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//
// Copyright 2016 Ettus Research LLC
// Copyright 2018 Ettus Research, a National Instruments Company
//
// SPDX-License-Identifier: GPL-3.0-or-later
//
// FFT conversion
#include "ascii_art_dft.hpp"
#include <uhd/usrp/multi_usrp.hpp>
#include <uhd/utils/safe_main.hpp>
#include <uhd/utils/thread.hpp>
#include <boost/program_options.hpp>
#include <boost/thread.hpp>
#include <boost/thread/thread_time.hpp>
#include <fstream>
/*
* This example shows how to implement fast frequency hopping using an X-Series
* motherboard and a TwinRX daughterboard.
*
* The TwinRX daughterboard is different than previous daughterboards in that it has two
* RX channels, each with a set of Local Oscillators (LOs). Either channel can be
* configured to use either LO set, allowing for the two channels to share an LO source.
*
* The TwinRX can be used like any other daughterboard, as the multi_usrp::set_rx_freq()
* function will automatically calculate and set the two LO frequencies as needed.
* However, this adds to the overall tuning time. If the LO frequencies are manually set
* with the multi_usrp::set_rx_lo_freq() function, the TwinRX will will not perform the
* calculation itself, resulting in a faster tune time. This example shows how to take
* advantage of this as follows:
*
* 1. Tune across the given frequency range, storing the calculated LO frequencies along
* the way.
* 2. Use timed commands to tell the TwinRX to receive bursts of samples at given
* intervals.
* 3. For each frequency, tune the LOs for the inactive channel for the next frequency and
* receive at the current frequency.
* 4. If applicable, send the next timed command for streaming.
*/
namespace pt = boost::posix_time;
namespace po = boost::program_options;
typedef std::vector<std::complex<float>> recv_buff_t;
typedef std::vector<recv_buff_t> recv_buffs_t;
// Global objects
static uhd::usrp::multi_usrp::sptr usrp;
static uhd::rx_streamer::sptr rx_stream;
static recv_buffs_t buffs;
static size_t recv_spb, spb;
static std::vector<double> rf_freqs;
static uhd::stream_cmd_t stream_cmd(uhd::stream_cmd_t::STREAM_MODE_NUM_SAMPS_AND_DONE);
double receive_interval;
// Define the active channel (connected to antenna) and the unused channel
size_t ACTIVE_CHAN = 0;
size_t UNUSED_CHAN = 1;
const int X300_COMMAND_FIFO_DEPTH = 16;
// This is a helper function for receiving samples from the USRP
static void twinrx_recv(recv_buff_t& buffer)
{
size_t num_acc_samps = 0;
uhd::rx_metadata_t md;
// Repeatedly retrieve samples until the entire acquisition is received
while (num_acc_samps < spb) {
size_t num_to_recv = std::min<size_t>(recv_spb, (spb - num_acc_samps));
// recv call will block until samples are ready or the call times out
size_t num_recvd =
rx_stream->recv(&buffer[num_acc_samps], num_to_recv, md, receive_interval);
if (md.error_code != uhd::rx_metadata_t::ERROR_CODE_NONE) {
std::cout << md.strerror() << std::endl;
break;
}
num_acc_samps += num_recvd;
}
}
// Function to write the acquisition FFT to a binary file
static void write_fft_to_file(const std::string& fft_path)
{
std::cout << "Calculating FFTs (this may take a while)... " << std::flush;
std::ofstream ofile(fft_path.c_str(), std::ios::binary);
BOOST_FOREACH (const recv_buff_t& buff, buffs) {
std::vector<float> fft = ascii_art_dft::log_pwr_dft(&buff.front(), buff.size());
ofile.write((char*)&fft[0], (sizeof(float) * fft.size()));
}
ofile.close();
std::cout << "done." << std::endl;
}
int UHD_SAFE_MAIN(int argc, char* argv[])
{
uhd::set_thread_priority_safe();
// Program options
std::string args, fft_path, subdev, ant;
double rate, gain;
double start_freq, end_freq;
// Set up the program options
po::options_description desc("Allowed options");
// clang-format off
desc.add_options()
("help", "Print this help message")
("args", po::value<std::string>(&args)->default_value(""), "UHD device args")
("subdev", po::value<std::string>(&subdev)->default_value("A:0 A:1"), "Subdevice specification")
("ant", po::value<std::string>(&ant)->default_value("RX1"), "RX Antenna")
("start-freq", po::value<double>(&start_freq), "Start frequency (defaults to lowest valid frequency)")
("end-freq", po::value<double>(&end_freq), "End frequency (defaults to highest valid frequency)")
("receive-interval", po::value<double>(&receive_interval)->default_value(5e-3), "Interval between scheduled receives")
("rate", po::value<double>(&rate)->default_value(1e6), "Incoming sample rate")
("gain", po::value<double>(&gain)->default_value(60), "RX gain")
("spb", po::value<size_t>(&spb)->default_value(1024), "Samples per buffer")
("fft-path", po::value<std::string>(&fft_path), "Output an FFT to this file (optional)")
("repeat", "repeat sweep until Ctrl-C is pressed")
;
// clang-format on
po::variables_map vm;
po::store(po::parse_command_line(argc, argv, desc), vm);
po::notify(vm);
if (vm.count("help")) {
std::cout << "TwinRX Frequency Hopping Example - " << desc << std::endl;
return EXIT_SUCCESS;
}
// Create a USRP device
std::cout << boost::format("\nCreating the USRP device with args: \"%s\"...\n")
% args;
usrp = uhd::usrp::multi_usrp::make(args);
// Make sure the USRP is an X3xx with a TwinRX
uhd::dict<std::string, std::string> info = usrp->get_usrp_rx_info();
if (info.get("mboard_id").find("X3") == std::string::npos) {
throw uhd::runtime_error(
"This example can only be used with an X-Series motherboard.");
}
if (info.get("rx_id").find("TwinRX") == std::string::npos) {
throw uhd::runtime_error(
"This example can only be used with a TwinRX daughterboard.");
}
// Validate frequency range
uhd::freq_range_t rx_freq_range = usrp->get_rx_freq_range();
if (!vm.count("start-freq")) {
start_freq = rx_freq_range.start();
}
if (!vm.count("end-freq")) {
end_freq = rx_freq_range.stop();
}
if (start_freq < rx_freq_range.start() or end_freq > rx_freq_range.stop()) {
throw uhd::runtime_error(
(boost::format("Start and stop frequencies must be between %d and %d MHz")
% (rx_freq_range.start() / 1e6) % (rx_freq_range.stop() / 1e6))
.str());
}
if (start_freq > end_freq) {
throw uhd::runtime_error("Start frequency must be less than end frequency.");
}
if ((end_freq - start_freq) > 0 and (end_freq - start_freq) < rate) {
throw uhd::runtime_error("The sample rate must be less than the range between "
"the start and end frequencies.");
}
// Set TwinRX settings
usrp->set_rx_subdev_spec(subdev);
// Set the unused channel to not use any LOs. This allows the active channel to
// control them.
