// // Copyright 2014-15 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 . // /*********************************************************************** * Included Files and Libraries **********************************************************************/ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "max287x.hpp" using namespace uhd; using namespace uhd::usrp; /*********************************************************************** * UBX Data Structures **********************************************************************/ enum ubx_gpio_field_id_t { SPI_ADDR, TX_EN_N, RX_EN_N, RX_ANT, TX_LO_LOCKED, RX_LO_LOCKED, CPLD_RST_N, TX_GAIN, RX_GAIN, RXLO1_SYNC, RXLO2_SYNC, TXLO1_SYNC, TXLO2_SYNC }; enum ubx_cpld_field_id_t { TXHB_SEL = 0, TXLB_SEL = 1, TXLO1_FSEL1 = 2, TXLO1_FSEL2 = 3, TXLO1_FSEL3 = 4, RXHB_SEL = 5, RXLB_SEL = 6, RXLO1_FSEL1 = 7, RXLO1_FSEL2 = 8, RXLO1_FSEL3 = 9, SEL_LNA1 = 10, SEL_LNA2 = 11, TXLO1_FORCEON = 12, TXLO2_FORCEON = 13, TXMOD_FORCEON = 14, TXMIXER_FORCEON = 15, TXDRV_FORCEON = 16, RXLO1_FORCEON = 17, RXLO2_FORCEON = 18, RXDEMOD_FORCEON = 19, RXMIXER_FORCEON = 20, RXDRV_FORCEON = 21, RXAMP_FORCEON = 22, RXLNA1_FORCEON = 23, RXLNA2_FORCEON = 24 }; struct ubx_gpio_field_info_t { ubx_gpio_field_id_t id; dboard_iface::unit_t unit; uint32_t offset; uint32_t mask; uint32_t width; enum {OUTPUT,INPUT} direction; bool is_atr_controlled; uint32_t atr_idle; uint32_t atr_tx; uint32_t atr_rx; uint32_t atr_full_duplex; }; struct ubx_gpio_reg_t { bool dirty; uint32_t value; uint32_t mask; uint32_t ddr; uint32_t atr_mask; uint32_t atr_idle; uint32_t atr_tx; uint32_t atr_rx; uint32_t atr_full_duplex; }; struct ubx_cpld_reg_t { void set_field(ubx_cpld_field_id_t field, uint32_t val) { UHD_ASSERT_THROW(val == (val & 0x1)); if (val) value |= uint32_t(1) << field; else value &= ~(uint32_t(1) << field); } uint32_t value; }; enum spi_dest_t { TXLO1 = 0x0, // 0x00: TXLO1, the main TXLO from 400MHz to 6000MHz TXLO2 = 0x1, // 0x01: TXLO2, the low band mixer TXLO 10MHz to 400MHz RXLO1 = 0x2, // 0x02: RXLO1, the main RXLO from 400MHz to 6000MHz RXLO2 = 0x3, // 0x03: RXLO2, the low band mixer RXLO 10MHz to 400MHz CPLD = 0x4 // 0x04: CPLD SPI Register }; /*********************************************************************** * UBX Constants **********************************************************************/ #define fMHz (1000000.0) static const dboard_id_t UBX_PROTO_V3_TX_ID(0x73); static const dboard_id_t UBX_PROTO_V3_RX_ID(0x74); static const dboard_id_t UBX_PROTO_V4_TX_ID(0x75); static const dboard_id_t UBX_PROTO_V4_RX_ID(0x76); static const dboard_id_t UBX_V1_40MHZ_TX_ID(0x77); static const dboard_id_t UBX_V1_40MHZ_RX_ID(0x78); static const dboard_id_t UBX_V1_160MHZ_TX_ID(0x79); static const dboard_id_t UBX_V1_160MHZ_RX_ID(0x7A); static const dboard_id_t UBX_V2_40MHZ_TX_ID(0x7B); static const dboard_id_t UBX_V2_40MHZ_RX_ID(0x7C); static const dboard_id_t UBX_V2_160MHZ_TX_ID(0x7D); static const dboard_id_t UBX_V2_160MHZ_RX_ID(0x7E); static const dboard_id_t UBX_LP_160MHZ_TX_ID(0x0200); static const dboard_id_t UBX_LP_160MHZ_RX_ID(0x0201); static const freq_range_t ubx_freq_range(10e6, 6.0e9); static const gain_range_t ubx_tx_gain_range(0, 31.5, double(0.5)); static const gain_range_t ubx_rx_gain_range(0, 31.5, double(0.5)); static const std::vector ubx_pgas = boost::assign::list_of("PGA-TX")("PGA-RX"); static const std::vector ubx_plls = boost::assign::list_of("TXLO")("RXLO"); static const std::vector ubx_tx_antennas = boost::assign::list_of("TX/RX")("CAL"); static const std::vector ubx_rx_antennas = boost::assign::list_of("TX/RX")("RX2")("CAL"); static const std::vector ubx_power_modes = boost::assign::list_of("performance")("powersave"); static const std::vector ubx_xcvr_modes = boost::assign::list_of("FDX")("TX")("TX/RX")("RX"); static const ubx_gpio_field_info_t ubx_proto_gpio_info[] = { //Field Unit Offset Mask Width Direction ATR IDLE,TX,RX,FDX {SPI_ADDR, dboard_iface::UNIT_TX, 0, 0x7, 3, ubx_gpio_field_info_t::INPUT, false, 0, 0, 0, 0}, {TX_EN_N, dboard_iface::UNIT_TX, 3, 0x1<<3, 1, ubx_gpio_field_info_t::INPUT, true, 1, 0, 1, 0}, {RX_EN_N, dboard_iface::UNIT_TX, 4, 0x1<<4, 1, ubx_gpio_field_info_t::INPUT, true, 1, 1, 0, 0}, {RX_ANT, dboard_iface::UNIT_TX, 5, 0x1<<5, 1, ubx_gpio_field_info_t::INPUT, false, 0, 0, 0, 0}, {TX_LO_LOCKED, dboard_iface::UNIT_TX, 6, 0x1<<6, 1, ubx_gpio_field_info_t::OUTPUT, false, 0, 0, 0, 0}, {RX_LO_LOCKED, dboard_iface::UNIT_TX, 7, 0x1<<7, 1, ubx_gpio_field_info_t::OUTPUT, false, 0, 0, 0, 0}, {CPLD_RST_N, dboard_iface::UNIT_TX, 9, 0x1<<9, 1, ubx_gpio_field_info_t::INPUT, false, 0, 0, 0, 0}, {TX_GAIN, dboard_iface::UNIT_TX, 10, 0x3F<<10, 10, ubx_gpio_field_info_t::INPUT, false, 0, 0, 0, 0}, {RX_GAIN, dboard_iface::UNIT_RX, 10, 0x3F<<10, 10, ubx_gpio_field_info_t::INPUT, false, 0, 0, 0, 0} }; static const ubx_gpio_field_info_t ubx_v1_gpio_info[] = { //Field Unit Offset Mask Width Direction ATR IDLE,TX,RX,FDX {SPI_ADDR, dboard_iface::UNIT_TX, 0, 0x7, 3, ubx_gpio_field_info_t::INPUT, false, 0, 0, 0, 0}, {CPLD_RST_N, dboard_iface::UNIT_TX, 3, 0x1<<3, 1, ubx_gpio_field_info_t::INPUT, false, 0, 0, 0, 0}, {RX_ANT, dboard_iface::UNIT_TX, 4, 0x1<<4, 1, ubx_gpio_field_info_t::INPUT, false, 0, 0, 