static uint16_t esky150_init()
{
    uint8_t rx_addr[ADDR_SIZE] = { 0x73, 0x73, 0x74, 0x63 };
    uint8_t tx_addr[ADDR_SIZE] = { 0x71, 0x0A, 0x31, 0xF4 };
    NRF24L01_Initialize();

    NRF24L01_WriteReg(NRF24L01_00_CONFIG, CRC_CONFIG); 
    NRF24L01_WriteReg(NRF24L01_01_EN_AA, 0x00);      // No Auto Acknoledgement
    NRF24L01_WriteReg(NRF24L01_02_EN_RXADDR, 0x01);  // Enable data pipe 0
    NRF24L01_WriteReg(NRF24L01_03_SETUP_AW, ADDR_SIZE-2);   // 4-byte RX/TX address
    NRF24L01_WriteReg(NRF24L01_04_SETUP_RETR, 0);    // Disable retransmit
    NRF24L01_SetPower(Model.tx_power);
    NRF24L01_SetBitrate(NRF24L01_BR_2M);
    NRF24L01_WriteRegisterMulti(NRF24L01_0A_RX_ADDR_P0, rx_addr, ADDR_SIZE);
    NRF24L01_WriteRegisterMulti(NRF24L01_10_TX_ADDR, tx_addr, ADDR_SIZE);


    NRF24L01_WriteReg(NRF24L01_07_STATUS, 0x70);     // Clear data ready, data sent, and retransmit
    NRF24L01_WriteReg(NRF24L01_11_RX_PW_P0, PAYLOADSIZE);   // bytes of data payload for pipe 0


    NRF24L01_Activate(0x73);
    NRF24L01_WriteReg(NRF24L01_1C_DYNPD, 1); // Dynamic payload for data pipe 0
    // Enable: Dynamic Payload Length, Payload with ACK , W_TX_PAYLOAD_NOACK
    NRF24L01_WriteReg(NRF24L01_1D_FEATURE, BV(NRF2401_1D_EN_DPL) | BV(NRF2401_1D_EN_ACK_PAY) | BV(NRF2401_1D_EN_DYN_ACK));

    // Check for Beken BK2421/BK2423 chip
    // It is done by using Beken specific activate code, 0x53
    // and checking that status register changed appropriately
    // There is no harm to run it on nRF24L01 because following
    // closing activate command changes state back even if it
    // does something on nRF24L01
    NRF24L01_Activate(0x53); // magic for BK2421 bank switch
    printf("Trying to switch banks\n");
    if (NRF24L01_ReadReg(NRF24L01_07_STATUS) & 0x80) {
        printf("BK2421 detected\n");
//        long nul = 0;
        // Beken registers don't have such nice names, so we just mention
        // them by their numbers
        // It's all magic, eavesdropped from real transfer and not even from the
        // data sheet - it has slightly different values
        NRF24L01_WriteRegisterMulti(0x00, (uint8_t *) "\x40\x4B\x01\xE2", 4);
        NRF24L01_WriteRegisterMulti(0x01, (uint8_t *) "\xC0\x4B\x00\x00", 4);
        NRF24L01_WriteRegisterMulti(0x02, (uint8_t *) "\xD0\xFC\x8C\x02", 4);
        NRF24L01_WriteRegisterMulti(0x03, (uint8_t *) "\xF9\x00\x39\x21", 4);
        NRF24L01_WriteRegisterMulti(0x04, (uint8_t *) "\xC1\x96\x9A\x1B", 4);
        NRF24L01_WriteRegisterMulti(0x05, (uint8_t *) "\x24\x06\x7F\xA6", 4);
        NRF24L01_WriteRegisterMulti(0x0C, (uint8_t *) "\x00\x12\x73\x00", 4);
        NRF24L01_WriteRegisterMulti(0x0D, (uint8_t *) "\x46\xB4\x80\x00", 4);
        NRF24L01_WriteRegisterMulti(0x0E, (uint8_t *) "\x41\x10\x04\x82\x20\x08\x08\xF2\x7D\xEF\xFF", 11);
        NRF24L01_WriteRegisterMulti(0x04, (uint8_t *) "\xC7\x96\x9A\x1B", 4);
        NRF24L01_WriteRegisterMulti(0x04, (uint8_t *) "\xC1\x96\x9A\x1B", 4);
    } else {
        printf("nRF24L01 detected\n");
    }
    NRF24L01_Activate(0x53); // switch bank back

    // Delay 50 ms
    return 50000u;
}
static void esky_init(u8 bind)
{
    NRF24L01_Initialize();

