portapack-mayhem/firmware/application/receiver_model.cpp

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/*
* Copyright (C) 2014 Jared Boone, ShareBrained Technology, Inc.
* Copyright (C) 2023 Kyle Reed
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*
* 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 "receiver_model.hpp"
#include "baseband_api.hpp"
#include "portapack_persistent_memory.hpp"
#include "hackrf_gpio.hpp"
#include "portapack.hpp"
#include "radio.hpp"
#include "audio.hpp"
#include "dsp_fir_taps.hpp"
#include "dsp_iir.hpp"
#include "dsp_iir_config.hpp"
#include "utility.hpp"
using namespace hackrf::one;
using namespace portapack;
namespace {
static constexpr std::array<baseband::AMConfig, 5> am_configs{{
// we config here all the non COMMON parameters to each AM modulation type in RX.
{taps_9k0_decim_2, taps_9k0_dsb_channel, AMConfigureMessage::Modulation::DSB}, // AM DSB-C BW 9khz (+-4k5) commercial EU bandwidth .
{taps_6k0_decim_2, taps_6k0_dsb_channel, AMConfigureMessage::Modulation::DSB}, // AM DSB-C BW 6khz (+-3k0) narrow AM , ham equipments.
{taps_6k0_decim_2, taps_2k8_usb_channel, AMConfigureMessage::Modulation::SSB}, // SSB USB BW 2K8 (+ 2K8)
{taps_6k0_decim_2, taps_2k8_lsb_channel, AMConfigureMessage::Modulation::SSB}, // SSB LSB BW 2K8 (- 2K8)
{taps_6k0_decim_2, taps_0k7_usb_channel, AMConfigureMessage::Modulation::SSB}, // SSB USB BW 0K7 (+ 0K7) used to get audio tone from CW Morse, assuming tx shifted +700hz aprox
}};
static constexpr std::array<baseband::NBFMConfig, 3> nbfm_configs{{
{taps_4k25_decim_0, taps_4k25_decim_1, taps_4k25_channel, 2500},
{taps_11k0_decim_0, taps_11k0_decim_1, taps_11k0_channel, 2500},
{taps_16k0_decim_0, taps_16k0_decim_1, taps_16k0_channel, 5000},
}};
static constexpr std::array<baseband::WFMConfig, 3> wfm_configs{{
{taps_200k_wfm_decim_0, taps_200k_wfm_decim_1},
{taps_180k_wfm_decim_0, taps_180k_wfm_decim_1},
{taps_40k_wfm_decim_0, taps_40k_wfm_decim_1},
}};
} /* namespace */
rf::Frequency ReceiverModel::target_frequency() const {
return persistent_memory::target_frequency();
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}
void ReceiverModel::set_target_frequency(rf::Frequency f) {
persistent_memory::set_target_frequency(f);
update_tuning_frequency();
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}
uint32_t ReceiverModel::baseband_bandwidth() const {
return settings_.baseband_bandwidth;
}
void ReceiverModel::set_baseband_bandwidth(uint32_t v) {
settings_.baseband_bandwidth = v;
update_baseband_bandwidth();
}
uint32_t ReceiverModel::sampling_rate() const {
return settings_.sampling_rate;
}
void ReceiverModel::set_sampling_rate(uint32_t v) {
settings_.sampling_rate = v;
update_sampling_rate();
}
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rf::Frequency ReceiverModel::frequency_step() const {
return settings_.frequency_step;
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}
void ReceiverModel::set_frequency_step(rf::Frequency f) {
settings_.frequency_step = f;
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}
uint8_t ReceiverModel::lna() const {
return settings_.lna_gain_db;
}
void ReceiverModel::set_lna(uint8_t v_db) {
settings_.lna_gain_db = v_db;
update_lna();
}
uint8_t ReceiverModel::vga() const {
return settings_.vga_gain_db;
}
void ReceiverModel::set_vga(uint8_t v_db) {
settings_.vga_gain_db = v_db;
update_vga();
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}
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bool ReceiverModel::rf_amp() const {
return settings_.rf_amp;
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}
void ReceiverModel::set_rf_amp(bool enabled) {
settings_.rf_amp = enabled;
update_rf_amp();
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}
ReceiverModel::Mode ReceiverModel::modulation() const {
return settings_.mode;
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}
void ReceiverModel::set_modulation(Mode v) {
settings_.mode = v;
update_modulation();
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}
uint8_t ReceiverModel::am_configuration() const {
return settings_.am_config_index;
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}
void ReceiverModel::set_am_configuration(uint8_t n) {
if (n < am_configs.size()) {
settings_.am_config_index = n;
update_modulation();
}
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}
uint8_t ReceiverModel::nbfm_configuration() const {
return settings_.nbfm_config_index;
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}
void ReceiverModel::set_nbfm_configuration(uint8_t n) {
if (n < nbfm_configs.size()) {
settings_.nbfm_config_index = n;
update_modulation();
}
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}
uint8_t ReceiverModel::wfm_configuration() const {
return settings_.wfm_config_index;
}
void ReceiverModel::set_wfm_configuration(uint8_t n) {
if (n < wfm_configs.size()) {
settings_.wfm_config_index = n;
update_modulation();
}
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}
uint8_t ReceiverModel::squelch_level() const {
return settings_.squelch_level;
}
void ReceiverModel::set_squelch_level(uint8_t v) {
settings_.squelch_level = v;
update_modulation();
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}
void ReceiverModel::set_antenna_bias() {
update_antenna_bias();
}
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volume_t ReceiverModel::headphone_volume() const {
return persistent_memory::headphone_volume();
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}
void ReceiverModel::set_headphone_volume(volume_t v) {
persistent_memory::set_headphone_volume(v);
update_headphone_volume();
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}
uint8_t ReceiverModel::normalized_headphone_volume() const {
auto db = (headphone_volume() - audio::headphone::volume_range().max).decibel();
return clip<uint8_t>(db + 99, 0, 99);
}
void ReceiverModel::set_normalized_headphone_volume(uint8_t v) {
// TODO: Linear map instead to ensure 0 is minimal value or fix volume_range_t::normalize.
