/*
This project 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 3 of the License, or
(at your option) any later version.
Multiprotocol 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 Multiprotocol. If not, see <http://www.gnu.org/licenses/>.
*/
// Last sync with main deviation/sfhss_cc2500.c dated 2016-03-23
#if defined(SFHSS_CC2500_INO)
#include "iface_cc2500.h"
#define SFHSS_COARSE 0
#define SFHSS_PACKET_LEN 13
#define SFHSS_TX_ID_LEN 2
uint8_t fhss_code=0; // 0-27
enum {
SFHSS_START = 0x00,
SFHSS_CAL = 0x01,
SFHSS_DATA1 = 0x02,
SFHSS_DATA2 = 0x03,
SFHSS_TUNE = 0x04
};
#define SFHSS_FREQ0_VAL 0xC4
// Some important initialization parameters, all others are either default,
// or not important in the context of transmitter
// IOCFG2 2F - GDO2_INV=0 GDO2_CFG=2F - HW0
// IOCFG1 2E - GDO1_INV=0 GDO1_CFG=2E - High Impedance
// IOCFG0 2F - GDO0 same as GDO2, TEMP_SENSOR_ENABLE=off
// FIFOTHR 07 - 33 decimal TX threshold
// SYNC1 D3
// SYNC0 91
// PKTLEN 0D - Packet length, 0D bytes
// PKTCTRL1 04 - APPEND_STATUS on, all other are receive parameters - irrelevant
// PKTCTRL0 0C - No whitening, use FIFO, CC2400 compatibility on, use CRC, fixed packet length
// ADDR 29
// CHANNR 10
// FSCTRL1 06 - IF 152343.75Hz, see page 65
// FSCTRL0 00 - zero freq offset
// FREQ2 5C - synthesizer frequency 2399999633Hz for 26MHz crystal, ibid
// FREQ1 4E
// FREQ0 C4
// MDMCFG4 7C - CHANBW_E - 01, CHANBW_M - 03, DRATE_E - 0C. Filter bandwidth = 232142Hz
// MDMCFG3 43 - DRATE_M - 43. Data rate = 128143bps
// MDMCFG2 83 - disable DC blocking, 2-FSK, no Manchester code, 15/16 sync bits detected (irrelevant for TX)
// MDMCFG1 23 - no FEC, 4 preamble bytes, CHANSPC_E - 03
// MDMCFG0 3B - CHANSPC_M - 3B. Channel spacing = 249938Hz (each 6th channel used, resulting in spacing of 1499628Hz)
// DEVIATN 44 - DEVIATION_E - 04, DEVIATION_M - 04. Deviation = 38085.9Hz
// MCSM2 07 - receive parameters, default, irrelevant
// MCSM1 0C - no CCA (transmit always), when packet received stay in RX, when sent go to IDLE
// MCSM0 08 - no autocalibration, PO_TIMEOUT - 64, no pin radio control, no forcing XTAL to stay in SLEEP
// FOCCFG 1D - not interesting, Frequency Offset Compensation
// FREND0 10 - PA_POWER = 0
const PROGMEM uint8_t SFHSS_init_values[] = {
/* 00 */ 0x2F, 0x2E, 0x2F, 0x07, 0xD3, 0x91, 0x0D, 0x04,
/* 08 */ 0x0C, 0x29, 0x10, 0x06, 0x00, 0x5C, 0x4E, SFHSS_FREQ0_VAL + SFHSS_COARSE,
/* 10 */ 0x7C, 0x43, 0x83, 0x23, 0x3B, 0x44, 0x07, 0x0C,
/* 18 */ 0x08, 0x1D, 0x1C, 0x43, 0x40, 0x91, 0x57, 0x6B,
/* 20 */ 0xF8, 0xB6, 0x10, 0xEA, 0x0A, 0x11, 0x11
};
static void __attribute__((unused)) SFHSS_rf_init()
{
CC2500_Strobe(CC2500_SIDLE);
for (uint8_t i = 0; i < 39; ++i)
CC2500_WriteReg(i, pgm_read_byte_near(&SFHSS_init_values[i]));
prev_option = option;
CC2500_WriteReg(CC2500_0C_FSCTRL0, option);
CC2500_SetTxRxMode(TX_EN);
CC2500_SetPower();
}
static void __attribute__((unused)) SFHSS_tune_chan()
{