    // 2-bytes CRC, radio off
    NRF24L01_WriteReg(NRF24L01_00_CONFIG, BV(NRF24L01_00_EN_CRC) | BV(NRF24L01_00_CRCO)); 
    NRF24L01_WriteReg(NRF24L01_01_EN_AA, 0x00);            // No Auto Acknoledgement
    NRF24L01_WriteReg(NRF24L01_02_EN_RXADDR, 0x01);        // Enable data pipe 0
    if (bind) {
        set_bind_address();
    } else {
        set_data_address();
    }
    NRF24L01_WriteReg(NRF24L01_04_SETUP_RETR, 0);          // No auto retransmission
    NRF24L01_WriteReg(NRF24L01_05_RF_CH, 50);              // Channel 50 for bind packets
    NRF24L01_SetBitrate(0);                                // 1Mbps
    NRF24L01_SetPower(Model.tx_power);
    NRF24L01_WriteReg(NRF24L01_07_STATUS, 0x70);           // Clear data ready, data sent, and retransmit
//    NRF24L01_WriteReg(NRF24L01_08_OBSERVE_TX, 0x00);     // no write bits in this field
//    NRF24L01_WriteReg(NRF24L01_00_CD, 0x00);             // same
//    NRF24L01_WriteReg(NRF24L01_0C_RX_ADDR_P2, 0xC3);       // LSB byte of pipe 2 receive address
//    NRF24L01_WriteReg(NRF24L01_0D_RX_ADDR_P3, 0xC4);
//    NRF24L01_WriteReg(NRF24L01_0E_RX_ADDR_P4, 0xC5);
//    NRF24L01_WriteReg(NRF24L01_0F_RX_ADDR_P5, 0xC6);
    NRF24L01_WriteReg(NRF24L01_11_RX_PW_P0, PAYLOADSIZE);  // bytes of data payload for pipe 0
    NRF24L01_WriteReg(NRF24L01_12_RX_PW_P1, PAYLOADSIZE);
    NRF24L01_WriteReg(NRF24L01_13_RX_PW_P2, PAYLOADSIZE);
    NRF24L01_WriteReg(NRF24L01_14_RX_PW_P3, PAYLOADSIZE);
    NRF24L01_WriteReg(NRF24L01_15_RX_PW_P4, PAYLOADSIZE);
    NRF24L01_WriteReg(NRF24L01_16_RX_PW_P5, PAYLOADSIZE);
    NRF24L01_WriteReg(NRF24L01_17_FIFO_STATUS, 0x00);      // Just in case, no real bits to write here
}
void send_packet()
{
    u32 temp;
    for(u8 ch=0;ch<8;ch++)
    {
        temp=((s32)Channels[ch] * 0x1f1 / CHAN_MAX_VALUE + 0x5d9)<<3;
        packet[2*ch]=temp>>8;
        packet[2*ch+1]=temp;
    }
    for(u8 i=0; i<ADDRESS_LENGTH; i++)
        packet[16+i]=packet[23-i];
    NRF24L01_WriteReg(NRF24L01_07_STATUS, 0x70);        // Clear data ready, data sent, and retransmit
    NRF24L01_FlushTx();
    NRF24L01_WritePayload(packet, PACKET_SIZE);

    // Check and adjust transmission power. We do this after
    // transmission to not bother with timeout after power
    // settings change -  we have plenty of time until next
    // packet.
    if (tx_power != Model.tx_power) {
        //Keep transmit power updated
        tx_power = Model.tx_power;
        NRF24L01_SetPower(tx_power);
    }
}
static int cflie_init()
{
    NRF24L01_Initialize();

    // CRC, radio on
    NRF24L01_SetTxRxMode(TX_EN);
    NRF24L01_WriteReg(NRF24L01_00_CONFIG, BV(NRF24L01_00_EN_CRC) | BV(NRF24L01_00_CRCO) | BV(NRF24L01_00_PWR_UP)); 
    NRF24L01_WriteReg(NRF24L01_01_EN_AA, 0x01);              // Auto Acknowledgement for data pipe 0
    NRF24L01_WriteReg(NRF24L01_02_EN_RXADDR, 0x01);          // Enable data pipe 0
    NRF24L01_WriteReg(NRF24L01_03_SETUP_AW, TX_ADDR_SIZE-2); // 5-byte RX/TX address
    NRF24L01_WriteReg(NRF24L01_04_SETUP_RETR, 0x13);         // 3 retransmits, 500us delay

