// // Copyright 2013-2015 Ettus Research LLC // Copyright 2018 Ettus Research, a National Instruments Company // // SPDX-License-Identifier: GPL-3.0-or-later // #include "lmk04816_regs.hpp" #include "x300_clock_ctrl.hpp" #include #include #include #include #include #include #include #include static const double X300_REF_CLK_OUT_RATE = 10e6; static const uint16_t X300_MAX_CLKOUT_DIV = 1045; struct x300_clk_delays { x300_clk_delays() : fpga_dly_ns(0.0),adc_dly_ns(0.0),dac_dly_ns(0.0),db_rx_dly_ns(0.0),db_tx_dly_ns(0.0) {} x300_clk_delays(double fpga, double adc, double dac, double db_rx, double db_tx) : fpga_dly_ns(fpga),adc_dly_ns(adc),dac_dly_ns(dac),db_rx_dly_ns(db_rx),db_tx_dly_ns(db_tx) {} double fpga_dly_ns; double adc_dly_ns; double dac_dly_ns; double db_rx_dly_ns; double db_tx_dly_ns; }; // Tune the FPGA->ADC clock delay to ensure a safe ADC_SSCLK -> RADIO_CLK crossing. // If the FPGA_CLK is delayed, we also need to delay the reference clocks going to the DAC // because the data interface clock is generated from FPGA_CLK. static const x300_clk_delays X300_REV0_6_CLK_DELAYS = x300_clk_delays( /*fpga=*/0.000, /*adc=*/2.200, /*dac=*/0.000, /*db_rx=*/0.000, /*db_tx=*/0.000); static const x300_clk_delays X300_REV7_CLK_DELAYS = x300_clk_delays( /*fpga=*/0.000, /*adc=*/0.000, /*dac=*/0.000, /*db_rx=*/0.000, /*db_tx=*/0.000); using namespace uhd; x300_clock_ctrl::~x300_clock_ctrl(void){ /* NOP */ } class x300_clock_ctrl_impl : public x300_clock_ctrl { public: ~x300_clock_ctrl_impl(void) {} x300_clock_ctrl_impl(uhd::spi_iface::sptr spiface, const size_t slaveno, const size_t hw_rev, const double master_clock_rate, const double dboard_clock_rate, const double system_ref_rate): _spiface(spiface), _slaveno(slaveno), _hw_rev(hw_rev), _master_clock_rate(master_clock_rate), _dboard_clock_rate(dboard_clock_rate), _system_ref_rate(system_ref_rate) { init(); } void reset_clocks() { _lmk04816_regs.RESET = lmk04816_regs_t::RESET_RESET; this->write_regs(0); _lmk04816_regs.RESET = lmk04816_regs_t::RESET_NO_RESET; for (size_t i = 0; i <= 16; ++i) { this->write_regs(i); } for (size_t i = 24; i <= 31; ++i) { this->write_regs(i); } sync_clocks(); } void sync_clocks(void) { //soft sync: //put the sync IO into output mode - FPGA must be input //write low, then write high - this triggers a soft sync _lmk04816_regs.SYNC_POL_INV = lmk04816_regs_t::SYNC_POL_INV_SYNC_LOW; this->write_regs(11); _lmk04816_regs.SYNC_POL_INV = lmk04816_regs_t::SYNC_POL_INV_SYNC_HIGH; this->write_regs(11); } double get_master_clock_rate(void) { return _master_clock_rate; } double get_sysref_clock_rate(void) { return _system_ref_rate; } double get_refout_clock_rate(void) { //We support only one reference output rate return X300_REF_CLK_OUT_RATE; } void set_dboard_rate(const x300_clock_which_t which, double rate) { uint16_t div = uint16_t(_vco_freq / rate); uint16_t *reg = NULL; uint8_t addr = 0xFF; // Make sure requested rate is an even divisor of the VCO frequency if (not math::frequencies_are_equal(_vco_freq / div, rate)) throw uhd::value_error("invalid dboard rate requested"); switch (which) { case X300_CLOCK_WHICH_DB0_RX: case X300_CLOCK_WHICH_DB1_RX: reg = &_lmk04816_regs.CLKout2_3_DIV; addr = 1; break; case X300_CLOCK_WHICH_DB0_TX: case X300_CLOCK_WHICH_DB1_TX: reg = &_lmk04816_regs.CLKout4_5_DIV; addr = 2; break; default: UHD_THROW_INVALID_CODE_PATH(); } if (*reg == div) return; // Since the clock rate on one daughter board cannot be changed without // affecting the other daughter board, don't allow it. throw uhd::not_implemented_error("x3xx set dboard clock rate does not support changing the clock rate"); // This is open source code and users may need to enable this function // to support other daughterboards. If so, comment out the line above // that throws the error and allow the program to reach the code below. // The LMK04816 datasheet says the register must be written twice if SYNC is enabled *reg = div; write_regs(addr); write_regs(addr); sync_clocks(); } double get_dboard_rate(const x300_clock_which_t which) { double rate = 0.0; switch (which) { case X300_CLOCK_WHICH_DB0_RX: case X300_CLOCK_WHICH_DB1_RX: rate = _vco_freq / _lmk04816_regs.CLKout2_3_DIV; break; case X300_CLOCK_WHICH_DB0_TX: case X300_CLOCK_WHICH_DB1_TX: rate = _vco_freq / _lmk04816_regs.CLKout4_5_DIV; break; default: UHD_THROW_INVALID_CODE_PATH(); } return rate; } std::vector get_dboard_rates(const x300_clock_which_t) { std::vector rates; for (size_t div = size_t(_vco_freq / _master_clock_rate); div <= X300_MAX_CLKOUT_DIV; div++) rates.push_back(_vco_freq / div); return rates; } void enable_dboard_clock(const x300_clock_which_t which, const bool enable) { switch (which) { case X300_CLOCK_WHICH_DB0_RX: if (enable != (_lmk04816_regs.CLKout2_TYPE == lmk04816_regs_t::CLKOUT2_TYPE_LVPECL_700MVPP)) { _lmk04816_regs.CLKout2_TYPE = enable ? lmk04816_regs_t::CLKOUT2_TYPE_LVPECL_700MVPP : lmk04816_regs_t::CLKOUT2_TYPE_P_DOWN; write_regs(6); } break; case X300_CLOCK_WHICH_DB1_RX: if (enable != (_lmk04816_regs.CLKout3_TYPE == lmk04816_regs_t::CLKOUT3_TYPE_LVPECL_700MVPP)) { _lmk04816_regs.CLKout3_TYPE = enable ? lmk04816_regs_t::CLKOUT3_TYPE_LVPECL_700MVPP : lmk04816_regs_t::CLKOUT3_TYPE_P_DOWN; write_regs(6); } break; case X300_CLOCK_WHICH_DB0_TX: if (enable != (_lmk04816_regs.CLKout5_TYPE == lmk04816_regs_t::CLKOUT5_TYPE_LVPECL_700MVPP)) { _lmk04816_regs.CLKout5_TYPE = enable ? lmk04816_regs_t::CLKOUT5_TYPE_LVPECL_700MVPP : lmk04816_regs_t::CLKOUT5_TYPE_P_DOWN; write_regs(7); } break; case X300_CLOCK_WHICH_DB1_TX: if (enable != (_lmk04816_regs.CLKout4_TYPE == lmk04816_regs_t::CLKOUT4_TYPE_LVPECL_700MVPP)) { _lmk04816_regs.CLKout4_TYPE = enable ? lmk04816_regs_t::CLKOUT4_TYPE_LVPECL_700MVPP : lmk04816_regs_t::CLKOUT4_TYPE_P_DOWN; write_regs(7); } break; default: UHD_THROW_INVALID_CODE_PATH(); } } void set_ref_out(const bool enable) { // TODO Implement divider configuration to allow for configurable output // rates if (enable) _lmk04816_regs.CLKout10_TYPE = lmk04816_regs_t::CLKOUT10_TYPE_LVDS; else _lmk04816_regs.CLKout10_TYPE = lmk04816_regs_t::CLKOUT10_TYPE_P_DOWN; this->write_regs(8); } void write_regs(uint8_t addr) { uint32_t data = _lmk04816_regs.get_reg(addr); _spiface->write_spi(_slaveno, spi_config_t::EDGE_RISE, data,32); } double set_clock_delay(const x300_clock_which_t which, const double delay_ns, const bool