CC2500_Strobe(CC2500_SIDLE);
CC2500_WriteReg(CC2500_0A_CHANNR, rf_ch_num*6+16);
CC2500_Strobe(CC2500_SCAL);
}
static void __attribute__((unused)) SFHSS_tune_chan_fast()
{
CC2500_Strobe(CC2500_SIDLE);
CC2500_WriteReg(CC2500_0A_CHANNR, rf_ch_num*6+16);
CC2500_WriteReg(CC2500_25_FSCAL1, calData[rf_ch_num]);
}
static void __attribute__((unused)) SFHSS_tune_freq()
{
if ( prev_option != option )
{
CC2500_WriteReg(CC2500_0C_FSCTRL0, option);
CC2500_WriteReg(CC2500_0F_FREQ0, SFHSS_FREQ0_VAL + SFHSS_COARSE);
prev_option = option ;
phase = SFHSS_START; // Restart the tune process if option is changed to get good tuned values
}
}
static void __attribute__((unused)) SFHSS_calc_next_chan()
{
rf_ch_num += fhss_code + 2;
if (rf_ch_num > 29)
{
if (rf_ch_num < 31)
rf_ch_num += fhss_code + 2;
rf_ch_num -= 31;
}
}
// Channel values are 12-bit values between 1020 and 2020, 1520 is the middle.
// Futaba @140% is 2070...1520...970
// Values grow down and to the right.
static void __attribute__((unused)) SFHSS_build_data_packet()
{
uint16_t ch[4];
// command.bit0 is the packet number indicator: =0 -> SFHSS_DATA1, =1 -> SFHSS_DATA2
// command.bit1 is unknown but seems to be linked to the payload[0].bit0 but more dumps are needed: payload[0]=0x82 -> =0, payload[0]=0x81 -> =1
// command.bit2 is the failsafe transmission indicator: =0 -> normal data, =1->failsafe data
// command.bit3 is the channels indicator: =0 -> CH1-4, =1 -> CH5-8
//Coding below matches the Futaba T8J transmission scheme DATA1->CH1-4, DATA2->CH5-8, DATA1->CH5-8, DATA2->CH1-4,...
// XK, T10J and TM-FH are different with a classic DATA1->CH1-4, DATA2->CH5-8,...
//Failsafe is sent twice every couple of seconds (unknown but >5s)
uint8_t command= (phase == SFHSS_DATA1) ? 0 : 1; // Building packet for Data1 or Data2
counter+=command;
#ifdef FAILSAFE_ENABLE
if( (counter&0x3FC) == 0x3FC && IS_FAILSAFE_VALUES_on)
{ // Transmit failsafe data twice every 7s
if( ((counter&1)^(command&1)) == 0 )
command|=0x04; // Failsafe
}
else
#endif
command|=0x02; // Assuming packet[0] == 0x81
counter&=0x3FF; // Reset failsafe counter
if(counter&1) command|=0x08; // Transmit lower and upper channels twice in a row
uint8_t ch_offset = (command&0x08) >> 1; // CH1..CH4 or CH5..CH8
#ifdef FAILSAFE_ENABLE
if(command&0x04)
{ //Failsafe data are:
// 0 to 1023 -> no output on channel
// 1024-2047 -> hold output on channel
// 2048-4095 -> channel_output=(data&0x3FF)*5/4+880 in µs
// Notes:
// 2048-2559 -> does not look valid since it only covers the range from 1520µs to 2160µs
// 2560-3583 -> valid for any channel values from 880µs to 2160µs
// 3584-4095 -> looks to be used for the throttle channel with values ranging from 880µs to 1520µs
for(uint8_t i=0;i<4;i++)
{
ch[i]=Failsafe_data[CH_AETR[ch_offset+i]];
if(ch[i]==FAILSAFE_CHANNEL_HOLD)
ch[i]=1024;
else if(ch[i]==FAILSAFE_CHANNEL_NOPULSES)
ch[i]=0;
else
{ //Use channel value
ch[i]=(ch[i]>>1)+2560;
