portapack-mayhem/firmware/application/radio.cpp
Brumi-2021 b8073bca0f
Adding_TX_IQ_phase_Calibration_to_Mic_App (#1843)
* Adding_TX_IQ_phase_Calibration_to_Mic_App

* Adding_persistent_CAL_data_and_correct_init_data
2024-02-03 17:57:45 -06:00

313 lines
9.8 KiB
C++

/*
* Copyright (C) 2014 Jared Boone, ShareBrained Technology, Inc.
*
* This file is part of PortaPack.
*
* 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 2, 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; see the file COPYING. If not, write to
* the Free Software Foundation, Inc., 51 Franklin Street,
* Boston, MA 02110-1301, USA.
*/
#include "radio.hpp"
#include "rf_path.hpp"
#include "rffc507x.hpp"
#include "max2837.hpp"
#include "max2839.hpp"
#include "max5864.hpp"
#include "baseband_cpld.hpp"
#include "tuning.hpp"
#include "spi_arbiter.hpp"
#include "hackrf_hal.hpp"
#include "hackrf_gpio.hpp"
using namespace hackrf::one;
#include "cpld_update.hpp"
#include "portapack.hpp"
#include "portapack_persistent_memory.hpp"
/* Direct access to the radio. Setting values incorrectly can damage
* the device. Applications should use ReceiverModel or TransmitterModel
* instead of calling these functions directly. */
namespace radio {
static constexpr uint32_t ssp1_cpsr = 2;
static constexpr uint32_t ssp_scr(
const float pclk_f,
const uint32_t cpsr,
const float spi_f) {
return static_cast<uint8_t>(pclk_f / cpsr / spi_f - 1);
}
static constexpr SPIConfig ssp_config_max283x = {
.end_cb = NULL,
.ssport = gpio_max283x_select.port(),
.sspad = gpio_max283x_select.pad(),
.cr0 =
CR0_CLOCKRATE(ssp_scr(ssp1_pclk_f, ssp1_cpsr, max283x_spi_f) + 3) | CR0_FRFSPI | CR0_DSS16BIT,
.cpsr = ssp1_cpsr,
};
static constexpr SPIConfig ssp_config_max5864 = {
.end_cb = NULL,
.ssport = gpio_max5864_select.port(),
.sspad = gpio_max5864_select.pad(),
.cr0 =
CR0_CLOCKRATE(ssp_scr(ssp1_pclk_f, ssp1_cpsr, max5864_spi_f)) | CR0_FRFSPI | CR0_DSS8BIT,
.cpsr = ssp1_cpsr,
};
static spi::arbiter::Arbiter ssp1_arbiter(portapack::ssp1);
static spi::arbiter::Target ssp1_target_max283x{
ssp1_arbiter,
ssp_config_max283x};
static spi::arbiter::Target ssp1_target_max5864{
ssp1_arbiter,
ssp_config_max5864};
static rf::path::Path rf_path;
rffc507x::RFFC507x first_if;
max283x::MAX283x* second_if;
max2837::MAX2837 second_if_max2837{ssp1_target_max283x};
max2839::MAX2839 second_if_max2839{ssp1_target_max283x};
static max5864::MAX5864 baseband_codec{ssp1_target_max5864};
static baseband::CPLD baseband_cpld;
// load_sram() is called at boot in portapack.cpp, including verify CPLD part, so default direction is Receive
static rf::Direction direction{rf::Direction::Receive};
static bool baseband_invert = false;
static bool mixer_invert = false;
void init() {
if (hackrf_r9) {
gpio_r9_not_ant_pwr.write(1);
gpio_r9_not_ant_pwr.output();
}
rf_path.init();
first_if.init();
second_if = hackrf_r9
? (max283x::MAX283x*)&second_if_max2839
: (max283x::MAX283x*)&second_if_max2837;
second_if->init();
baseband_codec.init();
baseband_cpld.init();
}
void set_direction(const rf::Direction new_direction) {
/* TODO: Refactor all the various "Direction" enumerations into one. */
/* TODO: Only make changes if direction changes, but beware of clock enabling. */
// Prevents ghosting when switching back to RX from TX mode.
hackrf::cpld::load_sram_no_verify();
direction = new_direction;
if (hackrf_r9) {
/*
* HackRF One r9 inverts analog baseband only for RX. Previous hardware
* revisions inverted analog baseband for neither direction because of
* compensation in the CPLD. If we ever simplify the CPLD to handle RX
* and TX the same way, we will need to update this baseband_invert
* logic.
*/
baseband_invert = (direction == rf::Direction::Receive);
} else {
/*
* Analog baseband is inverted in RX but not TX. The RX inversion is
* corrected by the CPLD, but future hardware or CPLD changes may
* change this for either or both directions. For a given hardware+CPLD
* platform, baseband inversion is set here for RX and/or TX. Spectrum
* inversion resulting from the mixer is tracked separately according
* to the tuning configuration. We ask the CPLD to apply a correction
* for the total inversion.
*/
baseband_invert = false;
}
baseband_cpld.set_invert(mixer_invert ^ baseband_invert);
second_if->set_mode((direction == rf::Direction::Transmit) ? max283x::Mode::Transmit : max283x::Mode::Receive);
rf_path.set_direction(direction);
