/*
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 .
*/
// Compatible with XK TX X4 and model A160S.
#if defined(XK2_CCNRF_INO)
#include "iface_xn297.h"
//#define FORCE_XK2_ID
//#define FORCE_XK2_P10_ID
#define XK2_RF_BIND_CHANNEL 71
#define XK2_P10_RF_BIND_CHANNEL 69
#define XK2_PAYLOAD_SIZE 9
#define XK2_PACKET_PERIOD 4911
#define XK2_RF_NUM_CHANNELS 4
#define XK2_WRITE_TIME 1000
enum {
XK2_BIND1,
XK2_BIND2,
XK2_DATA_PREP,
XK2_DATA,
XK2_RX,
};
static uint8_t __attribute__((unused)) XK2_checksum(uint8_t init)
{
for(uint8_t i=0; i 2) trim_ch = 0;
packet[4] = 0x20 + 0x40 * trim_ch; //Trims are A=01..20..3F/E=41..60..7F/R=81..A0..BF, E0 appears when telemetry is received, C1 when p[6] changes from 00->08, C0 when p[6] changes from 08->00
if(trim_ch == 2) //Drive rudder trim since otherwise there is no control...
{
packet[4] = 0x80 + (convert_channel_8b(RUDDER)>>2);
if(packet[4] <= 0x81) packet[4] = 0x81;
}
//Flags
packet[5] = GET_FLAG(CH5_SW, 0x01) //Rate
| GET_FLAG(CH7_SW, 0x20) //Hover
| GET_FLAG(CH8_SW, 0x40); //Light
if(CH6_SW)
packet[5] |= 0x10; //Gyro off (senior mode)
else if(Channel_data[CH6] > CHANNEL_MIN_COMMAND)
packet[5] |= 0x08; //3D
//Requiest telemetry flag
packet[6] = 0x01;
//RXID checksum
packet[7] = crc8; //Sum RX_ID[0..2]
}
//Checksum
packet[8] = XK2_checksum(IS_BIND_IN_PROGRESS ? 0xC0 : num_ch);
// Send
XN297_SetFreqOffset();
XN297_SetPower();
XN297_SetTxRxMode(TX_EN);
XN297_WritePayload(packet, XK2_PAYLOAD_SIZE);
#if 0
debug("P");
for(uint8_t i=0; i E5 20 F2 80 00 00 00 00 43
telemetry_link = 1;
v_lipo1 = packet[3] ? 137:162; // low voltage 7.1V
}
}
#endif
if(bind_counter)
{
bind_counter--;
if(bind_counter == 0)
phase = XK2_DATA_PREP;
break;
}
#ifndef XK2_HUB_TELEMETRY
break;
#else
phase++;
return XK2_WRITE_TIME;
default: //XK2_RX
/*{ // Wait for packet to be sent before switching to receive mode
uint16_t start=(uint16_t)micros(), count=0;
while ((uint16_t)((uint16_t)micros()-(uint16_t)start) < 500)
{
if(XN297_IsPacketSent())
break;
count++;
}
debugln("%d",count);
}*/
//Switch to RX
XN297_SetTxRxMode(TXRX_OFF);
XN297_SetTxRxMode(RX_EN);
phase = XK2_DATA;
return XK2_PACKET_PERIOD-XK2_WRITE_TIME;
#endif
}
return XK2_PACKET_PERIOD;
}
void XK2_init()
{
//BIND_IN_PROGRESS; // autobind protocol
XK2_initialize_txid();
XK2_RF_init();
if(IS_BIND_IN_PROGRESS)
phase = XK2_BIND1;
else
phase = XK2_DATA_PREP;
bind_counter = 0;
hopping_frequency_no = 0;
#ifdef XK2_HUB_TELEMETRY
RX_RSSI = 100; // Dummy value
#endif
}
#endif
/*
XK A160 Piper CUB
Bind
----
Plane sends these packets:
RX: 0us C=71 S=Y A= CC CC CC CC CC P(9)= 9C BB CC DD 38 12 10 00 19
P[0] = 9C bind phase 1
P[1] = Dummy TX_ID
P[2] = Dummy TX_ID
P[3] = Dummy TX_ID
P[4] = RX_ID[0]
P[5] = RX_ID[1]
P[6] = RX_ID[2]
