(); //variables to be set by po std::string args, wave_type, ant, subdev, ref, otw; size_t spb; double rate, freq, gain, wave_freq, bw; float ampl; //setup the program options po::options_description desc("Allowed options"); desc.add_options() ("help", "help message") ("args", po::value(&args)->default_value(""), "single uhd device address args") ("spb", po::value(&spb)->default_value(0), "samples per buffer, 0 for default") ("rate", po::value(&rate), "rate of outgoing samples") ("freq", po::value(&freq), "RF center frequency in Hz") ("ampl", po::value(&l)->default_value(float(0.3)), "amplitude of the waveform [0 to 0.7]") ("gain", po::value(&gain), "gain for the RF chain") ("ant", po::value(&ant), "daughterboard antenna selection") ("subdev", po::value(&subdev), "daughterboard subdevice specification") ("bw", po::value(&bw), "daughterboard IF filter bandwidth in Hz") ("wave-type", po::value(&wave_type)->default_value("CONST"), "waveform type (CONST, SQUARE, RAMP, SINE)") ("wave-freq", po::value(&wave_freq)->default_value(0), "waveform frequency in Hz") ("ref", po::value(&ref)->default_value("internal"), "clock reference (internal, external, mimo)") ("otw", po::value(&otw)->default_value("sc16"), "specify the over-the-wire sample mode") ; po::variables_map vm; po::store(po::parse_command_line(argc, argv, desc), vm); po::notify(vm); //print the help message if (vm.count("help")){ std::cout << boost::format("UHD TX Waveforms %s") % desc << std::endl; return ~0; } //create a usrp device std::cout << std::endl; std::cout << boost::format("Creating the usrp device with: %s...") % args << std::endl; uhd::usrp::multi_usrp::sptr usrp = uhd::usrp::multi_usrp::make(args); //Lock mboard clocks usrp->set_clock_source(ref); //always select the subdevice first, the channel mapping affects the other settings if (vm.count("subdev")) usrp->set_tx_subdev_spec(subdev); std::cout << boost::format("Using Device: %s") % usrp->get_pp_string() << std::endl; //set the sample rate if (not vm.count("rate")){ std::cerr << "Please specify the sample rate with --rate" << std::endl; return ~0; } std::cout << boost::format("Setting TX Rate: %f Msps...") % (rate/1e6) << std::endl; usrp->set_tx_rate(rate); std::cout << boost::format("Actual TX Rate: %f Msps...") % (usrp->get_tx_rate()/1e6) << std::endl << std::endl; //set the center frequency if (not vm.count("freq")){ std::cerr << "Please specify the center frequency with --freq" << std::endl; return ~0; } for(size_t chan = 0; chan < usrp->get_tx_num_channels(); chan++) { std::cout << boost::format("Setting TX Freq: %f MHz...") % (freq/1e6) << std::endl; usrp->set_tx_freq(freq, chan); std::cout << boost::format("Actual TX Freq: %f MHz...") % (usrp->get_tx_freq(chan)/1e6) << std::endl << std::endl; //set the rf gain if (vm.count("gain")){ std::cout << boost::format("Setting TX Gain: %f dB...") % gain << std::endl; usrp->set_tx_gain(gain, chan); std::cout << boost::format("Actual TX Gain: %f dB...") % usrp->get_tx_gain(chan) << std::endl << std::endl; } //set the IF filter bandwidth if (vm.count("bw")){ std::cout << boost::format("Setting TX Bandwidth: %f MHz...") % bw << std::endl; usrp->set_tx_bandwidth(bw, chan); std::cout << boost::format("Actual TX Bandwidth: %f MHz...") % usrp->get_tx_bandwidth(chan) << std::endl << std::endl; } //set the antenna if (vm.count("ant")) usrp->set_tx_antenna(ant, chan); } boost::this_thread::sleep(boost::posix_time::seconds(1)); //allow for some setup time //for the const wave, set the wave freq for small samples per period if (wave_freq == 0 and wave_type == "CONST"){ wave_freq = usrp->get_tx_rate()/2; } //error when the waveform is not possible to generate if (std::abs(wave_freq) > usrp->get_tx_rate()/2){ throw std::runtime_error("wave freq out of Nyquist zone"); } if (usrp->get_tx_rate()/std::abs(wave_freq) > wave_table_len/2){ throw std::runtime_error("wave freq too small for table"); } //pre-compute the waveform values const wave_table_class wave_table(wave_type, ampl); const size_t step = boost::math::iround(wave_freq/usrp->get_tx_rate() * wave_table_len); size_t index = 0; //create a transmit streamer //linearly map channels (index0 = channel0, index1 = channel1, ...) uhd::stream_args_t stream_args("fc32", otw); for (size_t chan = 0; chan < usrp->get_tx_num_channels(); chan++) stream_args.channels.push_back(chan); //linear mapping uhd::tx_streamer::sptr tx_stream = usrp->get_tx_stream(stream_args); //allocate a buffer which we re-use for each channel if (spb == 0) spb = tx_stream->get_max_num_samps()*10; std::vector > buff(spb); std::vector *> buffs(usrp->get_tx_num_channels(), &buff.front()); //setup the metadata flags uhd::tx_metadata_t md; md.start_of_burst = true; md.end_of_burst = false; md.has_time_spec = true; md.time_spec = uhd::time_spec_t(0.1); std::cout << boost::format("Setting device timestamp to 0...") << std::endl; usrp->set_time_now(uhd::time_spec_t(0.0)); //Check Ref and LO Lock detect std::vector sensor_names; sensor_names = usrp->get_tx_sensor_names(0); if (std::find(sensor_names.begin(), sensor_names.end(), "lo_locked") != sensor_names.end()) { uhd::sensor_value_t lo_locked = usrp->get_tx_sensor("lo_locked",0); std::cout << boost::format("Checking TX: %s ...") % lo_locked.to_pp_string() << std::endl; UHD_ASSERT_THROW(lo_locked.to_bool()); } sensor_names = usrp->get_mboard_sensor_names(0); if ((ref == "mimo") and (std::find(sensor_names.begin(), sensor_names.end(), "mimo_locked") != sensor_names.end())) { uhd::sensor_value_t mimo_locked = usrp->get_mboard_sensor("mimo_locked",0); std::cout << boost::format("Checking TX: %s ...") % mimo_locked.to_pp_string() << std::endl; UHD_ASSERT_THROW(mimo_locked.to_bool()); } if ((ref == "external") and (std::find(sensor_names.begin(), sensor_names.end(), "ref_locked") != sensor_names.end())) { uhd::sensor_value_t ref_locked = usrp->get_mboard_sensor("ref_locked",0); std::cout << boost::format("Checking TX: %s ...") % ref_locked.to_pp_string() << std::endl; UHD_ASSERT_THROW(ref_locked.to_bool()); } std::signal(SIGINT, &sig_int_handler); std::cout << "Press Ctrl + C to stop streaming..." << std::endl; //send data until the signal handler gets called while(not stop_signal_called){ //fill the buffer with the waveform for (size_t n = 0; n < buff.size(); n++){ buff[n] = wave_table(index += step); } //send the entire contents of the buffer tx_stream->send(buffs, buff.size(), md); md.start_of_burst = false; md.has_time_spec = false; } //send a mini EOB packet md.end_of_burst = true; tx_stream->send("", 0, md); //finished std::cout << std::endl << "Done!" << std::endl << std::endl; return EXIT_SUCCESS; }