resync = true) { //All dividers have are delayed by 5 taps by default. The delay //set by this function is relative to the 5 tap delay static const uint16_t DDLY_MIN_TAPS = 5; static const uint16_t DDLY_MAX_TAPS = 522; //Extended mode //The resolution and range of the analog delay is fixed static const double ADLY_RES_NS = 0.025; static const double ADLY_MIN_NS = 0.500; static const double ADLY_MAX_NS = 0.975; //Each digital tap delays the clock by one VCO period double vco_period_ns = 1.0e9/_vco_freq; double half_vco_period_ns = vco_period_ns/2.0; //Implement as much of the requested delay using digital taps. Whatever is leftover //will be made up using the analog delay element and the half-cycle digital tap. //A caveat here is that the analog delay starts at ADLY_MIN_NS, so we need to back off //by that much when coming up with the digital taps so that the difference can be made //up using the analog delay. uint16_t ddly_taps = 0; if (delay_ns < ADLY_MIN_NS) { ddly_taps = static_cast(std::floor((delay_ns)/vco_period_ns)); } else { ddly_taps = static_cast(std::floor((delay_ns-ADLY_MIN_NS)/vco_period_ns)); } double leftover_delay = delay_ns - (vco_period_ns * ddly_taps); //Compute settings uint16_t ddly_value = ddly_taps + DDLY_MIN_TAPS; bool adly_en = false; uint8_t adly_value = 0; uint8_t half_shift_en = 0; if (ddly_value > DDLY_MAX_TAPS) { throw uhd::value_error("set_clock_delay: Requested delay is out of range."); } double coerced_delay = (vco_period_ns * ddly_taps); if (leftover_delay > ADLY_MAX_NS) { //The VCO is running too slowly for us to compensate the digital delay difference using //analog delay. Do the best we can. adly_en = true; adly_value = static_cast(boost::math::round((ADLY_MAX_NS-ADLY_MIN_NS)/ADLY_RES_NS)); coerced_delay += ADLY_MAX_NS; } else if (leftover_delay >= ADLY_MIN_NS && leftover_delay <= ADLY_MAX_NS) { //The leftover delay can be compensated by the analog delay up to the analog delay resolution adly_en = true; adly_value = static_cast(boost::math::round((leftover_delay-ADLY_MIN_NS)/ADLY_RES_NS)); coerced_delay += ADLY_MIN_NS+(ADLY_RES_NS*adly_value); } else if (leftover_delay >= (ADLY_MIN_NS - half_vco_period_ns) && leftover_delay < ADLY_MIN_NS) { //The leftover delay if less than the minimum supported analog delay but if we move the digital //delay back by half a VCO cycle then it will be in the range of the analog delay. So do that! adly_en = true; adly_value = static_cast(boost::math::round((leftover_delay+half_vco_period_ns-ADLY_MIN_NS)/ADLY_RES_NS)); half_shift_en = 1; coerced_delay += ADLY_MIN_NS+(ADLY_RES_NS*adly_value)-half_vco_period_ns; } else { //Even after moving the digital delay back by half a cycle, we cannot make up the difference //so give up on compensating for the difference from the digital delay tap. //If control reaches here then the value of leftover_delay is possible very small and will still //be close to what the client requested. } UHD_LOG_DEBUG("X300", boost::format("x300_clock_ctrl::set_clock_delay: Which=%d, Requested=%f, Digital Taps=%d, Half Shift=%d, Analog Delay=%d (%s), Coerced Delay=%fns" ) % which % delay_ns % ddly_value % (half_shift_en?"ON":"OFF") % ((int)adly_value) % (adly_en?"ON":"OFF") % coerced_delay) //Apply settings switch (which) { case X300_CLOCK_WHICH_FPGA: _lmk04816_regs.CLKout0_1_DDLY = ddly_value; _lmk04816_regs.CLKout0_1_HS = half_shift_en; if (adly_en) { _lmk04816_regs.CLKout0_ADLY_SEL = lmk04816_regs_t::CLKOUT0_ADLY_SEL_D_BOTH; _lmk04816_regs.CLKout1_ADLY_SEL = lmk04816_regs_t::CLKOUT1_ADLY_SEL_D_BOTH; _lmk04816_regs.CLKout0_1_ADLY = adly_value; } else { _lmk04816_regs.CLKout0_ADLY_SEL = lmk04816_regs_t::CLKOUT0_ADLY_SEL_D_PD; _lmk04816_regs.CLKout1_ADLY_SEL = lmk04816_regs_t::CLKOUT1_ADLY_SEL_D_PD; } write_regs(0); write_regs(6); _delays.fpga_dly_ns = coerced_delay; break; case X300_CLOCK_WHICH_DB0_RX: case X300_CLOCK_WHICH_DB1_RX: _lmk04816_regs.CLKout2_3_DDLY = ddly_value; _lmk04816_regs.CLKout2_3_HS = half_shift_en; if (adly_en) { _lmk04816_regs.CLKout2_ADLY_SEL = lmk04816_regs_t::CLKOUT2_ADLY_SEL_D_BOTH; _lmk04816_regs.CLKout3_ADLY_SEL = lmk04816_regs_t::CLKOUT3_ADLY_SEL_D_BOTH; _lmk04816_regs.CLKout2_3_ADLY = adly_value; } else { _lmk04816_regs.CLKout2_ADLY_SEL = lmk04816_regs_t::CLKOUT2_ADLY_SEL_D_PD; _lmk04816_regs.CLKout3_ADLY_SEL = lmk04816_regs_t::CLKOUT3_ADLY_SEL_D_PD; } write_regs(1); write_regs(6); _delays.db_rx_dly_ns = coerced_delay; break; case X300_CLOCK_WHICH_DB0_TX: case X300_CLOCK_WHICH_DB1_TX: _lmk04816_regs.CLKout4_5_DDLY = ddly_value; _lmk04816_regs.CLKout4_5_HS = half_shift_en; if (adly_en) { _lmk04816_regs.CLKout4_ADLY_SEL = lmk04816_regs_t::CLKOUT4_ADLY_SEL_D_BOTH; _lmk04816_regs.CLKout5_ADLY_SEL = lmk04816_regs_t::CLKOUT5_ADLY_SEL_D_BOTH; _lmk04816_regs.CLKout4_5_ADLY = adly_value; } else { _lmk04816_regs.CLKout4_ADLY_SEL = lmk04816_regs_t::CLKOUT4_ADLY_SEL_D_PD; _lmk04816_regs.CLKout5_ADLY_SEL = lmk04816_regs_t::CLKOUT5_ADLY_SEL_D_PD; } write_regs(2); write_regs(7); _delays.db_tx_dly_ns = coerced_delay; break; case X300_CLOCK_WHICH_DAC0: case X300_CLOCK_WHICH_DAC1: _lmk04816_regs.CLKout6_7_DDLY = ddly_value; _lmk04816_regs.CLKout6_7_HS = half_shift_en; if (adly_en) { _lmk04816_regs.CLKout6_ADLY_SEL = lmk04816_regs_t::CLKOUT6_ADLY_SEL_D_BOTH; _lmk04816_regs.CLKout7_ADLY_SEL = lmk04816_regs_t::CLKOUT7_ADLY_SEL_D_BOTH; _lmk04816_regs.CLKout6_7_ADLY = adly_value; } else { _lmk04816_regs.CLKout6_ADLY_SEL = lmk04816_regs_t::CLKOUT6_ADLY_SEL_D_PD; _lmk04816_regs.CLKout7_ADLY_SEL = lmk04816_regs_t::CLKOUT7_ADLY_SEL_D_PD; } write_regs(3); write_regs(7); _delays.dac_dly_ns = coerced_delay; break; case X300_CLOCK_WHICH_ADC0: case X300_CLOCK_WHICH_ADC1: _lmk04816_regs.CLKout8_9_DDLY = ddly_value; _lmk04816_regs.CLKout8_9_HS = half_shift_en; if (adly_en) { _lmk04816_regs.CLKout8_ADLY_SEL = lmk04816_regs_t::CLKOUT8_ADLY_SEL_D_BOTH; _lmk04816_regs.CLKout9_ADLY_SEL = lmk04816_regs_t::CLKOUT9_ADLY_SEL_D_BOTH; _lmk04816_regs.CLKout8_9_ADLY = adly_value; } else { _lmk04816_regs.CLKout8_ADLY_SEL = lmk04816_regs_t::CLKOUT8_ADLY_SEL_D_PD; _lmk04816_regs.CLKout9_ADLY_SEL = lmk04816_regs_t::CLKOUT9_ADLY_SEL_D_PD; } write_regs(4); write_regs(8); _delays.adc_dly_ns = coerced_delay; break; default: throw uhd::value_error("set_clock_delay: Requested source is invalid."); } //Delays are applied only on a sync event if (resync) sync_clocks(); return