0, 0}, {TX_EN_N, dboard_iface::UNIT_TX, 5, 0x1<<5, 1, ubx_gpio_field_info_t::INPUT, true, 1, 0, 1, 0}, {RX_EN_N, dboard_iface::UNIT_TX, 6, 0x1<<6, 1, ubx_gpio_field_info_t::INPUT, true, 1, 1, 0, 0}, {TXLO1_SYNC, dboard_iface::UNIT_TX, 7, 0x1<<7, 1, ubx_gpio_field_info_t::INPUT, true, 0, 0, 0, 0}, {TXLO2_SYNC, dboard_iface::UNIT_TX, 9, 0x1<<9, 1, ubx_gpio_field_info_t::INPUT, true, 0, 0, 0, 0}, {TX_GAIN, dboard_iface::UNIT_TX, 10, 0x3F<<10, 10, ubx_gpio_field_info_t::INPUT, false, 0, 0, 0, 0}, {RX_LO_LOCKED, dboard_iface::UNIT_RX, 0, 0x1, 1, ubx_gpio_field_info_t::OUTPUT, false, 0, 0, 0, 0}, {TX_LO_LOCKED, dboard_iface::UNIT_RX, 1, 0x1<<1, 1, ubx_gpio_field_info_t::OUTPUT, false, 0, 0, 0, 0}, {RXLO1_SYNC, dboard_iface::UNIT_RX, 5, 0x1<<5, 1, ubx_gpio_field_info_t::INPUT, true, 0, 0, 0, 0}, {RXLO2_SYNC, dboard_iface::UNIT_RX, 7, 0x1<<7, 1, ubx_gpio_field_info_t::INPUT, true, 0, 0, 0, 0}, {RX_GAIN, dboard_iface::UNIT_RX, 10, 0x3F<<10, 10, ubx_gpio_field_info_t::INPUT, false, 0, 0, 0, 0} }; /*********************************************************************** * Macros for routing and writing SPI registers **********************************************************************/ #define ROUTE_SPI(iface, dest) \ set_gpio_field(SPI_ADDR, dest); \ write_gpio(); #define WRITE_SPI(iface, val) \ iface->write_spi(dboard_iface::UNIT_TX, spi_config_t::EDGE_RISE, val, 32); /*********************************************************************** * UBX Class Definition **********************************************************************/ class ubx_xcvr : public xcvr_dboard_base { public: ubx_xcvr(ctor_args_t args) : xcvr_dboard_base(args) { double bw = 40e6; double pfd_freq_max = 25e6; //////////////////////////////////////////////////////////////////// // Setup GPIO hardware //////////////////////////////////////////////////////////////////// _iface = get_iface(); dboard_id_t rx_id = get_rx_id(); dboard_id_t tx_id = get_tx_id(); if (rx_id == UBX_PROTO_V3_RX_ID and tx_id == UBX_PROTO_V3_TX_ID) { _rev = 0; } else if (rx_id == UBX_PROTO_V4_RX_ID and tx_id == UBX_PROTO_V4_TX_ID) { _rev = 1; } else if (rx_id == UBX_V1_40MHZ_RX_ID and tx_id == UBX_V1_40MHZ_TX_ID) { _rev = 1; } else if (rx_id == UBX_V2_40MHZ_RX_ID and tx_id == UBX_V2_40MHZ_TX_ID) { _rev = 2; } else if (rx_id == UBX_V1_160MHZ_RX_ID and tx_id == UBX_V1_160MHZ_TX_ID) { bw = 160e6; _rev = 1; } else if (rx_id == UBX_V2_160MHZ_RX_ID and tx_id == UBX_V2_160MHZ_TX_ID) { bw = 160e6; _rev = 2; } else if (rx_id == UBX_LP_160MHZ_RX_ID and tx_id == UBX_LP_160MHZ_TX_ID) { // The LP version behaves and looks like a regular UBX-160 v2 bw = 160e6; _rev = 2; } else { UHD_THROW_INVALID_CODE_PATH(); } switch(_rev) { case 0: for (size_t i = 0; i < sizeof(ubx_proto_gpio_info) / sizeof(ubx_gpio_field_info_t); i++) _gpio_map[ubx_proto_gpio_info[i].id] = ubx_proto_gpio_info[i]; pfd_freq_max = 25e6; break; case 1: case 2: for (size_t i = 0; i < sizeof(ubx_v1_gpio_info) / sizeof(ubx_gpio_field_info_t); i++) _gpio_map[ubx_v1_gpio_info[i].id] = ubx_v1_gpio_info[i]; pfd_freq_max = 50e6; break; } // Initialize GPIO registers memset(&_tx_gpio_reg,0,sizeof(ubx_gpio_reg_t)); memset(&_rx_gpio_reg,0,sizeof(ubx_gpio_reg_t)); for (std::map::iterator entry = _gpio_map.begin(); entry != _gpio_map.end(); entry++) { ubx_gpio_field_info_t info = entry->second; ubx_gpio_reg_t *reg = (info.unit == dboard_iface::UNIT_TX ? &_tx_gpio_reg : &_rx_gpio_reg); if (info.direction == ubx_gpio_field_info_t::INPUT) reg->ddr |= info.mask; if (info.is_atr_controlled) { reg->atr_mask |= info.mask; reg->atr_idle |= (info.atr_idle << info.offset) & info.mask; reg->atr_tx |= (info.atr_tx << info.offset) & info.mask; reg->atr_rx |= (info.atr_rx << info.offset) & info.mask; reg->atr_full_duplex |= (info.atr_full_duplex << info.offset) & info.mask; } } // Enable the reference clocks that we need _rx_target_pfd_freq = pfd_freq_max; _tx_target_pfd_freq = pfd_freq_max; if (_rev >= 1) { // set dboard clock rates to as close to the max PFD freq as possible if (_iface->get_clock_rate(dboard_iface::UNIT_RX) > pfd_freq_max) { std::vector rates = _iface->get_clock_rates(dboard_iface::UNIT_RX); double highest_rate = 0.0; BOOST_FOREACH(double rate, rates) { if (rate <= pfd_freq_max and rate > highest_rate) highest_rate = rate; } _iface->set_clock_rate(dboard_iface::UNIT_RX, highest_rate); _rx_target_pfd_freq = highest_rate; } if (_iface->get_clock_rate(dboard_iface::UNIT_TX) > pfd_freq_max) { std::vector rates = _iface->get_clock_rates(dboard_iface::UNIT_TX); double highest_rate = 0.0; BOOST_FOREACH(double rate, rates) { if (rate <= pfd_freq_max and rate > highest_rate) highest_rate = rate; } _iface->set_clock_rate(dboard_iface::UNIT_TX, highest_rate); _tx_target_pfd_freq = highest_rate; } } _iface->set_clock_enabled(dboard_iface::UNIT_TX, true); _iface->set_clock_enabled(dboard_iface::UNIT_RX, true); // Set direction of GPIO pins (1 is input to UBX, 0 is output) _iface->set_gpio_ddr(dboard_iface::UNIT_TX, _tx_gpio_reg.ddr); _iface->set_gpio_ddr(dboard_iface::UNIT_RX, _rx_gpio_reg.ddr); // Set default GPIO values set_gpio_field(TX_GAIN, 0); set_gpio_field(CPLD_RST_N, 0); set_gpio_field(RX_ANT, 1); set_gpio_field(TX_EN_N, 1); set_gpio_field(RX_EN_N, 