    NRF24L01_WriteReg(NRF24L01_05_RF_CH, rf_channel);        // Defined by model id
    NRF24L01_SetBitrate(data_rate);                          // Defined by model id

    NRF24L01_SetPower(Model.tx_power);
    NRF24L01_WriteReg(NRF24L01_07_STATUS, 0x70);             // Clear data ready, data sent, and retransmit

    NRF24L01_WriteRegisterMulti(NRF24L01_0A_RX_ADDR_P0, rx_tx_addr, TX_ADDR_SIZE);
    NRF24L01_WriteRegisterMulti(NRF24L01_10_TX_ADDR, rx_tx_addr, TX_ADDR_SIZE);

    // this sequence necessary for module from stock tx
    NRF24L01_ReadReg(NRF24L01_1D_FEATURE);
    NRF24L01_Activate(0x73);                          // Activate feature register
    NRF24L01_ReadReg(NRF24L01_1D_FEATURE);

    NRF24L01_WriteReg(NRF24L01_1C_DYNPD, 0x01);       // Enable Dynamic Payload Length on pipe 0
    NRF24L01_WriteReg(NRF24L01_1D_FEATURE, 0x06);     // Enable Dynamic Payload Length, enable Payload with ACK
    // 50ms delay in callback
    return 50000;
}
Exemple #5
0
void initrx(void)
{
    NRF24L01_Initialize();

    reset_beken();

    // 2-bytes CRC, radio off
    uint8_t config = BV(NRF24L01_00_EN_CRC) | BV(NRF24L01_00_CRCO) | BV(NRF24L01_00_PRIM_RX);

    NRF24L01_WriteReg(NRF24L01_00_CONFIG, config);
    NRF24L01_WriteReg(NRF24L01_01_EN_AA, 0x00);      // No Auto Acknoledgement
    NRF24L01_WriteReg(NRF24L01_02_EN_RXADDR, 0x01);  // Enable data pipe 0
    NRF24L01_WriteReg(NRF24L01_03_SETUP_AW, 0x03);   // 5-byte RX/TX address
    NRF24L01_WriteReg(NRF24L01_04_SETUP_RETR, 0xFF); // 4ms retransmit t/o, 15 tries
//    NRF24L01_WriteReg(NRF24L01_05_RF_CH, 0x08);      // Channel 8 - bind
    //NRF24L01_SetBitrate(NRF24L01_BR_1M);                          // 1Mbps
    NRF24L01_SetBitrate(NRF24L01_BR_250K); //250k for longer range.
    NRF24L01_SetPower(TXPOWER_100mW);
    NRF24L01_WriteReg(NRF24L01_07_STATUS, 0x70);     // Clear data ready, data sent, and retransmit
    NRF24L01_WriteReg(NRF24L01_11_RX_PW_P0, V2X2_PAYLOAD_SIZE);  // bytes of data payload for pipe 0
    NRF24L01_WriteReg(NRF24L01_17_FIFO_STATUS, 0x00); // Just in case, no real bits to write here
    uint8_t rx_tx_addr[] = {0x66, 0x88, 0x68, 0x68, 0x68};
//    uint8_t rx_p1_addr[] = {0x88, 0x66, 0x86, 0x86, 0x86};
    NRF24L01_WriteRegisterMulti(NRF24L01_0A_RX_ADDR_P0, rx_tx_addr, 5);
//    NRF24L01_WriteRegisterMulti(NRF24L01_0B_RX_ADDR_P1, rx_p1_addr, 5);
    NRF24L01_WriteRegisterMulti(NRF24L01_10_TX_ADDR, rx_tx_addr, 5);

    initialize_beken();

    lib_timers_delaymilliseconds(50);

    NRF24L01_FlushTx();
    NRF24L01_FlushRx();

    rf_ch_num = 0;

    // Turn radio power on
    config |= BV(NRF24L01_00_PWR_UP);
    NRF24L01_WriteReg(NRF24L01_00_CONFIG, config);
    // delayMicroseconds(150);
    lib_timers_delaymilliseconds(1); // 6 times more than needed

    valid_packets = missed_packets = bad_packets = 0;

