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mirror of https://github.com/f4exb/sdrangel.git synced 2024-11-23 00:18:37 -05:00
sdrangel/devices/plutosdr/deviceplutosdrbox.cpp
Robin Getz 95edff4985 plutosdr: grab the RF bandwidth range from the device
This will use the RF bandwidth from the device, which is different
between AD9363 and AD9364.

Things are now managed like the device likes - analog low pass bandwidth
is RF (complex) bandwidth, not baseband single I or Q bandwidth.

Signed-off-by: Robin Getz <robin.getz@analog.com>
2019-02-01 16:42:08 -05:00

844 lines
23 KiB
C++

///////////////////////////////////////////////////////////////////////////////////
// Copyright (C) 2017 Edouard Griffiths, F4EXB //
// //
// 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 as version 3 of the License, or //
// //
// 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 V3 for more details. //
// //
// You should have received a copy of the GNU General Public License //
// along with this program. If not, see <http://www.gnu.org/licenses/>. //
///////////////////////////////////////////////////////////////////////////////////
#include <iostream>
#include <cstdio>
#include <cstring>
#include <regex>
#include <iio.h>
#include <boost/lexical_cast.hpp>
#include <QtGlobal>
#include "dsp/dsptypes.h"
#include "dsp/wfir.h"
#include "deviceplutosdr.h"
#include "deviceplutosdrbox.h"
DevicePlutoSDRBox::DevicePlutoSDRBox(const std::string& uri) :
m_devSampleRate(0),
m_LOppmTenths(0),
m_lpfFIREnable(false),
m_lpfFIRBW(100.0f),
m_lpfFIRlog2Decim(0),
m_lpfFIRRxGain(0),
m_lpfFIRTxGain(0),
m_ctx(0),
m_devPhy(0),
m_devRx(0),
m_devTx(0),
m_chnRx0(0),
m_chnTx0i(0),
m_chnTx0q(0),
m_rxBuf(0),
m_txBuf(0),
m_xoInitial(0),
m_temp(0.0f)
{
m_ctx = iio_create_context_from_uri(uri.c_str());
if (m_ctx)
{
m_devPhy = iio_context_find_device(m_ctx, "ad9361-phy");
m_devRx = iio_context_find_device(m_ctx, "cf-ad9361-lpc");
m_devTx = iio_context_find_device(m_ctx, "cf-ad9361-dds-core-lpc");
}
m_valid = m_ctx && m_devPhy && m_devRx && m_devTx;
if (m_valid) {
getXO();
setTracking();
// int nb_channels = iio_device_get_channels_count(m_devRx);
// for (int i = 0; i < nb_channels; i++) {
// iio_channel_disable(iio_device_get_channel(m_devRx, i));
// }
// nb_channels = iio_device_get_channels_count(m_devTx);
// for (int i = 0; i < nb_channels; i++) {
// iio_channel_disable(iio_device_get_channel(m_devTx, i));
// }
}
}
DevicePlutoSDRBox::~DevicePlutoSDRBox()
{
deleteRxBuffer();
deleteTxBuffer();
closeRx();
closeTx();
if (m_ctx) { iio_context_destroy(m_ctx); }
}
bool DevicePlutoSDRBox::probeURI(const std::string& uri)
{
bool retVal;
struct iio_context *ctx;
ctx = iio_create_context_from_uri(uri.c_str());
retVal = (ctx != 0);
if (ctx) {
iio_context_destroy(ctx);
}
return retVal;
}
void DevicePlutoSDRBox::set_params(DeviceType devType,
const std::vector<std::string>& params)
{
iio_device *dev;
switch (devType)
{
case DEVICE_PHY:
dev = m_devPhy;
break;
case DEVICE_RX:
dev = m_devRx;
break;
case DEVICE_TX:
dev = m_devTx;
break;
default:
dev = m_devPhy;
break;
}
for (std::vector<std::string>::const_iterator it = params.begin(); it != params.end(); ++it)
{
struct iio_channel *chn = 0;
const char *attr = 0;
std::size_t pos;
int ret;
int type;
pos = it->find('=');
if (pos == std::string::npos)
{
