NRF receiver
Dependencies: TSI mbed nRF24L01P
main_send.cpp
- Committer:
- vmihalcut
- Date:
- 2013-05-27
- Revision:
- 0:4eda749091bd
File content as of revision 0:4eda749091bd:
#include "mbed.h" #include "nRF24L01P.h" #include "TSISensor.h" Serial pc(USBTX, USBRX); // tx, rx nRF24L01P my_nrf24l01p(PTD2, // MOSI PTD3, // MISO PTD1, // SCK PTA13, // CSN PTD5, // CE PTD0); // IRQ #define TRANSFER_SIZE 4 DigitalOut led(LED_GREEN); TSISensor tsi; int main() { pc.baud(115200); pc.format(); char txData[TRANSFER_SIZE]; int txDataCnt = 4; my_nrf24l01p.powerUp(); pc.printf( "nRF24L01+ Frequency : %d MHz\r\n", my_nrf24l01p.getRfFrequency() ); pc.printf( "nRF24L01+ Output power : %d dBm\r\n", my_nrf24l01p.getRfOutputPower() ); pc.printf( "nRF24L01+ Data Rate : %d kbps\r\n", my_nrf24l01p.getAirDataRate() ); pc.printf( "nRF24L01+ TX Address : 0x%010llX\r\n", my_nrf24l01p.getTxAddress() ); pc.printf( "nRF24L01+ RX Address : 0x%010llX\r\n", my_nrf24l01p.getRxAddress() ); pc.printf( "Type keys to test transfers:\r\n (transfers are grouped into %d characters)\r\n", TRANSFER_SIZE ); my_nrf24l01p.setTransferSize( TRANSFER_SIZE ); my_nrf24l01p.enable(); while (1) { while(tsi.readPercentage() < 0.5); txData[0] = 's'; txData[1] = 't'; txData[2] = 'a'; txData[3] = '\0'; my_nrf24l01p.write( NRF24L01P_PIPE_P0, txData, txDataCnt ); pc.printf("txData: %s \n\r", txData); wait(1); while(tsi.readPercentage() < 0.5); txData[0] = 'S'; txData[1] = 'T'; txData[2] = 'A'; txData[3] = '\0'; my_nrf24l01p.write( NRF24L01P_PIPE_P0, txData, txDataCnt ); pc.printf("txData: %s \n\r", txData); wait(1); } } /* ///////////////////////////////////////////////////////////////////////////////////// Serial pc(USBTX, USBRX); // tx, rx nRF24L01P my_nrf24l01p(PTD2, // MOSI PTD3, // MISO PTD1, // SCK PTA13, // CSN PTD5, // CE PTD0); // IRQ #define TRANSFER_SIZE 4 DigitalOut led(LED_GREEN); int main() { pc.baud(9600); pc.format(); char txData[TRANSFER_SIZE]; txData[0] = 's'; txData[1] = 't'; txData[2] = 'a'; txData[3] = '\0'; int txDataCnt = 4; my_nrf24l01p.powerUp(); pc.printf( "nRF24L01+ Frequency : %d MHz\r\n", my_nrf24l01p.getRfFrequency() ); pc.printf( "nRF24L01+ Output power : %d dBm\r\n", my_nrf24l01p.getRfOutputPower() ); pc.printf( "nRF24L01+ Data Rate : %d kbps\r\n", my_nrf24l01p.getAirDataRate() ); pc.printf( "nRF24L01+ TX Address : 0x%010llX\r\n", my_nrf24l01p.getTxAddress() ); pc.printf( "nRF24L01+ RX Address : 0x%010llX\r\n", my_nrf24l01p.getRxAddress() ); pc.printf( "Type keys to test transfers:\r\n (transfers are grouped into %d characters)\r\n", TRANSFER_SIZE ); my_nrf24l01p.setTransferSize( TRANSFER_SIZE ); my_nrf24l01p.enable(); while (1) { led = 1 - led; wait(2.0); my_nrf24l01p.write( NRF24L01P_PIPE_P0, txData, txDataCnt ); pc.printf("txData: %s \n\r", txData); } } ///////////////////////////////////////////////////////////////////////////////////// Serial pc(USBTX, USBRX); // tx, rx nRF24L01P my_nrf24l01p(PTD2, // MOSI PTD3, // MISO PTD1, // SCK PTA13, // CSN PTD5, // CE PTD0); // IRQ #define TRANSFER_SIZE 4 TSISensor tsi; DigitalOut led(LED_GREEN); int main() { pc.baud(9600); pc.format(); char txData[TRANSFER_SIZE]; txData[0] = 's'; txData[1] = 't'; txData[2] = 'a'; txData[3] = '\0'; int txDataCnt = 4; my_nrf24l01p.powerUp(); pc.printf( "nRF24L01+ Frequency : %d MHz\r\n", my_nrf24l01p.getRfFrequency() ); pc.printf( "nRF24L01+ Output power : %d dBm\r\n", my_nrf24l01p.getRfOutputPower() ); pc.printf( "nRF24L01+ Data Rate : %d kbps\r\n", my_nrf24l01p.getAirDataRate() ); pc.printf( "nRF24L01+ TX Address : 0x%010llX\r\n", my_nrf24l01p.getTxAddress() ); pc.printf( "nRF24L01+ RX Address : 0x%010llX\r\n", my_nrf24l01p.getRxAddress() ); pc.printf( "Type keys to test transfers:\r\n (transfers are grouped into %d characters)\r\n", TRANSFER_SIZE ); my_nrf24l01p.setTransferSize( TRANSFER_SIZE ); my_nrf24l01p.enable(); while(1) { my_nrf24l01p.write( NRF24L01P_PIPE_P0, txData, txDataCnt ); //wait(0.5); //pc.printf("txData: %s \n\r", txData); //led = 1 - led; } } ///////////////////////////////////////////////////////////////////////////////////// Serial pc(USBTX, USBRX); // tx, rx nRF24L01P my_nrf24l01p(p5, p6, p7, p8, p9); #define TRANSFER_SIZE 32 //DigitalOut led(LED_GREEN); int main() { pc.baud(115200); pc.format(); char txData[TRANSFER_SIZE]; txData[0] = 's'; txData[1] = 't'; txData[2] = 'a'; txData[3] = '\0'; int txDataCnt = 4; my_nrf24l01p.powerUp(); my_nrf24l01p.setAirDataRate(NRF24L01P_DATARATE_1_MBPS); pc.printf( "nRF24L01+ Frequency : %d MHz\r\n", my_nrf24l01p.getRfFrequency() ); pc.printf( "nRF24L01+ Output power : %d dBm\r\n", my_nrf24l01p.getRfOutputPower() ); pc.printf( "nRF24L01+ Data Rate : %d kbps\r\n", my_nrf24l01p.getAirDataRate() ); pc.printf( "nRF24L01+ TX Address : 0x%010llX\r\n", my_nrf24l01p.getTxAddress() ); pc.printf( "nRF24L01+ RX Address : 0x%010llX\r\n", my_nrf24l01p.getRxAddress() ); pc.printf( "Type keys to test transfers:\r\n (transfers are grouped into %d characters)\r\n", TRANSFER_SIZE ); my_nrf24l01p.setTransferSize( TRANSFER_SIZE ); my_nrf24l01p.enable(); while (1) { //while(tsi.readPercentage() < 0.5); txData[0] = 's'; txData[1] = 't'; txData[2] = 'a'; txData[3] = '\0'; my_nrf24l01p.write( NRF24L01P_PIPE_P0, txData, txDataCnt ); pc.printf("txData: %s \n\r", txData); wait(1); //while(tsi.readPercentage() < 0.5); txData[0] = 'S'; txData[1] = 'T'; txData[2] = 'A'; txData[3] = '\0'; my_nrf24l01p.write( NRF24L01P_PIPE_P0, txData, txDataCnt ); pc.printf("txData: %s \n\r", txData); wait(1); } }*/