1); set_gpio_field(SPI_ADDR, 0x7); set_gpio_field(RX_GAIN, 0); set_gpio_field(TXLO1_SYNC, 0); set_gpio_field(TXLO2_SYNC, 0); set_gpio_field(RXLO1_SYNC, 0); set_gpio_field(RXLO1_SYNC, 0); write_gpio(); // Configure ATR _iface->set_atr_reg(dboard_iface::UNIT_TX, gpio_atr::ATR_REG_IDLE, _tx_gpio_reg.atr_idle); _iface->set_atr_reg(dboard_iface::UNIT_TX, gpio_atr::ATR_REG_TX_ONLY, _tx_gpio_reg.atr_tx); _iface->set_atr_reg(dboard_iface::UNIT_TX, gpio_atr::ATR_REG_RX_ONLY, _tx_gpio_reg.atr_rx); _iface->set_atr_reg(dboard_iface::UNIT_TX, gpio_atr::ATR_REG_FULL_DUPLEX, _tx_gpio_reg.atr_full_duplex); _iface->set_atr_reg(dboard_iface::UNIT_RX, gpio_atr::ATR_REG_IDLE, _rx_gpio_reg.atr_idle); _iface->set_atr_reg(dboard_iface::UNIT_RX, gpio_atr::ATR_REG_TX_ONLY, _rx_gpio_reg.atr_tx); _iface->set_atr_reg(dboard_iface::UNIT_RX, gpio_atr::ATR_REG_RX_ONLY, _rx_gpio_reg.atr_rx); _iface->set_atr_reg(dboard_iface::UNIT_RX, gpio_atr::ATR_REG_FULL_DUPLEX, _rx_gpio_reg.atr_full_duplex); // Engage ATR control (1 is ATR control, 0 is manual control) _iface->set_pin_ctrl(dboard_iface::UNIT_TX, _tx_gpio_reg.atr_mask); _iface->set_pin_ctrl(dboard_iface::UNIT_RX, _rx_gpio_reg.atr_mask); // bring CPLD out of reset boost::this_thread::sleep(boost::posix_time::milliseconds(20)); // hold CPLD reset for minimum of 20 ms set_gpio_field(CPLD_RST_N, 1); write_gpio(); // Initialize LOs if (_rev == 0) { _txlo1 = max287x_iface::make(boost::bind(&ubx_xcvr::write_spi_regs, this, TXLO1, _1)); _txlo2 = max287x_iface::make(boost::bind(&ubx_xcvr::write_spi_regs, this, TXLO2, _1)); _rxlo1 = max287x_iface::make(boost::bind(&ubx_xcvr::write_spi_regs, this, RXLO1, _1)); _rxlo2 = max287x_iface::make(boost::bind(&ubx_xcvr::write_spi_regs, this, RXLO2, _1)); std::vector los = boost::assign::list_of(_txlo1)(_txlo2)(_rxlo1)(_rxlo2); BOOST_FOREACH(max287x_iface::sptr lo, los) { lo->set_auto_retune(false); lo->set_muxout_mode(max287x_iface::MUXOUT_DLD); lo->set_ld_pin_mode(max287x_iface::LD_PIN_MODE_DLD); } } else if (_rev == 1 or _rev == 2) { _txlo1 = max287x_iface::make(boost::bind(&ubx_xcvr::write_spi_regs, this, TXLO1, _1)); _txlo2 = max287x_iface::make(boost::bind(&ubx_xcvr::write_spi_regs, this, TXLO2, _1)); _rxlo1 = max287x_iface::make(boost::bind(&ubx_xcvr::write_spi_regs, this, RXLO1, _1)); _rxlo2 = max287x_iface::make(boost::bind(&ubx_xcvr::write_spi_regs, this, RXLO2, _1)); std::vector los = boost::assign::list_of(_txlo1)(_txlo2)(_rxlo1)(_rxlo2); BOOST_FOREACH(max287x_iface::sptr lo, los) { lo->set_auto_retune(false); //lo->set_cycle_slip_mode(true); // tried it - caused longer lock times lo->set_charge_pump_current(max287x_iface::CHARGE_PUMP_CURRENT_5_12MA); lo->set_muxout_mode(max287x_iface::MUXOUT_SYNC); lo->set_ld_pin_mode(max287x_iface::LD_PIN_MODE_DLD); } } else { UHD_THROW_INVALID_CODE_PATH(); } // Initialize CPLD register _prev_cpld_value = 0xFFFF; _cpld_reg.value = 0; write_cpld_reg(); //////////////////////////////////////////////////////////////////// // Register power save properties //////////////////////////////////////////////////////////////////// get_rx_subtree()->create >("power_mode/options") .set(ubx_power_modes); get_rx_subtree()->create("power_mode/value") .add_coerced_subscriber(boost::bind(&ubx_xcvr::set_power_mode, this, _1)) .set("performance"); get_rx_subtree()->create >("xcvr_mode/options") .set(ubx_xcvr_modes); get_rx_subtree()->create("xcvr_mode/value") .add_coerced_subscriber(boost::bind(&ubx_xcvr::set_xcvr_mode, this, _1)) .set("FDX"); get_tx_subtree()->create >("power_mode/options") .set(ubx_power_modes); get_tx_subtree()->create("power_mode/value") .add_coerced_subscriber(boost::bind(&uhd::property::set, &get_rx_subtree()->access("power_mode/value"), _1)) .set_publisher(boost::bind(&uhd::property::get, &get_rx_subtree()->access("power_mode/value"))); get_tx_subtree()->create >("xcvr_mode/options") .set(ubx_xcvr_modes); get_tx_subtree()->create("xcvr_mode/value") .add_coerced_subscriber(boost::bind(&uhd::property::set, &get_rx_subtree()->access("xcvr_mode/value"), _1)) .set_publisher(boost::bind(&uhd::property::get, &get_rx_subtree()->access("xcvr_mode/value"))); //////////////////////////////////////////////////////////////////// // Register TX properties //////////////////////////////////////////////////////////////////// get_tx_subtree()->create("name").set("UBX TX"); get_tx_subtree()->create("tune_args") .set(device_addr_t()); get_tx_subtree()->create("sensors/lo_locked") .set_publisher(boost::bind(&ubx_xcvr::get_locked, this, "TXLO")); get_tx_subtree()->create("gains/PGA0/value") .set_coercer(boost::bind(&ubx_xcvr::set_tx_gain, this, _1)).set(0); get_tx_subtree()->create("gains/PGA0/range") .set(ubx_tx_gain_range); get_tx_subtree()->create("freq/value") .set_coercer(boost::bind(&ubx_xcvr::set_tx_freq, this, _1)) .set(ubx_freq_range.start()); get_tx_subtree()->create("freq/range") .set(ubx_freq_range); get_tx_subtree()->create >("antenna/options") .set(ubx_tx_antennas); get_tx_subtree()->create("antenna/value") .add_coerced_subscriber(boost::bind(&ubx_xcvr::set_tx_ant, this, _1)) .set(ubx_tx_antennas.at(0)); get_tx_subtree()->create("connection") .set("QI"); get_tx_subtree()->create("enabled") .set(true); //always enabled