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radio.c
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radio.c
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/* Copyright 2023 Dual Tachyon
* https://github.com/DualTachyon
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "app/app.h"
#include "app/dtmf.h"
#ifdef ENABLE_FMRADIO
#include "app/fm.h"
#endif
#ifdef ENABLE_AM_FIX
#include "am_fix.h"
#endif
#include "audio.h"
#include "board.h"
#include "bsp/dp32g030/gpio.h"
#include "dcs.h"
#include "driver/bk4819.h"
#include "driver/eeprom.h"
#include "driver/gpio.h"
#include "driver/system.h"
#if defined(ENABLE_UART) && defined(ENABLE_UART_DEBUG)
#include "driver/uart.h"
#endif
#include "frequencies.h"
#include "functions.h"
#include "helper/battery.h"
#ifdef ENABLE_MDC1200
#include "mdc1200.h"
#endif
#include "misc.h"
#include "radio.h"
#include "settings.h"
#include "ui/menu.h"
#include "ui/ui.h"
vfo_info_t g_vfo_info[2];
vfo_info_t *g_tx_vfo;
vfo_info_t *g_rx_vfo;
vfo_info_t *g_current_vfo;
dcs_code_type_t g_selected_code_type;
dcs_code_type_t g_current_code_type;
uint8_t g_selected_code;
vfo_state_t g_vfo_state[2];
bool RADIO_channel_valid(uint16_t Channel, bool bCheckScanList, uint8_t VFO)
{ // return true if the channel appears valid
unsigned int i;
uint8_t priority_channel[2];
if (Channel > USER_CHANNEL_LAST)
return false;
if (g_eeprom.config.channel_attributes[Channel].band > BAND7_470MHz)
return false;
if (bCheckScanList)
{
switch (VFO)
{
case 0:
if (g_eeprom.config.channel_attributes[Channel].scanlist1 == 0)
return false;
for (i = 0; i < 2; i++)
priority_channel[i] = g_eeprom.config.setting.priority_scan_list[VFO].channel[i];
break;
case 1:
if (g_eeprom.config.channel_attributes[Channel].scanlist2 == 0)
return false;
for (i = 0; i < 2; i++)
priority_channel[i] = g_eeprom.config.setting.priority_scan_list[VFO].channel[i];
break;
default:
return true;
}
if (priority_channel[0] == Channel)
return false;
if (priority_channel[1] == Channel)
return false;
}
return true;
}
uint8_t RADIO_FindNextChannel(uint8_t Channel, scan_state_dir_t Direction, bool bCheckScanList, uint8_t VFO)
{
unsigned int i;
for (i = 0; i <= USER_CHANNEL_LAST; i++)
{
if (Channel == 0xFF)
Channel = USER_CHANNEL_LAST;
else
if (Channel > USER_CHANNEL_LAST)
Channel = USER_CHANNEL_FIRST;
if (RADIO_channel_valid(Channel, bCheckScanList, VFO))
return Channel;
Channel += Direction;
}
return 0xFF;
}
void RADIO_InitInfo(vfo_info_t *p_vfo, const uint8_t ChannelSave, const uint32_t Frequency)
{
if (p_vfo == NULL)
return;
memset(p_vfo, 0, sizeof(*p_vfo));
p_vfo->channel_attributes.band = FREQUENCY_GetBand(Frequency);
p_vfo->channel_attributes.scanlist1 = 1;
p_vfo->channel_attributes.scanlist2 = 1;
p_vfo->channel.step_setting = STEP_12_5kHz;
p_vfo->step_freq = STEP_FREQ_TABLE[p_vfo->channel.step_setting];
p_vfo->channel_save = ChannelSave;
p_vfo->channel.frequency_reverse = false;
p_vfo->channel.tx_power = OUTPUT_POWER_LOW;
p_vfo->freq_config_rx.frequency = Frequency;
p_vfo->freq_config_tx.frequency = Frequency;
p_vfo->p_rx = &p_vfo->freq_config_rx;
p_vfo->p_tx = &p_vfo->freq_config_tx;
p_vfo->channel.compand = 0; // off
p_vfo->channel.squelch_level = 0; // use main squelch
p_vfo->freq_in_channel = 0xff;
if (ChannelSave == (FREQ_CHANNEL_FIRST + BAND2_108MHz))
p_vfo->channel.mod_mode = MOD_MODE_AM;
RADIO_ConfigureSquelchAndOutputPower(p_vfo);
}
void RADIO_configure_channel(const unsigned int VFO, const unsigned int configure)
{
unsigned int channel;
unsigned int chan;
t_channel_attrib attributes;