std::cerr << "DevicePlutoSDRBox::set_params: Misformed line: " << *it << std::endl;
continue;
}
std::string key = it->substr(0, pos);
std::string val = it->substr(pos + 1, std::string::npos);
ret = iio_device_identify_filename(dev, key.c_str(), &chn, &attr);
if (ret)
{
std::cerr << "DevicePlutoSDRBox::set_params: Parameter not recognized: " << key << std::endl;
continue;
}
if (chn) {
ret = iio_channel_attr_write(chn, attr, val.c_str());
type = 0;
} else if (iio_device_find_attr(dev, attr)) {
ret = iio_device_attr_write(dev, attr, val.c_str());
type = 1;
} else {
ret = iio_device_debug_attr_write(dev, attr, val.c_str());
type = 2;
}
if (ret < 0)
{
std::string item;
char errstr[256];
switch (type)
{
case 0:
item = "channel";
break;
case 1:
item = "device";
break;
case 2:
item = "debug";
break;
default:
item = "unknown";
break;
}
iio_strerror(-ret, errstr, 255);
std::cerr << "DevicePlutoSDRBox::set_params: Unable to write " << item << " attribute " << key << "=" << val << ": " << errstr << " (" << ret << ") " << std::endl;
}
else
{
std::cerr << "DevicePlutoSDRBox::set_params: set attribute " << key << "=" << val << ": " << ret << std::endl;
}
}
}
bool DevicePlutoSDRBox::get_param(DeviceType devType, const std::string &param, std::string &value)
{
struct iio_channel *chn = 0;
const char *attr = 0;
char valuestr[256];
int ret;
ssize_t nchars;
iio_device *dev;
switch (devType)
{
case DEVICE_PHY:
dev = m_devPhy;
break;
case DEVICE_RX:
dev = m_devRx;
break;
case DEVICE_TX:
dev = m_devTx;
break;
default:
dev = m_devPhy;
break;
}
ret = iio_device_identify_filename(dev, param.c_str(), &chn, &attr);
if (ret)
{
std::cerr << "DevicePlutoSDRBox::get_param: Parameter not recognized: " << param << std::endl;
return false;
}
if (chn) {
nchars = iio_channel_attr_read(chn, attr, valuestr, 256);
} else if (iio_device_find_attr(dev, attr)) {
nchars = iio_device_attr_read(dev, attr, valuestr, 256);
} else {
nchars = iio_device_debug_attr_read(dev, attr, valuestr, 256);
}
if (nchars < 0)
{
std::cerr << "DevicePlutoSDRBox::get_param: Unable to read attribute " << param << ": " << nchars << std::endl;
return false;
}
else
{
value.assign(valuestr);
return true;
}
}
void DevicePlutoSDRBox::setFilter(const std::string &filterConfigStr)
{
int ret;
ret = iio_device_attr_write_raw(m_devPhy, "filter_fir_config", filterConfigStr.c_str(), filterConfigStr.size());
if (ret < 0)
{
std::cerr << "DevicePlutoSDRBox::set_filter: Unable to set: " << filterConfigStr << ": " << ret << std::endl;
}
}
bool DevicePlutoSDRBox::openRx()
{
if (!m_valid) { return false; }
if (!m_chnRx0) {
m_chnRx0 = iio_device_find_channel(m_devRx, "voltage0", false);
}
if (m_chnRx0) {
iio_channel_enable(m_chnRx0);
const struct iio_data_format *df = iio_channel_get_data_format(m_chnRx0);
qDebug("DevicePlutoSDRBox::openRx: length: %u bits: %u shift: %u signed: %s be: %s with_scale: %s scale: %lf repeat: %u",
df->length,
df->bits,
df->shift,
df->is_signed ? "true" : "false",
df->is_be ? "true" : "false",
df->with_scale? "true" : "false",
df->scale,
df->repeat);
return true;
} else {
std::cerr << "DevicePlutoSDRBox::openRx: failed" << std::endl;
return false;
}
}
bool DevicePlutoSDRBox::openTx()
{
if (!m_valid) { return false; }
if (!m_chnTx0i) {
m_chnTx0i = iio_device_find_channel(m_devTx, "voltage0", true);
}
if (m_chnTx0i) {
iio_channel_enable(m_chnTx0i);
const struct iio_data_format *df = iio_channel_get_data_format(m_chnTx0i);