    if (usersettings.boundprotocol == PROTO_NONE) {
        bind_phase = PHASE_NOT_BOUND;
        prepare_to_bind();
    } else {
        // Prepare to listen to bound protocol, if fails
        // try to bind
        bind_phase = PHASE_JUST_BOUND;
        set_bound();
    }
    switch_channel();
}
void init()
{
    NRF24L01_Initialize();
    NRF24L01_WriteReg(NRF24L01_03_SETUP_AW, 0x02);          // 4 bytes rx/tx address
    NRF24L01_WriteRegisterMulti(NRF24L01_10_TX_ADDR, (u8 *)"\x80\x80\x80\xB8", ADDRESS_LENGTH);     // Bind address
    NRF24L01_WriteRegisterMulti(NRF24L01_0A_RX_ADDR_P0, (u8 *)"\x80\x80\x80\xB8", ADDRESS_LENGTH);  // Bind address
    NRF24L01_FlushTx();
    NRF24L01_FlushRx();
    NRF24L01_WriteReg(NRF24L01_07_STATUS, 0x70);            // Clear data ready, data sent, and retransmit
    NRF24L01_WriteReg(NRF24L01_01_EN_AA, 0x00);             // No Auto Acknowldgement on all data pipes
    NRF24L01_WriteReg(NRF24L01_02_EN_RXADDR, 0x01);         // Enable data pipe 0 only
    NRF24L01_WriteReg(NRF24L01_11_RX_PW_P0, PACKET_SIZE);
    NRF24L01_SetPower(Model.tx_power);
}
Exemple #7
0
static void DM002_init()
{
    NRF24L01_Initialize();
    NRF24L01_SetTxRxMode(TX_EN);
    XN297_SetTXAddr((uint8_t *)"\x26\xA8\x67\x35\xCC", DM002_ADDRESS_SIZE);

    NRF24L01_FlushTx();
    NRF24L01_FlushRx();
    NRF24L01_WriteReg(NRF24L01_07_STATUS, 0x70);     // Clear data ready, data sent, and retransmit
    NRF24L01_WriteReg(NRF24L01_01_EN_AA, 0x00);      // No Auto Acknowldgement on all data pipes
    NRF24L01_WriteReg(NRF24L01_02_EN_RXADDR, 0x01);  // Enable data pipe 0 only
    NRF24L01_SetBitrate(NRF24L01_BR_1M);             // 1Mbps
    NRF24L01_SetPower(Model.tx_power);
    
    // Check for Beken BK2421/BK2423 chip
    // It is done by using Beken specific activate code, 0x53
    // and checking that status register changed appropriately
    // There is no harm to run it on nRF24L01 because following
    // closing activate command changes state back even if it
    // does something on nRF24L01
    NRF24L01_Activate(0x53); // magic for BK2421 bank switch
    dbgprintf("Trying to switch banks\n");
    if (NRF24L01_ReadReg(NRF24L01_07_STATUS) & 0x80) {
        dbgprintf("BK2421 detected\n");
        // Beken registers don't have such nice names, so we just mention
        // them by their numbers
        // It's all magic, eavesdropped from real transfer and not even from the
        // data sheet - it has slightly different values
        NRF24L01_WriteRegisterMulti(0x00, (u8 *) "\x40\x4B\x01\xE2", 4);
        NRF24L01_WriteRegisterMulti(0x01, (u8 *) "\xC0\x4B\x00\x00", 4);
        NRF24L01_WriteRegisterMulti(0x02, (u8 *) "\xD0\xFC\x8C\x02", 4);
        NRF24L01_WriteRegisterMulti(0x03, (u8 *) "\x99\x00\x39\x21", 4);
        NRF24L01_WriteRegisterMulti(0x04, (u8 *) "\xD9\x96\x82\x1B", 4);
        NRF24L01_WriteRegisterMulti(0x05, (u8 *) "\x24\x06\x7F\xA6", 4);
        NRF24L01_WriteRegisterMulti(0x0C, (u8 *) "\x00\x12\x73\x00", 4);
        NRF24L01_WriteRegisterMulti(0x0D, (u8 *) "\x46\xB4\x80\x00", 4);
        NRF24L01_WriteRegisterMulti(0x04, (u8 *) "\xDF\x96\x82\x1B", 4);
        NRF24L01_WriteRegisterMulti(0x04, (u8 *) "\xD9\x96\x82\x1B", 4);
    } else {
        dbgprintf("nRF24L01 detected\n");
    }
    NRF24L01_Activate(0x53); // switch bank back
}
Exemple #8
0
// Helper for sending a packet
// Assumes packet data has been put in tx_packet
// and tx_payload_len has been set correctly
static void send_packet()
{
    // clear packet status bits and Tx/Rx FIFOs
    NRF24L01_WriteReg(NRF24L01_07_STATUS, (BV(NRF24L01_07_TX_DS) | BV(NRF24L01_07_MAX_RT)));
    NRF24L01_FlushTx();
    NRF24L01_FlushRx();

    // Transmit the payload
    NRF24L01_WritePayload(tx_packet, tx_payload_len);