// uint16_t base;
uint32_t frequency;
vfo_info_t *p_vfo = &g_vfo_info[VFO];
if (!g_eeprom.config.setting.enable_350)
{
if (g_eeprom.config.setting.indices.vfo[VFO].frequency == (FREQ_CHANNEL_LAST - 2))
g_eeprom.config.setting.indices.vfo[VFO].frequency = FREQ_CHANNEL_LAST - 1;
if (g_eeprom.config.setting.indices.vfo[VFO].screen == (FREQ_CHANNEL_LAST - 2))
g_eeprom.config.setting.indices.vfo[VFO].screen = FREQ_CHANNEL_LAST - 1;
}
channel = g_eeprom.config.setting.indices.vfo[VFO].screen;
p_vfo->freq_in_channel = 0xff;
if (IS_VALID_CHANNEL(channel))
{
#ifdef ENABLE_NOAA
if (channel >= NOAA_CHANNEL_FIRST)
{
RADIO_InitInfo(p_vfo, g_eeprom.config.setting.indices.vfo[VFO].screen, NOAA_FREQUENCY_TABLE[channel - NOAA_CHANNEL_FIRST]);
if (g_eeprom.config.setting.cross_vfo == CROSS_BAND_OFF)
return;
g_eeprom.config.setting.cross_vfo = CROSS_BAND_OFF;
g_update_status = true;
return;
}
#endif
if (channel <= USER_CHANNEL_LAST)
{
channel = RADIO_FindNextChannel(channel, SCAN_STATE_DIR_FORWARD, false, VFO);
if (!IS_VALID_CHANNEL(channel))
{
channel = g_eeprom.config.setting.indices.vfo[VFO].frequency;
g_eeprom.config.setting.indices.vfo[VFO].screen = channel;
}
else
{
g_eeprom.config.setting.indices.vfo[VFO].screen = channel;
g_eeprom.config.setting.indices.vfo[VFO].user = channel;
}
}
}
else
{
channel = FREQ_CHANNEL_LAST - 1;
}
chan = CHANNEL_NUM(channel, VFO);
attributes = g_eeprom.config.channel_attributes[channel];
#if defined(ENABLE_UART) && defined(ENABLE_UART_DEBUG)
// UART_printf("config chan 1 %u %u %u %u %u\r\n", channel, chan, attributes.band, attributes.scanlist1, attributes.scanlist2);
#endif
if (attributes.attributes == 0xff)
{ // invalid/unused channel
unsigned int index;
if (channel <= USER_CHANNEL_LAST)
{
channel = g_eeprom.config.setting.indices.vfo[VFO].frequency;
g_eeprom.config.setting.indices.vfo[VFO].screen = channel;
}
index = channel - FREQ_CHANNEL_FIRST;
RADIO_InitInfo(p_vfo, channel, FREQ_BAND_TABLE[index].lower);
return;
}
if (attributes.band > BAND7_470MHz)
attributes.band = BAND6_400MHz;
if (channel <= USER_CHANNEL_LAST)
{ // USER channel
p_vfo->channel_attributes = attributes;
}
else
if (IS_FREQ_CHANNEL(channel))
{ // VFO channel
attributes.band = channel - FREQ_CHANNEL_FIRST;
p_vfo->channel_attributes = attributes;
#if 0
// don't allow the VFO's to change their scanlist bits
p_vfo->channel_attributes.scanlist2 = 1;
p_vfo->channel_attributes.scanlist1 = 1;
#endif
}
p_vfo->channel_save = channel;
// if (channel <= USER_CHANNEL_LAST)
// base = channel * 16;
// else
// base = 0x0C80 + ((channel - FREQ_CHANNEL_FIRST) * 16 * 2) + (VFO * 16); // VFO channel
if (configure == VFO_CONFIGURE_RELOAD || IS_FREQ_CHANNEL(channel))
{
// EEPROM_ReadBuffer(Base, &m_channel, sizeof(t_channel));
// EEPROM_ReadBuffer(Base, p_vfo->channel, sizeof(t_channel));
memcpy(&p_vfo->channel, &g_eeprom.config.channel[chan], sizeof(t_channel));
p_vfo->step_freq = STEP_FREQ_TABLE[p_vfo->channel.step_setting];
p_vfo->channel_attributes = g_eeprom.config.channel_attributes[channel];
p_vfo->freq_config_rx.frequency = p_vfo->channel.frequency;
p_vfo->freq_config_rx.code_type = p_vfo->channel.rx_ctcss_cdcss_type;
p_vfo->freq_config_rx.code = p_vfo->channel.rx_ctcss_cdcss_code;
p_vfo->freq_config_tx.code_type = p_vfo->channel.tx_ctcss_cdcss_type;
p_vfo->freq_config_tx.code = p_vfo->channel.tx_ctcss_cdcss_code;
#if defined(ENABLE_UART) && defined(ENABLE_UART_DEBUG)
// UART_printf("config chan 2 %u %u %u %u %u %uHz\r\n", channel, chan, p_vfo->channel_attributes.band, p_vfo->channel_attributes.scanlist1, p_vfo->channel_attributes.scanlist2, p_vfo->channel.frequency * 10);