baseband_codec.set_mode((direction == rf::Direction::Transmit) ? max5864::Mode::Transmit : max5864::Mode::Receive);
if (direction == rf::Direction::Receive)
led_rx.on();
else
led_tx.on();
}
bool set_tuning_frequency(const rf::Frequency frequency) {
rf::Frequency final_frequency = frequency;
// if converter feature is enabled
if (portapack::persistent_memory::config_converter()) {
// downconvert
if (portapack::persistent_memory::config_updown_converter()) {
final_frequency = frequency - portapack::persistent_memory::config_converter_freq();
} else // upconvert
{
final_frequency = frequency + portapack::persistent_memory::config_converter_freq();
}
}
// apply frequency correction
if (direction == rf::Direction::Transmit) {
if (portapack::persistent_memory::config_freq_tx_correction_updown()) // tx freq correction down
final_frequency = final_frequency - portapack::persistent_memory::config_freq_tx_correction();
else // tx freq correction up
final_frequency = final_frequency + portapack::persistent_memory::config_freq_tx_correction();
} else {
if (portapack::persistent_memory::config_freq_rx_correction_updown()) // rx freq correction down
final_frequency = final_frequency - portapack::persistent_memory::config_freq_rx_correction();
else // rx freq correction up
final_frequency = final_frequency + portapack::persistent_memory::config_freq_rx_correction();
}
const auto tuning_config = tuning::config::create(final_frequency);
if (tuning_config.is_valid()) {
first_if.disable();
// Program first local oscillator frequency (if there is one) into RFFC507x
if (tuning_config.first_lo_frequency) {
first_if.set_frequency(tuning_config.first_lo_frequency);
first_if.enable();
}
// Program second local oscillator frequency into MAX283x
const auto result_second_if = second_if->set_frequency(tuning_config.second_lo_frequency);
rf_path.set_band(tuning_config.rf_path_band);
mixer_invert = tuning_config.mixer_invert;
baseband_cpld.set_invert(mixer_invert ^ baseband_invert);
return result_second_if;
} else {
return false;
}
}
void set_rf_amp(const bool rf_amp) {
rf_path.set_rf_amp(rf_amp);
if (direction == rf::Direction::Transmit) {
if (rf_amp)
led_tx.on();
else
led_tx.off();
}
}
void set_lna_gain(const int_fast8_t db) {
second_if->set_lna_gain(db);
}
void set_vga_gain(const int_fast8_t db) {
second_if->set_vga_gain(db);
}
void set_tx_gain(const int_fast8_t db) {
second_if->set_tx_vga_gain(db);
}
void set_baseband_filter_bandwidth_rx(const uint32_t bandwidth_minimum) {
second_if->set_lpf_rf_bandwidth_rx(bandwidth_minimum);
}
void set_baseband_filter_bandwidth_tx(const uint32_t bandwidth_minimum) {
second_if->set_lpf_rf_bandwidth_tx(bandwidth_minimum);
}
void set_baseband_rate(const uint32_t rate) {
portapack::clock_manager.set_sampling_frequency(rate);
// TODO: actually set baseband too?
}
void set_antenna_bias(const bool on) {
/* Pull MOSFET gate low to turn on antenna bias. */
if (hackrf_r9) {
gpio_r9_not_ant_pwr.write(on ? 0 : 1);
} else {
first_if.set_gpo1(on ? 0 : 1);
}
}
void set_tx_max283x_iq_phase_calibration(const size_t v) {
second_if->set_tx_LO_iq_phase_calibration(v);
}
/*void enable(Configuration configuration) {
configure(configuration);
}
void configure(Configuration configuration) {
set_tuning_frequency(configuration.tuning_frequency);
set_rf_amp(configuration.rf_amp);
set_lna_gain(configuration.lna_gain);
set_vga_gain(configuration.vga_gain);
set_baseband_rate(configuration.baseband_rate);
set_baseband_filter_bandwidth(configuration.baseband_filter_bandwidth);
set_direction(configuration.direction);
}*/
void disable() {
set_antenna_bias(false);
baseband_codec.set_mode(max5864::Mode::Shutdown);
second_if->set_mode(max2837::Mode::Standby);
first_if.disable();
set_rf_amp(false);
led_rx.off();
led_tx.off();
}
namespace debug {
namespace first_if {
uint32_t register_read(const size_t register_number) {
return radio::first_if.read(register_number);
}
void register_write(const size_t register_number, uint32_t value) {
radio::first_if.write(register_number, value);
}
} /* namespace first_if */
namespace second_if {
uint32_t register_read(const size_t register_number) {
return radio::second_if->read(register_number);
}
void register_write(const size_t register_number, uint32_t value) {
radio::second_if->write(register_number, value);
}
int8_t temp_sense() {
return radio::second_if->temp_sense();
}
} /* namespace second_if */
} /* namespace debug */
} /* namespace radio */