UART console application for testing SX1272/SX1276
This is a UART console test application for using SX127x library driver for SX1272/SX1276 radio transceivers. Serial console is provided at 57600bps. Refer to Serial Communication with a PC for information about using the serial port with your PC.
Using this command interface, you can exercise the functionality of radio chip without needing specialized software application for your PC.
Commands which can be used include ?
to list available commands, or .
to query status from radio chip, for example.
The serial console allows you to configure the radio chip, such as setting spreading factor, bandwidth, operating frequency, etc.
A simple chat application is provided to try communications between two boards. The SX127x library object is instantiated with pin assignments generic arduino headers, but can be easily reassigned for any mbed board.
The same driver library can operate for both SX1272 and SX1276. Upon starting, the driver auto-detects whether SX1272 or SX1276 transceiver chip is connected by attempting to change the LowFrequencyModeOn
bit in RegOpMode
register. If this bit can be changed, then the radio device is SX1276. This bit is not implemented in SX1272. A few of the radio driver functions select behavior based on this detection. The differences between these two devices is small, from a software perspective.
Using with SX1276MB1xAS Shield
This component plugs into any board with arduino uno headers.
There are two different version of this shield. European version (MAS), and North American (LAS). The LAS shield uses PA_BOOST transmit pin to permit +20dBm power. The MAS version uses RFO transmit pin in Europe. This software reads RF switch pin (A4 pin) pulling resistor to determine which type of shield is installed.
Using with your own production board
This software is useful for validating RF performance your own LoRa board design, because only two external pins needs to be provided to PC (UART TX/RX). You can select an mbed platform which matches the CPU on your own board. If the memory size doesnt match exactly, you can export the program to an offline toolchain and edit the target type or linker file there.
Transmitter Test Guidelines
FSK mode is used for transmitter testing, because an unmodulated carrier can be sent, permitting easy measurement of TX power and frequency error.
commands used for transmitter testing:
frf915.0
change to your desired RF center frequency (in this case 915MHz)L
to toggle the radio chip into FSK mode.fdev0
to configure TX frequency deviation to zero, to put the transmitted carrier on the center frequency.pas
to select which TX pin is connected to antenna matching (RFO vs PA_BOOST).op<dBm>
to configure TX power.- If you desire to test higher power PA_BOOST, use
ocp<mA>
w 01 03
put radio chip into transmit mode (skips writing to FIFO). This will cause radio to transmit preamble, because the FIFO is empty in TX mode. Since Fdev is zero, an unmodulated carrier is sent.- Spectrum analyzer can now be used to to observe TX power, harmonics, power consumption, or frequency error.
stby
to end transmission, or useh
to reset radio chip to default condition.- Use period
.
command at any time to review current radio configuration.
LoRa transmitter testing
- use
L
command to toggle radio into LoRa, if necessary. - Normally the
tx
command is used to manually send single packets. txc
will toggleTxContinuousMode
in LoRa modem to send continuous modulated transmission.- Useful for checking adjacent channel power.
- enter
txc
again to end transmission.
Receiver Test Guidelines
FSK mode is used for receiver sensitivity testing, allowing the use of a BERT signal generator (such as R/S SMIQ03B). Using this method provides real-time indication of receiver sensitivity, useful for tuning and impedance matching. The radio chip outputs DCLK and DATA digital signals which are connected back to BERT signal generator.
commands used for receiver testing:
L
to toggle the radio chip into FSK mode.datam
to toggle FSK modem into continuous mode. This disables packet engine and gives direct access to demodulator.- configure DIO1 pin to DCLK function, and DIO2 pin to DATA function:
dio
command to list current DIO pin asignmentsd1
to cycle DIO1 function untilDclk
is selectedd2
for DIO2, onlyData
function is available in FSK continuous mode
frf915.0
change to your desired RF center frequency (in this case 915MHz)rx
to start receiverstby
to disable receiver
Full command list
Arguments shown in square brackets []
indicate required. <>
are optional, where leaving off the argument usually causes a read of the item, and providing the value causes a write operation. You should always have the radio chip datasheet on-hand when using these commands.
Hitting <enter> key by itself will repeat last command.
<Ctrl-C> will cancel an operation in progress.
command list: common commands (both LoRa and FSK)
command | description |
---|---|
. (period) | print current radio status |
? | list available commands |
L | toggle active radio modem (LoRa vs FSK) |
h | hardware reset, put radio into default power-on condition |
frf<MHz> | get/set RF operating frequency |
rx | start radio receiver (any received packets are printed onto your serial terminal) |
rssi | read instantaneous RSSI (level read at the time command is issued) |
tx<%d> | transmit test packet. Packet length value can be provided as argument, or uses last value if not provided |
payl<%d> | get/set payload length |
bw<KHz> | get/set bandwidth. In LoRa mode, both receive and transmit bandwidth are changed. For FSK, only receive bandwidth is affected. bwa accesses AFC bandwidth in FSK |
pas | toggle RFO / PA_BOOST transmit pin output selection |
op<dBm> | get/set TX output power. Value is provided in dBm. Special case is value of 20dBm (on PA_BOOST), which causes increase in TX DAC voltage |
ocp<mA> | get/set TX current limit, in milliamps. Necessary adjustment when +20dBm is used |
dio | show DIO pin assignments |
d<0-5> | change DIO pin assignment, the pin number is given as arguement. Each pin has up to 4 possible functions |
pres<%d> | set preamble length. LoRa: number of symbols. FSK: number of bytes |
crcon | toggle crcOn |
lnab | cycle LNA-boost setting (receiver performance adjustment) |
R | read all radio registers (use only while reading chip datasheet) |
r[%x] | read single radio register (use only while reading chip datasheet) |
w[%x %x] | write single radio register (use only while reading chip datasheet) |
pllbw | change PLL bandwidth |
stby | set chip mode to standby |
sleep | set chip mode to sleep |
fstx | set chip mode to fstx |
fsrx | set chip mode to fsrx |
Eiger range test commands | description |
pid<%d> | get set ID number in range test payload |
pertx<%d> | start Eiger PER transmit. The count of packets to send is provided as arguement |
perrx | start Eiger PER receive |
txpd<%d> | get/set tx delay between PER packets transmitted |
command list: LoRa modem commands
LoRa command | LoRa description |
---|---|
iqinv | toggle RX IQ invert |
cin | toggle TX IQ invert |
lhp<%d> | (RX) get/set hop period |
sync<%x> | get/set sync (post-preamble gap, single byte) |
cr<1-4> | get/set codingRate |
lhm | toggle explicit/implicit (explicit mode sends payload length with each packet) |
sf<%d> | get/set spreadingFactor (SF7 to SF12) |
ldr | toggle LowDataRateOptimize (changes payload encoding, for long packets) |
txc | toggle TxContinuousMode |
rxt<%d> | get/set SymbTimeout |
rxs | start RX_SINGLE (receives only for SymbTimeout symbols) |
cad<%d num tries> | run channel activity detection |
command list: FSK modem commands
FSK command | FSK description |
---|---|
c<%d> | get/set test cases. Several FSK bitrates/bandwidths pre-configured to give optimal performance. |
fdev<kHz> | (TX) get/set frequency deviation |
mods | (TX) increment modulation shaping |
par | (TX) increment paRamp |
datam | toggle DataMode (packet/continuous) |
fifot | toggle TxStartCondition (FifoThreshold level vs FifoNotEmpty) |
br<%f kbps> | get/set bitrate |
dcf | increment DcFree (manchester / whitening) |
pktf | toggle PacketFormat fixed/variable length |
syncon | toggle SyncOn (frame sync, SFD enable) |
bitsync | toggle BitSyncOn (continuous mode only) |
syncw<hex bytes> | get/set syncword. Sync bytes are provided by hex octects separated by spaces. |
fei | (RX) read FEI |
rxt | (RX) increment RxTrigger (RX start on rssi vs. preamble detect) |
rssit<-dBm> | (RX) get/set rssi threshold (trigger level for RSSI interrupt) |
rssis<%d> | (RX) get/set rssi smoothing |
rssio<%d> | (RX) get/set rssi offset |
agcauto | (RX) toggle AgcAutoOn (true = LNA gain set automatically) |
afcauto | (RX) toggle AfcAutoOn |
ac | (RX) AfcClear |
ar | (RX) increment AutoRestartRxMode |
alc | (RX) toggle AfcAutoClearOn (only if AfcAutoOn is set) |
prep | (RX) toggle PreamblePolarity (0xAA vs 0x55) |
pde | (RX) toggle PreambleDetectorOn |
pds<%d> | (RX) get/set PreambleDetectorSize |
pdt<%d> | (RX) get/set PreambleDetectorTol |
mp | (RX) toggle MapPreambleDetect (DIO function RSSI vs PreambleDetect) |
thr<%d> | get/set FifoThreshold (triggers FifoLevel interrupt) |
poll | toggle poll_irq_en. Radio events read from DIO pins vs polling of IrqFlags register |
E | empty out FIFO |
clkout | increment ClkOut divider |
ook | enter OOK mode |
ookt | increment OokThreshType |
ooks | increment OokPeakTheshStep |
sqlch<%d> | get/set OokFixedThresh |
main.cpp
- Committer:
- dudmuck
- Date:
- 2017-04-14
- Revision:
- 22:2005df80c8a8
- Parent:
- 21:b84a77dfb43c
- Child:
- 23:821b4f426ee6
File content as of revision 22:2005df80c8a8:
#include "sx127x_lora.h" #include "sx127x_fsk.h" #define __STDC_FORMAT_MACROS #include <inttypes.h> //#include "kermit.h" //#define FSK_PER //#define START_EIGER_RX //#define START_EIGER_TX //#define START_OOK_TX_TEST /* on B-L072Z-LRWAN1 use target NUCLEO-L073RX, and for correct baudrate must install SB36 and remove C24 */ //#define TYPE_ABZ DigitalOut led1(LED1); Serial pc(USBTX, USBRX); uint8_t tx_cnt; char pcbuf[64]; int pcbuf_len; typedef enum { APP_NONE = 0, APP_CHAT } app_e; app_e app = APP_NONE; #define FSK_LARGE_PKT_THRESHOLD 0x3f bool crc32_en; // ethcrc /*********** cmd_ulrx()... ************/ typedef enum { ULRX_STATE_OFF = 0, ULRX_STATE_NEED_LENGTH, ULRX_STATE_PAYLOAD, ULRX_STATE_SYNC1 } ulrx_state_e; ulrx_state_e ulrx_state = ULRX_STATE_OFF; bool ulrx_enable; /*********** ...cmd_ulrx() ************/ uint8_t rx_payload_idx; /************** fsk modeReady isr... **********/ bool rx_payloadReady_int_en; // cmd_prrx() #define N_RX_PKTS 32 #define RX_PKT_SIZE_LIMIT 32 uint8_t rx_pkts[N_RX_PKTS][RX_PKT_SIZE_LIMIT]; uint8_t n_rx_pkts; /************** ...fsk modeReady isr **********/ #ifdef TARGET_STM CRC_HandleTypeDef CrcHandle; #endif /* TARGET_STM */ int rssi_polling_thresh; // 0 = polling off bool ook_test_en; bool poll_irq_en; volatile RegIrqFlags2_t fsk_RegIrqFlags2_prev; volatile RegIrqFlags1_t fsk_RegIrqFlags1_prev; Timer rx_start_timer; uint32_t secs_rx_start; /***************************** eiger per: *************************************************/ uint32_t num_cads; bool cadper_enable; bool per_en; float per_tx_delay = 0.1; int per_id; uint32_t PacketTxCnt, PacketTxCntEnd; uint32_t PacketPerOkCnt; int PacketRxSequencePrev; uint32_t PacketPerKoCnt; uint32_t PacketNormalCnt; Timeout per_timeout; /******************************************************************************/ #ifdef TARGET_MTS_MDOT_F411RE // mosi, miso, sclk, cs, rst, dio0, dio1 SX127x radio(LORA_MOSI, LORA_MISO, LORA_SCK, LORA_NSS, LORA_RESET, LORA_DIO0, LORA_DIO1); DigitalOut txctl(LORA_TXCTL); DigitalOut rxctl(LORA_RXCTL); void rfsw_callback() { /* SKY13350 */ if (radio.RegOpMode.bits.Mode == RF_OPMODE_TRANSMITTER) { // start of transmission txctl = 1; rxctl = 0; } else { // reception: txctl = 0; rxctl = 1; } } #define FSK_RSSI_OFFSET 0 #define FSK_RSSI_SMOOTHING 2 DigitalIn dio2(LORA_DIO2); DigitalIn dio4(LORA_DIO4); #elif defined(TARGET_NUCLEO_L073RZ) && defined(TYPE_ABZ) /********************* ...mDot **********************/ /* Murata TypeABZ discovery board */ // mosi, miso, sclk, cs, rst, dio0, dio1 SX127x radio(PA_7, PA_6, PB_3, PA_15, PC_0, PB_4, PB_1); DigitalIn dio2(PB_0); DigitalIn dio3(PC_13); #define FSK_RSSI_OFFSET 0 #define FSK_RSSI_SMOOTHING 2 #define CRF1 PA_1 #define CRF2 PC_2 #define CRF3 PC_1 DigitalOut Vctl1(CRF1); DigitalOut Vctl2(CRF2); DigitalOut Vctl3(CRF3); void rfsw_callback() { if (radio.RegOpMode.bits.Mode == RF_OPMODE_TRANSMITTER) { Vctl1 = 0; if (radio.RegPaConfig.bits.PaSelect) { Vctl2 = 0; Vctl3 = 1; } else { Vctl2 = 1; Vctl3 = 0; } } else { if (radio.RegOpMode.bits.Mode == RF_OPMODE_RECEIVER || radio.RegOpMode.bits.Mode == RF_OPMODE_RECEIVER_SINGLE) Vctl1 = 1; else Vctl1 = 0; Vctl2 = 0; Vctl3 = 0; } } #else /***************** ..Type-ABZ and L073RZ *************/ // pin: 3 8 1 7 10 12 5 // mosi, miso, sclk, cs, rst, dio0, dio1 SX127x radio(D11, D12, D13, D10, A0, D2, D3); // sx1276 arduino shield // for SX1276 arduino shield: #ifdef TARGET_LPC11U6X //DigitalOut rfsw(P0_23); DigitalInOut rfsw(P0_23); #else //DigitalOut rfsw(A4); DigitalInOut rfsw(A4); #endif InterruptIn dio0int(D2); InterruptIn dio1int(D3); InterruptIn dio2int(D4); InterruptIn dio4int(D8); DigitalIn dio2(D4); DigitalIn dio3(D5); DigitalIn dio4(D8); DigitalIn dio5(D9); #if defined(TARGET_STM) DigitalOut pc3(PC_3); // nucleo corner pin for misc indication #endif void rfsw_callback() { if (radio.RegOpMode.bits.Mode == RF_OPMODE_TRANSMITTER) rfsw = 1; else rfsw = 0; } #define FSK_RSSI_OFFSET 5 #define FSK_RSSI_SMOOTHING 2 typedef enum { SHIELD_TYPE_NONE = 0, SHIELD_TYPE_LAS, SHIELD_TYPE_MAS, } shield_type_e; shield_type_e shield_type; #endif /* !TARGET_MTS_MDOT_F411RE */ SX127x_fsk fsk(radio); SX127x_lora lora(radio); //Kermit kermit(lora); #ifndef TYPE_ABZ volatile bool saved_dio4; #endif uint32_t crcTable[256]; void make_crc_table() { const uint32_t POLYNOMIAL = 0xEDB88320; uint32_t remainder; uint8_t b = 0; do{ // Start with the data byte remainder = b; for (unsigned long bit = 8; bit > 0; --bit) { if (remainder & 1) remainder = (remainder >> 1) ^ POLYNOMIAL; else remainder = (remainder >> 1); } crcTable[(size_t)b] = remainder; } while(0 != ++b); } uint32_t gen_crc(const uint8_t *p, size_t n) { uint32_t crc = 0xffffffff; size_t i; for(i = 0; i < n; i++) { crc = crcTable[*p++ ^ (crc&0xff)] ^ (crc>>8); } return(~crc); } void printLoraIrqs_(bool clear) { //in radio class -- RegIrqFlags_t RegIrqFlags; //already read RegIrqFlags.octet = radio.read_reg(REG_LR_IRQFLAGS); printf("\r\nIrqFlags:"); if (lora.RegIrqFlags.bits.CadDetected) printf("CadDetected "); if (lora.RegIrqFlags.bits.FhssChangeChannel) { //radio.RegHopChannel.octet = radio.read_reg(REG_LR_HOPCHANNEL); printf("FhssChangeChannel:%d ", lora.RegHopChannel.bits.FhssPresentChannel); } if (lora.RegIrqFlags.bits.CadDone) printf("CadDone "); if (lora.RegIrqFlags.bits.TxDone) printf("TxDone "); if (lora.RegIrqFlags.bits.ValidHeader) printf("[42mValidHeader[0m "); if (lora.RegIrqFlags.bits.PayloadCrcError) printf("[41mPayloadCrcError[0m "); if (lora.RegIrqFlags.bits.RxDone) printf("[42mRxDone[0m "); if (lora.RegIrqFlags.bits.RxTimeout) printf("RxTimeout "); printf("\r\n"); if (clear) radio.write_reg(REG_LR_IRQFLAGS, lora.RegIrqFlags.octet); } void lora_printCodingRate(bool from_rx) { uint8_t d = lora.getCodingRate(from_rx); printf("CodingRate:"); switch (d) { case 1: printf("4/5 "); break; case 2: printf("4/6 "); break; case 3: printf("4/7 "); break; case 4: printf("4/8 "); break; default: printf("%d ", d); break; } } void lora_printHeaderMode() { if (lora.getHeaderMode()) printf("implicit "); else printf("explicit "); } void lora_printBw() { (void)lora.getBw(); printf("Bw:"); if (radio.type == SX1276) { switch (lora.RegModemConfig.sx1276bits.Bw) { case 0: printf("7.8KHz "); break; case 1: printf("10.4KHz "); break; case 2: printf("15.6KHz "); break; case 3: printf("20.8KHz "); break; case 4: printf("31.25KHz "); break; case 5: printf("41.7KHz "); break; case 6: printf("62.5KHz "); break; case 7: printf("125KHz "); break; case 8: printf("250KHz "); break; case 9: printf("500KHz "); break; default: printf("%x ", lora.RegModemConfig.sx1276bits.Bw); break; } } else if (radio.type == SX1272) { switch (lora.RegModemConfig.sx1272bits.Bw) { case 0: printf("125KHz "); break; case 1: printf("250KHz "); break; case 2: printf("500KHz "); break; case 3: printf("11b "); break; } } } void lora_printAllBw() { int i, s; if (radio.type == SX1276) { s = lora.RegModemConfig.sx1276bits.Bw; for (i = 0; i < 10; i++ ) { lora.RegModemConfig.sx1276bits.Bw = i; printf("%d ", i); lora_printBw(); printf("\r\n"); } lora.RegModemConfig.sx1276bits.Bw = s; } else if (radio.type == SX1272) { s = lora.RegModemConfig.sx1272bits.Bw; for (i = 0; i < 3; i++ ) { lora.RegModemConfig.sx1272bits.Bw = i; printf("%d ", i); lora_printBw(); printf("\r\n"); } lora.RegModemConfig.sx1272bits.Bw = s; } } void lora_printSf() { // spreading factor same between sx127[26] printf("sf:%d ", lora.getSf()); } void lora_printRxPayloadCrcOn() { bool on = lora.getRxPayloadCrcOn(); printf("RxPayloadCrcOn:%d = ", on); if (lora.getHeaderMode()) printf("Rx/"); // implicit mode if (on) printf("Tx CRC Enabled\r\n"); else printf("Tx CRC disabled\r\n"); } void lora_printTxContinuousMode() { printf("TxContinuousMode:%d ", lora.RegModemConfig2.sx1276bits.TxContinuousMode); // same for sx1272 and sx1276 } void lora_printAgcAutoOn() { printf("AgcAutoOn:%d", lora.getAgcAutoOn()); } void lora_print_dio() { radio.RegDioMapping2.octet = radio.read_reg(REG_DIOMAPPING2); printf("DIO5:"); switch (radio.RegDioMapping2.bits.Dio5Mapping) { case 0: printf("ModeReady"); break; case 1: printf("ClkOut"); break; case 2: printf("ClkOut"); break; } printf(" DIO4:"); switch (radio.RegDioMapping2.bits.Dio4Mapping) { case 0: printf("CadDetected"); break; case 1: printf("PllLock"); break; case 2: printf("PllLock"); break; } radio.RegDioMapping1.octet = radio.read_reg(REG_DIOMAPPING1); printf(" DIO3:"); switch (radio.RegDioMapping1.bits.Dio3Mapping) { case 0: printf("CadDone"); break; case 1: printf("ValidHeader"); break; case 2: printf("PayloadCrcError"); break; } printf(" DIO2:"); switch (radio.RegDioMapping1.bits.Dio2Mapping) { case 0: case 1: case 2: printf("FhssChangeChannel"); break; } printf(" DIO1:"); switch (radio.RegDioMapping1.bits.Dio1Mapping) { case 0: printf("RxTimeout"); break; case 1: printf("FhssChangeChannel"); break; case 2: printf("CadDetected"); break; } printf(" DIO0:"); switch (radio.RegDioMapping1.bits.Dio0Mapping) { case 0: printf("RxDone"); break; case 1: printf("TxDone"); break; case 2: printf("CadDone"); break; } printf("\r\n"); } void fsk_print_dio() { radio.RegDioMapping2.octet = radio.read_reg(REG_DIOMAPPING2); printf("DIO5:"); switch (radio.RegDioMapping2.bits.Dio5Mapping) { case 0: printf("ClkOut"); break; case 1: printf("PllLock"); break; case 2: if (fsk.RegPktConfig2.bits.DataModePacket) printf("data"); else { if (radio.RegDioMapping2.bits.MapPreambleDetect) printf("preamble"); else printf("rssi"); } break; case 3: printf("ModeReady"); break; } printf(" DIO4:"); switch (radio.RegDioMapping2.bits.Dio4Mapping) { case 0: printf("temp/eol"); break; case 1: printf("PllLock"); break; case 2: printf("TimeOut"); break; case 3: if (fsk.RegPktConfig2.bits.DataModePacket) { if (radio.RegDioMapping2.bits.MapPreambleDetect) printf("preamble"); else printf("rssi"); } else printf("ModeReady"); break; } radio.RegDioMapping1.octet = radio.read_reg(REG_DIOMAPPING1); printf(" DIO3:"); if (fsk.RegPktConfig2.bits.DataModePacket) { if (radio.RegDioMapping1.bits.Dio3Mapping == 1) printf("TxReady"); else printf("FifoEmpty"); } else { switch (radio.RegDioMapping1.bits.Dio3Mapping) { case 0: printf("Timeout"); break; case 1: if (radio.RegDioMapping2.bits.MapPreambleDetect) printf("preamble"); else printf("rssi"); break; case 2: printf("?automode_status?"); break; case 3: printf("TempChange/LowBat"); break; } } printf(" DIO2:"); if (fsk.RegPktConfig2.bits.DataModePacket) { switch (radio.RegDioMapping1.bits.Dio2Mapping) { case 0: printf("FifoFull"); break; case 1: printf("RxReady"); break; case 2: printf("FifoFull/rx-timeout"); break; case 3: printf("FifoFull/rx-syncadrs"); break; } } else { printf("Data"); } printf(" DIO1:"); if (fsk.RegPktConfig2.bits.DataModePacket) { switch (radio.RegDioMapping1.bits.Dio1Mapping) { case 0: printf("FifoThresh"); break; case 1: printf("FifoEmpty"); break; case 2: printf("FifoFull"); break; case 3: printf("[41m-3-[0m"); break; } } else { switch (radio.RegDioMapping1.bits.Dio1Mapping) { case 0: printf("Dclk"); break; case 1: if (radio.RegDioMapping2.bits.MapPreambleDetect) printf("preamble"); else printf("rssi"); break; case 2: printf("[41m-2-[0m"); break; case 3: printf("[41m-3-[0m"); break; } } printf(" DIO0:"); if (fsk.RegPktConfig2.bits.DataModePacket) { switch (radio.RegDioMapping1.bits.Dio0Mapping) { case 0: printf("PayloadReady/PacketSent"); break; case 1: printf("CrcOk"); break; case 2: printf("[41m-2-[0m"); break; case 3: printf("TempChange/LowBat"); break; } } else { switch (radio.RegDioMapping1.bits.Dio0Mapping) { case 0: printf("SyncAdrs/TxReady"); break; case 1: if (radio.RegDioMapping2.bits.MapPreambleDetect) printf("preamble"); else printf("rssi"); break; case 2: printf("RxReady"); break; case 3: printf("[41m-3-[0m"); break; } } printf("\r\n"); } void lora_print_status() { radio.RegOpMode.octet = radio.read_reg(REG_OPMODE); if (!radio.RegOpMode.bits.LongRangeMode) { printf("FSK\r\n"); return; } lora_print_dio(); printf("LoRa "); // printing LoRa registers at 0x0d -> 0x3f lora.RegModemConfig.octet = radio.read_reg(REG_LR_MODEMCONFIG); lora.RegModemConfig2.octet = radio.read_reg(REG_LR_MODEMCONFIG2); lora_printCodingRate(false); // false: transmitted coding rate lora_printHeaderMode(); lora_printBw(); lora_printSf(); lora_printRxPayloadCrcOn(); // RegModemStat printf("ModemStat:0x%02x\r\n", radio.read_reg(REG_LR_MODEMSTAT)); // fifo ptrs: lora.RegPayloadLength = radio.read_reg(REG_LR_PAYLOADLENGTH); lora.RegRxMaxPayloadLength = radio.read_reg(REG_LR_RX_MAX_PAYLOADLENGTH); printf("fifoptr=0x%02x txbase=0x%02x rxbase=0x%02x payloadLength=0x%02x maxlen=0x%02x", radio.read_reg(REG_LR_FIFOADDRPTR), radio.read_reg(REG_LR_FIFOTXBASEADDR), radio.read_reg(REG_LR_FIFORXBASEADDR), lora.RegPayloadLength, lora.RegRxMaxPayloadLength ); lora.RegIrqFlags.octet = radio.read_reg(REG_LR_IRQFLAGS); printLoraIrqs_(false); lora.RegHopPeriod = radio.read_reg(REG_LR_HOPPERIOD); if (lora.RegHopPeriod != 0) { printf("\r\nHopPeriod:0x%02x\r\n", lora.RegHopPeriod); } printf("SymbTimeout:%d ", radio.read_u16(REG_LR_MODEMCONFIG2) & 0x3ff); lora.RegPreamble = radio.read_u16(REG_LR_PREAMBLEMSB); printf("PreambleLength:%d ", lora.RegPreamble); if (radio.RegOpMode.bits.Mode == RF_OPMODE_RECEIVER || radio.RegOpMode.bits.Mode == RF_OPMODE_RECEIVER_SINGLE) { printf("rssi:%ddBm ", lora.get_current_rssi()); } lora_printTxContinuousMode(); printf("\r\n"); lora_printAgcAutoOn(); if (radio.type == SX1272) { printf(" LowDataRateOptimize:%d\r\n", lora.RegModemConfig.sx1272bits.LowDataRateOptimize); } printf("\r\nHeaderCount:%d PacketCount:%d, ", radio.read_u16(REG_LR_RXHEADERCNTVALUE_MSB), radio.read_u16(REG_LR_RXPACKETCNTVALUE_MSB)); printf("Lora detection threshold:%02x\r\n", radio.read_reg(REG_LR_DETECTION_THRESHOLD)); lora.RegTest31.octet = radio.read_reg(REG_LR_TEST31); printf("detect_trig_same_peaks_nb:%d\r\n", lora.RegTest31.bits.detect_trig_same_peaks_nb); if (radio.type == SX1272) { lora.RegModemConfig.octet = radio.read_reg(REG_LR_MODEMCONFIG); printf("LowDataRateOptimize:%d ", lora.RegModemConfig.sx1272bits.LowDataRateOptimize); } else if (radio.type == SX1276) { lora.RegModemConfig3.octet = radio.read_reg(REG_LR_MODEMCONFIG3); printf("LowDataRateOptimize:%d ", lora.RegModemConfig3.sx1276bits.LowDataRateOptimize); } printf(" invert: rx=%d tx=%d\r\n", lora.RegTest33.bits.invert_i_q, !lora.RegTest33.bits.chirp_invert_tx); printf("\r\n"); //printf("A %02x\r\n", radio.RegModemConfig2.octet); } uint16_t fsk_get_PayloadLength(void) { fsk.RegPktConfig2.word = radio.read_u16(REG_FSK_PACKETCONFIG2); return fsk.RegPktConfig2.bits.PayloadLength; } void fsk_printAddressFiltering() { uint8_t FSKRegNodeAdrs, FSKRegBroadcastAdrs; printf(" AddressFiltering:"); switch (fsk.RegPktConfig1.bits.AddressFiltering) { case 0: printf("off"); break; case 1: // NodeAddress FSKRegNodeAdrs = radio.read_reg(REG_FSK_NODEADRS); printf("NodeAdrs:%02x\r\n", FSKRegNodeAdrs); break; case 2: // NodeAddress & BroadcastAddress FSKRegNodeAdrs = radio.read_reg(REG_FSK_NODEADRS); printf("NodeAdrs:%02x ", FSKRegNodeAdrs); FSKRegBroadcastAdrs = radio.read_reg(REG_FSK_BROADCASTADRS); printf("BroadcastAdrs:%02x\r\n", FSKRegBroadcastAdrs ); break; default: printf("%d", fsk.RegPktConfig1.bits.AddressFiltering); break; } } void fsk_print_IrqFlags2() { RegIrqFlags2_t RegIrqFlags2; printf("IrqFlags2: "); RegIrqFlags2.octet = radio.read_reg(REG_FSK_IRQFLAGS2); if (RegIrqFlags2.bits.FifoFull) printf("FifoFull "); if (RegIrqFlags2.bits.FifoEmpty) printf("FifoEmpty "); if (RegIrqFlags2.bits.FifoLevel) printf("FifoLevel "); if (RegIrqFlags2.bits.FifoOverrun) printf("FifoOverrun "); if (RegIrqFlags2.bits.PacketSent) printf("PacketSent "); if (RegIrqFlags2.bits.PayloadReady) printf("PayloadReady "); if (RegIrqFlags2.bits.CrcOk) printf("CrcOk "); if (RegIrqFlags2.bits.LowBat) printf("LowBat "); printf("\r\n"); } void fsk_print_status() { //uint16_t s; RegIrqFlags1_t RegIrqFlags1; if (radio.RegOpMode.bits.LongRangeMode) { printf("LoRa\r\n"); return; } if (radio.RegOpMode.bits.ModulationType == 0) { printf("FSK "); switch (radio.RegOpMode.bits.ModulationShaping) { case 1: printf("BT1.0 "); break; case 2: printf("BT0.5 "); break; case 3: printf("BT0.3 "); break; } } else if (radio.RegOpMode.bits.ModulationType == 1) { printf("OOK "); switch (radio.RegOpMode.bits.ModulationShaping) { case 1: printf("Fcutoff=bitrate"); break; case 2: printf("Fcutoff=2*bitrate"); break; case 3: printf("?"); break; } } printf("%" PRIu32 "bps fdev:%" PRIu32 "Hz\r\n", fsk.get_bitrate(), fsk.get_tx_fdev_hz()); fsk.RegPktConfig2.word = radio.read_u16(REG_FSK_PACKETCONFIG2); fsk_print_dio(); printf("rxbw:%" PRIu32 "Hz ", fsk.get_rx_bw_hz(REG_FSK_RXBW)); printf("afcbw:%" PRIu32 "Hz\r\n", fsk.get_rx_bw_hz(REG_FSK_AFCBW)); fsk.RegRssiConfig.octet = radio.read_reg(REG_FSK_RSSICONFIG); printf("RssiOffset:%ddB smoothing:%dsamples\r\n", fsk.RegRssiConfig.bits.RssiOffset, 1 << (fsk.RegRssiConfig.bits.RssiSmoothing+1)); fsk.RegSyncConfig.octet = radio.read_reg(REG_FSK_SYNCCONFIG); if (fsk.RegPktConfig2.bits.DataModePacket) { uint16_t len; /* packet mode */ len = fsk_get_PayloadLength(); printf("packet RegPayloadLength:0x%03x ", len); if (fsk.RegPktConfig2.bits.BeaconOn) printf("BeaconOn "); fsk.RegFifoThreshold.octet = radio.read_reg(REG_FSK_FIFOTHRESH); printf("FifoThreshold:%d TxStartCondition:", fsk.RegFifoThreshold.bits.FifoThreshold); if (fsk.RegFifoThreshold.bits.TxStartCondition) printf("!FifoEmpty"); else printf("FifoLevel"); printf("\r\nAutoRestartRxMode:"); switch (fsk.RegSyncConfig.bits.AutoRestartRxMode) { case 0: printf("off "); break; case 1: printf("no-pll-wait "); break; case 2: printf("pll-wait "); break; case 3: printf("3 "); break; } //...todo printf("PreambleSize:%d ", radio.read_u16(REG_FSK_PREAMBLEMSB)); fsk.RegOokPeak.octet = radio.read_reg(REG_FSK_OOKPEAK); if (fsk.RegOokPeak.bits.barker_en) printf("barker "); if (!fsk.RegOokPeak.bits.BitSyncOn) printf("BitSyncOff "); //...todo fsk.RegPktConfig1.octet = radio.read_reg(REG_FSK_PACKETCONFIG1); if (fsk.RegPktConfig1.bits.PacketFormatVariable) printf("variable"); else printf("fixed"); printf("-length\r\ncrc"); if (fsk.RegPktConfig1.bits.CrcOn) { printf("On"); } else printf("Off"); printf(" crctype:"); if (fsk.RegPktConfig1.bits.CrCWhiteningType) printf("IBM"); else printf("CCITT"); printf(" dcFree:"); switch (fsk.RegPktConfig1.bits.DcFree) { case 0: printf("none "); break; case 1: printf("Manchester "); break; case 2: printf("Whitening "); break; case 3: printf("[41mreserved[0m "); break; } fsk_printAddressFiltering(); printf("\r\n"); fsk_print_IrqFlags2(); } else { /* continuous mode */ printf("[7mcontinuous[27m "); } fsk.RegPreambleDetect.octet = radio.read_reg(REG_FSK_PREAMBLEDETECT); printf("PreambleDetect:"); if (fsk.RegPreambleDetect.bits.PreambleDetectorOn) { printf("size=%d,tol=%d ", fsk.RegPreambleDetect.bits.PreambleDetectorSize, fsk.RegPreambleDetect.bits.PreambleDetectorTol); } else printf("Off "); if (fsk.RegSyncConfig.bits.SyncOn) { printf(" syncsize:%d ", fsk.RegSyncConfig.bits.SyncSize); printf(" : %02x ", radio.read_reg(REG_FSK_SYNCVALUE1)); printf("%02x ", radio.read_reg(REG_FSK_SYNCVALUE2)); printf("%02x ", radio.read_reg(REG_FSK_SYNCVALUE3)); printf("%02x ", radio.read_reg(REG_FSK_SYNCVALUE4)); } else printf("Sync Off"); printf("\r\n"); // end sync config fsk.RegAfcFei.octet = radio.read_reg(REG_FSK_AFCFEI); printf("afcAutoClear:"); if (fsk.RegAfcFei.bits.AfcAutoClearOn) printf("On"); else