coerced_delay; } double get_clock_delay(const x300_clock_which_t which) { switch (which) { case X300_CLOCK_WHICH_FPGA: return _delays.fpga_dly_ns; case X300_CLOCK_WHICH_DB0_RX: case X300_CLOCK_WHICH_DB1_RX: return _delays.db_rx_dly_ns; case X300_CLOCK_WHICH_DB0_TX: case X300_CLOCK_WHICH_DB1_TX: return _delays.db_tx_dly_ns; case X300_CLOCK_WHICH_DAC0: case X300_CLOCK_WHICH_DAC1: return _delays.dac_dly_ns; case X300_CLOCK_WHICH_ADC0: case X300_CLOCK_WHICH_ADC1: return _delays.adc_dly_ns; default: throw uhd::value_error("get_clock_delay: Requested source is invalid."); } } private: void init() { /* The X3xx has two primary rates. The first is the * _system_ref_rate, which is sourced from the "clock_source"/"value" field * of the property tree, and whose value can be 10e6, 30.72e6, or 200e6. * The _system_ref_rate is the input to the clocking system, and * what comes out is a disciplined master clock running at the * _master_clock_rate. As such, only certain combinations of * system reference rates and master clock rates are supported. * Additionally, a subset of these will operate in "zero delay" mode. */ enum opmode_t { INVALID, m10M_200M_NOZDEL, // used for debug purposes only m10M_200M_ZDEL, // Normal mode m30_72M_184_32M_ZDEL, // LTE with external ref, aka CPRI Mode m10M_184_32M_NOZDEL, // LTE with 10 MHz ref m10M_120M_ZDEL }; // NI USRP 120 MHz Clocking /* The default clocking mode is 10MHz reference generating a 200 MHz master * clock, in zero-delay mode. */ opmode_t clocking_mode = INVALID; if (math::frequencies_are_equal(_system_ref_rate, 10e6)) { if (math::frequencies_are_equal(_master_clock_rate, 184.32e6)) { /* 10MHz reference, 184.32 MHz master clock out, NOT Zero Delay. */ clocking_mode = m10M_184_32M_NOZDEL; } else if (math::frequencies_are_equal(_master_clock_rate, 200e6)) { /* 10MHz reference, 200 MHz master clock out, Zero Delay */ clocking_mode = m10M_200M_ZDEL; } else if (math::frequencies_are_equal(_master_clock_rate, 120e6)) { /* 10MHz reference, 120 MHz master clock rate, Zero Delay */ clocking_mode = m10M_120M_ZDEL; } else { throw uhd::runtime_error(str( boost::format("Invalid master clock rate: %.2f MHz.\n" "Valid master clock rates when using a %f MHz reference clock are:\n" "120 MHz, 184.32 MHz and 200 MHz.") % (_master_clock_rate / 1e6) % (_system_ref_rate / 1e6) )); } } else if (math::frequencies_are_equal(_system_ref_rate, 30.72e6)) { if (math::frequencies_are_equal(_master_clock_rate, 184.32e6)) { /* 30.72MHz reference, 184.32 MHz master clock out, Zero Delay */ clocking_mode = m30_72M_184_32M_ZDEL; } else { throw uhd::runtime_error(str( boost::format("Invalid master clock rate: %.2f MHz.\n" "Valid master clock rate when using a %.2f MHz reference clock is: 184.32 MHz.") % (_master_clock_rate / 1e6) % (_system_ref_rate / 1e6) )); } } else { throw uhd::runtime_error(str( boost::format("Invalid system reference rate: %.2f MHz.