qDebug("DevicePlutoSDRBox::openTx: channel I: length: %u bits: %u shift: %u signed: %s be: %s with_scale: %s scale: %lf repeat: %u",
df->length,
df->bits,
df->shift,
df->is_signed ? "true" : "false",
df->is_be ? "true" : "false",
df->with_scale? "true" : "false",
df->scale,
df->repeat);
} else {
std::cerr << "DevicePlutoSDRBox::openTx: failed to open I channel" << std::endl;
return false;
}
if (!m_chnTx0q) {
m_chnTx0q = iio_device_find_channel(m_devTx, "voltage1", true);
}
if (m_chnTx0q) {
iio_channel_enable(m_chnTx0q);
const struct iio_data_format *df = iio_channel_get_data_format(m_chnTx0q);
qDebug("DevicePlutoSDRBox::openTx: channel Q: length: %u bits: %u shift: %u signed: %s be: %s with_scale: %s scale: %lf repeat: %u",
df->length,
df->bits,
df->shift,
df->is_signed ? "true" : "false",
df->is_be ? "true" : "false",
df->with_scale? "true" : "false",
df->scale,
df->repeat);
return true;
} else {
std::cerr << "DevicePlutoSDRBox::openTx: failed to open Q channel" << std::endl;
return false;
}
}
void DevicePlutoSDRBox::closeRx()
{
if (m_chnRx0) { iio_channel_disable(m_chnRx0); }
}
void DevicePlutoSDRBox::closeTx()
{
if (m_chnTx0i) { iio_channel_disable(m_chnTx0i); }
if (m_chnTx0q) { iio_channel_disable(m_chnTx0q); }
}
struct iio_buffer *DevicePlutoSDRBox::createRxBuffer(unsigned int size, bool cyclic)
{
if (m_devRx) {
m_rxBuf = iio_device_create_buffer(m_devRx, size, cyclic ? '\1' : '\0');
} else {
m_rxBuf = 0;
}
return m_rxBuf;
}
struct iio_buffer *DevicePlutoSDRBox::createTxBuffer(unsigned int size, bool cyclic)
{
if (m_devTx) {
m_txBuf = iio_device_create_buffer(m_devTx, size, cyclic ? '\1' : '\0');
} else {
m_txBuf = 0;
}
return m_txBuf;
}
void DevicePlutoSDRBox::deleteRxBuffer()
{
if (m_rxBuf) {
iio_buffer_destroy(m_rxBuf);
m_rxBuf = 0;
}
}
void DevicePlutoSDRBox::deleteTxBuffer()
{
if (m_txBuf) {
iio_buffer_destroy(m_txBuf);
m_txBuf = 0;
}
}
ssize_t DevicePlutoSDRBox::getRxSampleSize()
{
if (m_devRx) {
return iio_device_get_sample_size(m_devRx);
} else {
return 0;
}
}
ssize_t DevicePlutoSDRBox::getTxSampleSize()
{
if (m_devTx) {
return iio_device_get_sample_size(m_devTx);
} else {
return 0;
}
}
ssize_t DevicePlutoSDRBox::rxBufferRefill()
{
if (m_rxBuf) {
return iio_buffer_refill(m_rxBuf);
} else {
return 0;
}
}
ssize_t DevicePlutoSDRBox::txBufferPush()
{
if (m_txBuf) {
return iio_buffer_push(m_txBuf);
} else {
return 0;
}
}
std::ptrdiff_t DevicePlutoSDRBox::rxBufferStep()
{
if (m_rxBuf) {
return iio_buffer_step(m_rxBuf);
} else {
return 0;
}
}
char* DevicePlutoSDRBox::rxBufferEnd()
{
if (m_rxBuf) {
return (char *) iio_buffer_end(m_rxBuf);
} else {
return 0;
}
}
char* DevicePlutoSDRBox::rxBufferFirst()
{
if (m_rxBuf) {
return (char *) iio_buffer_first(m_rxBuf, m_chnRx0);
} else {
return 0;
}
}
std::ptrdiff_t DevicePlutoSDRBox::txBufferStep()
{
if (m_txBuf) {
return iio_buffer_step(m_txBuf);
} else {
return 0;
}
}
char* DevicePlutoSDRBox::txBufferEnd()
{
if (m_txBuf) {
return (char *) iio_buffer_end(m_txBuf);
} else {
return 0;
}
}
char* DevicePlutoSDRBox::txBufferFirst()
{
if (m_txBuf) {
return (char *) iio_buffer_first(m_txBuf, m_chnTx0i);
} else {
return 0;
}
}
void DevicePlutoSDRBox::txChannelConvert(int16_t *dst, int16_t *src)
{
if (m_chnTx0i) {
iio_channel_convert_inverse(m_chnTx0i, &dst[0], &src[0]);
}
if (m_chnTx0q) {
iio_channel_convert_inverse(m_chnTx0q, &dst[1], &src[1]);