P[7] = 00
P[8] = sum P[0..7] + BF
TX responds to plane:
RX 9D 66 4F 47 38 12 10 00 B3
P[0] = 9D bind phase 2
P[1] = TX_ID[0]
P[2] = TX_ID[1]
P[3] = TX_ID[2]
P[4] = RX_ID[0]
P[5] = RX_ID[1]
P[6] = RX_ID[2]
P[7] = 00
P[8] = sum P[0..7] + C0
Planes ack:
RX: 4299us C=71 S=Y A= CC CC CC CC CC P(9)= 9B 66 4F 47 38 12 10 00 B0
RX: 26222us C=71 S=Y A= CC CC CC CC CC P(9)= 9B 66 4F 47 38 12 10 00 B0
RX: 8743us C=71 S=Y A= CC CC CC CC CC P(9)= 9B 66 4F 47 38 12 10 00 B0
P[0] = 9B bind phase 3
P[1] = TX_ID[0]
P[2] = TX_ID[1]
P[3] = TX_ID[2]
P[4] = RX_ID[0]
P[5] = RX_ID[1]
P[6] = RX_ID[2]
P[7] = 00
P[8] = sum P[0..7] + BF
Normal
------
TX sends
C=65,69,73,77 -> only one channel when telemetry is working
250K C=69 S=Y A= 66 4F 47 CC CC P(9)= 32 32 00 32 E0 00 01 5A 50
P[0] = A 00..32..64
P[1] = E 00..32..64
P[2] = T 00..64
P[3] = R 00..32..64
P[4] = alternates 20,60,A0,E0
trims
A 01..20..3F
E 41..60..7F
R 81..A0..BF
telemetry
E0 present when the telemetry works
6g/3d
C1 few times if P[6] flag 00->08
C0 few times if P[6] = flag 08->00
P[5] = flags
01=high rate
20=hover=long_press_left
40=light -> temporary
08=6g/3d=short_press_right sequece also switches for a few packets to C1 if 8 C0 if 0
P[6] = 00 telemetry nok
01 telemetry ok but sometimes switch to 1 also when telemetry is nok...
P[7] = 5A -> sum RX_ID[0..2]
P[8] = sum P[0..7] + TX_ID[0] - TX_ID[1] + TX_ID[2] + 21
Telemetry
RX on channel: 69, Time: 3408us P: 66 4F 47 00 00 00 00 00 C8
P[0] = TX_ID[0]
P[1] = TX_ID[1]
P[2] = TX_ID[2]
P[8] = sum P[0..7] + CC
Timing when plane is not detected:
RF
2469 110713 0
2473 114560 3847
2477 120291 5731
2465 135684 15393
2469 142138 6454
2473 145984 3846
2477 151753 5769
2465 155330 3577
*/
/* P10 Piper CUB
Bind
----
Phase 1
Plane sends these packets:
250K C=69 S=Y A= CC CC CC CC CC P(9)= 9C BB CC DD 84 24 20 00 97
P[0] = 9C bind phase 1
P[1] = Dummy TX_ID
P[2] = Dummy TX_ID
P[3] = Dummy TX_ID
P[4] = RX_ID[0]
P[5] = RX_ID[1]
P[6] = RX_ID[2]
P[7] = 00
P[8] = sum P[0..7] + BF + 10
Normal
------
TX sends
C=67 -> only one channel when telemetry is working
A= E8 25 3B CC CC P(9)= 32 32 00 32 A0 40 01 C8 6E
P[0] = A 00..32..64
P[1] = E 00..32..64
P[2] = T 00..64
P[3] = R 00..32..64
P[4] = alternates 20,60,A0,E0
trims
A 01..20..3F
E 41..60..7F
R 81..A0..BF
telemetry
E0 present when the telemetry works
6g/3d
C1 few times if P[6] flag 00->08
C0 few times if P[6] = flag 08->00
P[5] = flags
01=high rate
20=hover=long_press_left
40=light -> temporary
08=6g/3d=short_press_right sequece also switches for a few packets to C1 if 8 C0 if 0
P[6] = 00 telemetry nok
01 telemetry ok but sometimes switch to 1 also when telemetry is nok...
P[7] = C8 -> sum RX_ID[0..2]
P[8] = sum P[0..7] + TX_ID[0] - TX_ID[1] + TX_ID[2] + 21 +10
*/