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|
//
// Copyright 2010 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 <http://www.gnu.org/licenses/>.
//
// Common IO Pins
#define ANTSW_IO ((1 << 5)|(1 << 15)) // on UNIT_TX, 0 = TX, 1 = RX, on UNIT_RX 0 = main ant, 1 = RX2
#define ADF4350_CE (1 << 3)
#define ADF4350_PDBRF (1 << 2)
#define ADF4350_MUXOUT (1 << 1) // INPUT!!!
#define LOCKDET_MASK (1 << 0) // INPUT!!!
// TX IO Pins
#define TX_PUP_5V (1 << 7) // enables 5.0V power supply
#define TX_PUP_3V (1 << 6) // enables 3.3V supply
#define TXMOD_EN (1 << 4) // on UNIT_TX, 1 enables TX Modulator
// RX IO Pins
#define RX_PUP_5V (1 << 7) // enables 5.0V power supply
#define RX_PUP_3V (1 << 6) // enables 3.3V supply
#define RXBB_PDB (1 << 4) // on UNIT_RX, 1 powers up RX baseband
// RX Attenuator Pins
#define RX_ATTN_SHIFT 8 // lsb of RX Attenuator Control
#define RX_ATTN_MASK (63 << RX_ATTN_SHIFT) // valid bits of RX Attenuator Control
// Mixer functions
#define TX_MIXER_ENB (TXMOD_EN|ADF4350_PDBRF)
#define TX_MIXER_DIS 0
#define RX_MIXER_ENB (RXBB_PDB|ADF4350_PDBRF)
#define RX_MIXER_DIS 0
// Pin functions
#define TX_POWER_IO (TX_PUP_5V|TX_PUP_3V) // high enables power supply
#define TXIO_MASK (TX_POWER_IO|ANTSW_IO|ADF4350_CE|ADF4350_PDBRF|TXMOD_EN)
#define RX_POWER_IO (RX_PUP_5V|RX_PUP_3V) // high enables power supply
#define RXIO_MASK (RX_POWER_IO|ANTSW_IO|ADF4350_CE|ADF4350_PDBRF|RXBB_PDB|RX_ATTN_MASK)
// Power functions
#define TX_POWER_UP (TX_POWER_IO|ADF4350_CE)
#define TX_POWER_DOWN 0
#define RX_POWER_UP (RX_POWER_IO|ADF4350_CE)
#define RX_POWER_DOWN 0
// Antenna constants
#define ANT_TX 0 //the tx line is transmitting
#define ANT_RX ANTSW_IO //the tx line is receiving
#define ANT_TXRX 0 //the rx line is on txrx
#define ANT_RX2 ANTSW_IO //the rx line in on rx2
#define ANT_XX 0 //dont care how the antenna is set
#include "adf4350_regs.hpp"
#include <uhd/types/dict.hpp>
#include <uhd/usrp/subdev_props.hpp>
#include <uhd/types/ranges.hpp>
#include <uhd/utils/assert.hpp>
#include <uhd/utils/static.hpp>
#include <uhd/utils/algorithm.hpp>
#include <uhd/utils/warning.hpp>
#include <uhd/usrp/dboard_base.hpp>
#include <uhd/usrp/dboard_manager.hpp>
#include <boost/assign/list_of.hpp>
#include <boost/format.hpp>
#include <boost/math/special_functions/round.hpp>
using namespace uhd;
using namespace uhd::usrp;
using namespace boost::assign;
/***********************************************************************
* The WBX dboard constants
**********************************************************************/
static const bool wbx_debug = false;
static const freq_range_t wbx_freq_range(68.75e6, 2.2e9);
static const prop_names_t wbx_tx_antennas = list_of("TX/RX");
static const prop_names_t wbx_rx_antennas = list_of("TX/RX")("RX2");
static const uhd::dict<std::string, gain_range_t> wbx_tx_gain_ranges = map_list_of
("PGA0", gain_range_t(0, 25, float(0.05)))
;
static const uhd::dict<std::string, gain_range_t> wbx_rx_gain_ranges = map_list_of
("PGA0", gain_range_t(0, 31.5, float(0.5)))
;
/***********************************************************************
* The WBX dboard
**********************************************************************/
class wbx_xcvr : public xcvr_dboard_base{
public:
wbx_xcvr(ctor_args_t args);
~wbx_xcvr(void);
void rx_get(const wax::obj &key, wax::obj &val);
void rx_set(const wax::obj &key, const wax::obj &val);
void tx_get(const wax::obj &key, wax::obj &val);
void tx_set(const wax::obj &key, const wax::obj &val);
private:
uhd::dict<std::string, float> _tx_gains, _rx_gains;
double _rx_lo_freq, _tx_lo_freq;
std::string _tx_ant, _rx_ant;
void set_rx_lo_freq(double freq);
void set_tx_lo_freq(double freq);
void set_rx_ant(const std::string &ant);
void set_tx_ant(const std::string &ant);
void set_rx_gain(float gain, const std::string &name);
void set_tx_gain(float gain, const std::string &name);
void update_atr(void);
/*!