usrp->set_rx_lo_source("disabled", uhd::usrp::multi_usrp::ALL_LOS, UNUSED_CHAN);
// Set user settings
std::cout << boost::format("Setting antenna to: %s\n") % ant;
usrp->set_rx_antenna(ant, ACTIVE_CHAN);
std::cout << boost::format("Actual antenna: %s\n")
% usrp->get_rx_antenna(ACTIVE_CHAN);
std::cout << boost::format("Setting sample rate to: %d\n") % rate;
usrp->set_rx_rate(rate);
std::cout << boost::format("Actual sample rate: %d\n") % usrp->get_rx_rate();
std::cout << boost::format("Setting gain to: %d\n") % gain;
usrp->set_rx_gain(gain);
std::cout << boost::format("Actual gain: %d\n") % usrp->get_rx_gain();
// Get an rx_streamer from the device
uhd::stream_args_t stream_args("fc32", "sc16");
stream_args.channels.push_back(0);
rx_stream = usrp->get_rx_stream(stream_args);
recv_spb = rx_stream->get_max_num_samps();
// Calculate the frequency hops
for (double rx_freq = start_freq; rx_freq <= end_freq; rx_freq += rate) {
rf_freqs.push_back(rx_freq);
}
std::cout << boost::format("Total Hops: %d\n") % rf_freqs.size();
// Set up buffers
buffs = recv_buffs_t(rf_freqs.size(), recv_buff_t(spb));
// Tune the active channel to the first frequency and reset the USRP's time
usrp->set_rx_freq(rf_freqs[0], ACTIVE_CHAN);
usrp->set_time_now(uhd::time_spec_t(0.0));
// Configure the stream command which will be issued to acquire samples at each
// frequency
stream_cmd.num_samps = spb;
stream_cmd.stream_now = false;
stream_cmd.time_spec = uhd::time_spec_t(0.0);
// Stream commands will be scheduled at regular intervals
uhd::time_spec_t receive_interval_ts = uhd::time_spec_t(receive_interval);
// Issue stream commands to fill the command queue on the FPGA
size_t num_initial_cmds = std::min<size_t>(X300_COMMAND_FIFO_DEPTH, rf_freqs.size());
size_t num_issued_commands;
for (num_issued_commands = 0; num_issued_commands < num_initial_cmds;
num_issued_commands++) {
stream_cmd.time_spec += receive_interval_ts;
rx_stream->issue_stream_cmd(stream_cmd);
}
// Hop frequencies and acquire bursts of samples at each until done sweeping
while (1) {
std::cout << "Scanning..." << std::endl;
auto start_time = boost::get_system_time();
for (size_t i = 0; i < rf_freqs.size(); i++) {
// Swap the mapping of synthesizers by setting the LO source
// The unused channel will always
std::string lo_src = (i % 2) ? "companion" : "internal";
usrp->set_rx_lo_source(lo_src, uhd::usrp::multi_usrp::ALL_LOS, ACTIVE_CHAN);
// Preconfigure the next frequency
usrp->set_rx_freq(rf_freqs[(i + 1) % rf_freqs.size()], UNUSED_CHAN);
// Program the current frequency
// This frequency was already pre-programmed in the previous iteration so the
// local oscillators are already tuned. This call will only configure
// front-end filter, amplifiers, etc
usrp->set_rx_freq(rf_freqs[i], ACTIVE_CHAN);
// Receive one burst of samples
twinrx_recv(buffs[i]);
// Schedule another acquisition if necessary
if (vm.count("repeat") or num_issued_commands < rf_freqs.size()) {
stream_cmd.time_spec += receive_interval_ts;
rx_stream->issue_stream_cmd(stream_cmd);
num_issued_commands++;
}
}
auto end_time = boost::get_system_time();
std::cout << boost::format("Sweep done in %d milliseconds.\n")
% ((end_time - start_time).total_milliseconds() * 1000);
// Optionally convert received samples to FFT and write to file
if (vm.count("fft-path")) {
write_fft_to_file(fft_path);
}
if (!vm.count("repeat")) {
break;
}
}
std::cout << "Done!" << std::endl;
usrp.reset();
return EXIT_SUCCESS;
}
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