\nValid reference frequencies are: 10 MHz, 30.72 MHz.") % (_system_ref_rate / 1e6) )); } UHD_ASSERT_THROW(clocking_mode != INVALID); // For 200 MHz output, the VCO is run at 2400 MHz // For the LTE/CPRI rate of 184.32 MHz, the VCO runs at 2580.48 MHz // Note: PLL2 N2 prescaler is enabled for all cases // PLL2 reference doubler is enabled for all cases /* All LMK04816 settings are from the LMK datasheet for our clocking * architecture. Please refer to the datasheet for more information. */ switch (clocking_mode) { case m10M_200M_NOZDEL: _vco_freq = 2400e6; _lmk04816_regs.MODE = lmk04816_regs_t::MODE_DUAL_INT; // PLL1 - 2 MHz compare frequency _lmk04816_regs.PLL1_N_28 = 48; _lmk04816_regs.PLL1_R_27 = 5; _lmk04816_regs.PLL1_CP_GAIN_27 = lmk04816_regs_t::PLL1_CP_GAIN_27_100UA; // PLL2 - 48 MHz compare frequency _lmk04816_regs.PLL2_N_30 = 25; _lmk04816_regs.PLL2_P_30 = lmk04816_regs_t::PLL2_P_30_DIV_2A; _lmk04816_regs.PLL2_R_28 = 4; _lmk04816_regs.PLL2_CP_GAIN_26 = lmk04816_regs_t::PLL2_CP_GAIN_26_3200UA; break; case m10M_200M_ZDEL: _vco_freq = 2400e6; _lmk04816_regs.MODE = lmk04816_regs_t::MODE_DUAL_INT_ZER_DELAY; // PLL1 - 2 MHz compare frequency _lmk04816_regs.PLL1_N_28 = 5; _lmk04816_regs.PLL1_R_27 = 5; _lmk04816_regs.PLL1_CP_GAIN_27 = lmk04816_regs_t::PLL1_CP_GAIN_27_1600UA; // PLL2 - 96 MHz compare frequency _lmk04816_regs.PLL2_N_30 = 5; _lmk04816_regs.PLL2_P_30 = lmk04816_regs_t::PLL2_P_30_DIV_5; _lmk04816_regs.PLL2_R_28 = 2; if(_hw_rev <= 4) _lmk04816_regs.PLL2_CP_GAIN_26 = lmk04816_regs_t::PLL2_CP_GAIN_26_1600UA; else _lmk04816_regs.PLL2_CP_GAIN_26 = lmk04816_regs_t::PLL2_CP_GAIN_26_400UA; break; case m30_72M_184_32M_ZDEL: _vco_freq = 2580.48e6; _lmk04816_regs.MODE = lmk04816_regs_t::MODE_DUAL_INT_ZER_DELAY; // PLL1 - 2.048 MHz compare frequency _lmk04816_regs.PLL1_N_28 = 15; _lmk04816_regs.PLL1_R_27 = 15; _lmk04816_regs.PLL1_CP_GAIN_27 = lmk04816_regs_t::PLL1_CP_GAIN_27_100UA; // PLL2 - 7.68 MHz compare frequency _lmk04816_regs.PLL2_N_30 = 168; _lmk04816_regs.PLL2_P_30 = lmk04816_regs_t::PLL2_P_30_DIV_2A; _lmk04816_regs.PLL2_R_28 = 25; _lmk04816_regs.PLL2_CP_GAIN_26 = lmk04816_regs_t::PLL2_CP_GAIN_26_3200UA; _lmk04816_regs.PLL2_R3_LF = lmk04816_regs_t::PLL2_R3_LF_1KILO_OHM; _lmk04816_regs.PLL2_C3_LF = lmk04816_regs_t::PLL2_C3_LF_39PF; _lmk04816_regs.PLL2_R4_LF = lmk04816_regs_t::PLL2_R4_LF_1KILO_OHM; _lmk04816_regs.PLL2_C4_LF = lmk04816_regs_t::PLL2_C4_LF_34PF; break; case m10M_184_32M_NOZDEL: _vco_freq = 2580.48e6; _lmk04816_regs.MODE = lmk04816_regs_t::MODE_DUAL_INT; // PLL1 - 2 MHz compare frequency _lmk04816_regs.PLL1_N_28 = 48; _lmk04816_regs.PLL1_R_27 = 5; _lmk04816_regs.PLL1_CP_GAIN_27 = lmk04816_regs_t::PLL1_CP_GAIN_27_100UA; // PLL2 - 7.68 MHz compare frequency _lmk04816_regs.PLL2_N_30 = 168; _lmk04816_regs.PLL2_P_30 = lmk04816_regs_t::PLL2_P_30_DIV_2A; _lmk04816_regs.PLL2_R_28 = 25; _lmk04816_regs.PLL2_CP_GAIN_26 = lmk04816_regs_t::PLL2_CP_GAIN_26_3200UA; _lmk04816_regs.PLL2_R3_LF = lmk04816_regs_t::PLL2_R3_LF_4KILO_OHM; _lmk04816_regs.PLL2_C3_LF = lmk04816_regs_t::PLL2_C3_LF_39PF; _lmk04816_regs.PLL2_R4_LF = lmk04816_regs_t::PLL2_R4_LF_1KILO_OHM; _lmk04816_regs.PLL2_C4_LF = lmk04816_regs_t::PLL2_C4_LF_71PF; break; case m10M_120M_ZDEL: _vco_freq = 2400e6; _lmk04816_regs.MODE = lmk04816_regs_t::MODE_DUAL_INT_ZER_DELAY; // PLL1 - 2 MHz compare frequency _lmk04816_regs.PLL1_N_28 = 5; _lmk04816_regs.PLL1_R_27 = 5; _lmk04816_regs.PLL1_CP_GAIN_27 = lmk04816_regs_t::PLL1_CP_GAIN_27_100UA; // PLL2 - 96 MHz compare frequency _lmk04816_regs.PLL2_N_30 = 5; _lmk04816_regs.PLL2_P_30 = lmk04816_regs_t::PLL2_P_30_DIV_5; _lmk04816_regs.PLL2_R_28 = 2; if(_hw_rev <= 4) _lmk04816_regs.PLL2_CP_GAIN_26 = lmk04816_regs_t::PLL2_CP_GAIN_26_1600UA; else _lmk04816_regs.PLL2_CP_GAIN_26 = lmk04816_regs_t::PLL2_CP_GAIN_26_400UA; break; default: UHD_THROW_INVALID_CODE_PATH(); break; }; uint16_t master_clock_div = static_cast( std::ceil(_vco_freq / _master_clock_rate)); uint16_t dboard_div = static_cast( std::ceil(_vco_freq / _dboard_clock_rate)); /* Reset the LMK clock controller. */ _lmk04816_regs.RESET = lmk04816_regs_t::RESET_RESET; this->write_regs(0); _lmk04816_regs.RESET = lmk04816_regs_t::RESET_NO_RESET; this->write_regs(0); /* Initial power-up */ _lmk04816_regs.CLKout0_1_PD = lmk04816_regs_t::CLKOUT0_1_PD_POWER_UP; this->write_regs(0); _lmk04816_regs.CLKout0_1_DIV = master_clock_div; this->write_regs(0); // Register 1 _lmk04816_regs.CLKout2_3_PD = lmk04816_regs_t::CLKOUT2_3_PD_POWER_UP; _lmk04816_regs.CLKout2_3_DIV = dboard_div; // Register 2 _lmk04816_regs.CLKout4_5_PD = lmk04816_regs_t::CLKOUT4_5_PD_POWER_UP; _lmk04816_regs.CLKout4_5_DIV = dboard_div; // Register 3 _lmk04816_regs.CLKout6_7_DIV = master_clock_div; _lmk04816_regs.CLKout6_7_OSCin_Sel = lmk04816_regs_t::CLKOUT6_7_OSCIN_SEL_VCO; // Register 4 _lmk04816_regs.CLKout8_9_DIV = master_clock_div; // Register 5 _lmk04816_regs.CLKout10_11_PD = lmk04816_regs_t::CLKOUT10_11_PD_NORMAL; _lmk04816_regs.CLKout10_11_DIV = static_cast(std::ceil(_vco_freq / _system_ref_rate)); // Register 6 _lmk04816_regs.CLKout0_TYPE = lmk04816_regs_t::CLKOUT0_TYPE_LVDS; //FPGA _lmk04816_regs.CLKout1_TYPE = lmk04816_regs_t::CLKOUT1_TYPE_P_DOWN; //CPRI feedback clock, use LVDS _lmk04816_regs.CLKout2_TYPE = lmk04816_regs_t::CLKOUT2_TYPE_LVPECL_700MVPP; //DB_0_RX _lmk04816_regs.CLKout3_TYPE = lmk04816_regs_t::CLKOUT3_TYPE_LVPECL_700MVPP; //DB_1_RX // Register 7 _lmk04816_regs.CLKout4_TYPE = lmk04816_regs_t::CLKOUT4_TYPE_LVPECL_700MVPP; //DB_1_TX _lmk04816_regs.CLKout5_TYPE = lmk04816_regs_t::CLKOUT5_TYPE_LVPECL_700MVPP; //DB_0_TX _lmk04816_regs.CLKout6_TYPE = lmk04816_regs_t::CLKOUT6_TYPE_LVPECL_700MVPP; //DB0_DAC _lmk04816_regs.CLKout7_TYPE = lmk04816_regs_t::CLKOUT7_TYPE_LVPECL_700MVPP; //DB1_DAC _lmk04816_regs.CLKout8_TYPE = lmk04816_regs_t::CLKOUT8_TYPE_LVPECL_700MVPP; //DB0_ADC // Register 8 _lmk04816_regs.CLKout9_TYPE = lmk04816_regs_t::CLKOUT9_TYPE_LVPECL_700MVPP; //DB1_ADC _lmk04816_regs.CLKout10_TYPE = lmk04816_regs_t::CLKOUT10_TYPE_LVDS; //REF_CLKOUT _lmk04816_regs.CLKout11_TYPE = lmk04816_regs_t::CLKOUT11_TYPE_P_DOWN; //Debug header, use LVPECL // Register 10 _lmk04816_regs.EN_OSCout0 = lmk04816_regs_t::EN_OSCOUT0_DISABLED; //Debug header _lmk04816_regs.FEEDBACK_MUX = 5; //use output 10 (REF OUT) for feedback _lmk04816_regs.EN_FEEDBACK_MUX = lmk04816_regs_t::EN_FEEDBACK_MUX_ENABLED; // Register 11 // MODE set in individual cases above _lmk04816_regs.SYNC_QUAL = lmk04816_regs_t::SYNC_QUAL_FB_MUX; _lmk04816_regs.EN_SYNC = lmk04816_regs_t::EN_SYNC_ENABLE; _lmk04816_regs.NO_SYNC_CLKout0_1 = lmk04816_regs_t::NO_SYNC_CLKOUT0_1_CLOCK_XY_SYNC; _lmk04816_regs.NO_SYNC_CLKout2_3 = lmk04816_regs_t::NO_SYNC_CLKOUT2_3_CLOCK_XY_SYNC; _lmk04816_regs.NO_SYNC_CLKout4_5 = lmk04816_regs_t::NO_SYNC_CLKOUT4_5_CLOCK_XY_SYNC; _lmk04816_regs.NO_SYNC_CLKout6_7 = lmk04816_regs_t::NO_SYNC_CLKOUT6_7_CLOCK_XY_SYNC; _lmk04816_regs.NO_SYNC_CLKout8_9 = lmk04816_regs_t::NO_SYNC_CLKOUT8_9_CLOCK_XY_SYNC; _lmk04816_regs.NO_SYNC_CLKout10_11 = lmk04816_regs_t::NO_SYNC_CLKOUT10_11_CLOCK_XY_SYNC; _lmk04816_regs.SYNC_TYPE = lmk04816_regs_t::SYNC_TYPE_INPUT; // Register 12 _lmk04816_regs.LD_MUX = lmk04816_regs_t::LD_MUX_BOTH; /* Input Clock Configurations */ // Register 13 _lmk04816_regs.EN_CLKin0 = lmk04816_regs_t::EN_CLKIN0_NO_VALID_USE; // This is not connected _lmk04816_regs.EN_CLKin2 = lmk04816_regs_t::EN_CLKIN2_NO_VALID_USE; // Used only for CPRI _lmk04816_regs.Status_CLKin1_MUX = lmk04816_regs_t::STATUS_CLKIN1_MUX_UWIRE_RB; _lmk04816_regs.CLKin_Select_MODE = lmk04816_regs_t::CLKIN_SELECT_MODE_CLKIN1_MAN; _lmk04816_regs.HOLDOVER_MUX = lmk04816_regs_t::HOLDOVER_MUX_PLL1_R; // Register 14 _lmk04816_regs.Status_CLKin1_TYPE = lmk04816_regs_t::STATUS_CLKIN1_TYPE_OUT_PUSH_PULL; _lmk04816_regs.Status_CLKin0_TYPE = lmk04816_regs_t::STATUS_CLKIN0_TYPE_OUT_PUSH_PULL; // Register 26 // PLL2_CP_GAIN_26 set above in individual cases _lmk04816_regs.PLL2_CP_POL_26 = lmk04816_regs_t::PLL2_CP_POL_26_NEG_SLOPE; _lmk04816_regs.EN_PLL2_REF_2X = lmk04816_regs_t::EN_PLL2_REF_2X_DOUBLED_FREQ_REF; // Register 27 // PLL1_CP_GAIN_27 set in individual cases above // PLL1_R_27 set in the individual cases above // Register 28 // PLL1_N_28 and PLL2_R_28 are set in the individual cases above // Register 29 _lmk04816_regs.PLL2_N_CAL_29 = _lmk04816_regs.PLL2_N_30; // N_CAL should always match N _lmk04816_regs.OSCin_FREQ_29 = lmk04816_regs_t::OSCIN_FREQ_29_63_TO_127MHZ; // Register 30 // PLL2_P_30 set in individual cases above // PLL2_N_30 set in individual cases above if (_hw_rev >= 7) { _delays = X300_REV7_CLK_DELAYS; } else { _delays = X300_REV0_6_CLK_DELAYS; } //Apply delay values set_clock_delay(X300_CLOCK_WHICH_FPGA, _delays.fpga_dly_ns, false); set_clock_delay(X300_CLOCK_WHICH_DB0_RX, _delays.db_rx_dly_ns, false); //Sets both Ch0 and Ch1 set_clock_delay(X300_CLOCK_WHICH_DB0_TX, _delays.db_tx_dly_ns, false); //Sets both Ch0 and Ch1 set_clock_delay(X300_CLOCK_WHICH_ADC0, _delays.adc_dly_ns, false); //Sets both Ch0 and Ch1 set_clock_delay(X300_CLOCK_WHICH_DAC0, _delays.dac_dly_ns, false); //Sets both Ch0 and Ch1 /* Write the configuration values into the LMK */ for (size_t i = 1; i <= 16; ++i) { this->write_regs(i); } for (size_t i = 24; i <= 31; ++i) { this->write_regs(i); } this->sync_clocks(); } const spi_iface::sptr _spiface; const size_t _slaveno; const size_t _hw_rev; const double _master_clock_rate; const double _dboard_clock_rate; const double _system_ref_rate; lmk04816_regs_t _lmk04816_regs; double _vco_freq; x300_clk_delays _delays; }; x300_clock_ctrl::sptr x300_clock_ctrl::make(uhd::spi_iface::sptr spiface, const size_t slaveno, const size_t hw_rev, const double master_clock_rate, const double dboard_clock_rate, const double system_ref_rate) { return sptr(new x300_clock_ctrl_impl(spiface, slaveno, hw_rev, master_clock_rate, dboard_clock_rate, system_ref_rate)); }