get_tx_subtree()->create("use_lo_offset") .set(false); get_tx_subtree()->create("bandwidth/value") .set(bw); get_tx_subtree()->create("bandwidth/range") .set(freq_range_t(bw, bw)); get_tx_subtree()->create("sync_delay") .add_coerced_subscriber(boost::bind(&ubx_xcvr::set_sync_delay, this, true, _1)) .set(-8); //////////////////////////////////////////////////////////////////// // Register RX properties //////////////////////////////////////////////////////////////////// get_rx_subtree()->create("name").set("UBX RX"); get_rx_subtree()->create("tune_args") .set(device_addr_t()); get_rx_subtree()->create("sensors/lo_locked") .set_publisher(boost::bind(&ubx_xcvr::get_locked, this, "RXLO")); get_rx_subtree()->create("gains/PGA0/value") .set_coercer(boost::bind(&ubx_xcvr::set_rx_gain, this, _1)) .set(0); get_rx_subtree()->create("gains/PGA0/range") .set(ubx_rx_gain_range); get_rx_subtree()->create("freq/value") .set_coercer(boost::bind(&ubx_xcvr::set_rx_freq, this, _1)) .set(ubx_freq_range.start()); get_rx_subtree()->create("freq/range") .set(ubx_freq_range); get_rx_subtree()->create >("antenna/options") .set(ubx_rx_antennas); get_rx_subtree()->create("antenna/value") .add_coerced_subscriber(boost::bind(&ubx_xcvr::set_rx_ant, this, _1)).set("RX2"); get_rx_subtree()->create("connection") .set("IQ"); get_rx_subtree()->create("enabled") .set(true); //always enabled get_rx_subtree()->create("use_lo_offset") .set(false); get_rx_subtree()->create("bandwidth/value") .set(bw); get_rx_subtree()->create("bandwidth/range") .set(freq_range_t(bw, bw)); get_rx_subtree()->create("sync_delay") .add_coerced_subscriber(boost::bind(&ubx_xcvr::set_sync_delay, this, false, _1)) .set(-8); } virtual ~ubx_xcvr(void) { UHD_SAFE_CALL ( // Shutdown synthesizers _txlo1->shutdown(); _txlo2->shutdown(); _rxlo1->shutdown(); _rxlo2->shutdown(); // Reset CPLD values _cpld_reg.value = 0; write_cpld_reg(); // Reset GPIO values set_gpio_field(TX_GAIN, 0); set_gpio_field(CPLD_RST_N, 0); set_gpio_field(RX_ANT, 1); set_gpio_field(TX_EN_N, 1); set_gpio_field(RX_EN_N, 1); set_gpio_field(SPI_ADDR, 0x7); set_gpio_field(RX_GAIN, 0); set_gpio_field(TXLO1_SYNC, 0); set_gpio_field(TXLO2_SYNC, 0); set_gpio_field(RXLO1_SYNC, 0); set_gpio_field(RXLO1_SYNC, 0); write_gpio(); ) } private: enum power_mode_t {PERFORMANCE,POWERSAVE}; /*********************************************************************** * Helper Functions **********************************************************************/ void write_spi_reg(spi_dest_t dest, uint32_t value) { boost::mutex::scoped_lock lock(_spi_mutex); ROUTE_SPI(_iface, dest); WRITE_SPI(_iface, value); } void write_spi_regs(spi_dest_t dest, std::vector values) { boost::mutex::scoped_lock lock(_spi_mutex); ROUTE_SPI(_iface, dest); BOOST_FOREACH(uint32_t value, values) WRITE_SPI(_iface, value); } void set_cpld_field(ubx_cpld_field_id_t id, uint32_t value) { _cpld_reg.set_field(id, value); } void write_cpld_reg() { if (_cpld_reg.value != _prev_cpld_value) { write_spi_reg(CPLD, _cpld_reg.value); _prev_cpld_value = _cpld_reg.value; } } void set_gpio_field(ubx_gpio_field_id_t id, uint32_t value) { // Look up field info std::map::iterator entry = _gpio_map.find(id); if (entry == _gpio_map.end()) return; ubx_gpio_field_info_t field_info = entry->second; if (field_info.direction == ubx_gpio_field_info_t::OUTPUT) return; ubx_gpio_reg_t *reg = (field_info.unit == dboard_iface::UNIT_TX ? &_tx_gpio_reg : &_rx_gpio_reg); uint32_t _value = reg->value; uint32_t _mask = reg->mask; // Set field and mask _value &= ~field_info.mask; _value |= (value << field_info.offset) & field_info.mask; _mask |= field_info.mask; // Mark whether register is dirty or not if (_value != reg->value) { reg->value = _value; reg->mask = _mask; reg->dirty = true; } } uint32_t get_gpio_field(ubx_gpio_field_id_t id) { // Look up field info std::map::iterator entry = _gpio_map.find(id); if (entry == _gpio_map.end()) return 0; ubx_gpio_field_info_t field_info = entry->second; if (field_info.direction == ubx_gpio_field_info_t::INPUT) { ubx_gpio_reg_t *reg = (field_info.unit == dboard_iface::UNIT_TX ? &_tx_gpio_reg : &_rx_gpio_reg); return (reg->value >> field_info.offset) & field_info.mask; } // Read register uint32_t value = _iface->read_gpio(field_info.unit); value &= field_info.mask; value >>= field_info.offset; // Return field value return value; } void write_gpio() { if (_tx_gpio_reg.dirty) { _iface->set_gpio_out(dboard_iface::UNIT_TX, _tx_gpio_reg.value, _tx_gpio_reg.mask); _tx_gpio_reg.dirty = false; _tx_gpio_reg.mask = 0; } if (_rx_gpio_reg.dirty) { _iface->set_gpio_out(dboard_iface::UNIT_RX, _rx_gpio_reg.value, _rx_gpio_reg.mask); _rx_gpio_reg.dirty = false; _rx_gpio_reg.mask = 0; } } void sync_phase(uhd::time_spec_t cmd_time, uhd::direction_t dir) { // Send phase sync signal only if the command time is set if (cmd_time != uhd::time_spec_t(0.0)) { // Delay 400 microseconds to allow LOs to lock cmd_time += uhd::time_spec_t(0.0004); // Phase synchronization for MAX2871 requires that the sync signal // is at least 4/(N*PFD_freq) + 2.6ns before the rising edge of the // ref clock and 4/(N*PFD_freq) after the rising edge of the ref clock. // Since the ref clock, the radio clock, and the VITA time are all // synchronized to the 