printf("OFF"); printf(" afc:%dHz ", (int)(FREQ_STEP_HZ * radio.read_s16(REG_FSK_AFCMSB))); printf("fei:%dHz\r\n", (int)(FREQ_STEP_HZ * radio.read_s16(REG_FSK_FEIMSB))); fsk.RegRxConfig.octet = radio.read_reg(REG_FSK_RXCONFIG); printf("RxTrigger:"); switch (fsk.RegRxConfig.bits.RxTrigger) { case 0: printf("none "); break; case 1: printf("rssi "); break; case 6: printf("preamble "); break; case 7: printf("both "); break; default: printf("-%d- ", fsk.RegRxConfig.bits.RxTrigger); break; } printf("AfcAuto:"); if (fsk.RegRxConfig.bits.AfcAutoOn) printf("On "); else printf("OFF "); radio.RegLna.octet = radio.read_reg(REG_LNA); if (!fsk.RegRxConfig.bits.AgcAutoOn) { printf("AgcAutoOff:G%d ", radio.RegLna.bits.LnaGain); } printf("LnaBoostHF:%d ", radio.RegLna.bits.LnaBoostHF); fsk.RegTimerResol.octet = radio.read_reg(REG_FSK_TIMERRESOL); if (fsk.RegTimerResol.bits.hlm_started) printf("[35mhlm_started[0m "); else printf("hlm_stopped "); fsk.RegRssiThresh = radio.read_reg(REG_FSK_RSSITHRESH); printf("rssiThreshold:-%.1f@%02x ", fsk.RegRssiThresh / 2.0, REG_FSK_RSSITHRESH); radio.RegOpMode.octet = radio.read_reg(REG_OPMODE); if (radio.RegOpMode.bits.Mode == RF_OPMODE_RECEIVER || radio.RegOpMode.bits.Mode == RF_OPMODE_SYNTHESIZER_RX) { printf("rssi:-%.1f ", radio.read_reg(REG_FSK_RSSIVALUE) / 2.0); } fsk.RegSeqConfig1.octet = radio.read_reg(REG_FSK_SEQCONFIG1); printf("\r\nsequencer: "); printf("FromStart:"); switch (fsk.RegSeqConfig1.bits.FromStart) { case 0: printf("lowPowerSelection-"); if (fsk.RegSeqConfig1.bits.LowPowerSelection) printf("idle"); else printf("sequencerOff"); break; case 1: printf("rx"); break; case 2: printf("tx"); break; case 3: printf("tx on fifolevel"); break; } printf(" lowPowerSelection:"); if (fsk.RegSeqConfig1.bits.LowPowerSelection) printf("idle"); else printf("SequencerOff"); if (fsk.RegSeqConfig1.bits.FromStart != 0 && fsk.RegSeqConfig1.bits.LowPowerSelection != 0) { // if sequencer enabled: printf("\r\nsequencer: IdleMode:"); if (fsk.RegSeqConfig1.bits.IdleMode) printf("Sleep"); else printf("standby"); printf("\r\nsequencer: FromIdle to:"); if (fsk.RegSeqConfig1.bits.FromIdle) printf("rx"); else printf("tx"); printf("\r\nsequencer: FromTransmit to:"); if (fsk.RegSeqConfig1.bits.FromTransmit) printf("rx-on-PacketSent"); else { printf("lowPowerSelection-"); if (fsk.RegSeqConfig1.bits.LowPowerSelection) printf("idle"); else printf("SequencerOff"); printf("-on-PacketSent"); } fsk.RegSeqConfig2.octet = radio.read_reg(REG_FSK_SEQCONFIG2); printf("\r\nsequencer: FromReceive:"); switch (fsk.RegSeqConfig2.bits.FromReceive) { case 1: printf("PacketRecevied on PayloadReady"); break; case 2: printf("lowPowerSelection-"); if (fsk.RegSeqConfig1.bits.LowPowerSelection) printf("idle"); else printf("SequencerOff"); printf("-on-payloadReady"); break; case 3: printf("PacketRecevied-on-CrcOk"); break; case 4: printf("SequencerOff-on-Rssi"); break; case 5: printf("SequencerOff-on-SyncAddress"); break; case 6: printf("SequencerOff-PreambleDetect"); break; default: printf("-%d-", fsk.RegSeqConfig2.bits.FromReceive); break; } printf("\r\nsequencer: FromRxTimeout:"); switch (fsk.RegSeqConfig2.bits.FromRxTimeout) { case 0: printf("rx"); break; case 1: printf("tx"); break; case 2: printf("lowPowerSelection-"); if (fsk.RegSeqConfig1.bits.LowPowerSelection) printf("idle"); else printf("SequencerOff"); break; case 3: printf("SequencerOff"); break; } printf("\r\nsequencer: FromPacketReceived to:"); switch (fsk.RegSeqConfig2.bits.FromPacketReceived) { case 0: printf("SequencerOff"); break; case 1: printf("tx on FifoEmpty"); break; case 2: printf("lowPowerSelection-"); if (fsk.RegSeqConfig1.bits.LowPowerSelection) printf("idle"); else printf("sequencerOff"); break; case 3: printf("rx via fs"); break; case 4: printf("rx"); break; } fsk.RegTimerResol.octet = radio.read_reg(REG_FSK_TIMERRESOL); printf("\r\nsequencer: timer1:"); switch (fsk.RegTimerResol.bits.timer1_resol) { case 0: printf("off"); break; case 1: printf("%dus", radio.read_reg(REG_FSK_TIMER1COEF) * 64); break; case 2: printf("%.1fms", radio.read_reg(REG_FSK_TIMER1COEF) * 4.1); break; case 3: printf("%.1fs", radio.read_reg(REG_FSK_TIMER1COEF) * 0.262); break; } printf(" timer2:"); switch (fsk.RegTimerResol.bits.timer2_resol) { case 0: printf("off"); break; case 1: printf("%dus", radio.read_reg(REG_FSK_TIMER2COEF) * 64); break; case 2: printf("%.1fms", radio.read_reg(REG_FSK_TIMER2COEF) * 4.1); break; case 3: printf("%.1fs", radio.read_reg(REG_FSK_TIMER2COEF) * 0.262); break; } } // ..if sequencer enabled printf("\r\nIrqFlags1:"); RegIrqFlags1.octet = radio.read_reg(REG_FSK_IRQFLAGS1); if (RegIrqFlags1.bits.ModeReady) printf("ModeReady "); if (RegIrqFlags1.bits.RxReady) printf("RxReady "); if (RegIrqFlags1.bits.TxReady) printf("TxReady "); if (RegIrqFlags1.bits.PllLock) printf("PllLock "); if (RegIrqFlags1.bits.Rssi) printf("Rssi "); if (RegIrqFlags1.bits.Timeout) printf("Timeout "); if (RegIrqFlags1.bits.PreambleDetect) printf("PreambleDetect "); if (RegIrqFlags1.bits.SyncAddressMatch) printf("SyncAddressMatch "); printf("\r\n"); /* TODO if (!SX1272FSK->RegPktConfig1.bits.PacketFormatVariable) { // if fixed-length packet format: s = fsk_get_PayloadLength(); if (s > FSK_LARGE_PKT_THRESHOLD) flags.fifo_flow_ctl = 1; else flags.fifo_flow_ctl = 0; }*/ fsk.RegImageCal.octet = radio.read_reg(REG_FSK_IMAGECAL); if (fsk.RegImageCal.bits.TempMonitorOff) { printf("[42mTempMonitorOff[\r0m\n"); } else { printf("TempThreshold:"); switch (fsk.RegImageCal.bits.TempThreshold) { case 0: printf("5C"); break; case 1: printf("10C"); break; case 2: printf("15C"); break; case 3: printf("20C"); break; } printf("\r\n"); } if (fsk.RegImageCal.bits.ImageCalRunning) printf("[33mImageCalRunning[\r0m\n"); if (rx_payloadReady_int_en) { #ifdef TYPE_ABZ printf("n_rx_pkts:%u, dio:%u,%u,%u,%u\r\n", n_rx_pkts, dio3.read(), dio2.read(), radio.dio1.read(), radio.dio0.read()); #else printf("n_rx_pkts:%u, dio:%u,%u,%u,%u,%u\r\n", n_rx_pkts, dio4.read(), dio3.read(), dio2.read(), radio.dio1.read(), radio.dio0.read()); #endif } } void printOpMode() { radio.RegOpMode.octet = radio.read_reg(REG_OPMODE); switch (radio.RegOpMode.bits.Mode) { case RF_OPMODE_SLEEP: printf("[7msleep[0m"); break; case RF_OPMODE_STANDBY: printf("[7mstby[0m"); break; case RF_OPMODE_SYNTHESIZER_TX: printf("[33mfstx[0m"); break; case RF_OPMODE_TRANSMITTER: printf("[31mtx[0m"); break; case RF_OPMODE_SYNTHESIZER_RX: printf("[33mfsrx[0m"); break; case RF_OPMODE_RECEIVER: printf("[32mrx[0m"); break; case 6: if (radio.RegOpMode.bits.LongRangeMode) printf("[42mrxs[0m"); else printf("-6-"); break; // todo: different lora/fsk case 7: if (radio.RegOpMode.bits.LongRangeMode) printf("[45mcad[0m"); else printf("-7-"); break; // todo: different lora/fsk } } void printPa() { radio.RegPaConfig.octet = radio.read_reg(REG_PACONFIG); if (radio.RegPaConfig.bits.PaSelect) { float output_dBm = 17 - (15-radio.RegPaConfig.bits.OutputPower); printf(" PABOOST OutputPower=%.1fdBm", output_dBm); } else { float pmax = (0.6*radio.RegPaConfig.bits.MaxPower) + 10.8; float output_dBm = pmax - (15-radio.RegPaConfig.bits.OutputPower); #ifdef TARGET_MTS_MDOT_F411RE printf(" \x1b[31mRFO pmax=%.1fdBm OutputPower=%.1fdBm\x1b[0m", pmax, output_dBm); // not connected #else printf(" RFO pmax=%.1fdBm OutputPower=%.1fdBm", pmax, output_dBm); #endif } } void /* things always present, whether lora or fsk */ common_print_status() { printf("version:0x%02x %.3fMHz ", radio.read_reg(REG_VERSION), radio.get_frf_MHz()); printOpMode(); printPa(); radio.RegOcp.octet = radio.read_reg(REG_OCP); if (radio.RegOcp.bits.OcpOn) { int imax = 0; if (radio.RegOcp.bits.OcpTrim < 16) imax = 45 + (5 * radio.RegOcp.bits.OcpTrim); else if (radio.RegOcp.bits.OcpTrim < 28) imax = -30 + (10 * radio.RegOcp.bits.OcpTrim); else imax = 240; printf(" OcpOn %dmA ", imax); } else printf(" OcpOFF "); printf("\r\n"); if (per_en) { if (cadper_enable) { printf("cadper %" PRIu32 ", ", num_cads); } printf("per_tx_delay:%f\r\n", per_tx_delay); printf("PER device ID:%d\r\n", per_id); } if (poll_irq_en) { printf("poll_irq_en\r\n"); if (!radio.RegOpMode.bits.LongRangeMode) { printf("saved irqs: %02x %02x\r\n", fsk_RegIrqFlags1_prev.octet, fsk_RegIrqFlags2_prev.octet); } } } void print_rx_buf(int len) { int i; printf("000:"); for (i = 0; i < len; i++) { //printf("(%d)%02x ", i % 16, rx_buf[i]); printf("%02x ", radio.rx_buf[i]); if (i % 16 == 15 && i != len-1) printf("\r\n%03d:", i+1); } printf("\r\n"); } void lora_print_rx_verbose(uint8_t dlen) { float dbm; printLoraIrqs_(false); if (lora.RegHopPeriod > 0) { lora.RegHopChannel.octet = radio.read_reg(REG_LR_HOPCHANNEL); printf("HopCH:%d ", lora.RegHopChannel.bits.FhssPresentChannel); } printf("%dHz ", lora.get_freq_error_Hz()); lora_printCodingRate(true); // true: of received packet dbm = lora.get_pkt_rssi(); printf(" crc%s %.1fdB %.1fdBm\r\n", lora.RegHopChannel.bits.RxPayloadCrcOn ? "On" : "OFF", lora.RegPktSnrValue / 4.0, dbm ); print_rx_buf(dlen); } void set_per_en(bool en) { if (en) { if (radio.RegOpMode.bits.LongRangeMode) { if (radio.type == SX1272) { lora.RegModemConfig.sx1272bits.LowDataRateOptimize = 1; radio.write_reg(REG_LR_MODEMCONFIG, lora.RegModemConfig.octet); } else if (radio.type == SX1276) { lora.RegModemConfig3.sx1276bits.LowDataRateOptimize = 1; radio.write_reg(REG_LR_MODEMCONFIG3, lora.RegModemConfig3.octet); } lora.RegPayloadLength = 9; radio.write_reg(REG_LR_PAYLOADLENGTH, lora.RegPayloadLength); radio.RegDioMapping1.bits.Dio3Mapping = 1; // to ValidHeader radio.write_reg(REG_DIOMAPPING1, radio.RegDioMapping1.octet); } else { // fsk.. //fsk_tx_length = 9; } PacketRxSequencePrev = 0; // transmitter side PacketTxCnt is 1 at