v = clip<uint8_t>(v, 0, 99);
auto new_volume = volume_t::decibel(v - 99) + audio::headphone::volume_range().max;
set_headphone_volume(new_volume);
}
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void ReceiverModel::enable() {
enabled_ = true;
radio::set_direction(rf::Direction::Receive);
update_tuning_frequency();
update_antenna_bias();
update_rf_amp();
update_lna();
update_vga();
update_baseband_bandwidth();
update_sampling_rate();
update_modulation();
// TODO: maybe not the perfect place for this, but it's reasonable.
update_headphone_volume();
led_rx.on();
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}
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void ReceiverModel::disable() {
enabled_ = false;
// TODO: Responsibility for enabling/disabling the radio is muddy.
// Some happens in ReceiverModel, some inside radio namespace.
radio::disable();
led_rx.off();
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}
void ReceiverModel::initialize() {
settings_ = settings_t{};
}
void ReceiverModel::set_configuration_without_update(
Mode new_mode,
rf::Frequency new_frequency_step,
size_t new_am_config_index,
size_t new_nbfm_config_index,
size_t new_wfm_config_index,
uint8_t new_squelch_level) {
settings_.mode = new_mode;
settings_.frequency_step = new_frequency_step;
settings_.am_config_index = new_am_config_index;
settings_.nbfm_config_index = new_nbfm_config_index;
settings_.wfm_config_index = new_wfm_config_index;
settings_.squelch_level = new_squelch_level;
}
void ReceiverModel::configure_from_app_settings(
const app_settings::AppSettings& settings) {
settings_.baseband_bandwidth = settings.baseband_bandwidth;
settings_.sampling_rate = settings.sampling_rate;
settings_.lna_gain_db = settings.lna;
settings_.vga_gain_db = settings.vga;
settings_.rf_amp = settings.rx_amp;
settings_.squelch_level = settings.squelch;
}
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int32_t ReceiverModel::tuning_offset() {
if ((modulation() == Mode::SpectrumAnalysis)) {
return 0;
} else {
return -(sampling_rate() / 4);
}
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}
void ReceiverModel::update_tuning_frequency() {
// TODO: use positive offset if freq < offset.
radio::set_tuning_frequency(target_frequency() + tuning_offset());
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}
void ReceiverModel::update_baseband_bandwidth() {
radio::set_baseband_filter_bandwidth_rx(baseband_bandwidth());
}
void ReceiverModel::update_sampling_rate() {
// TODO: Move more low-level radio control stuff to M4. It'll enable tighter
// synchronization for things like wideband (sweeping) spectrum analysis, and
// protocols that need quick RX/TX turn-around.
// Disabling baseband while changing sampling rates seems like a good idea...
radio::set_baseband_rate(sampling_rate());
update_tuning_frequency();
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}
void ReceiverModel::update_lna() {
radio::set_lna_gain(lna());
}
void ReceiverModel::update_vga() {
radio::set_vga_gain(vga());
}
void ReceiverModel::update_rf_amp() {
radio::set_rf_amp(rf_amp());
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}
void ReceiverModel::update_modulation() {
switch (modulation()) {
default:
case Mode::AMAudio:
update_am_configuration();
break;
case Mode::NarrowbandFMAudio:
update_nbfm_configuration();
break;
case Mode::WidebandFMAudio:
update_wfm_configuration();
break;
case Mode::SpectrumAnalysis:
case Mode::Capture:
break;
}
}
void ReceiverModel::update_am_configuration() {
am_configs[am_configuration()].apply();
}
void ReceiverModel::update_nbfm_configuration() {
nbfm_configs[nbfm_configuration()].apply(squelch_level());
}
void ReceiverModel::update_wfm_configuration() {
wfm_configs[wfm_configuration()].apply();
}
void ReceiverModel::update_antenna_bias() {
if (enabled_)
radio::set_antenna_bias(portapack::get_antenna_bias());
}
void ReceiverModel::update_headphone_volume() {
audio::headphone::set_volume(headphone_volume());
}