    ++packet_counter;

    // Check and adjust transmission power. We do this after
    // transmission to not bother with timeout after power
    // settings change -  we have plenty of time until next
    // packet.
    if (tx_power != Model.tx_power) {
        //Keep transmit power updated
        tx_power = Model.tx_power;
        NRF24L01_SetPower(tx_power);
    }
}
static void send_packet(u8 bind)
{
    union {
        u16 value;
        struct {
            u8 lsb;
            u8 msb;
        } bytes;
    } chanval;

    if (bind) {
        if (telemetry)
            packet[0] = 0xa3;
        else
            packet[0] = 0xa4;

        memcpy(&packet[1], rx_tx_addr, 5);
        memcpy(&packet[6], rf_channels, 4);
        switch (Model.proto_opts[PROTOOPTS_FORMAT]) {
                case FORMAT_REGULAR:
                    packet[10] = txid[0];
                    packet[11] = txid[1];
                    break;
                case FORMAT_X16_AH:
                    packet[10] = 0x00;
                    packet[11] = 0x00;
                    break;
                case FORMAT_IRDRONE:
                    packet[10] = 0x30;
                    packet[11] = 0x01;
                    break;
        }

    } else {
        switch (Model.proto_opts[PROTOOPTS_FORMAT]) {
                case FORMAT_REGULAR:
                    packet[0] = 0xa5;
                    break;
                case FORMAT_X16_AH:
                case FORMAT_IRDRONE:
                    packet[0] = 0xa6;
                    break;
        }
        packet[1] = 0xfa;       // normal mode is 0xf7, expert 0xfa
        packet[2] = GET_FLAG(CHANNEL_FLIP, 0x08)
            | GET_FLAG(CHANNEL_HEADLESS, 0x02)
            | GET_FLAG(CHANNEL_RTH, 0x01)
            | GET_FLAG(CHANNEL_VIDEO, 0x10)
            | GET_FLAG(CHANNEL_PICTURE, 0x20);
        packet[3] = GET_FLAG(CHANNEL_INVERTED, 0x80)
            | GET_FLAG(CHANNEL_TO, 0x20)
		    | GET_FLAG(CHANNEL_EMGSTOP, 0x04);
        chanval.value = scale_channel(CHANNEL1, 0x3ff, 0);      // aileron
        packet[4] = chanval.bytes.msb + DYNTRIM(chanval.value);
        packet[5] = chanval.bytes.lsb;
        chanval.value = scale_channel(CHANNEL2, 0, 0x3ff);      // elevator
        packet[6] = chanval.bytes.msb + DYNTRIM(chanval.value);
        packet[7] = chanval.bytes.lsb;
        chanval.value = scale_channel(CHANNEL3, 0, 0x3ff);      // throttle
        packet[8] = chanval.bytes.msb + 0x7c;
        packet[9] = chanval.bytes.lsb;
        chanval.value = scale_channel(CHANNEL4, 0x3ff, 0);      // rudder
        packet[10] = chanval.bytes.msb + DYNTRIM(chanval.value);
        packet[11] = chanval.bytes.lsb;
    }

    switch (Model.proto_opts[PROTOOPTS_FORMAT]) {
            case FORMAT_REGULAR:
                packet[12] = txid[2];
                packet[13] = 0x0a;
                break;
            case FORMAT_X16_AH:
                packet[12] = 0x00;
                packet[13] = 0x00;
                break;
            case FORMAT_IRDRONE:
                packet[12] = 0xe0;
                packet[13] = 0x2e;
                break;
    }

    packet[14] = checksum();



    NRF24L01_WriteReg(NRF24L01_05_RF_CH,
              bind ? bind_chan : rf_channels[rf_chan++]);

    rf_chan %= sizeof(rf_channels);

    NRF24L01_WriteReg(NRF24L01_07_STATUS, 0x70);
    NRF24L01_FlushTx();

    XN297_WritePayload(packet, PACKET_SIZE);

    NRF24L01_SetTxRxMode(TXRX_OFF);
    NRF24L01_SetTxRxMode(TX_EN);