#endif
}
else
{
#if defined(ENABLE_UART) && defined(ENABLE_UART_DEBUG)
// UART_printf("config chan 3 %u %u %u %u %uHz\r\n", channel, p_vfo->channel_attributes.band, p_vfo->channel_attributes.scanlist1, p_vfo->channel_attributes.scanlist2, p_vfo->channel.frequency * 10);
#endif
}
frequency = p_vfo->freq_config_rx.frequency;
if (frequency < FREQ_BAND_TABLE[attributes.band].lower)
frequency = FREQ_BAND_TABLE[attributes.band].lower;
else
if (frequency >= FREQ_BAND_TABLE[attributes.band].upper)
frequency = FREQUENCY_floor_to_step(frequency, p_vfo->step_freq, FREQ_BAND_TABLE[attributes.band].lower, FREQ_BAND_TABLE[attributes.band].upper);
// else
// if (channel >= FREQ_CHANNEL_FIRST)
// frequency = FREQUENCY_floor_to_step(frequency, p_vfo->step_freq, FREQ_BAND_TABLE[attributes.band].lower, FREQ_BAND_TABLE[attributes.band].upper);
if (!g_eeprom.config.setting.enable_350 && frequency >= 35000000 && frequency < 40000000)
{ // 350~400Mhz not allowed
// hop onto the next band up
frequency = 43350000;
p_vfo->freq_config_rx.frequency = frequency;
p_vfo->freq_config_tx.frequency = frequency;
attributes.band = FREQUENCY_GetBand(frequency);
p_vfo->channel_attributes.band = attributes.band;
p_vfo->channel.frequency_reverse = 0;
p_vfo->channel.tx_offset_dir = TX_OFFSET_FREQ_DIR_OFF;
p_vfo->channel.tx_offset = 0;
// TODO: also update other settings such as step size
}
p_vfo->freq_config_rx.frequency = frequency;
if (frequency >= AIR_BAND.lower && frequency < AIR_BAND.upper)
{ // air band
p_vfo->channel.tx_offset_dir = TX_OFFSET_FREQ_DIR_OFF;
p_vfo->channel.tx_offset = 0;
}
else
if (channel > USER_CHANNEL_LAST)
{
p_vfo->channel.tx_offset = FREQUENCY_floor_to_step(p_vfo->channel.tx_offset + (p_vfo->step_freq / 2), p_vfo->step_freq, 0, p_vfo->channel.tx_offset + p_vfo->step_freq);
}
RADIO_ApplyOffset(p_vfo, true);
// channel name
memset(&p_vfo->channel_name, 0, sizeof(p_vfo->channel_name));
if (channel <= USER_CHANNEL_LAST)
// EEPROM_ReadBuffer(0x0F50 + (channel * 16), p_vfo->channel_name, 10); // only 10 bytes used
memcpy(p_vfo->channel_name.name, &g_eeprom.config.channel_name[channel].name, sizeof(p_vfo->channel_name.name));
if (p_vfo->channel.mod_mode != MOD_MODE_FM)
{ // freq/chan is in AM mode
// disable stuff, even though it can all still be used with AM ???
p_vfo->channel.scrambler = 0;
// p_vfo->channel.dtmf_decoding_enable = 0;
p_vfo->freq_config_rx.code_type = CODE_TYPE_NONE;
p_vfo->freq_config_tx.code_type = CODE_TYPE_NONE;
}
RADIO_ConfigureSquelchAndOutputPower(p_vfo);
#ifdef ENABLE_AM_FIX
AM_fix_reset(VFO);
if (p_vfo->channel.mod_mode != MOD_MODE_FM && g_eeprom.config.setting.am_fix)
{
AM_fix_10ms(VFO);
}
else
{ // don't do agc in FM mode
BK4819_DisableAGC();
BK4819_write_reg(0x13, (orig_lnas << 8) | (orig_lna << 5) | (orig_mixer << 3) | (orig_pga << 0));
}
#else
if (p_vfo->mod_mode != MOD_MODE_FM)
{
BK4819_EnableAGC();
}
else
{ // don't do agc in FM mode
BK4819_DisableAGC();
BK4819_write_reg(0x13, (orig_lnas << 8) | (orig_lna << 5) | (orig_mixer << 3) | (orig_pga << 0));
}
#endif
// if (configure == VFO_CONFIGURE_RELOAD || IS_FREQ_CHANNEL(channel))
if (IS_FREQ_CHANNEL(channel))
p_vfo->freq_in_channel = SETTINGS_find_channel(frequency); // find channel that has this frequency
}
#ifdef ENABLE_VOX
void RADIO_enable_vox(unsigned int level)
{
uint16_t threshold_enable;
uint16_t threshold_disable;
if (level > (ARRAY_SIZE(g_eeprom.calib.vox[0].threshold) - 1))
level = ARRAY_SIZE(g_eeprom.calib.vox[0].threshold) - 1;
// my eeprom values ..