first TX //PacketRxSequence = 0; PacketPerKoCnt = 0; PacketPerOkCnt = 0; PacketNormalCnt = 0; } // ..if (per_en) else { per_timeout.detach(); } per_en = en; } void per_cb() { int i; PacketTxCnt++; radio.tx_buf[0] = per_id; radio.tx_buf[1] = PacketTxCnt >> 24; radio.tx_buf[2] = PacketTxCnt >> 16; radio.tx_buf[3] = PacketTxCnt >> 8; radio.tx_buf[4] = PacketTxCnt; radio.tx_buf[5] = 'P'; radio.tx_buf[6] = 'E'; radio.tx_buf[7] = 'R'; radio.tx_buf[8] = 0; for (i = 0; i < 8; i++) radio.tx_buf[8] += radio.tx_buf[i]; if (radio.RegOpMode.bits.LongRangeMode) { lora.start_tx(lora.RegPayloadLength); } else { fsk.start_tx(9); } led1 = !led1.read(); if (PacketTxCnt == PacketTxCntEnd) { set_per_en(false); return; } } int per_parse_rx(uint8_t len) { if (len > 8 && radio.rx_buf[5] == 'P' && radio.rx_buf[6] == 'E' && radio.rx_buf[7] == 'R') { int i; float per; /* this is PER packet */ int PacketRxSequence = (radio.rx_buf[1] << 24) | (radio.rx_buf[2] << 16) | (radio.rx_buf[3] << 8) | radio.rx_buf[4]; PacketPerOkCnt++; if( PacketRxSequence <= PacketRxSequencePrev ) { // Sequence went back => resynchronization // dont count missed packets this time i = 0; } else { // determine number of missed packets i = PacketRxSequence - PacketRxSequencePrev - 1; } led1 = !led1.read(); // be ready for the next PacketRxSequencePrev = PacketRxSequence; // increment 'missed' counter for the RX session PacketPerKoCnt += i; per = ( (float)1.0 - ( float )PacketPerOkCnt / ( float )( PacketPerOkCnt + PacketPerKoCnt ) ) * (float)100.0; printf("%d, ok=%" PRIu32 " missed=%" PRIu32 " normal=%" PRIu32 " per:%.3f ", PacketRxSequence, PacketPerOkCnt, PacketPerKoCnt, PacketNormalCnt, per); if (radio.RegOpMode.bits.LongRangeMode) printf("pkt:%ddBm, snr:%.1fdB, %ddBm\r\n", lora.get_pkt_rssi(), lora.RegPktSnrValue / 4.0, lora.get_current_rssi()); else { wait_us(10000); printf(" -%.1fdBm\r\n", radio.read_reg(REG_FSK_RSSIVALUE) / 2.0); } return 1; } else { return 0; } } typedef enum { ON_TXDONE_STATE_NONE = 0, ON_TXDONE_STATE_SYNC_HI_NIBBLE, ON_TXDONE_STATE_SYNC_LO_NIBBLE, ON_TXDONE_STATE_PAYLOAD_LENGTH, } on_txdone_state_e; on_txdone_state_e on_txdone_state; uint8_t lora_sync_byte; float on_txdone_delay; Timeout on_txdone_timeout; uint8_t on_txdone_repeat_cnt; void txdone_timeout_cb() { uint8_t nib; switch (on_txdone_state) { case ON_TXDONE_STATE_SYNC_HI_NIBBLE: nib = lora_sync_byte >> 4; if (nib >= 15) { on_txdone_state = ON_TXDONE_STATE_SYNC_LO_NIBBLE; lora_sync_byte = 0x00; } else nib++; lora_sync_byte = nib << 4; radio.write_reg(REG_LR_SYNC_BYTE, lora_sync_byte); printf("upper %02x\r\n", lora_sync_byte); break; case ON_TXDONE_STATE_SYNC_LO_NIBBLE: nib = lora_sync_byte & 0x0f; if (nib >= 15) { on_txdone_state = ON_TXDONE_STATE_SYNC_LO_NIBBLE; lora_sync_byte = 0x00; } else nib++; lora_sync_byte = nib & 0x0f; radio.write_reg(REG_LR_SYNC_BYTE, lora_sync_byte); printf("lower %02x\r\n", lora_sync_byte); break; case ON_TXDONE_STATE_PAYLOAD_LENGTH: if (++on_txdone_repeat_cnt >= 10) { on_txdone_repeat_cnt = 0; if (lora.RegPayloadLength == 255) { lora.RegPayloadLength = 1; printf("done\r\n"); on_txdone_state = ON_TXDONE_STATE_NONE; return; } lora.RegPayloadLength++; radio.write_reg(REG_LR_PAYLOADLENGTH, lora.RegPayloadLength); printf("pl %d\r\n", lora.RegPayloadLength); } tx_cnt++; radio.tx_buf[0] = tx_cnt; radio.tx_buf[1] = ~tx_cnt; break; default: return; } // ..switch (on_txdone_state) lora.start_tx(lora.RegPayloadLength); } void poll_service_radio() { if (radio.RegOpMode.bits.LongRangeMode) { } else { // fsk: if (rx_payloadReady_int_en) return; /*RegIrqFlags2_t RegIrqFlags2; if (radio.RegOpMode.bits.Mode == RF_OPMODE_TRANSMITTER) { RegIrqFlags2.octet = radio.read_reg(REG_FSK_IRQFLAGS2); if (RegIrqFlags2.bits.PacketSent) { radio.set_opmode(RF_OPMODE_SLEEP); printf("poll mode fsk tx done\r\n"); } }*/ static uint8_t rssi; RegIrqFlags2_t RegIrqFlags2; RegIrqFlags1_t RegIrqFlags1; RegIrqFlags1.octet = radio.read_reg(REG_FSK_IRQFLAGS1); if (RegIrqFlags1.octet != fsk_RegIrqFlags1_prev.octet) { printf("iF1:"); if (RegIrqFlags1.bits.ModeReady ^ fsk_RegIrqFlags1_prev.bits.ModeReady) { printf("ModeReady-"); if (RegIrqFlags1.bits.ModeReady) printf("on "); else printf("off "); } if (RegIrqFlags1.bits.RxReady ^ fsk_RegIrqFlags1_prev.bits.RxReady) { printf("RxReady-"); if (RegIrqFlags1.bits.RxReady) printf("on "); else printf("off "); } if (RegIrqFlags1.bits.TxReady ^ fsk_RegIrqFlags1_prev.bits.TxReady) { printf("TxReady-"); if (RegIrqFlags1.bits.TxReady) printf("on "); else printf("off "); } if (RegIrqFlags1.bits.PllLock ^ fsk_RegIrqFlags1_prev.bits.PllLock) { printf("PllLock-"); if (RegIrqFlags1.bits.PllLock) printf("on "); else printf("off "); } if (RegIrqFlags1.bits.Rssi ^ fsk_RegIrqFlags1_prev.bits.Rssi) { printf("Rssi-"); if (RegIrqFlags1.bits.Rssi) printf("on "); else printf("off "); } if (RegIrqFlags1.bits.Timeout ^ fsk_RegIrqFlags1_prev.bits.Timeout) { printf("Timeout-"); if (RegIrqFlags1.bits.Timeout) printf("on "); else printf("off "); } if (RegIrqFlags1.bits.PreambleDetect ^ fsk_RegIrqFlags1_prev.bits.PreambleDetect) { printf("PreambleDetect-"); if (RegIrqFlags1.bits.PreambleDetect) printf("on "); else printf("off "); } if (RegIrqFlags1.bits.SyncAddressMatch ^ fsk_RegIrqFlags1_prev.bits.SyncAddressMatch) { printf("SyncAddressMatch-"); if (RegIrqFlags1.bits.SyncAddressMatch) printf("on "); else printf("off "); } fsk_RegIrqFlags1_prev.octet = RegIrqFlags1.octet; printf("\r\n"); fflush(stdout); } RegIrqFlags2.octet = radio.read_reg(REG_FSK_IRQFLAGS2); if (RegIrqFlags2.octet != fsk_RegIrqFlags2_prev.octet) { printf("iF2:"); if (RegIrqFlags2.bits.FifoFull ^ fsk_RegIrqFlags2_prev.bits.FifoFull) { printf("FifoFull-"); if (RegIrqFlags2.bits.FifoFull) printf("on "); else printf("off "); } if (RegIrqFlags2.bits.FifoEmpty ^ fsk_RegIrqFlags2_prev.bits.FifoEmpty) { printf("FifoEmpty-"); if (RegIrqFlags2.bits.FifoEmpty) printf("on "); else { printf("off "); rssi = radio.read_reg(REG_FSK_RSSIVALUE); } } if (RegIrqFlags2.bits.FifoLevel ^ fsk_RegIrqFlags2_prev.bits.FifoLevel) { printf("FifoLevel-"); if (RegIrqFlags2.bits.FifoLevel) printf("on "); else printf("off "); } if (RegIrqFlags2.bits.FifoOverrun ^ fsk_RegIrqFlags2_prev.bits.FifoOverrun) { printf("FifoOverrun-"); if (RegIrqFlags2.bits.FifoOverrun) printf("on "); else printf("off "); } if (RegIrqFlags2.bits.PacketSent ^ fsk_RegIrqFlags2_prev.bits.PacketSent) { printf("PacketSent-"); if (RegIrqFlags2.bits.PacketSent) { printf("on "); } else printf("off "); } if (RegIrqFlags2.bits.PayloadReady ^ fsk_RegIrqFlags2_prev.bits.PayloadReady) { printf("PayloadReady-"); if (RegIrqFlags2.bits.PayloadReady) printf("on "); else printf("off "); } if (RegIrqFlags2.bits.CrcOk ^ fsk_RegIrqFlags2_prev.bits.CrcOk) { printf("CrcOk-"); if (RegIrqFlags2.bits.CrcOk) printf("on "); else printf("off "); } if (RegIrqFlags2.bits.LowBat ^ fsk_RegIrqFlags2_prev.bits.LowBat) { printf("LowBat-"); if (RegIrqFlags2.bits.LowBat) printf("on "); else printf("off "); } fsk_RegIrqFlags2_prev.octet = RegIrqFlags2.octet; printf("\r\n"); fflush(stdout); if (RegIrqFlags2.bits.PacketSent) { if (fsk.tx_done_sleep) radio.set_opmode(RF_OPMODE_SLEEP); else radio.set_opmode(RF_OPMODE_STANDBY); } if (RegIrqFlags2.bits.CrcOk || RegIrqFlags2.bits.PayloadReady) { if (fsk.RegRxConfig.bits.AfcAutoOn) { fsk.RegAfcValue = radio.read_s16(REG_FSK_AFCMSB); printf("%dHz ", (int)(FREQ_STEP_HZ * fsk.RegAfcValue)); if (rssi != 0) { printf("pkt:-%.1fdBm ", rssi / 2.0); rssi = 0; } } if (fsk.RegPktConfig1.bits.PacketFormatVariable) { fsk.rx_buf_length = radio.read_reg(REG_FIFO); } else { fsk.rx_buf_length = fsk.RegPktConfig2.bits.PayloadLength; } radio.m_cs = 0; radio.m_spi.write(REG_FIFO); // bit7 is low for reading from radio for (int i = 0; i < fsk.rx_buf_length; i++) { radio.rx_buf[i] = radio.m_spi.write(0); } radio.m_cs = 1; /****/ if (per_en) { if (!per_parse_rx(fsk.rx_buf_length)) { PacketNormalCnt++; print_rx_buf(fsk.rx_buf_length); } } else { print_rx_buf(fsk.rx_buf_length); } fflush(stdout); } // ..if CrcOk or PayloadReady } // ..if RegIrqFlags2 changed } // ...fsk } void cadper_service() { lora.RegIrqFlags.octet = radio.read_reg(REG_LR_IRQFLAGS); if (lora.RegIrqFlags.bits.CadDetected) { lora.start_rx(RF_OPMODE_RECEIVER_SINGLE); do { lora.RegIrqFlags.octet = radio.read_reg(REG_LR_IRQFLAGS); if (lora.RegIrqFlags.bits.RxDone) { service_action_e act = lora.service(); if (act == SERVICE_READ_FIFO) { if (!per_parse_rx(lora.RegRxNbBytes)) { PacketNormalCnt++; lora_print_rx_verbose(lora.RegRxNbBytes); } } break; } } while (!lora.RegIrqFlags.bits.RxTimeout); radio.write_reg(REG_LR_IRQFLAGS, lora.RegIrqFlags.octet); } if (lora.RegIrqFlags.bits.CadDone) { lora.RegIrqFlags.octet = radio.read_reg(REG_LR_IRQFLAGS); num_cads++; radio.set_opmode(RF_OPMODE_CAD); } } void cmd_restart_rx(uint8_t); int preamble_to_sync_us; #ifndef TYPE_ABZ Timeout timeout_syncAddress; bool get_syncAddress; #endif float preamble_detect_at; void callback_sa_timeout() { printf("syncAddress timeout "); if (dio2.read() == 0) { //cmd_restart_rx(0); rx_start_timer.reset(); radio.set_opmode(RF_OPMODE_STANDBY); printf("(false preamble detect at %f, secs:%u)\r\n", preamble_detect_at, time(NULL) - secs_rx_start); secs_rx_start = time(NULL); radio.set_opmode(RF_OPMODE_RECEIVER); } else printf("\r\n"); } void service_radio() { service_action_e act; static uint8_t rssi = 0; if (radio.RegOpMode.bits.LongRangeMode) { if (rssi_polling_thresh != 0 && radio.RegOpMode.bits.Mode == RF_OPMODE_RECEIVER) { int rssi = lora.get_current_rssi(); // dBm returned, negative value #if defined(TARGET_STM) && !defined(TYPE_ABZ) if (rssi < rssi_polling_thresh) pc3 = 0; // signal weaker than threshold else pc3 = 1; // signal stronger than threshold #endif } if (cadper_enable) { cadper_service(); } act = lora.service(); switch (act) { case SERVICE_READ_FIFO: if (app == APP_NONE) { if (per_en) { if (!per_parse_rx(lora.RegRxNbBytes)) { PacketNormalCnt++; lora_print_rx_verbose(lora.RegRxNbBytes); } } else lora_print_rx_verbose(lora.RegRxNbBytes); fflush(stdout); } else if (app == APP_CHAT) { if (lora.RegHopChannel.bits.RxPayloadCrcOn) { if (lora.RegIrqFlags.bits.PayloadCrcError) printf("crcError\r\n"); else { int n = lora.RegRxNbBytes; radio.rx_buf[n++] = '\r'; radio.rx_buf[n++] = '\n'; radio.rx_buf[n] = 0; // null terminate printf((char *)radio.rx_buf); } } else printf("crcOff\r\n"); // clear Irq flags radio.write_reg(REG_LR_IRQFLAGS, lora.RegIrqFlags.octet); // should still be in receive mode } break; case SERVICE_TX_DONE: if (app == APP_CHAT) { lora.start_rx(RF_OPMODE_RECEIVER); } else if (per_en) { per_timeout.attach(&per_cb, per_tx_delay); // start next TX } else if (on_txdone_state != ON_TXDONE_STATE_NONE) { on_txdone_timeout.attach(&txdone_timeout_cb, on_txdone_delay); } break; case SERVICE_ERROR: printf("error\r\n"); break; case SERVICE_NONE: break; } // ...switch (act) } else { /* FSK: */ if (rx_payloadReady_int_en) return; // radio service by ISR only if (ulrx_enable) return; act = fsk.service(); switch (act) { case SERVICE_READ_FIFO: if (app == APP_CHAT) { int n = fsk.rx_buf_length; radio.rx_buf[n++] = '\r'; radio.rx_buf[n++] = '\n'; radio.rx_buf[n] = 0; // null terminate printf((char *)radio.rx_buf); } else { if (fsk.RegRxConfig.bits.AfcAutoOn) { printf("%dHz ", (int)(FREQ_STEP_HZ * fsk.RegAfcValue)); if (rssi != 0) { printf("pkt:-%.1fdBm ", rssi / 2.0); rssi = 0; } } if (per_en) { if (!per_parse_rx(fsk.rx_buf_length)) { PacketNormalCnt++; print_rx_buf(fsk.rx_buf_length); } } else { print_rx_buf(fsk.rx_buf_length); } } if (crc32_en) { uint32_t c, *u32_ptr = (uint32_t*)&radio.rx_buf[fsk.rx_buf_length-4]; printf("rx crc:%08x, ", *u32_ptr); c = gen_crc(radio.rx_buf, fsk.rx_buf_length-4); printf("calc crc:%08x\r\n", c); } fflush(stdout); break; case SERVICE_TX_DONE: if (ook_test_en) radio.set_opmode(RF_OPMODE_SLEEP); if (app == APP_CHAT) { fsk.start_rx(); } else if (per_en) { per_timeout.attach(&per_cb, per_tx_delay); // start next TX } break; case SERVICE_ERROR: case SERVICE_NONE: break; } // ...switch (act) #ifndef TYPE_ABZ /* FSK receiver handling of preamble detection */ if (radio.RegDioMapping2.bits.MapPreambleDetect && radio.RegDioMapping2.bits.Dio4Mapping == 3) { if (saved_dio4 != dio4.read()) { //printf("predet-dio4:%d\r\n", dio4.read()); /* FSK: preamble detect state change */ if (dio4.read()) { if (radio.RegDioMapping1.bits.Dio2Mapping == 3) { // if we can see SyncAddress get_syncAddress = true; timeout_syncAddress.attach_us(callback_sa_timeout, preamble_to_sync_us); } /* how long after RX start is preamble detection occuring? */ //printf("preamble detect at %f\r\n", rx_start_timer.read()); preamble_detect_at = rx_start_timer.read(); } else { get_syncAddress = false; //printf("preamble detect clear\r\n"); } saved_dio4 = dio4.read(); } } // ..if dio4 is if (radio.RegDioMapping1.bits.Dio2Mapping == 3) { if (dio2.read()) { if (get_syncAddress) { timeout_syncAddress.detach(); get_syncAddress = false; } rssi = radio.read_reg(REG_FSK_RSSIVALUE); } } #endif /* !TYPE_ABZ */ if (rssi_polling_thresh != 0 && radio.RegOpMode.bits.Mode == RF_OPMODE_RECEIVER) { rssi = radio.read_reg(REG_FSK_RSSIVALUE); rssi = -rssi; #if defined(TARGET_STM) && !defined(TYPE_ABZ) if (rssi < rssi_polling_thresh) pc3 = 0; // signal weaker than threshold else pc3 = 1; // signal stronger than threshold #endif } } // ...!radio.RegOpMode.bits.LongRangeMode } /*int get_kbd_str(char* buf, int size) { char c; int i; static int prev_len; for (i = 0;;) { if (pc.readable()) { c = pc.getc(); if (c == 8 && i > 0) { pc.putc(8); pc.putc(' '); pc.putc(8); i--; } else if (c == '\r') { if (i == 0) { return prev_len; // repeat previous } else { buf[i] = 0; // null terminate prev_len = i; return i; } } else if (c == 3) { // ctrl-C abort return -1; } else if (i < size) { buf[i++] = c; pc.putc(c); } } else { service_radio(); } } // ...for() }*/ void console_chat() { //int i, len = get_kbd_str(pcbuf, sizeof(pcbuf)); service_radio(); if (pcbuf_len < 0) { printf("chat abort\r\n"); pcbuf_len = 0; app = APP_NONE; return; } else if (pcbuf_len == 0) { return; } else { int i; for (i = 0; i < pcbuf_len; i++) radio.tx_buf[i] = pcbuf[i]; if (radio.RegOpMode.bits.LongRangeMode) { lora.RegPayloadLength = pcbuf_len; radio.write_reg(REG_LR_PAYLOADLENGTH, lora.RegPayloadLength); lora.start_tx(pcbuf_len); } else { fsk.start_tx(pcbuf_len); } pcbuf_len = 0; printf("\r\n"); } } const uint8_t ookt_tx_payload[29] = { 0x55, 0x55, 0x55, 0x55, 0xA9, 0x66, 0x69, 0x65, 0x39, 0x53, 0xAA, 0xC3, 0xA6, 0x95, 0xC6, 0x3C, 0x6A, 0x33, 0x33, 0xC6, 0xCA, 0xA6, 0x33, 0x33, 0x55, 0x6A, 0xA6, 0xAA, 0x53 }; volatile uint32_t ook_tx_cnt = 0; void callback_ook_tx_test() { int i; //radio.write_reg(REG_FSK_SYNCCONFIG, 0); printf("%u ookTx: ", ook_tx_cnt++); for (i = 0; i < sizeof(ookt_tx_payload); i++) { radio.tx_buf[i] = ookt_tx_payload[i]; printf("%02x ", radio.tx_buf[i]); } printf("\r\n"); //printf("syncConf:%x\r\n", radio.read_reg(REG_FSK_SYNCCONFIG)); fsk.start_tx(sizeof(ookt_tx_payload)); } typedef enum { TXTICKER_STATE_OFF = 0, TXTICKER_STATE_TOGGLE_PAYLOAD_BIT, TXTICKER_STATE_CYCLE_PAYLOAD_LENGTH, TXTICKER_STATE_CYCLE_CODING_RATE, TXTICKER_STATE_TOG_HEADER_MODE, TXTICKER_STATE_TOG_CRC_ON, TXTICKER_STATE_CYCLE_SYNC_1, TXTICKER_STATE_CYCLE_SYNC_2, TXTICKER_STATE_RAMP_PAYLOAD_DATA_START, TXTICKER_STATE_RAMP_PAYLOAD_DATA, TXTICKER_STATE_SYMBOL_SWEEP, TXTICKER_STATE_TOGGLE_ALL_BITS_START, TXTICKER_STATE_TOGGLE_ALL_BITS, } txticker_state_e; txticker_state_e txticker_state; float tx_ticker_rate = 0.5; Ticker tx_ticker; uint8_t txticker_sync_byte; uint8_t payload_length_stop; uint8_t symbol_num; uint32_t symbol_sweep_bit_counter = 0; unsigned int symbol_sweep_bit_counter_stop; uint8_t symbol_sweep_nbits; uint8_t byte_pad_length; uint8_t tab_current_byte_num; uint8_t tab_current_bit_in_byte; void fp_cb() { int i; if (!radio.RegOpMode.bits.LongRangeMode) return; switch (txticker_state) { case TXTICKER_STATE_TOGGLE_PAYLOAD_BIT: /* { if (fp_tog_bit_ < 32) { uint32_t bp = 1 << fp_tog_bit_; fp_data ^= bp; //printf("bp%02x ", bp); } memcpy(radio.tx_buf, &fp_data, fp_data_length); printf("TX "); for (i = 0; i < fp_data_length; i++) printf("%02x ", radio.tx_buf[i]); printf("\r\n"); lora.start_tx(lora.RegPayloadLength); break; } */ tx_ticker.detach(); break; case TXTICKER_STATE_CYCLE_PAYLOAD_LENGTH: { if (lora.RegPayloadLength > payload_length_stop) lora.RegPayloadLength = 0; else lora.RegPayloadLength++; radio.write_reg(REG_LR_PAYLOADLENGTH, lora.RegPayloadLength); lora.start_tx(lora.RegPayloadLength); printf("RegPayloadLength:%d\r\n", lora.RegPayloadLength); break; } case TXTICKER_STATE_CYCLE_CODING_RATE: { uint8_t cr = lora.getCodingRate(false); // false: TX coding rate if (cr == 4) cr = 0; else cr++; lora.setCodingRate(cr); lora.start_tx(lora.RegPayloadLength); printf("tx cr:%d\r\n", cr); break; } case TXTICKER_STATE_TOG_HEADER_MODE: { lora.setHeaderMode(!lora.getHeaderMode()); lora.start_tx(lora.RegPayloadLength); lora.RegModemConfig.octet = radio.read_reg(REG_LR_MODEMCONFIG); lora_printHeaderMode(); printf("\r\n"); break; } case TXTICKER_STATE_TOG_CRC_ON: { lora.setRxPayloadCrcOn(!lora.getRxPayloadCrcOn()); lora.start_tx(lora.RegPayloadLength); printf("crc on:%d\r\n", lora.getRxPayloadCrcOn()); break; } case TXTICKER_STATE_CYCLE_SYNC_1: { /* cycle hi nibble of 0x39 register */ if ((txticker_sync_byte & 0xf0) == 0xf0) txticker_sync_byte &= 0x0f; else txticker_sync_byte += 0x10; radio.write_reg(REG_LR_SYNC_BYTE, txticker_sync_byte); lora.start_tx(lora.RegPayloadLength); printf("0x39: %02x\r\n", txticker_sync_byte); break; } case TXTICKER_STATE_CYCLE_SYNC_2: { /* cycle lo nibble of 0x39 register */ if ((txticker_sync_byte & 0x0f) == 0x0f) txticker_sync_byte &= 0xf0; else txticker_sync_byte += 0x01; radio.write_reg(REG_LR_SYNC_BYTE, txticker_sync_byte); lora.start_tx(lora.RegPayloadLength); printf("0x39: %02x\r\n", txticker_sync_byte); break; } case TXTICKER_STATE_RAMP_PAYLOAD_DATA_START: txticker_state = TXTICKER_STATE_RAMP_PAYLOAD_DATA; for (i = 0; i < lora.RegPayloadLength; i++) radio.tx_buf[i] = 0; lora.start_tx(lora.RegPayloadLength); printf("payload start, len:%d\r\n", lora.RegPayloadLength); break; case TXTICKER_STATE_RAMP_PAYLOAD_DATA: for (i = lora.RegPayloadLength-1; i >= 0; i--) { //printf("i:%d ", i); if (radio.tx_buf[i] == 255) { radio.tx_buf[i] = 0; } else { radio.tx_buf[i]++; break; } } //printf("\r\n"); printf("send:"); for (i = 0; i < lora.RegPayloadLength; i++) { printf("%02x ", radio.tx_buf[i]); } printf("\r\n"); lora.start_tx(lora.RegPayloadLength); if (radio.tx_buf[0] == 255) { printf("payload ramp done\r\n"); tx_ticker.detach(); } break; case TXTICKER_STATE_SYMBOL_SWEEP: // fpsNL command, where N=symbol num, L=nbytes { uint32_t mask; /*for (i = 0; i < lora.RegPayloadLength; i++) radio.tx_buf[i] = 0;*/ i = byte_pad_length; printf("bit_counter 0x%" PRIx32 " : ", symbol_sweep_bit_counter); for (int bn = 0; bn < symbol_sweep_nbits; bn += 2) { /* 2 lsbits going into first byte */ mask = 1 << bn; if (symbol_sweep_bit_counter & mask) radio.tx_buf[i] |= 1 << symbol_num; else radio.tx_buf[i] &= ~(1 << symbol_num); mask = 2 << bn; if (symbol_sweep_bit_counter & mask) radio.tx_buf[i] |= 0x10 << symbol_num; else radio.tx_buf[i] &= ~(0x10 << symbol_num); //printf("%02x ", radio.tx_buf[i]); i++; } for (i = 0; i < lora.RegPayloadLength; i++) printf("%02x ", radio.tx_buf[i]); printf("\r\n"); lora.start_tx(lora.RegPayloadLength); if (++symbol_sweep_bit_counter == symbol_sweep_bit_counter_stop) { printf("stop\r\n"); tx_ticker.detach(); } } break; case TXTICKER_STATE_TOGGLE_ALL_BITS_START: tab_current_byte_num = byte_pad_length; tab_current_bit_in_byte = 0; printf("tx "); for (i = 0; i < lora.RegPayloadLength; i++) { radio.tx_buf[i] = 0; printf("%02x ", radio.tx_buf[i]); } printf("\r\n"); txticker_state = TXTICKER_STATE_TOGGLE_ALL_BITS; lora.start_tx(lora.RegPayloadLength); break; case TXTICKER_STATE_TOGGLE_ALL_BITS: { uint8_t mask = 1 << tab_current_bit_in_byte; radio.tx_buf[tab_current_byte_num] = mask; printf("bit%d in [%d]: tx ", tab_current_bit_in_byte, tab_current_byte_num); for (i = 0; i < lora.RegPayloadLength; i++) { printf("%02x ", radio.tx_buf[i]); } printf("\r\n"); lora.start_tx(lora.RegPayloadLength); if (++tab_current_bit_in_byte == 8) { radio.tx_buf[tab_current_byte_num] = 0; tab_current_bit_in_byte = 0; if (++tab_current_byte_num == lora.RegPayloadLength) { tx_ticker.detach(); } } } break; default: tx_ticker.detach(); break; } // ...switch (txticker_state) } void ook_test_tx(int len) { int i; /* fsk.RegPktConfig2.bits.PayloadLength = i; radio.write_u16(REG_FSK_PACKETCONFIG2, fsk.RegPktConfig2.word);fsk.RegPktConfig2.bits.PayloadLength = i; radio.write_u16(REG_FSK_PACKETCONFIG2, fsk.RegPktConfig2.word); */ for (i = 0; i < 4; i++) { radio.tx_buf[i] = 0xaa; } printf("ooktx:"); for (i = 0; i < len; i++) { radio.tx_buf[i+4] = rand() & 0xff; printf("%02x ", radio.tx_buf[i+4]); } printf("\r\n"); fsk.start_tx(len+4); while (radio.RegOpMode.bits.Mode == RF_OPMODE_TRANSMITTER) { if (poll_irq_en) poll_service_radio(); else service_radio(); } } void cmd_init(uint8_t args_at) { printf("init\r\n"); radio.init(); if (!radio.RegOpMode.bits.LongRangeMode) { fsk.init(); // put FSK modem to some functioning default } else { // lora configuration is more simple } } void cmd_per_tx_delay(uint8_t idx) { int i; if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &i); per_tx_delay = i / 1000.0; } printf("per_tx_delay:%dms\r\n", (int)(per_tx_delay * 1000)); } const uint8_t test_payload_A[7] = { 0x80, 0x02, 0x58, 0xF5, 0xDF, 0xB8, 0x9E }; const uint8_t test_payload_B[] = { 0xca, 0xfe, 0xba, 0xbe }; const uint8_t test_payload_C[0x1a] = { 0x88, 0x39, 0x1F, 0xC6, 0xD3, 0xEB, 0xA4, 0xAC, 0xFB, 0xB9, 0xBA, 0xB9, 0xBE, 0x13, 0x61, 0x4C, 0x43, 0x83, 0x00, 0x92, 0x84, 0x00, 0x6F, 0x87, 0x7C, 0xB2 }; void cmd_tx(uint8_t idx) { int i; static uint16_t fsk_tx_length; if (radio.RegOpMode.bits.LongRangeMode) { if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &i); lora.RegPayloadLength = i; radio.write_reg(REG_LR_PAYLOADLENGTH, lora.RegPayloadLength); } if (pcbuf[idx] == 'A') { } else if (pcbuf[idx] == 'B') { } else if (pcbuf[idx] == 'C') { } else { tx_cnt++; printf("payload:%02x\r\n", tx_cnt); for (i = 0; i < lora.RegPayloadLength; i++) radio.tx_buf[i] = tx_cnt; } lora.start_tx(lora.RegPayloadLength); } else { // FSK: /* always variable-length format */ fsk.RegPktConfig1.octet = radio.read_reg(REG_FSK_PACKETCONFIG1); if (!fsk.RegPktConfig1.bits.PacketFormatVariable) { printf("fsk fixed->variable\r\n"); fsk.RegPktConfig1.bits.PacketFormatVariable = 1; radio.write_reg(REG_FSK_PACKETCONFIG1, fsk.RegPktConfig1.octet); } if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &i); fsk_tx_length = i; } if (ook_test_en) { ook_test_tx(fsk_tx_length); } else { if (radio.RegOpMode.bits.Mode != RF_OPMODE_TRANSMITTER) { // if not already busy transmitting if (pcbuf[idx] == 'A') { fsk_tx_length = sizeof(test_payload_A); memcpy(radio.tx_buf, test_payload_A, fsk_tx_length); } else if (pcbuf[idx] == 'B') { fsk_tx_length = sizeof(test_payload_B); memcpy(radio.tx_buf, test_payload_B, fsk_tx_length); } else if (pcbuf[idx] == 'C') { fsk_tx_length = sizeof(test_payload_C); memcpy(radio.tx_buf, test_payload_C, fsk_tx_length); } else { tx_cnt++; printf("payload:%02x\r\n", tx_cnt); for (i = 0; i < fsk_tx_length; i++) { radio.tx_buf[i] = tx_cnt; } } fsk.start_tx(fsk_tx_length); } } } // !LoRa } volatile uint16_t long_byte_count, long_byte_count_at_full; const uint8_t test_preamble_sync[] = { 0xaa, 0xaa, 0xaa, 0xaa, 0xaa, 0x33, 0xcb, 0x82 }; void _ulm_write_fifo(uint8_t len) { uint8_t i; //dio2 is FifoFull radio.m_cs = 0; radio.m_spi.write(REG_FIFO | 0x80); // bit7 is high for writing to radio for (i = 0; i < len; ) { //printf("_%02x\r\n", radio.tx_buf[i]); radio.m_spi.write(radio.tx_buf[i++]); long_byte_count++; if (dio2) { long_byte_count_at_full = long_byte_count; while (radio.dio1) ; } } radio.m_cs = 1; } int write_buf_to_fifo(const uint8_t* send_buf, uint8_t target_length) { /* block until all is written */ uint8_t total_sent = 0; //printf("wbtf %u\r\n", target_length); while (target_length > total_sent) { uint8_t this_length = target_length - total_sent; memcpy(radio.tx_buf+total_sent, send_buf+total_sent, this_length); _ulm_write_fifo(this_length); total_sent += this_length; } return total_sent; } #define TEST_PAYLOAD test_payload_C //#define TEST_PAYLOAD test_payload_A void cmd_long_tx(uint8_t idx) { unsigned int pkt_cnt = 0; bool first_pkt; /* transmit multipe packets without any time between packets (back to back) */ if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%u", &pkt_cnt); } printf("tx %u pkts\r\n", pkt_cnt); if (pkt_cnt < 1) return; radio.RegDioMapping2.octet = radio.read_reg(REG_DIOMAPPING2); radio.RegDioMapping2.bits.Dio5Mapping = 2; // data output to observation radio.RegDioMapping2.bits.Dio4Mapping = 3; // output preamble detect indication radio.RegDioMapping2.bits.MapPreambleDetect = 1; radio.write_reg(REG_DIOMAPPING2, radio.RegDioMapping2.octet); //unlimited packet length mode fsk.RegPktConfig1.octet = radio.read_reg(REG_FSK_PACKETCONFIG1); fsk.RegPktConfig1.bits.PacketFormatVariable = 0; // fixed length format radio.write_reg(REG_FSK_PACKETCONFIG1, fsk.RegPktConfig1.octet); fsk.RegPktConfig2.word = radio.read_u16(REG_FSK_PACKETCONFIG2); fsk.RegPktConfig2.bits.PayloadLength = 0; radio.write_u16(REG_FSK_PACKETCONFIG2, fsk.RegPktConfig2.word); //DIO3 to FifoEmpty (for end of tx) radio.RegDioMapping1.octet = radio.read_reg(REG_DIOMAPPING1); radio.RegDioMapping1.bits.Dio3Mapping = 0; // FifoEmpty //DIO2 to FifoFull radio.RegDioMapping1.bits.Dio2Mapping = 0; // FIfoFull //DIO1 to FifoLevel radio.RegDioMapping1.bits.Dio1Mapping = 0; // FifoLevel radio.RegDioMapping1.bits.Dio0Mapping = 0; // PacketSent radio.write_reg(REG_DIOMAPPING1, radio.RegDioMapping1.octet); //FifoThreshold to approx 1/5th full fsk.RegFifoThreshold.octet = radio.read_reg(REG_FSK_FIFOTHRESH); fsk.RegFifoThreshold.bits.FifoThreshold = sizeof(TEST_PAYLOAD)-1; // allow single packet // tx start condition to FifoLevel fsk.RegFifoThreshold.bits.TxStartCondition = 0; // start on FifoLevel radio.write_reg(REG_FSK_FIFOTHRESH, fsk.RegFifoThreshold.octet); long_byte_count = 0; long_byte_count_at_full = 0xffff; radio.set_opmode(RF_OPMODE_TRANSMITTER); first_pkt = true; // preamble+sync sent by packet engine only for first packet for (; pkt_cnt > 0; pkt_cnt--) { uint8_t len; if (first_pkt) first_pkt = false; else { if (dio3) { printf("fail-empty\r\n"); } write_buf_to_fifo(test_preamble_sync, sizeof(test_preamble_sync)); } len = sizeof(TEST_PAYLOAD); //TEST_PAYLOAD doesnt start with length write_buf_to_fifo(&len, 1); write_buf_to_fifo(TEST_PAYLOAD, sizeof(TEST_PAYLOAD)); } // .. rx_start_timer.reset(); rx_start_timer.start(); while (!dio3) { if (rx_start_timer.read() > 1) { printf("fifoEmpty fail\r\n"); radio.set_opmode(RF_OPMODE_STANDBY); return; } } rx_start_timer.reset(); rx_start_timer.start(); while (!radio.dio0) { if (rx_start_timer.read() > 3) { printf("PacketSent fail\r\n"); radio.set_opmode(RF_OPMODE_STANDBY); return; } } wait_us(100); radio.set_opmode(RF_OPMODE_STANDBY); printf("done ok %u, %u\r\n", long_byte_count, long_byte_count_at_full); } void cmd_hw_reset(uint8_t idx) { printf("hw_reset()\r\n"); radio.hw_reset(); ook_test_en = false; poll_irq_en = false; } void cmd_read_all_regs(uint8_t idx) { uint8_t a, d; // read all registers for (a = 1; a < 0x71; a++) { d = radio.read_reg(a); printf("%02x: %02x\r\n", a, d); } } void cmd_read_current_rssi(uint8_t idx) { if (radio.RegOpMode.bits.Mode != RF_OPMODE_RECEIVER) { radio.set_opmode(RF_OPMODE_RECEIVER); wait_us(10000); } if (radio.RegOpMode.bits.LongRangeMode) printf("rssi:%ddBm\r\n", lora.get_current_rssi()); else printf("rssi:-%.1f\r\n", radio.read_reg(REG_FSK_RSSIVALUE) / 2.0); } void cmd_rssi_polling(uint8_t idx) { if ((pcbuf[idx] >= '0' && pcbuf[idx] <= '9') || pcbuf[idx] == '-') { sscanf(pcbuf+idx, "%d", &rssi_polling_thresh); } printf("rssi_polling_thresh:%d\r\n", rssi_polling_thresh); } void cmd_lora_continuous_tx(uint8_t idx) { /* TxContinuousMode same for sx1272 and sx1276 */ lora.RegModemConfig2.octet = radio.read_reg(REG_LR_MODEMCONFIG2); lora.RegModemConfig2.sx1276bits.TxContinuousMode ^= 1; radio.write_reg(REG_LR_MODEMCONFIG2, lora.RegModemConfig2.octet); lora.RegModemConfig2.octet = radio.read_reg(REG_LR_MODEMCONFIG2); lora_printTxContinuousMode(); printf("\r\n"); } void cmd_fsk_test_case(uint8_t idx) { if (pcbuf[idx] < '0' || pcbuf[idx] > '9') { printf("%" PRIu32 "bps fdev:%" PRIu32 "hz ", fsk.get_bitrate(), fsk.get_tx_fdev_hz()); printf("rxbw:%" PRIu32 "Hz ", fsk.get_rx_bw_hz(REG_FSK_RXBW)); printf("afcbw:%" PRIu32 "Hz preambleLen:%" PRIu16 "\r\n", fsk.get_rx_bw_hz(REG_FSK_AFCBW), radio.read_u16(REG_FSK_PREAMBLEMSB)); } else { radio.set_opmode(RF_OPMODE_STANDBY); per_tx_delay = 0.3; if (radio.read_reg(REG_FSK_SYNCVALUE1) == 0x55 && radio.read_reg(REG_FSK_SYNCVALUE2)) { fsk.RegSyncConfig.octet = radio.read_reg(REG_FSK_SYNCCONFIG); fsk.RegSyncConfig.bits.SyncSize = 