    // Power on, TX mode, 2byte CRC
    // Why CRC0? xn297 does not interpret it - either 16-bit CRC or nothing
    XN297_Configure(BV(NRF24L01_00_EN_CRC) | BV(NRF24L01_00_CRCO) |
                    BV(NRF24L01_00_PWR_UP));


    if (telemetry) {
        // switch radio to rx, no crc
        NRF24L01_WriteReg(NRF24L01_00_CONFIG, 0x03);
    }
    // Check and adjust transmission power. We do this after
    // transmission to not bother with timeout after power
    // settings change -  we have plenty of time until next
    // packet.
    if (tx_power != Model.tx_power) {
        //Keep transmit power updated
        tx_power = Model.tx_power;
        NRF24L01_SetPower(tx_power);
    }
#ifdef EMULATOR
    dbgprintf("next chan 0x%02x, bind %d, data %02x",
              bind ? bind_chan : rf_channels[rf_chan], bind,
              packet[0]);
    for (int i = 1; i < PACKET_SIZE; i++)
        dbgprintf(" %02x", packet[i]);
    dbgprintf("\n");
#endif
}
Exemple #10
0
static int cflie_init()
{
    NRF24L01_Initialize();

    // CRC, radio on
    NRF24L01_SetTxRxMode(TX_EN);
    NRF24L01_WriteReg(NRF24L01_00_CONFIG, BV(NRF24L01_00_EN_CRC) | BV(NRF24L01_00_CRCO) | BV(NRF24L01_00_PWR_UP)); 
    NRF24L01_WriteReg(NRF24L01_01_EN_AA, 0x01);              // Auto Acknowledgement for data pipe 0
    NRF24L01_WriteReg(NRF24L01_02_EN_RXADDR, 0x01);          // Enable data pipe 0
    NRF24L01_WriteReg(NRF24L01_03_SETUP_AW, TX_ADDR_SIZE-2); // 5-byte RX/TX address
    NRF24L01_WriteReg(NRF24L01_04_SETUP_RETR, 0x13);         // 3 retransmits, 500us delay

    NRF24L01_WriteReg(NRF24L01_05_RF_CH, rf_channel);        // Defined by model id
    NRF24L01_SetBitrate(data_rate);                          // Defined by model id

    NRF24L01_SetPower(Model.tx_power);
    NRF24L01_WriteReg(NRF24L01_07_STATUS, 0x70);             // Clear data ready, data sent, and retransmit

    NRF24L01_WriteRegisterMulti(NRF24L01_0A_RX_ADDR_P0, rx_tx_addr, TX_ADDR_SIZE);
    NRF24L01_WriteRegisterMulti(NRF24L01_10_TX_ADDR, rx_tx_addr, TX_ADDR_SIZE);

    // this sequence necessary for module from stock tx
    NRF24L01_ReadReg(NRF24L01_1D_FEATURE);
    NRF24L01_Activate(0x73);                          // Activate feature register
    NRF24L01_ReadReg(NRF24L01_1D_FEATURE);

    NRF24L01_WriteReg(NRF24L01_1C_DYNPD, 0x01);       // Enable Dynamic Payload Length on pipe 0
    NRF24L01_WriteReg(NRF24L01_1D_FEATURE, 0x06);     // Enable Dynamic Payload Length, enable Payload with ACK

    // Check for Beken BK2421/BK2423 chip
    // It is done by using Beken specific activate code, 0x53
    // and checking that status register changed appropriately
    // There is no harm to run it on nRF24L01 because following
    // closing activate command changes state back even if it
    // does something on nRF24L01
    NRF24L01_Activate(0x53); // magic for BK2421 bank switch
    dbgprintf("Trying to switch banks\n");
    if (NRF24L01_ReadReg(NRF24L01_07_STATUS) & 0x80) {
        dbgprintf("BK2421 detected\n");
        long nul = 0;
        // Beken registers don't have such nice names, so we just mention
        // them by their numbers
        // It's all magic, eavesdropped from real transfer and not even from the
        // data sheet - it has slightly different values
        NRF24L01_WriteRegisterMulti(0x00, (u8 *) "\x40\x4B\x01\xE2", 4);
        NRF24L01_WriteRegisterMulti(0x01, (u8 *) "\xC0\x4B\x00\x00", 4);
        NRF24L01_WriteRegisterMulti(0x02, (u8 *) "\xD0\xFC\x8C\x02", 4);
        NRF24L01_WriteRegisterMulti(0x03, (u8 *) "\xF9\x00\x39\x21", 4);
        NRF24L01_WriteRegisterMulti(0x04, (u8 *) "\xC1\x96\x9A\x1B", 4);
        NRF24L01_WriteRegisterMulti(0x05, (u8 *) "\x24\x06\x7F\xA6", 4);
        NRF24L01_WriteRegisterMulti(0x06, (u8 *) &nul, 4);
        NRF24L01_WriteRegisterMulti(0x07, (u8 *) &nul, 4);
        NRF24L01_WriteRegisterMulti(0x08, (u8 *) &nul, 4);
        NRF24L01_WriteRegisterMulti(0x09, (u8 *) &nul, 4);
        NRF24L01_WriteRegisterMulti(0x0A, (u8 *) &nul, 4);
        NRF24L01_WriteRegisterMulti(0x0B, (u8 *) &nul, 4);
        NRF24L01_WriteRegisterMulti(0x0C, (u8 *) "\x00\x12\x73\x00", 4);
        NRF24L01_WriteRegisterMulti(0x0D, (u8 *) "\x46\xB4\x80\x00", 4);
        NRF24L01_WriteRegisterMulti(0x0E, (u8 *) "\x41\x10\x04\x82\x20\x08\x08\xF2\x7D\xEF\xFF", 11);
        NRF24L01_WriteRegisterMulti(0x04, (u8 *) "\xC7\x96\x9A\x1B", 4);
        NRF24L01_WriteRegisterMulti(0x04, (u8 *) "\xC1\x96\x9A\x1B", 4);
    } else {
        dbgprintf("nRF24L01 detected\n");
    }
    NRF24L01_Activate(0x53); // switch bank back