//
// vox threshold enable 30 50 70 90 110 130 150 170 200 230 FFFF FFFF
// vox threshold disable 20 40 60 80 100 120 140 160 190 220 FFFF FFFF
//
#ifdef ENABLE_VOX_MORE_SENSITIVE
// more sensitive
threshold_enable = g_eeprom.calib.vox[0].threshold[level] / 3;
threshold_disable = (threshold_enable > 13) ? threshold_enable - 10 : 3;
#else
threshold_enable = g_eeprom.calib.vox[0].threshold[level];
threshold_disable = g_eeprom.calib.vox[1].threshold[level];
#endif
BK4819_EnableVox(threshold_enable, threshold_disable);
BK4819_write_reg(0x3F, BK4819_read_reg(0x3F) | BK4819_REG_3F_VOX_FOUND | BK4819_REG_3F_VOX_LOST);
}
#endif
void RADIO_ConfigureSquelchAndOutputPower(vfo_info_t *p_vfo)
{
// *******************************
// squelch
const unsigned int squelch_level = (p_vfo->channel.squelch_level > 0) ? p_vfo->channel.squelch_level : g_eeprom.config.setting.squelch_level;
// note that 'noise' and 'glitch' values are inverted compared to 'rssi' values
if (squelch_level == 0)
{ // squelch == 0 (off)
p_vfo->squelch_open_rssi_thresh = 0; // 0 ~ 255
p_vfo->squelch_close_rssi_thresh = 0; // 0 ~ 255
p_vfo->squelch_open_noise_thresh = 127; // 127 ~ 0
p_vfo->squelch_close_noise_thresh = 127; // 127 ~ 0
p_vfo->squelch_open_glitch_thresh = 255; // 255 ~ 0
p_vfo->squelch_close_glitch_thresh = 255; // 255 ~ 0
}
else
{ // squelch >= 1
// my calibration data
//
// bands 4567
// 0A 4B 53 56 59 5C 5F 62 64 66 FF FF FF FF FF FF // open rssi
// 05 46 50 53 56 59 5C 5F 62 64 FF FF FF FF FF FF // close rssi
// 5A 2D 29 26 23 20 1D 1A 17 14 FF FF FF FF FF FF // open noise
// 64 30 2D 29 26 23 20 1D 1A 17 FF FF FF FF FF FF // close noise
// 5A 14 11 0E 0B 08 03 02 02 02 FF FF FF FF FF FF // open glitch
// 64 11 0E 0B 08 05 05 04 04 04 FF FF FF FF FF FF // close glitch
//
// bands 123
// 32 68 6B 6E 6F 72 75 77 79 7B FF FF FF FF FF FF // open rssi
// 28 64 67 6A 6C 6E 71 73 76 78 FF FF FF FF FF FF // close rssi
// 41 32 2D 28 24 21 1E 1A 17 16 FF FF FF FF FF FF // open noise
// 46 37 32 2D 28 25 22 1E 1B 19 FF FF FF FF FF FF // close noise
// 5A 19 0F 0A 09 08 07 06 05 04 FF FF FF FF FF FF // open glitch
// 64 1E 14 0F 0D 0C 0B 0A 09 08 FF FF FF FF FF FF // close glitch
unsigned int band = (unsigned int)FREQUENCY_GetBand(p_vfo->p_rx->frequency);
band = (band < BAND4_174MHz) ? 1 : 0;
p_vfo->squelch_open_rssi_thresh = g_eeprom.calib.squelch_band[band].open_rssi_thresh[squelch_level];
p_vfo->squelch_close_rssi_thresh = g_eeprom.calib.squelch_band[band].close_rssi_thresh[squelch_level];
p_vfo->squelch_open_noise_thresh = g_eeprom.calib.squelch_band[band].open_noise_thresh[squelch_level];
p_vfo->squelch_close_noise_thresh = g_eeprom.calib.squelch_band[band].close_noise_thresh[squelch_level];
p_vfo->squelch_open_glitch_thresh = g_eeprom.calib.squelch_band[band].open_glitch_thresh[squelch_level];
p_vfo->squelch_close_glitch_thresh = g_eeprom.calib.squelch_band[band].close_glitch_thresh[squelch_level];
// *********
int16_t rssi_open = p_vfo->squelch_open_rssi_thresh; // 0 ~ 255
int16_t rssi_close = p_vfo->squelch_close_rssi_thresh; // 0 ~ 255
int16_t noise_open = p_vfo->squelch_open_noise_thresh; // 127 ~ 0
int16_t noise_close = p_vfo->squelch_close_noise_thresh; // 127 ~ 0
int16_t glitch_open = p_vfo->squelch_open_glitch_thresh; // 255 ~ 0
int16_t glitch_close = p_vfo->squelch_close_glitch_thresh; // 255 ~ 0
