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https://github.com/eried/portapack-mayhem.git
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033c4e9a5b
* Updated style * Updated files * fixed new line * Updated spacing * File fix WIP * Updated to clang 13 * updated comment style * Removed old comment code
280 lines
8.3 KiB
C++
280 lines
8.3 KiB
C++
/*
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* Copyright (C) 2014 Jared Boone, ShareBrained Technology, Inc.
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*
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* This file is part of PortaPack.
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2, or (at your option)
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* any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; see the file COPYING. If not, write to
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* the Free Software Foundation, Inc., 51 Franklin Street,
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* Boston, MA 02110-1301, USA.
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*/
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#include "rffc507x.hpp"
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#include <array>
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#include "utility.hpp"
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#include "hackrf_hal.hpp"
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#include "hackrf_gpio.hpp"
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using namespace hackrf::one;
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#include "hal.h"
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namespace rffc507x {
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/* Empirical tests indicate no minimum reset pulse width, but the speed
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* of the processor and GPIO probably produce at least 20ns pulse width.
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*/
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constexpr float seconds_during_reset = 1.0e-6;
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constexpr halrtcnt_t ticks_during_reset = (base_m4_clk_f * seconds_during_reset + 1);
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/* Empirical testing indicates >3.5us delay required after reset, before
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* registers can be reliably written. Make it 5us, just for fun. Tests were
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* conducted at high temperatures (with a hair dryer) increased room
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* temperature minimum delay of 2.9us to the requirement above.
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*/
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constexpr float seconds_after_reset = 5.0e-6;
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constexpr halrtcnt_t ticks_after_reset = (base_m4_clk_f * seconds_after_reset + 1);
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constexpr auto reference_frequency = rffc5072_reference_f;
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namespace vco {
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constexpr rf::FrequencyRange range{2700000000, 5400000000};
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} /* namespace vco */
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namespace lo {
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constexpr size_t divider_log2_min = 0;
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constexpr size_t divider_log2_max = 5;
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constexpr size_t divider_min = 1U << divider_log2_min;
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constexpr size_t divider_max = 1U << divider_log2_max;
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constexpr rf::FrequencyRange range{vco::range.minimum / divider_max, vco::range.maximum / divider_min};
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size_t divider_log2(const rf::Frequency lo_frequency) {
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/* TODO: Error */
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/*
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if( lo::range.out_of_range(lo_frequency) ) {
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return;
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}
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*/
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/* Compute LO divider. */
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auto lo_divider_log2 = lo::divider_log2_min;
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auto vco_frequency = lo_frequency;
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while (vco::range.below_range(vco_frequency)) {
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vco_frequency <<= 1;
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lo_divider_log2 += 1;
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}
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return lo_divider_log2;
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}
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} /* namespace lo */
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namespace prescaler {
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constexpr rf::Frequency max_frequency = 1600000000U;
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constexpr size_t divider_log2_min = 1;
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constexpr size_t divider_log2_max = 2;
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constexpr size_t divider_min = 1U << divider_log2_min;
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constexpr size_t divider_max = 1U << divider_log2_max;
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constexpr size_t divider_log2(const rf::Frequency vco_frequency) {
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return (vco_frequency > (prescaler::divider_min * prescaler::max_frequency))
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? prescaler::divider_log2_max
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: prescaler::divider_log2_min;
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}
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} /* namespace prescaler */
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struct SynthConfig {
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const size_t lo_divider_log2;
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const size_t prescaler_divider_log2;
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const uint64_t n_divider_q24;
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static SynthConfig calculate(
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const rf::Frequency lo_frequency) {
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/* RFFC507x frequency synthesizer is is accurate to about 2ppb (two parts
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* per BILLION). There's not much point to worrying about rounding and
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* tuning error, when it amounts to 8Hz at 5GHz!
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*/
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const size_t lo_divider_log2 = lo::divider_log2(lo_frequency);
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const size_t lo_divider = 1U << lo_divider_log2;
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const rf::Frequency vco_frequency = lo_frequency * lo_divider;
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const size_t prescaler_divider_log2 = prescaler::divider_log2(vco_frequency);
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const uint64_t prescaled_lo_q24 = vco_frequency << (24 - prescaler_divider_log2);
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const uint64_t n_divider_q24 = prescaled_lo_q24 / reference_frequency;
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return {
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lo_divider_log2,
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prescaler_divider_log2,
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n_divider_q24,
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};
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}
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};
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/* Readback values, RFFC5072 rev A:
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* 0000: 0x8a01 => dev_id=1000101000000 mrev_id=001
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* 0001: 0x3f7c => lock=0 ct_cal=0111111 cp_cal=011111 ctfail=0 0
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* 0010: 0x806f => v0_cal=10000000 v1_cal=01101111
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* 0011: 0x0000 => rsm_state=00000 f_errflag=00
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* 0100: 0x0000 => vco_count_l=0
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* 0101: 0x0000 => vco_count_h=0
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* 0110: 0xc000 => cal_fbi=1 cal_fbq=1
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* 0111: 0x0000 => vco_sel=0 vco_tc_curve=0
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*/
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void RFFC507x::init() {
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gpio_rffc5072_resetx.set();
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gpio_rffc5072_resetx.output();
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reset();
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_bus.init();
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_dirty.set();
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flush();
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}
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void RFFC507x::reset() {
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/* TODO: Is RESETB pin ignored if sdi_ctrl.sipin=1? Programming guide
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* description of sdi_ctrl.sipin suggests the pin is not ignored.