* Set the LO frequency for the particular dboard unit.
* \param unit which unit rx or tx
* \param target_freq the desired frequency in Hz
* \return the actual frequency in Hz
*/
double set_lo_freq(dboard_iface::unit_t unit, double target_freq);
/*!
* Get the lock detect status of the LO.
* \param unit which unit rx or tx
* \return true for locked
*/
bool get_locked(dboard_iface::unit_t unit){
return (this->get_iface()->read_gpio(unit) & LOCKDET_MASK) != 0;
}
};
/***********************************************************************
* Register the WBX dboard (min freq, max freq, rx div2, tx div2)
**********************************************************************/
static dboard_base::sptr make_wbx(dboard_base::ctor_args_t args){
return dboard_base::sptr(new wbx_xcvr(args));
}
UHD_STATIC_BLOCK(reg_wbx_dboards){
dboard_manager::register_dboard(0x0053, 0x0052, &make_wbx, "WBX");
}
/***********************************************************************
* Structors
**********************************************************************/
wbx_xcvr::wbx_xcvr(ctor_args_t args) : xcvr_dboard_base(args){
//enable the clocks that we need
this->get_iface()->set_clock_enabled(dboard_iface::UNIT_TX, true);
this->get_iface()->set_clock_enabled(dboard_iface::UNIT_RX, true);
//set the gpio directions and atr controls (identically)
this->get_iface()->set_pin_ctrl(dboard_iface::UNIT_TX, TXIO_MASK);
this->get_iface()->set_pin_ctrl(dboard_iface::UNIT_RX, RXIO_MASK);
this->get_iface()->set_gpio_ddr(dboard_iface::UNIT_TX, TXIO_MASK);
this->get_iface()->set_gpio_ddr(dboard_iface::UNIT_RX, RXIO_MASK);
if (wbx_debug) std::cerr << boost::format(
"WBX GPIO Direction: RX: 0x%08x, TX: 0x%08x"
) % RXIO_MASK % TXIO_MASK << std::endl;
//set some default values
set_rx_lo_freq((wbx_freq_range.min + wbx_freq_range.max)/2.0);
set_tx_lo_freq((wbx_freq_range.min + wbx_freq_range.max)/2.0);
set_rx_ant("RX2");
BOOST_FOREACH(const std::string &name, wbx_tx_gain_ranges.keys()){
set_tx_gain(wbx_tx_gain_ranges[name].min, name);
}
BOOST_FOREACH(const std::string &name, wbx_rx_gain_ranges.keys()){
set_rx_gain(wbx_rx_gain_ranges[name].min, name);
}
}
wbx_xcvr::~wbx_xcvr(void){
/* NOP */
}
/***********************************************************************
* Gain Handling
**********************************************************************/
static int rx_pga0_gain_to_iobits(float &gain){
//clip the input
gain = std::clip<float>(gain, wbx_rx_gain_ranges["PGA0"].min, wbx_rx_gain_ranges["PGA0"].max);
//convert to attenuation and update iobits for atr
float attn = wbx_rx_gain_ranges["PGA0"].max - gain;
//calculate the attenuation
int attn_code = int(floor(attn*2));
int iobits = ((~attn_code) << RX_ATTN_SHIFT) & RX_ATTN_MASK;
if (wbx_debug) std::cerr << boost::format(
"WBX Attenuation: %f dB, Code: %d, IO Bits %x, Mask: %x"
) % attn % attn_code % (iobits & RX_ATTN_MASK) % RX_ATTN_MASK << std::endl;
//the actual gain setting