// *********
#if ENABLE_SQUELCH_MORE_SENSITIVE
// make squelch a little more sensitive
//
// getting the best general settings here is experimental, bare with me
#if 0
rssi_open = (rssi_open * 8) / 9;
noise_open = (noise_open * 9) / 8;
glitch_open = (glitch_open * 9) / 8;
#else
// even more sensitive .. use when RX bandwidths are fixed (no weak signal auto adjust)
rssi_open = (rssi_open * 1) / 2;
noise_open = (noise_open * 2) / 1;
glitch_open = (glitch_open * 2) / 1;
#endif
#else
// more sensitive .. use when RX bandwidths are fixed (no weak signal auto adjust)
rssi_open = (rssi_open * 3) / 4;
noise_open = (noise_open * 4) / 3;
glitch_open = (glitch_open * 4) / 3;
#endif
// *********
// ensure the 'close' threshold is lower than the 'open' threshold
// ie, maintain a minimum level of hysteresis
rssi_close = (rssi_open * 4) / 6;
noise_close = (noise_open * 6) / 4;
glitch_close = (glitch_open * 6) / 4;
if (rssi_open < 8)
rssi_open = 8;
if (rssi_close > (rssi_open - 8))
rssi_close = rssi_open - 8;
if (noise_open > (127 - 4))
noise_open = 127 - 4;
if (noise_close < (noise_open + 4))
noise_close = noise_open + 4;
if (glitch_open > (255 - 8))
glitch_open = 255 - 8;
if (glitch_close < (glitch_open + 8))
glitch_close = glitch_open + 8;
// *********
p_vfo->squelch_open_rssi_thresh = (rssi_open > 255) ? 255 : (rssi_open < 0) ? 0 : rssi_open;
p_vfo->squelch_close_rssi_thresh = (rssi_close > 255) ? 255 : (rssi_close < 0) ? 0 : rssi_close;
p_vfo->squelch_open_noise_thresh = (noise_open > 127) ? 127 : (noise_open < 0) ? 0 : noise_open;
p_vfo->squelch_close_noise_thresh = (noise_close > 127) ? 127 : (noise_close < 0) ? 0 : noise_close;
p_vfo->squelch_open_glitch_thresh = (glitch_open > 255) ? 255 : (glitch_open < 0) ? 0 : glitch_open;
p_vfo->squelch_close_glitch_thresh = (glitch_close > 255) ? 255 : (glitch_close < 0) ? 0 : glitch_close;
}
// *******************************
// output power
{
// my calibration data
//
// 1ED0 32 32 32 64 64 64 8C 8C 8C FF FF FF FF FF FF FF .. 50 MHz
// 1EE0 32 32 32 64 64 64 8C 8C 8C FF FF FF FF FF FF FF .. 108 MHz
// 1EF0 5F 5F 5F 69 69 69 91 91 8F FF FF FF FF FF FF FF .. 137 MHz
// 1F00 32 32 32 64 64 64 8C 8C 8C FF FF FF FF FF FF FF .. 174 MHz
// 1F10 5A 5A 5A 64 64 64 82 82 82 FF FF FF FF FF FF FF .. 350 MHz
// 1F20 5A 5A 5A 64 64 64 8F 91 8A FF FF FF FF FF FF FF .. 400 MHz
// 1F30 32 32 32 64 64 64 8C 8C 8C FF FF FF FF FF FF FF .. 470 MHz
uint8_t tx_power[3];
const unsigned int band = (unsigned int)FREQUENCY_GetBand(p_vfo->p_tx->frequency);
// EEPROM_ReadBuffer(0x1ED0 + (band * 16) + (p_vfo->output_power * 3), tx_power, 3);
memcpy(&tx_power, &g_eeprom.calib.tx_band_power[band].level[p_vfo->channel.tx_power], 3);
#ifdef ENABLE_REDUCE_LOW_MID_TX_POWER
// make low and mid even lower
if (p_vfo->channel.tx_power == OUTPUT_POWER_LOW)
{
tx_power[0] /= 5; //tx_power[0] /= 8;
tx_power[1] /= 5; //tx_power[1] /= 8;
tx_power[2] /= 5; //tx_power[2] /= 8; get more low power
}
else
if (p_vfo->channel.tx_power == OUTPUT_POWER_MID)
{
tx_power[0] /= 3; //tx_power[0] /= 5;
tx_power[1] /= 3; //tx_power[1] /= 5;
tx_power[2] /= 3; //tx_power[2] /= 5; get more low power
}
#endif
p_vfo->txp_calculated_setting = FREQUENCY_CalculateOutputPower(
tx_power[0],
tx_power[1],
tx_power[2],
FREQ_BAND_TABLE[band].lower,
(FREQ_BAND_TABLE[band].lower + FREQ_BAND_TABLE[band].upper) / 2,