}
}
bool DevicePlutoSDRBox::getRxSampleRates(SampleRates& sampleRates)
{
std::string srStr;
if (get_param(DEVICE_PHY, "rx_path_rates", srStr)) {
qDebug("DevicePlutoSDRBox::getRxSampleRates: %s", srStr.c_str());
return parseSampleRates(srStr, sampleRates);
} else {
return false;
}
}
bool DevicePlutoSDRBox::getTxSampleRates(SampleRates& sampleRates)
{
std::string srStr;
if (get_param(DEVICE_PHY, "tx_path_rates", srStr)) {
return parseSampleRates(srStr, sampleRates);
} else {
return false;
}
}
bool DevicePlutoSDRBox::parseSampleRates(const std::string& rateStr, SampleRates& sampleRates)
{
// Rx: "BBPLL:983040000 ADC:245760000 R2:122880000 R1:61440000 RF:30720000 RXSAMP:30720000"
// Tx: "BBPLL:983040000 DAC:122880000 T2:122880000 T1:61440000 TF:30720000 TXSAMP:30720000"
std::regex desc_regex("BBPLL:(.+) ..C:(.+) .2:(.+) .1:(.+) .F:(.+) .XSAMP:(.+)");
std::smatch desc_match;
std::regex_search(rateStr, desc_match, desc_regex);
std::string valueStr;
if (desc_match.size() == 7)
{
try
{
sampleRates.m_bbRateHz = boost::lexical_cast<uint32_t>(desc_match[1]);
sampleRates.m_addaConnvRate = boost::lexical_cast<uint32_t>(desc_match[2]);
sampleRates.m_hb3Rate = boost::lexical_cast<uint32_t>(desc_match[3]);
sampleRates.m_hb2Rate = boost::lexical_cast<uint32_t>(desc_match[4]);
sampleRates.m_hb1Rate = boost::lexical_cast<uint32_t>(desc_match[5]);
sampleRates.m_firRate = boost::lexical_cast<uint32_t>(desc_match[6]);
return true;
}
catch (const boost::bad_lexical_cast &e)
{
qWarning("DevicePlutoSDRBox::parseSampleRates: bad conversion to numeric");
return false;
}
}
else
{
return false;
}
}
void DevicePlutoSDRBox::setSampleRate(uint32_t sampleRate)
{
char buff[100];
std::vector<std::string> params;
snprintf(buff, sizeof(buff), "in_voltage_sampling_frequency=%d", sampleRate);
params.push_back(std::string(buff));
snprintf(buff, sizeof(buff), "out_voltage_sampling_frequency=%d", sampleRate);
params.push_back(std::string(buff));
set_params(DEVICE_PHY, params);
m_devSampleRate = sampleRate;
}
/**
* @param sampleRate baseband sample rate (S/s)
* @param log2IntDec FIR interpolation or decimation factor
* @param use Rx or Tx. Applies to the rest of the parameters
* @param bw FIR filter bandwidth at approximately -6 dB cutoff (Hz)
* @param gain FIR filter gain (dB)
*/
void DevicePlutoSDRBox::setFIR(uint32_t sampleRate, uint32_t log2IntDec, DeviceUse use, uint32_t bw, int gain)
{
SampleRates sampleRates;
std::ostringstream ostr;
uint32_t nbTaps;
double normalizedBW;
uint32_t intdec = 1<<(log2IntDec > 2 ? 2 : log2IntDec);
// update gain parameter
if (use == USE_RX) {
m_lpfFIRRxGain = gain;
} else {
m_lpfFIRTxGain = gain;
}
// set a dummy minimal filter first to get the sample rates right
setFIREnable(false); // disable first
formatFIRHeader(ostr, intdec);
formatFIRCoefficients(ostr, 16, 0.5);
setFilter(ostr.str());
ostr.str(""); // reset string stream
setFIREnable(true); // re-enable
setSampleRate(sampleRate); // set to new sample rate
if (!getRxSampleRates(sampleRates)) {
return;
}
setFIREnable(false); // disable again
uint32_t nbGroups = sampleRates.m_addaConnvRate / 16;
nbTaps = nbGroups*8 > 128 ? 128 : nbGroups*8;
nbTaps = intdec == 1 ? (nbTaps > 64 ? 64 : nbTaps) : nbTaps;
normalizedBW = ((float) bw) / sampleRates.m_hb1Rate;
normalizedBW = normalizedBW < DevicePlutoSDR::firBWLowLimitFactor ?