gain = wbx_rx_gain_ranges["PGA0"].max - float(attn_code)/2;
return iobits;
}
static float tx_pga0_gain_to_dac_volts(float &gain){
//clip the input
gain = std::clip<float>(gain, wbx_tx_gain_ranges["PGA0"].min, wbx_tx_gain_ranges["PGA0"].max);
//voltage level constants
static const float max_volts = float(0.5), min_volts = float(1.4);
static const float slope = (max_volts-min_volts)/wbx_tx_gain_ranges["PGA0"].max;
//calculate the voltage for the aux dac
float dac_volts = gain*slope + min_volts;
if (wbx_debug) std::cerr << boost::format(
"WBX TX Gain: %f dB, dac_volts: %f V"
) % gain % dac_volts << std::endl;
//the actual gain setting
gain = (dac_volts - min_volts)/slope;
return dac_volts;
}
void wbx_xcvr::set_tx_gain(float gain, const std::string &name){
assert_has(wbx_tx_gain_ranges.keys(), name, "wbx tx gain name");
if(name == "PGA0"){
float dac_volts = tx_pga0_gain_to_dac_volts(gain);
_tx_gains[name] = gain;
//write the new voltage to the aux dac
this->get_iface()->write_aux_dac(dboard_iface::UNIT_TX, dboard_iface::AUX_DAC_A, dac_volts);
}
else UHD_THROW_INVALID_CODE_PATH();
}
void wbx_xcvr::set_rx_gain(float gain, const std::string &name){
assert_has(wbx_rx_gain_ranges.keys(), name, "wbx rx gain name");
if(name == "PGA0"){
rx_pga0_gain_to_iobits(gain);
_rx_gains[name] = gain;
//write the new gain to atr regs
update_atr();
}
else UHD_THROW_INVALID_CODE_PATH();
}
/***********************************************************************
* Antenna Handling
**********************************************************************/
void wbx_xcvr::update_atr(void){
//calculate atr pins
int pga0_iobits = rx_pga0_gain_to_iobits(_rx_gains["PGA0"]);
//setup the tx atr (this does not change with antenna)
this->get_iface()->set_atr_reg(dboard_iface::UNIT_TX, dboard_iface::ATR_REG_IDLE, TX_POWER_UP | ANT_XX | TX_MIXER_DIS);
this->get_iface()->set_atr_reg(dboard_iface::UNIT_TX, dboard_iface::ATR_REG_RX_ONLY, TX_POWER_UP | ANT_RX | TX_MIXER_DIS);
this->get_iface()->set_atr_reg(dboard_iface::UNIT_TX, dboard_iface::ATR_REG_TX_ONLY, TX_POWER_UP | ANT_TX | TX_MIXER_ENB);
this->get_iface()->set_atr_reg(dboard_iface::UNIT_TX, dboard_iface::ATR_REG_FULL_DUPLEX, TX_POWER_UP | ANT_TX | TX_MIXER_ENB);
//setup the rx atr (this does not change with antenna)
this->get_iface()->set_atr_reg(dboard_iface::UNIT_RX, dboard_iface::ATR_REG_IDLE,
pga0_iobits | RX_POWER_UP | ANT_XX | RX_MIXER_DIS);
this->get_iface()->set_atr_reg(dboard_iface::UNIT_RX, dboard_iface::ATR_REG_TX_ONLY,
pga0_iobits | RX_POWER_UP | ANT_XX | RX_MIXER_DIS);
this->get_iface()->set_atr_reg(dboard_iface::UNIT_RX, dboard_iface::ATR_REG_FULL_DUPLEX,
pga0_iobits | RX_POWER_UP | ANT_RX2| RX_MIXER_ENB);
//set the rx atr regs that change with antenna setting
this->get_iface()->set_atr_reg(dboard_iface::UNIT_RX, dboard_iface::ATR_REG_RX_ONLY,
pga0_iobits | RX_POWER_UP | RX_MIXER_ENB | ((_rx_ant == "TX/RX")? ANT_TXRX : ANT_RX2));
if (wbx_debug) std::cerr << boost::format(