FREQ_BAND_TABLE[band].upper,
p_vfo->p_tx->frequency);
}
// *******************************
}
void RADIO_ApplyOffset(vfo_info_t *p_vfo, const bool set_pees)
{
uint32_t Frequency = p_vfo->freq_config_rx.frequency;
switch (p_vfo->channel.tx_offset_dir)
{
case TX_OFFSET_FREQ_DIR_OFF:
break;
case TX_OFFSET_FREQ_DIR_ADD:
Frequency += p_vfo->channel.tx_offset;
break;
case TX_OFFSET_FREQ_DIR_SUB:
Frequency -= p_vfo->channel.tx_offset;
break;
}
if (Frequency < FREQ_BAND_TABLE[0].lower)
Frequency = FREQ_BAND_TABLE[0].lower;
else
if (Frequency > FREQ_BAND_TABLE[ARRAY_SIZE(FREQ_BAND_TABLE) - 1].upper)
Frequency = FREQ_BAND_TABLE[ARRAY_SIZE(FREQ_BAND_TABLE) - 1].upper;
p_vfo->freq_config_tx.frequency = Frequency;
if (set_pees)
{
if (!p_vfo->channel.frequency_reverse)
{
p_vfo->p_rx = &p_vfo->freq_config_rx;
p_vfo->p_tx = &p_vfo->freq_config_tx;
}
else
{
p_vfo->p_rx = &p_vfo->freq_config_tx;
p_vfo->p_tx = &p_vfo->freq_config_rx;
}
}
}
void RADIO_select_vfos(void)
{
g_eeprom.config.setting.tx_vfo_num = get_TX_VFO();
g_rx_vfo_num = (g_eeprom.config.setting.cross_vfo == CROSS_BAND_OFF) ? g_eeprom.config.setting.tx_vfo_num : (g_eeprom.config.setting.tx_vfo_num + 1) & 1u;
g_tx_vfo = &g_vfo_info[g_eeprom.config.setting.tx_vfo_num];
g_rx_vfo = &g_vfo_info[g_rx_vfo_num];
g_current_vfo = (g_eeprom.config.setting.cross_vfo == CROSS_BAND_OFF) ? g_rx_vfo : &g_vfo_info[g_eeprom.config.setting.tx_vfo_num];
}
void RADIO_setup_registers(bool switch_to_function_foreground)
{
BK4819_filter_bandwidth_t Bandwidth = g_rx_vfo->channel.channel_bandwidth;
uint16_t interrupt_mask;
uint32_t Frequency;
if (!g_monitor_enabled)
{
#ifdef ENABLE_FMRADIO
if (!g_fm_radio_mode && g_request_display_screen != DISPLAY_FM)
#endif
GPIO_ClearBit(&GPIOC->DATA, GPIOC_PIN_SPEAKER);
}
// turn green LED off
BK4819_set_GPIO_pin(BK4819_GPIO6_PIN2_GREEN, false);
switch (Bandwidth)
{
default:
Bandwidth = BK4819_FILTER_BW_WIDE;
// Fallthrough
case BK4819_FILTER_BW_WIDE:
case BK4819_FILTER_BW_NARROW:
#ifdef ENABLE_AM_FIX
#if 0
BK4819_SetFilterBandwidth(Bandwidth);
BK4819_EnableAFC();
#else
if (g_rx_vfo->channel.mod_mode != MOD_MODE_FM)
{
BK4819_SetFilterBandwidth(BK4819_FILTER_BW_NARROWER); // sideband
BK4819_DisableAFC();
}
else
{
BK4819_SetFilterBandwidth(Bandwidth);
BK4819_EnableAFC();
}
#endif
#else
BK4819_SetFilterBandwidth(Bandwidth, false);
BK4819_EnableAFC();
#endif
break;
}
BK4819_write_reg(0x30, 0);
BK4819_write_reg(0x30,
BK4819_REG_30_ENABLE_VCO_CALIB |
// BK4819_REG_30_ENABLE_UNKNOWN |
BK4819_REG_30_ENABLE_RX_LINK |
BK4819_REG_30_ENABLE_AF_DAC |
BK4819_REG_30_ENABLE_DISC_MODE |
BK4819_REG_30_ENABLE_PLL_VCO |
// BK4819_REG_30_ENABLE_PA_GAIN |
// BK4819_REG_30_ENABLE_MIC_ADC |
// BK4819_REG_30_ENABLE_TX_DSP |
BK4819_REG_30_ENABLE_RX_DSP |
0);
BK4819_set_GPIO_pin(BK4819_GPIO5_PIN1_RED, false); // LED off
BK4819_SetupPowerAmplifier(0, 0);
BK4819_set_GPIO_pin(BK4819_GPIO1_PIN29_PA_ENABLE, false); // PA off
while (1)
{ // wait for interrupts to clear
const uint16_t int_bits = BK4819_read_reg(0x0C);
if ((int_bits & (1u << 0)) == 0)
break;
BK4819_write_reg(0x02, 0); // clear the interrupt bits
SYSTEM_DelayMs(1);
}
BK4819_write_reg(0x3F, 0); // disable interrupts
#ifdef ENABLE_NOAA
if (IS_NOAA_CHANNEL(g_rx_vfo->channel_save) && g_noaa_mode)
Frequency = NOAA_FREQUENCY_TABLE[g_noaa_channel];
else
#endif
