// // Copyright 2013 Ettus Research LLC // Copyright 2018 Ettus Research, a National Instruments Company // // Original ADF4001 driver written by: bistromath // Mar 1, 2013 // // Re-used and re-licensed with permission. // // SPDX-License-Identifier: GPL-3.0-or-later // #include #include #include #include using namespace uhd; using namespace uhd::usrp; adf4001_regs_t::adf4001_regs_t(void) { ref_counter = 0; n = 0; charge_pump_current_1 = 0; charge_pump_current_2 = 0; anti_backlash_width = ANTI_BACKLASH_WIDTH_2_9NS; lock_detect_precision = LOCK_DETECT_PRECISION_3CYC; charge_pump_gain = CHARGE_PUMP_GAIN_1; counter_reset = COUNTER_RESET_NORMAL; power_down = POWER_DOWN_NORMAL; muxout = MUXOUT_TRISTATE_OUT; phase_detector_polarity = PHASE_DETECTOR_POLARITY_NEGATIVE; charge_pump_mode = CHARGE_PUMP_TRISTATE; fastlock_mode = FASTLOCK_MODE_DISABLED; timer_counter_control = TIMEOUT_3CYC; } uint32_t adf4001_regs_t::get_reg(uint8_t addr) { uint32_t reg = 0; switch (addr) { case 0: reg |= (uint32_t(ref_counter) & 0x003FFF) << 2; reg |= (uint32_t(anti_backlash_width) & 0x000003) << 16; reg |= (uint32_t(lock_detect_precision) & 0x000001) << 20; break; case 1: reg |= (uint32_t(n) & 0x001FFF) << 8; reg |= (uint32_t(charge_pump_gain) & 0x000001) << 21; break; case 2: reg |= (uint32_t(counter_reset) & 0x000001) << 2; reg |= (uint32_t(power_down) & 0x000001) << 3; reg |= (uint32_t(muxout) & 0x000007) << 4; reg |= (uint32_t(phase_detector_polarity) & 0x000001) << 7; reg |= (uint32_t(charge_pump_mode) & 0x000001) << 8; reg |= (uint32_t(fastlock_mode) & 0x000003) << 9; reg |= (uint32_t(timer_counter_control) & 0x00000F) << 11; reg |= (uint32_t(charge_pump_current_1) & 0x000007) << 15; reg |= (uint32_t(charge_pump_current_2) & 0x000007) << 18; reg |= (uint32_t(power_down) & 0x000002) << 20; break; case 3: reg |= (uint32_t(counter_reset) & 0x000001) << 2; reg |= (uint32_t(power_down) & 0x000001) << 3; reg |= (uint32_t(muxout) & 0x000007) << 4; reg |= (uint32_t(phase_detector_polarity) & 0x000001) << 7; reg |= (uint32_t(charge_pump_mode) & 0x000001) << 8; reg |= (uint32_t(fastlock_mode) & 0x000003) << 9; reg |= (uint32_t(timer_counter_control) & 0x00000F) << 11; reg |= (uint32_t(charge_pump_current_1) & 0x000007) << 15; reg |= (uint32_t(charge_pump_current_2) & 0x000007) << 18; reg |= (uint32_t(power_down) & 0x000002) << 20; break; default: break; } reg |= (uint32_t(addr) & 0x03); return reg; } adf4001_ctrl::adf4001_ctrl(uhd::spi_iface::sptr _spi, int slaveno): spi_iface(_spi), slaveno(slaveno) { spi_config.mosi_edge = spi_config_t::EDGE_RISE; //set defaults adf4001_regs.ref_counter = 1; adf4001_regs.n = 4; adf4001_regs.charge_pump_current_1 = 7; adf4001_regs.charge_pump_current_2 = 7; adf4001_regs.muxout = adf4001_regs_t::MUXOUT_DLD; adf4001_regs.counter_reset = adf4001_regs_t::COUNTER_RESET_NORMAL; adf4001_regs.phase_detector_polarity = adf4001_regs_t::PHASE_DETECTOR_POLARITY_POSITIVE; adf4001_regs.charge_pump_mode = adf4001_regs_t::CHARGE_PUMP_TRISTATE; //everything else should be defaults program_regs(); } void adf4001_ctrl::set_lock_to_ext_ref(bool external) { if(external) { adf4001_regs.charge_pump_mode = adf4001_regs_t::CHARGE_PUMP_NORMAL; } else { adf4001_regs.charge_pump_mode = adf4001_regs_t::CHARGE_PUMP_TRISTATE; } program_regs(); } void adf4001_ctrl::program_regs(void) { //no control over CE, only LE, therefore we use the initialization latch method write_reg(3); //conduct a function latch (2) write_reg(2); //write R counter latch (0) write_reg(0); //write N counter latch (1) write_reg(1); } void adf4001_ctrl::write_reg(uint8_t addr) { uint32_t reg = adf4001_regs.get_reg(addr); //load the reg data spi_iface->transact_spi(slaveno, spi_config, reg, 24, false); }