"WBX RXONLY ATR REG: 0x%08x"
) % (pga0_iobits | RX_POWER_UP | RX_MIXER_ENB | ((_rx_ant == "TX/RX")? ANT_TXRX : ANT_RX2)) << std::endl;
}
void wbx_xcvr::set_rx_ant(const std::string &ant){
//validate input
assert_has(wbx_rx_antennas, ant, "wbx rx antenna name");
//shadow the setting
_rx_ant = ant;
//write the new antenna setting to atr regs
update_atr();
}
void wbx_xcvr::set_tx_ant(const std::string &ant){
assert_has(wbx_tx_antennas, ant, "wbx tx antenna name");
//only one antenna option, do nothing
}
/***********************************************************************
* Tuning
**********************************************************************/
void wbx_xcvr::set_rx_lo_freq(double freq){
_rx_lo_freq = set_lo_freq(dboard_iface::UNIT_RX, freq);
}
void wbx_xcvr::set_tx_lo_freq(double freq){
_tx_lo_freq = set_lo_freq(dboard_iface::UNIT_TX, freq);
}
double wbx_xcvr::set_lo_freq(
dboard_iface::unit_t unit,
double target_freq
){
if (wbx_debug) std::cerr << boost::format(
"WBX tune: target frequency %f Mhz"
) % (target_freq/1e6) << std::endl;
//clip the input
target_freq = std::clip(target_freq, wbx_freq_range.min, wbx_freq_range.max);
//map prescaler setting to mininmum integer divider (N) values (pg.18 prescaler)
static const uhd::dict<int, int> prescaler_to_min_int_div = map_list_of
(0,23) //adf4350_regs_t::PRESCALER_4_5
(1,75) //adf4350_regs_t::PRESCALER_8_9
;
//map rf divider select output dividers to enums
static const uhd::dict<int, adf4350_regs_t::rf_divider_select_t> rfdivsel_to_enum = map_list_of
(1, adf4350_regs_t::RF_DIVIDER_SELECT_DIV1)
(2, adf4350_regs_t::RF_DIVIDER_SELECT_DIV2)
(4, adf4350_regs_t::RF_DIVIDER_SELECT_DIV4)
(8, adf4350_regs_t::RF_DIVIDER_SELECT_DIV8)
(16, adf4350_regs_t::RF_DIVIDER_SELECT_DIV16)
;
double actual_freq, pfd_freq;
double ref_freq = this->get_iface()->get_clock_rate(unit);
int R=0, BS=0, N=0, FRAC=0, MOD=0;
int RFdiv = 1;
adf4350_regs_t::reference_divide_by_2_t T = adf4350_regs_t::REFERENCE_DIVIDE_BY_2_DISABLED;
adf4350_regs_t::reference_doubler_t D = adf4350_regs_t::REFERENCE_DOUBLER_DISABLED;
//Reference doubler for 50% duty cycle
// if ref_freq < 12.5MHz enable regs.reference_divide_by_2
if(ref_freq <= 12.5e6) D = adf4350_regs_t::REFERENCE_DOUBLER_ENABLED;
//increase RF divider until acceptable VCO frequency
//start with target_freq*2 because mixer has divide by 2
double vco_freq = target_freq*2;
while (vco_freq < 2.2e9) {
vco_freq *= 2;
RFdiv *= 2;
}
//use 8/9 prescaler for vco_freq > 3 GHz (pg.18 prescaler)
adf4350_regs_t::prescaler_t prescaler = vco_freq > 3e9 ? adf4350_regs_t::PRESCALER_8_9 : adf4350_regs_t::PRESCALER_4_5;
/*
* The goal here is to loop though possible R dividers,
* band select clock dividers, N (int) dividers, and FRAC
* (frac) dividers.
*
* Calculate the N and F dividers for each set of values.
* The loop exists when it meets all of the constraints.
* The resulting loop values are loaded into the registers.