Frequency = g_rx_vfo->p_rx->frequency;
BK4819_set_rf_frequency(Frequency, false);
BK4819_set_rf_filter_path(Frequency);
BK4819_SetupSquelch(
g_rx_vfo->squelch_open_rssi_thresh, g_rx_vfo->squelch_close_rssi_thresh,
g_rx_vfo->squelch_open_noise_thresh, g_rx_vfo->squelch_close_noise_thresh,
g_rx_vfo->squelch_close_glitch_thresh, g_rx_vfo->squelch_open_glitch_thresh);
// enable the RX front end
BK4819_set_GPIO_pin(BK4819_GPIO0_PIN28_RX_ENABLE, true);
// AF RX Gain and DAC
// if (g_rx_vfo->channel.mod_mode != MOD_MODE_FM)
// {
// BK4819_write_reg(0x48, 0xB3A8); // 1011 0011 1010 1000
// }
// else
{
BK4819_write_reg(0x48,
(11u << 12) | // ??? .. 0 ~ 15, doesn't seem to make any difference
( 0u << 10) | // AF Rx Gain-1
(g_eeprom.calib.volume_gain << 4) | // AF Rx Gain-2
(g_eeprom.calib.dac_gain << 0)); // AF DAC Gain (after Gain-1 and Gain-2)
}
if (!g_monitor_enabled)
{
#ifdef ENABLE_FMRADIO
if (!g_fm_radio_mode && g_request_display_screen != DISPLAY_FM)
#endif
{
#ifdef ENABLE_VOICE
#ifdef MUTE_AUDIO_FOR_VOICE
if (g_voice_write_index == 0)
AUDIO_set_mod_mode(g_rx_vfo->channel.mod_mode);
#else
AUDIO_set_mod_mode(g_rx_vfo->channel.mod_mode);
#endif
#else
AUDIO_set_mod_mode(g_rx_vfo->channel.mod_mode);
#endif
}
}
interrupt_mask = BK4819_REG_3F_SQUELCH_FOUND | BK4819_REG_3F_SQUELCH_LOST;
if (IS_NOT_NOAA_CHANNEL(g_rx_vfo->channel_save))
{
if (g_rx_vfo->channel.mod_mode == MOD_MODE_FM)
{ // FM
uint8_t code_type = g_selected_code_type;
uint8_t code = g_selected_code;
if (g_css_scan_mode == CSS_SCAN_MODE_OFF)
{
code_type = g_rx_vfo->p_rx->code_type;
code = g_rx_vfo->p_rx->code;
}
switch (code_type)
{
default:
case CODE_TYPE_NONE:
BK4819_set_CTCSS_freq(670);
BK4819_set_tail_detection(550); // QS's 55Hz tone method
interrupt_mask |= BK4819_REG_3F_CxCSS_TAIL;
break;
case CODE_TYPE_CONTINUOUS_TONE:
BK4819_set_CTCSS_freq(CTCSS_TONE_LIST[code]);
// #ifdef ENABLE_CTCSS_TAIL_PHASE_SHIFT
// BK4819_set_tail_detection(CTCSS_TONE_LIST[code]); // doesn't work in RX mode
// #else
// BK4819_set_tail_detection(550); // QS's 55Hz tone method
// #endif
interrupt_mask |=
BK4819_REG_3F_CxCSS_TAIL |
BK4819_REG_3F_CTCSS_FOUND |
BK4819_REG_3F_CTCSS_LOST;
break;
case CODE_TYPE_DIGITAL:
case CODE_TYPE_REVERSE_DIGITAL:
BK4819_set_CDCSS_code(DCS_GetGolayCodeWord(code_type, code));
interrupt_mask |=
BK4819_REG_3F_CxCSS_TAIL |
BK4819_REG_3F_CDCSS_FOUND |
BK4819_REG_3F_CDCSS_LOST;
break;
}
if (g_eeprom.config.setting.enable_scrambler)
BK4819_set_scrambler(g_rx_vfo->channel.scrambler);
else
BK4819_set_scrambler(0);
}
}
#ifdef ENABLE_NOAA
else
{
BK4819_set_CTCSS_freq(0); // NOAA 1050Hz stuff
interrupt_mask |= BK4819_REG_3F_CTCSS_FOUND | BK4819_REG_3F_CTCSS_LOST;
}
#endif
#ifdef ENABLE_VOX
if (
#ifdef ENABLE_FMRADIO
!g_fm_radio_mode &&
#endif
g_eeprom.config.setting.vox_enabled &&
IS_NOT_NOAA_CHANNEL(g_current_vfo->channel_save) &&
g_current_vfo->channel.mod_mode == MOD_MODE_FM)
{
RADIO_enable_vox(g_eeprom.config.setting.vox_level);
interrupt_mask |= BK4819_REG_3F_VOX_FOUND | BK4819_REG_3F_VOX_LOST;
}
else
#endif
BK4819_DisableVox();
// RX expander
BK4819_SetCompander((g_rx_vfo->channel.mod_mode == MOD_MODE_FM && g_rx_vfo->channel.compand >= 2) ? g_rx_vfo->channel.compand : 0);
BK4819_EnableDTMF();
interrupt_mask |= BK4819_REG_3F_DTMF_5TONE_FOUND;
#ifdef ENABLE_MDC1200
BK4819_enable_mdc1200_rx(true);