DevicePlutoSDR::firBWLowLimitFactor :
normalizedBW > DevicePlutoSDR::firBWHighLimitFactor ? DevicePlutoSDR::firBWHighLimitFactor : normalizedBW;
qDebug("DevicePlutoSDRBox::setFIR: intdec: %u gain: %d nbTaps: %u BWin: %u BW: %f (%f)",
intdec,
gain,
nbTaps,
bw,
normalizedBW*sampleRates.m_hb1Rate,
normalizedBW);
// set the right filter
formatFIRHeader(ostr, intdec);
formatFIRCoefficients(ostr, nbTaps, normalizedBW);
setFilter(ostr.str());
m_lpfFIRlog2Decim = log2IntDec;
m_lpfFIRBW = bw;
// enable and set sample rate will be done by the caller
}
void DevicePlutoSDRBox::setFIREnable(bool enable)
{
char buff[100];
std::vector<std::string> params;
snprintf(buff, sizeof(buff), "in_out_voltage_filter_fir_en=%d", enable ? 1 : 0);
params.push_back(std::string(buff));
set_params(DEVICE_PHY, params);
m_lpfFIREnable = enable;
}
void DevicePlutoSDRBox::setLOPPMTenths(int ppmTenths)
{
char buff[100];
std::vector<std::string> params;
int64_t newXO = m_xoInitial + ((m_xoInitial*ppmTenths) / 10000000L);
snprintf(buff, sizeof(buff), "xo_correction=%ld", (long int) newXO);
params.push_back(std::string(buff));
set_params(DEVICE_PHY, params);
m_LOppmTenths = ppmTenths;
}
void DevicePlutoSDRBox::formatFIRHeader(std::ostringstream& ostr,uint32_t intdec)
{
ostr << "RX 3 GAIN " << m_lpfFIRRxGain << " DEC " << intdec << std::endl;
ostr << "TX 3 GAIN " << m_lpfFIRTxGain << " INT " << intdec << std::endl;
}
void DevicePlutoSDRBox::formatFIRCoefficients(std::ostringstream& ostr, uint32_t nbTaps, double normalizedBW)
{
double *fcoeffs = new double[nbTaps];
WFIR::BasicFIR(fcoeffs, nbTaps, WFIR::LPF, normalizedBW, 0.0, normalizedBW < 0.2 ? WFIR::wtHAMMING : WFIR::wtBLACKMAN_HARRIS, 0.0);
for (unsigned int i = 0; i < nbTaps; i++) {
ostr << (int16_t) (fcoeffs[i] * 32768.0f) << ", " << (int16_t) (fcoeffs[i] * 32768.0f) << std::endl;
}
delete[] fcoeffs;
}
void DevicePlutoSDRBox::getXO()
{
std::string valueStr;
get_param(DEVICE_PHY, "xo_correction", valueStr);
try
{
m_xoInitial = boost::lexical_cast<int64_t>(valueStr);
qDebug("DevicePlutoSDRBox::getXO: %ld", m_xoInitial);
}
catch (const boost::bad_lexical_cast &e)
{
qWarning("DevicePlutoSDRBox::getXO: cannot get initial XO correction");
}
}
bool DevicePlutoSDRBox::getRxGain(int& gaindB, unsigned int chan)
{
chan = chan % 2;
char buff[30];
snprintf(buff, sizeof(buff), "in_voltage%d_hardwaregain", chan);
std::string gainStr;
get_param(DEVICE_PHY, buff, gainStr);
std::regex gain_regex("(.+)\\.(.+) dB");
std::smatch gain_match;
std::regex_search(gainStr, gain_match, gain_regex);
if (gain_match.size() == 3)
{
try
{
gaindB = boost::lexical_cast<int>(gain_match[1]);
return true;
}
catch (const boost::bad_lexical_cast &e)
{
qWarning("DevicePlutoSDRBox::getRxGain: bad conversion to numeric");
return false;
}
}
else
{
return false;
}
}
bool DevicePlutoSDRBox::getRxRSSI(std::string& rssiStr, unsigned int chan)
{
chan = chan % 2;
char buff[20];
snprintf(buff, sizeof(buff), "in_voltage%d_rssi", chan);
return get_param(DEVICE_PHY, buff, rssiStr);
}
bool DevicePlutoSDRBox::getTxRSSI(std::string& rssiStr, unsigned int chan)
{
chan = chan % 2;
char buff[20];
snprintf(buff, sizeof(buff), "out_voltage%d_rssi", chan);
