GNSS SDR custom processing block
We aim at demonstrating how to add custom frontend processing in gnss-sdr.
Copy the files in the subdirectories of src/algorithms/signal_source of
the gnss-sdr source code.
Activate the flag in the configuration file, as shown in UHD-GNSS-SDR-receiver.conf
Compile gnss-sdr and run with gnss-sdr -c UHD-GNSS-SDR-receiver.conf
As opposed to hardware implementations of GNSS receivers, gnss-sdr allows for controlling all steps of the processing chain, from the reception of the radiofrequency signal as a stream of I/Q coefficients, to acquisition, tracking and positioning/timing. Here we are interested in analyzing the properties of the radiofrequency waves reaching the antenna(s). Since an Ettus Research B210 SDR frontend is used, we start from the UHD source provided by GNSS-SDR, add a custom flag for triggering the custom processing block, and implement the block.
Following the GNU Radio architecture, the custom processing block is split between the block connection flowchart (equivalent to top_block with GNU Radio Companion) and the processing itself for accessing the I/Q stream.
In the gnss-sdr architecture of Signal Source -> Signal Conditioning -> Acquisition/Tracking, our aim is to address the initial acquisition step so that the files we are intersted in are located in src/algorithms/signal_source of the gnss-sdr source code. The block connection functions are provided in adapters/uhd_signal_source.cc while the signal processing block is added in libs whose CMakeLists.txt is updated accordingly.
The uhd_signal_source.cc is complemented with an additional flag switched in the configuration file
jmf_ = configuration->property(role + ".jmf", 0);which, in this implementation, overrides the RF_channels_ variable in the source block, allowing for a many-to-one stream architecture.
Upon selecting the custom block processing, the object is created
jmf_block_=gnss_sdr_make_jmf(item_size_, queue_);and connected to the UHD source
for (int i = 0; i < RF_channels_; i++)
{
if (jmf_ != 0)
{
top_block->connect(uhd_source_, i, jmf_block_, i);
printf("UHD -> JMF connect: %d\n",i);fflush(stdout);
}
}Finally, since the signal conditionner will be looking for the right-most source processing block, the custom block is declared as the last signal source block:
gr::basic_block_sptr UhdSignalSource::get_right_block(int RF_channel)
{
if ( jmf_ != 0ULL)
{
return jmf_block_;
}
return uhd_source_;
}which will return the UHD source if the custom block is not selected. The custom block is now inserted between the UHD source and the signal conditionner.
The implementation of the custom block signal processing follows the classical architecture of a GNU Radio block, where a constructor initializes variable and the work function is provided with the I/Q stream to be processed.
int Gnss_JMF::work(int noutput_items,
gr_vector_const_void_star &input_items,
gr_vector_void_star &output_items)
{ int ch = 0;
int t;
unsigned int alignment = volk_get_alignment();
gr_complex* bufin;
gr_complex* bufout;
const gr_complex* in;
gr_complex* carre=(gr_complex*)volk_malloc(sizeof(gr_complex)*CHUNK_SIZE, alignment);
// see https://github.com/gnss-sdr/gnss-sdr/blob/master/src/algorithms/acquisition/gnuradio_blocks/pcps_acquisition_fine_doppler_cc.h for declaration of gr::fft
printf("JMF block: %d items, %d out, %d in\n",noutput_items,output_items.size(),input_items.size());
for (ch = 0; ch < input_items.size(); ch++)
{ // identity: output the same as 1st channel input
in= (const gr_complex*)input_items[ch]; // all channels
volk_32fc_x2_multiply_32fc(carre, in, in, CHUNK_SIZE);
memcpy(output_items[0], carre, noutput_items * input_signature()->sizeof_stream_item(ch));
}
volk_free(carre);
return noutput_items;
}