    // 50ms delay in callback
    return 50000;
}
Exemple #11
0
static void esky_init(u8 bind)
{
    NRF24L01_Initialize();

    // 2-bytes CRC, radio off
    NRF24L01_WriteReg(NRF24L01_00_CONFIG, BV(NRF24L01_00_EN_CRC) | BV(NRF24L01_00_CRCO)); 
    NRF24L01_WriteReg(NRF24L01_01_EN_AA, 0x00);            // No Auto Acknoledgement
    NRF24L01_WriteReg(NRF24L01_02_EN_RXADDR, 0x01);        // Enable data pipe 0
    if (bind) {
        set_bind_address();
    } else {
        set_data_address();
    }
    NRF24L01_WriteReg(NRF24L01_04_SETUP_RETR, 0);          // No auto retransmission
    NRF24L01_WriteReg(NRF24L01_05_RF_CH, 50);              // Channel 50 for bind packets
    NRF24L01_SetBitrate(0);                                // 1Mbps
    NRF24L01_SetPower(Model.tx_power);
    NRF24L01_WriteReg(NRF24L01_07_STATUS, 0x70);           // Clear data ready, data sent, and retransmit
//    NRF24L01_WriteReg(NRF24L01_08_OBSERVE_TX, 0x00);     // no write bits in this field
//    NRF24L01_WriteReg(NRF24L01_00_CD, 0x00);             // same
//    NRF24L01_WriteReg(NRF24L01_0C_RX_ADDR_P2, 0xC3);       // LSB byte of pipe 2 receive address
//    NRF24L01_WriteReg(NRF24L01_0D_RX_ADDR_P3, 0xC4);
//    NRF24L01_WriteReg(NRF24L01_0E_RX_ADDR_P4, 0xC5);
//    NRF24L01_WriteReg(NRF24L01_0F_RX_ADDR_P5, 0xC6);
    NRF24L01_WriteReg(NRF24L01_11_RX_PW_P0, PAYLOADSIZE);  // bytes of data payload for pipe 0
    NRF24L01_WriteReg(NRF24L01_12_RX_PW_P1, PAYLOADSIZE);
    NRF24L01_WriteReg(NRF24L01_13_RX_PW_P2, PAYLOADSIZE);
    NRF24L01_WriteReg(NRF24L01_14_RX_PW_P3, PAYLOADSIZE);
    NRF24L01_WriteReg(NRF24L01_15_RX_PW_P4, PAYLOADSIZE);
    NRF24L01_WriteReg(NRF24L01_16_RX_PW_P5, PAYLOADSIZE);
    NRF24L01_WriteReg(NRF24L01_17_FIFO_STATUS, 0x00);      // Just in case, no real bits to write here