return get_param(DEVICE_PHY, buff, rssiStr);
}
void DevicePlutoSDRBox::getRxLORange(uint64_t& minLimit, uint64_t& maxLimit)
{
// values are returned in Hz
qint64 stepLimit;
std::string rangeStr;
char buff[50];
snprintf(buff, sizeof(buff), "out_altvoltage0_RX_LO_frequency_available");
if (get_param(DEVICE_PHY, buff, rangeStr))
{
std::istringstream instream(rangeStr.substr(1, rangeStr.size() - 2));
instream >> minLimit >> stepLimit >> maxLimit;
}
else
{
minLimit = DevicePlutoSDR::rxLOLowLimitFreq;
maxLimit = DevicePlutoSDR::rxLOHighLimitFreq;
}
}
void DevicePlutoSDRBox::getTxLORange(uint64_t& minLimit, uint64_t& maxLimit)
{
// values are returned in Hz
qint64 stepLimit;
std::string rangeStr;
char buff[50];
snprintf(buff, sizeof(buff), "out_altvoltage1_TX_LO_frequency_available");
if (get_param(DEVICE_PHY, buff, rangeStr))
{
std::istringstream instream(rangeStr.substr(1, rangeStr.size() - 2));
instream >> minLimit >> stepLimit >> maxLimit;
}
else
{
minLimit = DevicePlutoSDR::txLOLowLimitFreq;
maxLimit = DevicePlutoSDR::txLOHighLimitFreq;
}
}
void DevicePlutoSDRBox::getbbLPRxRange(uint32_t& minLimit, uint32_t& maxLimit)
{
// values are returned in Hz of RF (complex channel) bandwidth
qint32 stepLimit;
std::string rangeStr;
char buff[50];
snprintf(buff, sizeof(buff), "in_voltage_rf_bandwidth_available");
if (get_param(DEVICE_PHY, buff, rangeStr))
{
std::istringstream instream(rangeStr.substr(1, rangeStr.size() - 2));
instream >> minLimit >> stepLimit >> maxLimit;
}
else
{
minLimit = DevicePlutoSDR::bbLPRxLowLimitFreq;
maxLimit = DevicePlutoSDR::bbLPRxHighLimitFreq;
}
}
void DevicePlutoSDRBox::getbbLPTxRange(uint32_t& minLimit, uint32_t& maxLimit)
{
// values are returned in Hz
qint32 stepLimit;
std::string rangeStr;
char buff[50];
snprintf(buff, sizeof(buff), "out_voltage_rf_bandwidth_available");
if (get_param(DEVICE_PHY, buff, rangeStr))
{
std::istringstream instream(rangeStr.substr(1, rangeStr.size() - 2));
instream >> minLimit >> stepLimit >> maxLimit;
}
else
{
minLimit = DevicePlutoSDR::bbLPTxLowLimitFreq;
maxLimit = DevicePlutoSDR::bbLPTxHighLimitFreq;
}
}
bool DevicePlutoSDRBox::fetchTemp()
{
std::string temp_mC_str;
if (get_param(DEVICE_PHY, "in_temp0_input", temp_mC_str))
{
try
{
uint32_t temp_mC = boost::lexical_cast<uint32_t>(temp_mC_str);
m_temp = temp_mC / 1000.0;
return true;
}
catch (const boost::bad_lexical_cast &e)
{
std::cerr << "PlutoSDRDevice::getTemp: bad conversion to numeric" << std::endl;
return false;
}
}
else
{
return false;
}
}
bool DevicePlutoSDRBox::getRateGovernors(std::string& rateGovernors)
{
return get_param(DEVICE_PHY, "trx_rate_governor", rateGovernors);
}
void DevicePlutoSDRBox::setTracking()
{
// in_voltage_quadrature_tracking_en
char buff[100];
std::vector<std::string> params;
snprintf(buff, sizeof(buff), "in_voltage_quadrature_tracking_en=1");
params.push_back(std::string(buff));
snprintf(buff, sizeof(buff), "in_voltage_bb_dc_offset_tracking_en=1");
params.push_back(std::string(buff));
snprintf(buff, sizeof(buff), "in_voltage_rf_dc_offset_tracking_en=1");
params.push_back(std::string(buff));
set_params(DEVICE_PHY, params);
}