*
* from pg.21
*
* f_pfd = f_ref*(1+D)/(R*(1+T))
* f_vco = (N + (FRAC/MOD))*f_pfd
* N = f_vco/f_pfd - FRAC/MOD = f_vco*((R*(T+1))/(f_ref*(1+D))) - FRAC/MOD
* f_rf = f_vco/RFdiv)
* f_actual = f_rf/2
*/
for(R = 1; R <= 1023; R+=1){
//PFD input frequency = f_ref/R ... ignoring Reference doubler/divide-by-2 (D & T)
pfd_freq = ref_freq*(1+D)/(R*(1+T));
//keep the PFD frequency at or below 25MHz (Loop Filter Bandwidth)
if (pfd_freq > 25e6) continue;
//ignore fractional part of tuning
N = int(std::floor(vco_freq/pfd_freq));
//keep N > minimum int divider requirement
if (N < prescaler_to_min_int_div[prescaler]) continue;
for(BS=1; BS <= 255; BS+=1){
//keep the band select frequency at or below 100KHz
//constraint on band select clock
if (pfd_freq/BS > 100e3) continue;
goto done_loop;
}
} done_loop:
//Fractional-N calculation
MOD = 4095; //max fractional accuracy
FRAC = int((vco_freq/pfd_freq - N)*MOD);
//Reference divide-by-2 for 50% duty cycle
// if R even, move one divide by 2 to to regs.reference_divide_by_2
if(R % 2 == 0){
T = adf4350_regs_t::REFERENCE_DIVIDE_BY_2_ENABLED;
R /= 2;
}
//actual frequency calculation
actual_freq = double((N + (double(FRAC)/double(MOD)))*ref_freq*(1+int(D))/(R*(1+int(T)))/RFdiv/2);
if (wbx_debug) {
std::cerr << boost::format("WBX Intermediates: ref=%0.2f, outdiv=%f, fbdiv=%f") % (ref_freq*(1+int(D))/(R*(1+int(T)))) % double(RFdiv*2) % double(N + double(FRAC)/double(MOD)) << std::endl;
std::cerr << boost::format("WBX tune: R=%d, BS=%d, N=%d, FRAC=%d, MOD=%d, T=%d, D=%d, RFdiv=%d, LD=%d"
) % R % BS % N % FRAC % MOD % T % D % RFdiv % get_locked(unit)<< std::endl
<< boost::format("WBX Frequencies (MHz): REQ=%0.2f, ACT=%0.2f, VCO=%0.2f, PFD=%0.2f, BAND=%0.2f"
) % (target_freq/1e6) % (actual_freq/1e6) % (vco_freq/1e6) % (pfd_freq/1e6) % (pfd_freq/BS/1e6) << std::endl;
}
//load the register values
adf4350_regs_t regs;
regs.frac_12_bit = FRAC;
regs.int_16_bit = N;
regs.mod_12_bit = MOD;
regs.prescaler = prescaler;
regs.r_counter_10_bit = R;
regs.reference_divide_by_2 = T;
regs.reference_doubler = D;
regs.band_select_clock_div = BS;
UHD_ASSERT_THROW(rfdivsel_to_enum.has_key(RFdiv));
regs.rf_divider_select = rfdivsel_to_enum[RFdiv];
//write the registers
//correct power-up sequence to write registers (5, 4, 3, 2, 1, 0)
int addr;
for(addr=5; addr>=0; addr--){
if (wbx_debug) std::cerr << boost::format(
"WBX SPI Reg (0x%02x): 0x%08x"
) % addr % regs.get_reg(addr) << std::endl;
this->get_iface()->write_spi(
unit, spi_config_t::EDGE_RISE,
regs.get_reg(addr), 32
);
}
//return the actual frequency
if (wbx_debug) std::cerr << boost::format(
"WBX tune: actual frequency %f Mhz"
) % (actual_freq/1e6) << std::endl;
return actual_freq;
}
/***********************************************************************
* RX Get and Set
**********************************************************************/
void wbx_xcvr::rx_get(const wax::obj &key_, wax::obj &val){
named_prop_t key = named_prop_t::extract(key_);
//handle the get request conditioned on the key
switch(key.as<subdev_prop_t>()){
case SUBDEV_PROP_NAME:
val = get_rx_id().to_pp_string();
return;
case SUBDEV_PROP_OTHERS:
val = prop_names_t(); //empty
return;
case SUBDEV_PROP_GAIN:
assert_has(_rx_gains.keys(), key.name, "wbx rx gain name");
val = _rx_gains[key.name];
return;
case SUBDEV_PROP_GAIN_RANGE:
assert_has(wbx_rx_gain_ranges.keys(), key.name, "wbx rx gain name");
val = wbx_rx_gain_ranges[key.name];
return;
case SUBDEV_PROP_GAIN_NAMES:
val = prop_names_t(wbx_rx_gain_ranges.keys());
return;
case SUBDEV_PROP_FREQ:
val = _rx_lo_freq;
return;
case SUBDEV_PROP_FREQ_RANGE:
val = wbx_freq_range;
return;
case SUBDEV_PROP_ANTENNA:
val = _rx_ant;
return;
case SUBDEV_PROP_ANTENNA_NAMES:
val = wbx_rx_antennas;
return;
case SUBDEV_PROP_CONNECTION:
val = SUBDEV_CONN_COMPLEX_IQ;
return;
case SUBDEV_PROP_ENABLED:
val = true; //always enabled
return;
case SUBDEV_PROP_USE_LO_OFFSET:
val = false;
return;
case SUBDEV_PROP_LO_LOCKED:
val = this->get_locked(dboard_iface::UNIT_RX);
return;
case SUBDEV_PROP_BANDWIDTH:
val = 2*30.0e6; //20MHz low-pass, we want complex double-sided
return;
default: UHD_THROW_PROP_GET_ERROR();
}
}
void wbx_xcvr::rx_set(const wax::obj &key_, const wax::obj &val){
named_prop_t key = named_prop_t::extract(key_);
//handle the get request conditioned on the key
switch(key.as<subdev_prop_t>()){
case SUBDEV_PROP_FREQ:
this->set_rx_lo_freq(val.as<double>());
return;
case SUBDEV_PROP_GAIN:
this->set_rx_gain(val.as<float>(), key.name);
return;
case SUBDEV_PROP_ANTENNA:
this->set_rx_ant(val.as<std::string>());
return;
case SUBDEV_PROP_ENABLED:
return; //always enabled
case SUBDEV_PROP_BANDWIDTH:
uhd::print_warning(
str(boost::format("WBX: No tunable bandwidth, fixed filtered to 40MHz"))
);
return;
default: UHD_THROW_PROP_SET_ERROR();
}
}
/***********************************************************************
* TX Get and Set
**********************************************************************/
void wbx_xcvr::tx_get(const wax::obj &key_, wax::obj &val){
named_prop_t key = named_prop_t::extract(key_);
//handle the get request conditioned on the key
switch(key.as<subdev_prop_t>()){
case SUBDEV_PROP_NAME:
val = get_tx_id().to_pp_string();
return;
case SUBDEV_PROP_OTHERS:
val = prop_names_t(); //empty
return;
case SUBDEV_PROP_GAIN:
assert_has(_tx_gains.keys(), key.name, "wbx tx gain name");
val = _tx_gains[key.name];
return;
case SUBDEV_PROP_GAIN_RANGE:
assert_has(wbx_tx_gain_ranges.keys(), key.name, "wbx tx gain name");
val = wbx_tx_gain_ranges[key.name];
return;
case SUBDEV_PROP_GAIN_NAMES:
val = prop_names_t(wbx_tx_gain_ranges.keys());
return;
case SUBDEV_PROP_FREQ:
val = _tx_lo_freq;
return;
case SUBDEV_PROP_FREQ_RANGE:
val = wbx_freq_range;
return;
case SUBDEV_PROP_ANTENNA:
val = std::string("TX/RX");
return;
case SUBDEV_PROP_ANTENNA_NAMES:
val = wbx_tx_antennas;
return;
case SUBDEV_PROP_CONNECTION:
val = SUBDEV_CONN_COMPLEX_IQ;
return;
case SUBDEV_PROP_ENABLED:
val = true; //always enabled
return;
case SUBDEV_PROP_USE_LO_OFFSET:
val = false;
return;
case SUBDEV_PROP_LO_LOCKED:
val = this->get_locked(dboard_iface::UNIT_TX);
return;
case SUBDEV_PROP_BANDWIDTH:
val = 2*30.0e6; //20MHz low-pass, we want complex double-sided
return;
default: UHD_THROW_PROP_GET_ERROR();
}
}
void wbx_xcvr::tx_set(const wax::obj &key_, const wax::obj &val){
named_prop_t key = named_prop_t::extract(key_);
//handle the get request conditioned on the key
switch(key.as<subdev_prop_t>()){
case SUBDEV_PROP_FREQ:
this->set_tx_lo_freq(val.as<double>());
return;
case SUBDEV_PROP_GAIN:
this->set_tx_gain(val.as<float>(), key.name);
return;
case SUBDEV_PROP_ANTENNA:
this->set_tx_ant(val.as<std::string>());
return;
case SUBDEV_PROP_ENABLED:
return; //always enabled
case SUBDEV_PROP_BANDWIDTH:
uhd::print_warning(
str(boost::format("WBX: No tunable bandwidth, fixed filtered to 40MHz"))
);
return;
default: UHD_THROW_PROP_SET_ERROR();
}
}
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