interrupt_mask |= BK4819_REG_3F_FSK_RX_SYNC | BK4819_REG_3F_FSK_RX_FINISHED | BK4819_REG_3F_FSK_FIFO_ALMOST_FULL;
#endif
// enable BK4819 interrupts
BK4819_write_reg(0x3F, interrupt_mask);
FUNCTION_Init();
if (switch_to_function_foreground)
FUNCTION_Select(FUNCTION_FOREGROUND);
// if (g_monitor_enabled)
// GPIO_SetBit(&GPIOC->DATA, GPIOC_PIN_SPEAKER);
}
#ifdef ENABLE_NOAA
void RADIO_ConfigureNOAA(void)
{
uint8_t ChanAB;
g_update_status = true;
if (g_eeprom.config.setting.noaa_auto_scan)
{
if (g_eeprom.config.setting.dual_watch != DUAL_WATCH_OFF)
{
if (IS_NOT_NOAA_CHANNEL(g_eeprom.config.setting.indices.vfo[0].screen))
{
if (IS_NOT_NOAA_CHANNEL(g_eeprom.config.setting.indices.vfo[1].screen))
{
g_noaa_mode = false;
return;
}
ChanAB = 1;
}
else
ChanAB = 0;
if (!g_noaa_mode)
g_noaa_channel = g_vfo_info[ChanAB].channel_save - NOAA_CHANNEL_FIRST;
g_noaa_mode = true;
return;
}
if (g_rx_vfo->channel_save >= NOAA_CHANNEL_FIRST)
{
g_noaa_mode = true;
g_noaa_channel = g_rx_vfo->channel_save - NOAA_CHANNEL_FIRST;
g_noaa_tick_10ms = noaa_tick_2_10ms;
g_schedule_noaa = false;
}
else
g_noaa_mode = false;
}
else
g_noaa_mode = false;
}
#endif
void RADIO_enableTX(const bool fsk_tx)
{
BK4819_filter_bandwidth_t Bandwidth = g_current_vfo->channel.channel_bandwidth;
GPIO_ClearBit(&GPIOC->DATA, GPIOC_PIN_SPEAKER);
BK4819_set_GPIO_pin(BK4819_GPIO0_PIN28_RX_ENABLE, false);
switch (Bandwidth)
{
default:
Bandwidth = BK4819_FILTER_BW_WIDE;
// Fallthrough
case BK4819_FILTER_BW_WIDE:
case BK4819_FILTER_BW_NARROW:
#ifdef ENABLE_AM_FIX
#if 0
BK4819_SetFilterBandwidth(Bandwidth);
BK4819_EnableAFC();
#else
if (g_current_vfo->channel.mod_mode == MOD_MODE_DSB)
{
BK4819_SetFilterBandwidth(BK4819_FILTER_BW_NARROWER); // sideband
BK4819_DisableAFC();
}
else
{
BK4819_SetFilterBandwidth(Bandwidth);
BK4819_EnableAFC();
}
#endif
#else
BK4819_SetFilterBandwidth(Bandwidth);
BK4819_EnableAFC();
#endif
break;
}
// if DTMF is enabled when TX'ing, it changes the TX audio filtering ! .. 1of11
// so MAKE SURE that DTMF is disabled - until needed
BK4819_DisableDTMF();
BK4819_SetCompander((!fsk_tx && g_rx_vfo->channel.mod_mode == MOD_MODE_FM && (g_rx_vfo->channel.compand == 1 || g_rx_vfo->channel.compand >= 3)) ? g_rx_vfo->channel.compand : 0);
BK4819_set_rf_frequency(g_current_vfo->p_tx->frequency, false);
BK4819_set_rf_filter_path(g_current_vfo->p_tx->frequency);
BK4819_PrepareTransmit();
BK4819_set_GPIO_pin(BK4819_GPIO1_PIN29_PA_ENABLE, true); // PA on
if (g_current_display_screen != DISPLAY_AIRCOPY)
BK4819_SetupPowerAmplifier(g_current_vfo->txp_calculated_setting, g_current_vfo->p_tx->frequency);
else
BK4819_SetupPowerAmplifier(0, g_current_vfo->p_tx->frequency); // very low power when in AIRCOPY mode
BK4819_set_GPIO_pin(BK4819_GPIO5_PIN1_RED, true); // turn the RED LED on
if (fsk_tx)
{
BK4819_disable_sub_audible();
}
else
{
switch (g_current_vfo->p_tx->code_type)
{
default:
case CODE_TYPE_NONE:
BK4819_disable_sub_audible();
break;
case CODE_TYPE_CONTINUOUS_TONE:
BK4819_gen_tail(4);
BK4819_set_CTCSS_freq(CTCSS_TONE_LIST[g_current_vfo->p_tx->code]);
break;
case CODE_TYPE_DIGITAL:
case CODE_TYPE_REVERSE_DIGITAL:
BK4819_gen_tail(4);
BK4819_set_CDCSS_code(DCS_GetGolayCodeWord(g_current_vfo->p_tx->code_type, g_current_vfo->p_tx->code));
break;
}
}
}
void RADIO_set_vfo_state(vfo_state_t State)
{
if (State == VFO_STATE_NORMAL)