//if(IS_DISABLE_CH_MAP_off && ch_offset+i==CH3 && ch[i]<3072) // Throttle
// ch[i]+=1024;
}
}
}
else
#endif
{ //Normal data
for(uint8_t i=0;i<4;i++)
ch[i] = convert_channel_16b_nolimit(CH_AETR[ch_offset+i],2020,1020);
}
// XK [0]=0x81 [3]=0x00 [4]=0x00
// T8J [0]=0x81 [3]=0x42 [4]=0x07
// T10J [0]=0x81 [3]=0x0F [4]=0x09
// TM-FH [0]=0x82 [3]=0x9A [4]=0x06
packet[0] = 0x81; // can be 80 or 81 for Orange, only 81 for XK
packet[1] = rx_tx_addr[0];
packet[2] = rx_tx_addr[1];
packet[3] = 0x00; // unknown but prevents some receivers to bind if not 0
packet[4] = 0x00; // unknown but prevents some receivers to bind if not 0
packet[5] = (rf_ch_num << 3) | ((ch[0] >> 9) & 0x07);
packet[6] = (ch[0] >> 1);
packet[7] = (ch[0] << 7) | ((ch[1] >> 5) & 0x7F );
packet[8] = (ch[1] << 3) | ((ch[2] >> 9) & 0x07 );
packet[9] = (ch[2] >> 1);
packet[10] = (ch[2] << 7) | ((ch[3] >> 5) & 0x7F );
packet[11] = (ch[3] << 3) | ((fhss_code >> 2) & 0x07 );
packet[12] = (fhss_code << 6) | command;
}
static void __attribute__((unused)) SFHSS_send_packet()
{
CC2500_WriteData(packet, SFHSS_PACKET_LEN);
}
uint16_t ReadSFHSS()
{
switch(phase)
{
case SFHSS_START:
rf_ch_num = 0;
SFHSS_tune_chan();
phase = SFHSS_CAL;
return 2000;
case SFHSS_CAL:
calData[rf_ch_num]=CC2500_ReadReg(CC2500_25_FSCAL1);
if (++rf_ch_num < 30)
SFHSS_tune_chan();
else
{
rf_ch_num = 0;
counter = 0;
phase = SFHSS_DATA1;
}
return 2000;
/* Work cycle: 6.8ms */
#define SFHSS_PACKET_PERIOD 6800
#define SFHSS_DATA2_TIMING 1625 // Adjust this value between 1600 and 1650 if your RX(s) are not operating properly
case SFHSS_DATA1:
#ifdef MULTI_SYNC
telemetry_set_input_sync(6800);
#endif
SFHSS_build_data_packet();
SFHSS_send_packet();
phase = SFHSS_DATA2;
return SFHSS_DATA2_TIMING; // original 1650
case SFHSS_DATA2:
SFHSS_build_data_packet();
SFHSS_send_packet();
SFHSS_calc_next_chan();
phase = SFHSS_TUNE;
return (SFHSS_PACKET_PERIOD -2000 -SFHSS_DATA2_TIMING); // original 2000
case SFHSS_TUNE:
phase = SFHSS_DATA1;
SFHSS_tune_freq();
SFHSS_tune_chan_fast();
CC2500_SetPower();
return 2000; // original 3150
}
return 0;
}
// Generate internal id
static void __attribute__((unused)) SFHSS_get_tx_id()
{
// Some receivers (Orange) behaves better if they tuned to id that has
// no more than 6 consecutive zeros and ones
uint32_t fixed_id;
uint8_t run_count = 0;
// add guard for bit count
fixed_id = 1 ^ (MProtocol_id & 1);
for (uint8_t i = 0; i < 16; ++i)
{
fixed_id = (fixed_id << 1) | (MProtocol_id & 1);
MProtocol_id >>= 1;
// If two LS bits are the same
if ((fixed_id & 3) == 0 || (fixed_id & 3) == 3)
{
if (++run_count > 6)
{
fixed_id ^= 1;
run_count = 0;
}
}
else
run_count = 0;
}
// fixed_id = 0xBC11;
rx_tx_addr[0] = fixed_id >> 8;
rx_tx_addr[1] = fixed_id >> 0;
}
uint16_t initSFHSS()
{
BIND_DONE; // Not a TX bind protocol
SFHSS_get_tx_id();
fhss_code=random(0xfefefefe)%28; // Initialize it to random 0-27 inclusive
SFHSS_rf_init();
phase = SFHSS_START;
return 10000;
}
#endif