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*/
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gpio_rffc5072_resetx.clear();
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halPolledDelay(ticks_during_reset);
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gpio_rffc5072_resetx.set();
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halPolledDelay(ticks_after_reset);
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}
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void RFFC507x::flush() {
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if (_dirty) {
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for (size_t i = 0; i < _map.w.size(); i++) {
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if (_dirty[i]) {
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write(i, _map.w[i]);
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}
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}
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_dirty.clear();
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}
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}
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void RFFC507x::write(const address_t reg_num, const spi::reg_t value) {
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_bus.write(reg_num, value);
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}
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spi::reg_t RFFC507x::read(const address_t reg_num) {
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return _bus.read(reg_num);
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}
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void RFFC507x::write(const Register reg, const spi::reg_t value) {
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write(toUType(reg), value);
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}
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spi::reg_t RFFC507x::read(const Register reg) {
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return read(toUType(reg));
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}
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void RFFC507x::flush_one(const Register reg) {
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const auto reg_num = toUType(reg);
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write(reg_num, _map.w[reg_num]);
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_dirty.clear(reg_num);
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}
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void RFFC507x::enable() {
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_map.r.sdi_ctrl.enbl = 1;
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flush_one(Register::SDI_CTRL);
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/* TODO: Reset PLLCPL after CT_CAL? */
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/* TODO: After device is enabled and CT_cal is complete and VCO > 3.2GHz,
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* change prescaler divider to 2, update synthesizer ratio, change
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* lf.pllcpl from 3 to 2.
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*/
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}
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void RFFC507x::disable() {
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_map.r.sdi_ctrl.enbl = 0;
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flush_one(Register::SDI_CTRL);
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}
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void RFFC507x::set_mixer_current(const uint8_t value) {
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/* MIX IDD = 0b000 appears to turn the mixer completely off */
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/* TODO: Adjust mixer current. Graphs in datasheet suggest:
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* MIX_IDD=1 has lowest noise figure (10.1dB vs 13dB @ MIX_IDD=7).
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* MIX_IDD=5 has highest IP3 (24dBm vs 10.3dBm @ MIX_IDD=1).
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* MIX_IDD=5 has highest P1dB (11.8dBm vs 1.5dBm @ MIX_IDD=1).
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* Mixer input impedance ~85 Ohms at MIX_IDD=4.
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* Mixer input impedance inversely proportional to MIX_IDD.
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* Balun balanced (mixer) side is 100 Ohms. Perhaps reduce MIX_IDD
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* a bit to get 100 Ohms from mixer.
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*/
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_map.r.mix_cont.p1mixidd = value;
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_map.r.mix_cont.p2mixidd = value;
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flush_one(Register::MIX_CONT);
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}
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void RFFC507x::set_frequency(const rf::Frequency lo_frequency) {
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const SynthConfig synth_config = SynthConfig::calculate(lo_frequency);
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/* Boost charge pump leakage if VCO frequency > 3.2GHz, indicated by
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* prescaler divider set to 4 (log2=2) instead of 2 (log2=1).
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*/
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if (synth_config.prescaler_divider_log2 == 2) {
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_map.r.lf.pllcpl = 3;
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} else {
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_map.r.lf.pllcpl = 2;
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}
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flush_one(Register::LF);
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_map.r.p2_freq1.p2n = synth_config.n_divider_q24 >> 24;
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_map.r.p2_freq1.p2lodiv = synth_config.lo_divider_log2;
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_map.r.p2_freq1.p2presc = synth_config.prescaler_divider_log2;
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_map.r.p2_freq2.p2nmsb = (synth_config.n_divider_q24 >> 8) & 0xffff;
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_map.r.p2_freq3.p2nlsb = synth_config.n_divider_q24 & 0xff;
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_dirty[Register::P2_FREQ1] = 1;
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_dirty[Register::P2_FREQ2] = 1;
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_dirty[Register::P2_FREQ3] = 1;
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flush();
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}
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void RFFC507x::set_gpo1(const bool new_value) {
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if (new_value) {
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_map.r.gpo.p2gpo |= 1;
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_map.r.gpo.p1gpo |= 1;
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} else {
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_map.r.gpo.p2gpo &= ~1;
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_map.r.gpo.p1gpo &= ~1;
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}
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flush_one(Register::GPO);
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}
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spi::reg_t RFFC507x::readback(const Readback readback) {
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/* TODO: This clobbers the rest of the DEV_CTRL register
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* Time to implement bitfields for registers.
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*/
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_map.r.dev_ctrl.readsel = toUType(readback);
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flush_one(Register::DEV_CTRL);
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return read(Register::READBACK);
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}
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} /* namespace rffc507x */
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