    // Check for Beken BK2421/BK2423 chip
    // It is done by using Beken specific activate code, 0x53
    // and checking that status register changed appropriately
    // There is no harm to run it on nRF24L01 because following
    // closing activate command changes state back even if it
    // does something on nRF24L01
    NRF24L01_Activate(0x53); // magic for BK2421 bank switch
    printf("Trying to switch banks\n");
    if (NRF24L01_ReadReg(NRF24L01_07_STATUS) & 0x80) {
        printf("BK2421 detected\n");
        // Beken registers don't have such nice names, so we just mention
        // them by their numbers
        // It's all magic, eavesdropped from real transfer and not even from the
        // data sheet - it has slightly different values
        NRF24L01_WriteRegisterMulti(0x00, (u8 *) "\x40\x4B\x01\xE2", 4);
        NRF24L01_WriteRegisterMulti(0x01, (u8 *) "\xC0\x4B\x00\x00", 4);
        NRF24L01_WriteRegisterMulti(0x02, (u8 *) "\xD0\xFC\x8C\x02", 4);
        NRF24L01_WriteRegisterMulti(0x03, (u8 *) "\xF9\x00\x39\x21", 4);
        NRF24L01_WriteRegisterMulti(0x04, (u8 *) "\xC1\x96\x9A\x1B", 4);
        NRF24L01_WriteRegisterMulti(0x05, (u8 *) "\x24\x06\x7F\xA6", 4);
        NRF24L01_WriteRegisterMulti(0x0C, (u8 *) "\x00\x12\x73\x00", 4);
        NRF24L01_WriteRegisterMulti(0x0D, (u8 *) "\x46\xB4\x80\x00", 4);
        NRF24L01_WriteRegisterMulti(0x0E, (u8 *) "\x41\x10\x04\x82\x20\x08\x08\xF2\x7D\xEF\xFF", 11);
        NRF24L01_WriteRegisterMulti(0x04, (u8 *) "\xC7\x96\x9A\x1B", 4);
        NRF24L01_WriteRegisterMulti(0x04, (u8 *) "\xC1\x96\x9A\x1B", 4);
    } else {
        printf("nRF24L01 detected\n");
    }
    NRF24L01_Activate(0x53); // switch bank back

    // Implicit delay in callback
    // delay(50);
}
Exemple #12
0
static void DM002_send_packet(u8 bind)
{
    memcpy(&packet[5],(uint8_t *)"\x00\x7F\x7F\x7F\x00\x00\x00",7);
    if(bind)
    {
        packet[0] = 0xAA;
        packet[1] = rx_tx_addr[0]; 
        packet[2] = rx_tx_addr[1];
        packet[3] = rx_tx_addr[2];
        packet[4] = rx_tx_addr[3];
    }
    else
    {
        packet[0]=0x55;
        // Throttle : 0 .. 200
        packet[1]=scale_channel(CHANNEL3,0,200);
        // Other channels min 0x57, mid 0x7F, max 0xA7
        packet[2] = scale_channel(CHANNEL4,0xA7,0x57);     // rudder
        packet[3] = scale_channel(CHANNEL1, 0xA7,0x57);  // aileron
        packet[4] = scale_channel(CHANNEL2, 0xA7, 0x57); // elevator
        // Features
        packet[9] =   DM002_FLAG_HIGH // high rate
                    | GET_FLAG(CHANNEL_FLIP,    DM002_FLAG_FLIP)
                    | GET_FLAG_INV(CHANNEL_LED, DM002_FLAG_LED)
                    | GET_FLAG(CHANNEL_CAMERA1, DM002_FLAG_CAMERA1)
                    | GET_FLAG(CHANNEL_CAMERA2, DM002_FLAG_CAMERA2)
                    | GET_FLAG(CHANNEL_HEADLESS,DM002_FLAG_HEADLESS)
                    | GET_FLAG(CHANNEL_RTH,     DM002_FLAG_RTH);
        // Packet counter
        if(packet_count&0x03)
        {
            packet_count++;
            hopping_frequency_no++;
            hopping_frequency_no&=4;
        }
        packet_count&=0x0F;
        packet[10] = packet_count;
        packet_count++;
    }
    //CRC
    for(uint8_t i=0;i<DM002_PACKET_SIZE-1;i++)
        packet[11]+=packet[i];
    
    // Power on, TX mode, 2byte CRC
    // Why CRC0? xn297 does not interpret it - either 16-bit CRC or nothing
    XN297_Configure(BV(NRF24L01_00_EN_CRC) | BV(NRF24L01_00_CRCO) | BV(NRF24L01_00_PWR_UP));
    if (bind)
        NRF24L01_WriteReg(NRF24L01_05_RF_CH, DM002_RF_BIND_CHANNEL);
    else
        NRF24L01_WriteReg(NRF24L01_05_RF_CH, hopping_frequency[hopping_frequency_no]);
    // clear packet status bits and TX FIFO
    NRF24L01_WriteReg(NRF24L01_07_STATUS, 0x70);
    NRF24L01_FlushTx();
    XN297_WritePayload(packet, DM002_PACKET_SIZE);

    if (tx_power != Model.tx_power) {
        //Keep transmit power updated
        tx_power = Model.tx_power;
        NRF24L01_SetPower(tx_power);
    }
}