10 MHz clock, use the time spec to move // the rising edge of the sync signal away from the 10 MHz edge, // which will move it away from the ref clock edge by the same amount. // Since the MAX2871 requires the ref freq and PFD freq be the same // for phase synchronization, the dboard clock rate is used as the PFD // freq and the worst case value of 20 is used for the N value to // calculate the offset. double pfd_freq = _iface->get_clock_rate(dir == TX_DIRECTION ? dboard_iface::UNIT_TX : dboard_iface::UNIT_RX); double tick_rate = _iface->get_codec_rate(dir == TX_DIRECTION ? dboard_iface::UNIT_TX : dboard_iface::UNIT_RX); int64_t ticks = cmd_time.to_ticks(tick_rate); ticks -= ticks % (int64_t)(tick_rate / 10e6); // align to 10 MHz clock ticks += dir == TX_DIRECTION ? _tx_sync_delay : _rx_sync_delay; ticks += std::ceil(tick_rate*4/(20*pfd_freq)); // add required offset (using worst case N value of 20) cmd_time = uhd::time_spec_t::from_ticks(ticks, tick_rate); _iface->set_command_time(cmd_time); // Assert SYNC ubx_gpio_field_info_t lo1_field_info = _gpio_map.find(dir == TX_DIRECTION ? TXLO1_SYNC : RXLO1_SYNC)->second; ubx_gpio_field_info_t lo2_field_info = _gpio_map.find(dir == TX_DIRECTION ? TXLO2_SYNC : RXLO2_SYNC)->second; uint16_t value = (1 << lo1_field_info.offset) | (1 << lo2_field_info.offset); uint16_t mask = lo1_field_info.mask | lo2_field_info.mask; dboard_iface::unit_t unit = lo1_field_info.unit; UHD_ASSERT_THROW(lo1_field_info.unit == lo2_field_info.unit); _iface->set_atr_reg(unit, gpio_atr::ATR_REG_IDLE, value, mask); cmd_time += uhd::time_spec_t(1/pfd_freq); _iface->set_command_time(cmd_time); _iface->set_atr_reg(unit, gpio_atr::ATR_REG_TX_ONLY, value, mask); cmd_time += uhd::time_spec_t(1/pfd_freq); _iface->set_command_time(cmd_time); _iface->set_atr_reg(unit, gpio_atr::ATR_REG_RX_ONLY, value, mask); cmd_time += uhd::time_spec_t(1/pfd_freq); _iface->set_command_time(cmd_time); _iface->set_atr_reg(unit, gpio_atr::ATR_REG_FULL_DUPLEX, value, mask); // De-assert SYNC // Head of line blocking means the command time does not need to be set. _iface->set_atr_reg(unit, gpio_atr::ATR_REG_IDLE, 0, mask); _iface->set_atr_reg(unit, gpio_atr::ATR_REG_TX_ONLY, 0, mask); _iface->set_atr_reg(unit, gpio_atr::ATR_REG_RX_ONLY, 0, mask); _iface->set_atr_reg(unit, gpio_atr::ATR_REG_FULL_DUPLEX, 0, mask); } } /*********************************************************************** * Board Control Handling **********************************************************************/ sensor_value_t get_locked(const std::string &pll_name) { boost::mutex::scoped_lock lock(_mutex); assert_has(ubx_plls, pll_name, "ubx pll name"); if(pll_name == "TXLO") { _txlo_locked = (get_gpio_field(TX_LO_LOCKED) != 0); return sensor_value_t("TXLO", _txlo_locked, "locked", "unlocked"); } else if(pll_name == "RXLO") { _rxlo_locked = (get_gpio_field(RX_LO_LOCKED) != 0); return sensor_value_t("RXLO", _rxlo_locked, "locked", "unlocked"); } return sensor_value_t("Unknown", false, "locked", "unlocked"); } void set_tx_ant(const std::string &ant) { //validate input assert_has(ubx_tx_antennas, ant, "ubx tx antenna name"); } // Set RX antennas void set_rx_ant(const std::string &ant) { boost::mutex::scoped_lock lock(_mutex); //validate input assert_has(ubx_rx_antennas, ant, "ubx rx antenna name"); // Due to an issue with TX path into to the RF switch (U32), there // is a long transient at the beginning of transmission when the RX // antenna is set to RX2. Forcing on the TX PA removes the transient, // so it is forced on only when the RX2 antenna is selected. It is // cleared when the TX/RX antenna is selected to avoid a higher noise // floor on RX. if (ant == "TX/RX") { set_gpio_field(RX_ANT, 0); set_cpld_field(TXDRV_FORCEON, 0); // Turn off PA in TDD mode } else { set_gpio_field(RX_ANT, 1); set_cpld_field(TXDRV_FORCEON, 1); // Keep PA on } write_gpio(); write_cpld_reg(); } /*********************************************************************** * Gain Handling **********************************************************************/ double set_tx_gain(double gain) { boost::mutex::scoped_lock lock(_mutex); gain = ubx_tx_gain_range.clip(gain); int attn_code = int(std::floor(gain * 2)); _ubx_tx_atten_val = ((attn_code & 0x3F) << 10); set_gpio_field(TX_GAIN, attn_code); write_gpio(); UHD_LOGV(rarely) << boost::format("UBX TX Gain: %f dB, Code: %d, IO Bits 0x%04x") % gain % attn_code % _ubx_tx_atten_val << std::endl; _tx_gain = gain; return gain; } double set_rx_gain(double gain) { boost::mutex::scoped_lock lock(_mutex); gain = ubx_rx_gain_range.clip(gain); int attn_code = int(std::floor(gain * 2)); _ubx_rx_atten_val = ((attn_code & 0x3F) << 10); set_gpio_field(RX_GAIN, attn_code); write_gpio(); UHD_LOGV(rarely) << boost::format("UBX RX Gain: %f dB, Code: %d, IO Bits 0x%04x") % gain % attn_code % _ubx_rx_atten_val << std::endl; _rx_gain = gain; return gain; } /*********************************************************************** * Frequency Handling **********************************************************************/ double set_tx_freq(double freq) { boost::mutex::scoped_lock lock(_mutex); double freq_lo1 = 0.0; double freq_lo2 = 0.0; double ref_freq = _iface->get_clock_rate(dboard_iface::UNIT_TX); bool is_int_n = false; /* * If the user sets 'mode_n=integer' in the tuning args, the user wishes to * tune in Integer-N mode, which can result in better spur * performance on some mixers. The default is fractional tuning. */ property_tree::sptr subtree = this->get_tx_subtree(); device_addr_t tune_args = subtree->access("tune_args").get(); is_int_n = boost::iequals(tune_args.get("mode_n",""), "integer"); UHD_LOGV(rarely) << boost::format("UBX TX: the requested frequency is %f MHz") % (freq/1e6) << std::endl; double target_pfd_freq = _tx_target_pfd_freq; if (is_int_n and tune_args.has_key("int_n_step")) { target_pfd_freq = tune_args.cast("int_n_step", _tx_target_pfd_freq); if (target_pfd_freq > _tx_target_pfd_freq) { UHD_MSG(warning) << boost::format("Requested int_n_step of %f MHz too large, clipping to %f MHz") % (target_pfd_freq/1e6) % (_tx_target_pfd_freq/1e6) << std::endl; target_pfd_freq = _tx_target_pfd_freq; } } // Clip the frequency to the valid range freq = ubx_freq_range.clip(freq); // Power up/down LOs if (_txlo1->is_shutdown()) _txlo1->power_up(); if (_txlo2->is_shutdown() and (_power_mode == PERFORMANCE or freq < (500*fMHz))) _txlo2->power_up(); else if (freq >= 500*fMHz and _power_mode == POWERSAVE) _txlo2->shutdown(); // Set up LOs for phase sync if command time is set uhd::time_spec_t cmd_time = _iface->get_command_time(); if (cmd_time != uhd::time_spec_t(0.0)) { _txlo1->config_for_sync(true); if (not _txlo2->is_shutdown()) _txlo2->config_for_sync(true); } else { _txlo1->config_for_sync(false); if (not _txlo2->is_shutdown()) _txlo2->config_for_sync(false); } // Set up registers for the requested frequency if (freq < (500*fMHz)) { set_cpld_field(TXLO1_FSEL3, 0); set_cpld_field(TXLO1_FSEL2, 1); set_cpld_field(TXLO1_FSEL1, 0); set_cpld_field(TXLB_SEL, 1); set_cpld_field(TXHB_SEL, 0); // Set LO1 to IF of 2100 MHz (offset from RX IF to reduce leakage) freq_lo1 = _txlo1->set_frequency(2100*fMHz, ref_freq, target_pfd_freq, is_int_n); _txlo1->set_output_power(max287x_iface::OUTPUT_POWER_5DBM); // Set LO2 to IF minus desired frequency freq_lo2 = _txlo2->set_frequency(freq_lo1 - freq, ref_freq, target_pfd_freq, is_int_n); _txlo2->set_output_power(max287x_iface::OUTPUT_POWER_2DBM); } else if ((freq >= (500*fMHz)) && (freq <= (800*fMHz))) { set_cpld_field(TXLO1_FSEL3, 0); set_cpld_field(TXLO1_FSEL2, 0); set_cpld_field(TXLO1_FSEL1, 1); set_cpld_field(TXLB_SEL, 0); set_cpld_field(TXHB_SEL, 1); freq_lo1 = _txlo1->set_frequency(freq, ref_freq, target_pfd_freq, is_int_n); _txlo1->set_output_power(max287x_iface::OUTPUT_POWER_2DBM); } else if ((freq > (800*fMHz)) && (freq <= (1000*fMHz))) { set_cpld_field(TXLO1_FSEL3, 0); set_cpld_field(TXLO1_FSEL2, 0); set_cpld_field(TXLO1_FSEL1, 1); set_cpld_field(TXLB_SEL, 0); set_cpld_field(TXHB_SEL, 1); freq_lo1 = _txlo1->set_frequency(freq, ref_freq, target_pfd_freq, is_int_n); _txlo1->set_output_power(max287x_iface::OUTPUT_POWER_5DBM); } else if ((freq > (1000*fMHz)) && (freq <= (2200*fMHz))) { set_cpld_field(TXLO1_FSEL3, 0); set_cpld_field(TXLO1_FSEL2, 1); set_cpld_field(TXLO1_FSEL1, 0); set_cpld_field(TXLB_SEL, 0); set_cpld_field(TXHB_SEL, 1); freq_lo1 = _txlo1->set_frequency(freq, ref_freq, target_pfd_freq, is_int_n); _txlo1->set_output_power(max287x_iface::OUTPUT_POWER_2DBM); } else if ((freq > (2200*fMHz)) && (freq <= (2500*fMHz))) { set_cpld_field(TXLO1_FSEL3, 0); set_cpld_field(TXLO1_FSEL2, 1); set_cpld_field(TXLO1_FSEL1, 0); set_cpld_field(TXLB_SEL, 0); set_cpld_field(TXHB_SEL, 1); freq_lo1 = _txlo1->set_frequency(freq, ref_freq, target_pfd_freq, is_int_n); _txlo1->set_output_power(max287x_iface::OUTPUT_POWER_2DBM); } else if ((freq > (2500*fMHz)) && (freq <= (6000*fMHz))) { set_cpld_field(TXLO1_FSEL3, 1); set_cpld_field(TXLO1_FSEL2, 0); set_cpld_field(TXLO1_FSEL1, 0); set_cpld_field(TXLB_SEL, 0); set_cpld_field(TXHB_SEL, 1); freq_lo1 = _txlo1->set_frequency(freq, ref_freq, target_pfd_freq, is_int_n); _txlo1->set_output_power(max287x_iface::OUTPUT_POWER_5DBM); } // To reduce the number of commands issued to the device, write to the // SPI destination already addressed first. This avoids the writes to // the GPIO registers to route the SPI to the same destination. switch (get_gpio_field(SPI_ADDR)) { case TXLO1: _txlo1->commit(); if (freq < (500*fMHz)) _txlo2->commit(); write_cpld_reg(); break; case TXLO2: if (freq < (500*fMHz)) _txlo2->commit(); _txlo1->commit(); write_cpld_reg(); break; default: write_cpld_reg(); _txlo1->commit(); if (freq < (500*fMHz)) _txlo2->commit(); break; } if (cmd_time != uhd::time_spec_t(0.0) and _txlo1->can_sync()) { sync_phase(cmd_time, TX_DIRECTION); } _tx_freq = freq_lo1 - freq_lo2; _txlo1_freq = freq_lo1; _txlo2_freq = freq_lo2; UHD_LOGV(rarely) << boost::format("UBX TX: the actual frequency is %f MHz") % (_tx_freq/1e6) << std::endl; return _tx_freq; } double set_rx_freq(double freq) { boost::mutex::scoped_lock lock(_mutex); double freq_lo1 = 0.0; double freq_lo2 = 0.0; double ref_freq = _iface->get_clock_rate(dboard_iface::UNIT_RX); bool is_int_n = false; UHD_LOGV(rarely) << boost::format("UBX RX: the requested frequency is %f MHz") % (freq/1e6) << std::endl; property_tree::sptr subtree = this->get_rx_subtree(); device_addr_t tune_args = subtree->access("tune_args").get(); is_int_n = boost::iequals(tune_args.get("mode_n",""), "integer"); double target_pfd_freq = _rx_target_pfd_freq; if (is_int_n and tune_args.has_key("int_n_step")) { target_pfd_freq = tune_args.cast("int_n_step", _rx_target_pfd_freq); if (target_pfd_freq > _rx_target_pfd_freq) { UHD_MSG(warning) << boost::format("Requested int_n_step of %f Mhz too large, clipping to %f MHz") % (target_pfd_freq/1e6) % (_rx_target_pfd_freq/1e6) << std::endl; target_pfd_freq = _rx_target_pfd_freq; } } // Clip the frequency to the valid range freq = ubx_freq_range.clip(freq); // Power up/down LOs if (_rxlo1->is_shutdown()) _rxlo1->power_up(); if (_rxlo2->is_shutdown() and (_power_mode == PERFORMANCE or freq < 500*fMHz)) _rxlo2->power_up(); else if (freq >= 500*fMHz and _power_mode == POWERSAVE) _rxlo2->shutdown(); // Set up LOs for phase sync if command time is set uhd::time_spec_t cmd_time = _iface->get_command_time(); if (cmd_time != uhd::time_spec_t(0.0)) { _rxlo1->config_for_sync(true); if (not _rxlo2->is_shutdown()) _rxlo2->config_for_sync(true); } else { _rxlo1->config_for_sync(false); if (not _rxlo2->is_shutdown()) _rxlo2->config_for_sync(false); } // Work with frequencies if (freq < 100*fMHz) { set_cpld_field(SEL_LNA1, 0); set_cpld_field(SEL_LNA2, 1); set_cpld_field(RXLO1_FSEL3, 1); set_cpld_field(RXLO1_FSEL2, 0); set_cpld_field(RXLO1_FSEL1, 0); set_cpld_field(RXLB_SEL, 1); set_cpld_field(RXHB_SEL, 0); // Set LO1 to IF of 2380 MHz (2440 MHz filter center minus 60 MHz offset to minimize LO leakage) freq_lo1 = _rxlo1->set_frequency(2380*fMHz, ref_freq, target_pfd_freq, is_int_n); _rxlo1->set_output_power(max287x_iface::OUTPUT_POWER_5DBM); // Set LO2 to IF minus desired frequency freq_lo2 = _rxlo2->set_frequency(freq_lo1 - freq, ref_freq, target_pfd_freq, is_int_n); _rxlo2->set_output_power(max287x_iface::OUTPUT_POWER_2DBM); } else if ((freq >= 100*fMHz) && (freq < 500*fMHz)) { set_cpld_field(SEL_LNA1, 0); set_cpld_field(SEL_LNA2, 1); set_cpld_field(RXLO1_FSEL3, 1); set_cpld_field(RXLO1_FSEL2, 0); set_cpld_field(RXLO1_FSEL1, 0); set_cpld_field(RXLB_SEL, 1); set_cpld_field(RXHB_SEL, 0); // Set LO1 to IF of 2440 (center of filter) freq_lo1 = _rxlo1->set_frequency(2440*fMHz, ref_freq, target_pfd_freq, is_int_n); _rxlo1->set_output_power(max287x_iface::OUTPUT_POWER_5DBM); // Set LO2 to IF minus desired frequency freq_lo2 = _rxlo2->set_frequency(freq_lo1 - freq, ref_freq, target_pfd_freq, is_int_n); _rxlo1->set_output_power(max287x_iface::OUTPUT_POWER_2DBM); } else if ((freq >= 500*fMHz) && (freq < 800*fMHz)) { set_cpld_field(SEL_LNA1, 0); set_cpld_field(SEL_LNA2, 1); set_cpld_field(RXLO1_FSEL3, 0); set_cpld_field(RXLO1_FSEL2, 0); set_cpld_field(RXLO1_FSEL1, 1); set_cpld_field(RXLB_SEL, 0); set_cpld_field(RXHB_SEL, 1); freq_lo1 = _rxlo1->set_frequency(freq, ref_freq, target_pfd_freq, is_int_n); _rxlo1->set_output_power(max287x_iface::OUTPUT_POWER_2DBM); } else if ((freq >= 800*fMHz) && (freq < 1000*fMHz)) { set_cpld_field(SEL_LNA1, 0); set_cpld_field(SEL_LNA2, 1); set_cpld_field(RXLO1_FSEL3, 0); set_cpld_field(RXLO1_FSEL2, 0); set_cpld_field(RXLO1_FSEL1, 1); set_cpld_field(RXLB_SEL, 0); set_cpld_field(RXHB_SEL, 1); freq_lo1 = _rxlo1->set_frequency(freq, ref_freq, target_pfd_freq, is_int_n); _rxlo1->set_output_power(max287x_iface::OUTPUT_POWER_5DBM); } else if ((freq >= 1000*fMHz) && (freq < 1500*fMHz)) { set_cpld_field(SEL_LNA1, 0); set_cpld_field(SEL_LNA2, 1); set_cpld_field(RXLO1_FSEL3, 0); set_cpld_field(RXLO1_FSEL2, 1); set_cpld_field(RXLO1_FSEL1, 0); set_cpld_field(RXLB_SEL, 0); set_cpld_field(RXHB_SEL, 1); freq_lo1 = _rxlo1->set_frequency(freq, ref_freq, target_pfd_freq, is_int_n); _rxlo1->set_output_power(max287x_iface::OUTPUT_POWER_2DBM); } else if ((freq >= 1500*fMHz) && (freq < 2200*fMHz)) { set_cpld_field(SEL_LNA1, 1); set_cpld_field(SEL_LNA2, 0); set_cpld_field(RXLO1_FSEL3, 0); set_cpld_field(RXLO1_FSEL2, 1); set_cpld_field(RXLO1_FSEL1, 0); set_cpld_field(RXLB_SEL, 0); set_cpld_field(RXHB_SEL, 1); freq_lo1 = _rxlo1->set_frequency(freq, ref_freq, target_pfd_freq, is_int_n); _rxlo1->set_output_power(max287x_iface::OUTPUT_POWER_2DBM); } else if ((freq >= 2200*fMHz) && (freq < 2500*fMHz)) { set_cpld_field(SEL_LNA1, 1); set_cpld_field(SEL_LNA2, 0); set_cpld_field(RXLO1_FSEL3, 0); set_cpld_field(RXLO1_FSEL2, 1); set_cpld_field(RXLO1_FSEL1, 0); set_cpld_field(RXLB_SEL, 0); set_cpld_field(RXHB_SEL, 1); freq_lo1 = _rxlo1->set_frequency(freq, ref_freq, target_pfd_freq, is_int_n); _rxlo1->set_output_power(max287x_iface::OUTPUT_POWER_2DBM); } else if ((freq >= 2500*fMHz) && (freq <= 6000*fMHz)) { set_cpld_field(SEL_LNA1, 1); set_cpld_field(SEL_LNA2, 0); set_cpld_field(RXLO1_FSEL3, 1); set_cpld_field(RXLO1_FSEL2, 0); set_cpld_field(RXLO1_FSEL1, 0); set_cpld_field(RXLB_SEL, 0); set_cpld_field(RXHB_SEL, 1); freq_lo1 = _rxlo1->set_frequency(freq, ref_freq, target_pfd_freq, is_int_n); _rxlo1->set_output_power(max287x_iface::OUTPUT_POWER_5DBM); } // To reduce the number of commands issued to the device, write to the // SPI destination already addressed first. This avoids the writes to // the GPIO registers to route the SPI to the same destination. switch (get_gpio_field(SPI_ADDR)) { case RXLO1: _rxlo1->commit(); if (freq < (500*fMHz)) _rxlo2->commit(); write_cpld_reg(); break; case RXLO2: if (freq < (500*fMHz)) _rxlo2->commit(); _rxlo1->commit(); write_cpld_reg(); break; default: write_cpld_reg(); _rxlo1->commit(); if (freq < (500*fMHz)) _rxlo2->commit(); break; } if (cmd_time != uhd::time_spec_t(0.0) and _rxlo1->can_sync()) { sync_phase(cmd_time, RX_DIRECTION); } _rx_freq = freq_lo1 - freq_lo2; _rxlo1_freq = freq_lo1; _rxlo2_freq = freq_lo2; UHD_LOGV(rarely) << boost::format("UBX RX: the actual frequency is %f MHz") % (_rx_freq/1e6) << std::endl; return _rx_freq; } /*********************************************************************** * Setting Modes **********************************************************************/ void set_power_mode(std::string mode) { boost::mutex::scoped_lock lock(_mutex); if (mode == "performance") { // performance mode attempts to reduce tuning and settling time // as much as possible without adding noise. // RXLNA2 has a ~100ms warm up time, so the LNAs are forced on // here to reduce the settling time as much as possible. The // force on signals are gated by the LNA selection so the LNAs // are turned on/off during tuning. Unfortunately, that means // there is still a long settling time when tuning from the high // band (>1.5 GHz) to the low band (<1.5 GHz). set_cpld_field(RXLNA1_FORCEON, 1); set_cpld_field(RXLNA2_FORCEON, 1); /* // Placeholders in case some components need to be forced on to // reduce settling time. Note that some FORCEON lines are still gated // by other bits in the CPLD register are are asserted during // frequency tuning. set_cpld_field(RXAMP_FORCEON, 0); set_cpld_field(RXDEMOD_FORCEON, 0); set_cpld_field(RXDRV_FORCEON, 0); set_cpld_field(RXMIXER_FORCEON, 0); set_cpld_field(RXLO1_FORCEON, 0); set_cpld_field(RXLO2_FORCEON, 0); //set_cpld_field(TXDRV_FORCEON, 1); // controlled by RX antenna selection set_cpld_field(TXMOD_FORCEON, 0); set_cpld_field(TXMIXER_FORCEON, 0); set_cpld_field(TXLO1_FORCEON, 0); set_cpld_field(TXLO2_FORCEON, 0); */ write_cpld_reg(); _power_mode = PERFORMANCE; } else if (mode == "powersave") { // powersave mode attempts to use the least amount of power possible // by powering on components only when needed. Longer tuning and // settling times are expected. // Clear the LNA force on bits. set_cpld_field(RXLNA1_FORCEON, 0); set_cpld_field(RXLNA2_FORCEON, 0); /* // Placeholders in case other force on bits need to be set or cleared. set_cpld_field(RXAMP_FORCEON, 0); set_cpld_field(RXDEMOD_FORCEON, 0); set_cpld_field(RXDRV_FORCEON, 0); set_cpld_field(RXMIXER_FORCEON, 0); set_cpld_field(RXLO1_FORCEON, 0); set_cpld_field(RXLO2_FORCEON, 0); //set_cpld_field(TXDRV_FORCEON, 1); // controlled by RX antenna selection set_cpld_field(TXMOD_FORCEON, 0); set_cpld_field(TXMIXER_FORCEON, 0); set_cpld_field(TXLO1_FORCEON, 0); set_cpld_field(TXLO2_FORCEON, 0); */ write_cpld_reg(); _power_mode = POWERSAVE; } } void set_xcvr_mode(std::string mode) { // TO DO: Add implementation // The intent is to add behavior based on whether // the board is in TX, RX, or full duplex mode // to reduce power consumption and RF noise. _xcvr_mode = mode; } void set_sync_delay(bool is_tx, int64_t value) { if (is_tx) _tx_sync_delay = value; else _rx_sync_delay = value; } /*********************************************************************** * Variables **********************************************************************/ dboard_iface::sptr _iface; boost::mutex _spi_mutex; boost::mutex _mutex; ubx_cpld_reg_t _cpld_reg; uint32_t _prev_cpld_value; std::map _gpio_map; boost::shared_ptr _txlo1; boost::shared_ptr _txlo2; boost::shared_ptr _rxlo1; boost::shared_ptr _rxlo2; double _tx_target_pfd_freq; double _rx_target_pfd_freq; double _tx_gain; double _rx_gain; double _tx_freq; double _txlo1_freq; double _txlo2_freq; double _rx_freq; double _rxlo1_freq; double _rxlo2_freq; bool _rxlo_locked; bool _txlo_locked; std::string _rx_ant; int _ubx_tx_atten_val; int _ubx_rx_atten_val; power_mode_t _power_mode; std::string _xcvr_mode; size_t _rev; double _prev_tx_freq; double _prev_rx_freq; ubx_gpio_reg_t _tx_gpio_reg; ubx_gpio_reg_t _rx_gpio_reg; int64_t _tx_sync_delay; int64_t _rx_sync_delay; }; /*********************************************************************** * Register the UBX dboard (min freq, max freq, rx div2, tx div2) **********************************************************************/ static dboard_base::sptr make_ubx(dboard_base::ctor_args_t args) { return dboard_base::sptr(new ubx_xcvr(args)); } UHD_STATIC_BLOCK(reg_ubx_dboards) { dboard_manager::register_dboard(UBX_PROTO_V3_RX_ID, UBX_PROTO_V3_TX_ID, &make_ubx, "UBX v0.3"); dboard_manager::register_dboard(UBX_PROTO_V4_RX_ID, UBX_PROTO_V4_TX_ID, &make_ubx, "UBX v0.4"); dboard_manager::register_dboard(UBX_V1_40MHZ_RX_ID, UBX_V1_40MHZ_TX_ID, &make_ubx, "UBX-40 v1"); dboard_manager::register_dboard(UBX_V1_160MHZ_RX_ID, UBX_V1_160MHZ_TX_ID, &make_ubx, "UBX-160 v1"); dboard_manager::register_dboard(UBX_V2_40MHZ_RX_ID, UBX_V2_40MHZ_TX_ID, &make_ubx, "UBX-40 v2"); dboard_manager::register_dboard(UBX_V2_160MHZ_RX_ID, UBX_V2_160MHZ_TX_ID, &make_ubx, "UBX-160 v2"); dboard_manager::register_dboard(UBX_LP_160MHZ_RX_ID, UBX_LP_160MHZ_TX_ID, &make_ubx, "UBX-160-LP"); }