2; radio.write_reg(REG_FSK_SYNCCONFIG, fsk.RegSyncConfig.octet); radio.write_reg(REG_FSK_SYNCVALUE3, 0x90); radio.write_reg(REG_FSK_SYNCVALUE2, 0x4e); radio.write_reg(REG_FSK_SYNCVALUE1, 0x63); } fsk.RegPreambleDetect.octet = radio.read_reg(REG_FSK_PREAMBLEDETECT); fsk.RegPreambleDetect.bits.PreambleDetectorOn = 1; radio.write_reg(REG_FSK_PREAMBLEDETECT, fsk.RegPreambleDetect.octet); fsk.RegRxConfig.octet = radio.read_reg(REG_FSK_RXCONFIG); fsk.RegRxConfig.bits.AfcAutoOn = 1; fsk.RegRxConfig.bits.AgcAutoOn = 1; fsk.RegRxConfig.bits.RxTrigger = 7; // both radio.write_reg(REG_FSK_RXCONFIG, fsk.RegRxConfig.octet); fsk.RegPreambleDetect.bits.PreambleDetectorOn = 1; fsk.RegPreambleDetect.bits.PreambleDetectorSize = 1; fsk.RegPreambleDetect.bits.PreambleDetectorTol = 10; radio.write_reg(REG_FSK_PREAMBLEDETECT, fsk.RegPreambleDetect.octet); switch (pcbuf[idx]) { case '0': fsk.set_bitrate(4800); fsk.set_tx_fdev_hz(5005); fsk.set_rx_dcc_bw_hz(10417, 0); // rxbw fsk.set_rx_dcc_bw_hz(50000, 1); // afcbw radio.write_u16(REG_FSK_PREAMBLEMSB, 8); break; case '1': fsk.set_bitrate(50000); fsk.set_tx_fdev_hz(25000); fsk.set_rx_dcc_bw_hz(62500, 0); // rxbw fsk.set_rx_dcc_bw_hz(100000, 1); // afcbw radio.write_u16(REG_FSK_PREAMBLEMSB, 9); break; case '2': fsk.set_bitrate(38400); fsk.set_tx_fdev_hz(20020); fsk.set_rx_dcc_bw_hz(50000, 0); // rxbw fsk.set_rx_dcc_bw_hz(100000, 1); // afcbw radio.write_u16(REG_FSK_PREAMBLEMSB, 8); break; case '3': fsk.set_bitrate(1201); fsk.set_tx_fdev_hz(20020); fsk.set_rx_dcc_bw_hz(25000, 0); // rxbw fsk.set_rx_dcc_bw_hz(50000, 1); // afcbw radio.write_u16(REG_FSK_PREAMBLEMSB, 8); break; case '4': fsk.set_bitrate(1201); fsk.set_tx_fdev_hz(4028); fsk.set_rx_dcc_bw_hz(7813, 0); // rxbw fsk.set_rx_dcc_bw_hz(25000, 1); // afcbw radio.write_u16(REG_FSK_PREAMBLEMSB, 8); break; case '5': fsk.set_bitrate(1201); fsk.set_tx_fdev_hz(4028); fsk.set_rx_dcc_bw_hz(5208, 0); // rxbw fsk.set_rx_dcc_bw_hz(10417, 1); // afcbw radio.write_u16(REG_FSK_PREAMBLEMSB, 8); break; case '6': fsk.set_bitrate(65536); fsk.set_tx_fdev_hz(16384); fsk.set_rx_dcc_bw_hz(62500, 0); // rxbw fsk.set_rx_dcc_bw_hz(100000, 1); // afcbw fsk.RegPktConfig1.octet = radio.read_reg(REG_FSK_PACKETCONFIG1); fsk.RegPktConfig1.bits.CrcOn = 0; radio.write_reg(REG_FSK_PACKETCONFIG1, fsk.RegPktConfig1.octet); radio.write_u16(REG_FSK_PREAMBLEMSB, 5); fsk.RegSyncConfig.octet = radio.read_reg(REG_FSK_SYNCCONFIG); fsk.RegSyncConfig.bits.SyncSize = 2; fsk.RegSyncConfig.bits.SyncOn = 1; radio.write_reg(REG_FSK_SYNCCONFIG, fsk.RegSyncConfig.octet); radio.write_reg(REG_FSK_SYNCVALUE1, 0x33); radio.write_reg(REG_FSK_SYNCVALUE2, 0xcb); radio.write_reg(REG_FSK_SYNCVALUE3, 0x82); radio.RegOpMode.octet = radio.read_reg(REG_OPMODE); radio.RegOpMode.bits.ModulationType = 0; // 0 = FSK radio.RegOpMode.bits.ModulationShaping = 2; // 2=BT0.5 radio.write_reg(REG_OPMODE, radio.RegOpMode.octet); fsk.RegAfcFei.octet = radio.read_reg(REG_FSK_AFCFEI); fsk.RegAfcFei.bits.AfcAutoClearOn = 0; radio.write_reg(REG_FSK_AFCFEI, fsk.RegAfcFei.octet); fsk.RegRxConfig.bits.RxTrigger = 6; // preamble radio.write_reg(REG_FSK_RXCONFIG, fsk.RegRxConfig.octet); radio.RegDioMapping2.bits.Dio4Mapping = 3; radio.RegDioMapping2.bits.MapPreambleDetect = 1; // dio4 to preambleDetect in RX radio.write_reg(REG_DIOMAPPING2, radio.RegDioMapping2.octet); radio.RegDioMapping1.bits.Dio2Mapping = 3; // dio2 to SyncAddress in RX radio.RegDioMapping1.bits.Dio1Mapping = 1; // to FifoEmpty radio.write_reg(REG_DIOMAPPING1, radio.RegDioMapping1.octet); break; } // ...switch (pcbuf[idx]) printf("%" PRIu32 "bps fdev:%" PRIu32 "hz ", fsk.get_bitrate(), fsk.get_tx_fdev_hz()); printf("rxbw:%" PRIu32 "Hz ", fsk.get_rx_bw_hz(REG_FSK_RXBW)); printf("afcbw:%" PRIu32 "Hz preambleLen:%" PRIu16 "\r\n", fsk.get_rx_bw_hz(REG_FSK_AFCBW), radio.read_u16(REG_FSK_PREAMBLEMSB)); /* time between preamble occurring and syncAddress occuring * = bitrate in microseconds * 8 * (preamble bytes + sync bytes) */ preamble_to_sync_us = (1.0 / fsk.get_bitrate())*1e6 * 8 * (radio.read_u16(REG_FSK_PREAMBLEMSB)+1 + fsk.RegSyncConfig.bits.SyncSize+2); //printf("bitrate:%d, %f\r\n", fsk.get_bitrate(), 1.0 / fsk.get_bitrate()*1e6); printf("preamble_to_sync_us:%d\r\n", preamble_to_sync_us); } } void cmd_restart_rx(uint8_t idx) { fsk.RegRxConfig.octet = radio.read_reg(REG_FSK_RXCONFIG); fsk.RegRxConfig.bits.RestartRxWithoutPllLock = 1; radio.write_reg(REG_FSK_RXCONFIG, fsk.RegRxConfig.octet); rx_start_timer.reset(); secs_rx_start = time(NULL); fsk.RegRxConfig.bits.RestartRxWithoutPllLock = 0; printf("RestartRxWithoutPllLock\r\n"); } void cmd_toggle_modem(uint8_t idx) { ook_test_en = false; poll_irq_en = false; if (radio.RegOpMode.bits.LongRangeMode) fsk.enable(false); else lora.enable(); radio.RegOpMode.octet = radio.read_reg(REG_OPMODE); if (radio.RegOpMode.bits.LongRangeMode) printf("LoRa\r\n"); else printf("FSK\r\n"); } void cmd_empty_fifo(uint8_t idx) { RegIrqFlags2_t RegIrqFlags2; RegIrqFlags2.octet = radio.read_reg(REG_FSK_IRQFLAGS2); while (!RegIrqFlags2.bits.FifoEmpty) { if (pc.readable()) break; printf("%02x\r\n", radio.read_reg(REG_FIFO)); RegIrqFlags2.octet = radio.read_reg(REG_FSK_IRQFLAGS2); } } void cmd_print_status(uint8_t idx) { if (radio.type == SX1276) { #if defined(TARGET_MTS_MDOT_F411RE) || defined(TYPE_ABZ) printf("\r\nSX1276 "); #else if (shield_type == SHIELD_TYPE_LAS) printf("\r\nSX1276LAS "); if (shield_type == SHIELD_TYPE_MAS) printf("\r\nSX1276MAS "); #endif /* !TARGET_MTS_MDOT_F411RE */ } else if (radio.type == SX1272) printf("\r\nSX1272 "); radio.RegOpMode.octet = radio.read_reg(REG_OPMODE); if (radio.RegOpMode.bits.LongRangeMode) lora_print_status(); else fsk_print_status(); common_print_status(); } void cmd_hop_period(uint8_t idx) { int i; if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &i); lora.RegHopPeriod = i; radio.write_reg(REG_LR_HOPPERIOD, lora.RegHopPeriod); if (radio.RegDioMapping1.bits.Dio1Mapping != 1) { radio.RegDioMapping1.bits.Dio1Mapping = 1; radio.write_reg(REG_DIOMAPPING1, radio.RegDioMapping1.octet); } } lora.RegHopPeriod = radio.read_reg(REG_LR_HOPPERIOD); printf("HopPeriod:0x%02x\r\n", lora.RegHopPeriod); } void cmd_lora_ppg(uint8_t idx) { int i; if (pcbuf[idx] != 0) { sscanf(pcbuf+idx, "%x", &i); radio.write_reg(REG_LR_SYNC_BYTE, i); } printf("lora sync:0x%02x\r\n", radio.read_reg(REG_LR_SYNC_BYTE)); } void cmd_rssi_offset(uint8_t idx) { int i; if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &i); fsk.RegRssiConfig.bits.RssiOffset = i; radio.write_reg(REG_FSK_RSSICONFIG, fsk.RegRssiConfig.octet); } fsk.RegRssiConfig.octet = radio.read_reg(REG_FSK_RSSICONFIG); printf("RssiOffset:%d\r\n", fsk.RegRssiConfig.bits.RssiOffset); } void cmd_rssi_smoothing(uint8_t idx) { int i; if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &i); fsk.RegRssiConfig.bits.RssiSmoothing = i; radio.write_reg(REG_FSK_RSSICONFIG, fsk.RegRssiConfig.octet); } fsk.RegRssiConfig.octet = radio.read_reg(REG_FSK_RSSICONFIG); printf("RssiSmoothing:%d\r\n", fsk.RegRssiConfig.bits.RssiSmoothing); } void cmd_rssi_threshold(uint8_t idx) { if ((pcbuf[idx] >= '0' && pcbuf[idx] <= '9') || pcbuf[idx] == '-') { float dbm; sscanf(pcbuf+idx, "%f", &dbm); dbm *= (float)2.0; fsk.RegRssiThresh = (int)fabs(dbm); radio.write_reg(REG_FSK_RSSITHRESH, fsk.RegRssiThresh); } fsk.RegRssiThresh = radio.read_reg(REG_FSK_RSSITHRESH); printf("rssiThreshold:-%.1f\r\n", fsk.RegRssiThresh / 2.0); } void cmd_rx_trigger(uint8_t idx) { printf("RxTrigger:"); switch (fsk.RegRxConfig.bits.RxTrigger) { case 0: fsk.RegRxConfig.bits.RxTrigger = 1; printf("rssi\r\n"); break; case 1: fsk.RegRxConfig.bits.RxTrigger = 6; printf("preamble\r\n"); break; case 6: fsk.RegRxConfig.bits.RxTrigger = 7; printf("both\r\n"); break; case 7: fsk.RegRxConfig.bits.RxTrigger = 0; printf("none\r\n"); break; default: fsk.RegRxConfig.bits.RxTrigger = 0; printf("none\r\n"); break; } radio.write_reg(REG_FSK_RXCONFIG, fsk.RegRxConfig.octet); } void cmd_cadper(uint8_t idx) { set_per_en(true); PacketNormalCnt = 0; PacketRxSequencePrev = 0; // transmitter side PacketTxCnt is 1 at first TX PacketPerKoCnt = 0; PacketPerOkCnt = 0; cadper_enable = true; lora.RegIrqFlags.octet = radio.read_reg(REG_LR_IRQFLAGS); /* clear any stale flag */ radio.write_reg(REG_LR_IRQFLAGS, lora.RegIrqFlags.octet); /* start first CAD */ radio.set_opmode(RF_OPMODE_CAD); num_cads = 0; } #if 0 void cmd_cadrx(uint8_t idx) { int n_tries = 1; lora.RegIrqFlags.octet = radio.read_reg(REG_LR_IRQFLAGS); /* clear any stale flag */ radio.write_reg(REG_LR_IRQFLAGS, lora.RegIrqFlags.octet); if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &n_tries); } while (n_tries > 0) { radio.set_opmode(RF_OPMODE_CAD); do { lora.RegIrqFlags.octet = radio.read_reg(REG_LR_IRQFLAGS); } while (!lora.RegIrqFlags.bits.CadDetected && !lora.RegIrqFlags.bits.CadDone); if (lora.RegIrqFlags.bits.CadDetected) { lora.start_rx(RF_OPMODE_RECEIVER_SINGLE); n_tries = 1; // end printf("CadDetected "); } if (lora.RegIrqFlags.bits.CadDone) { printf("CadDone "); } radio.write_reg(REG_LR_IRQFLAGS, lora.RegIrqFlags.octet); printf("\r\n"); n_tries--; } } #endif /* #if 0 */ void cmd_cad(uint8_t idx) { int n_tries = 1; lora.RegIrqFlags.octet = radio.read_reg(REG_LR_IRQFLAGS); /* clear any stale flag */ radio.write_reg(REG_LR_IRQFLAGS, lora.RegIrqFlags.octet); if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &n_tries); } while (n_tries > 0) { radio.set_opmode(RF_OPMODE_CAD); do { lora.RegIrqFlags.octet = radio.read_reg(REG_LR_IRQFLAGS); } while (!lora.RegIrqFlags.bits.CadDetected && !lora.RegIrqFlags.bits.CadDone); if (lora.RegIrqFlags.bits.CadDetected) { n_tries = 1; // end printf("CadDetected "); } if (lora.RegIrqFlags.bits.CadDone) { if (n_tries == 1) // print on last try printf("CadDone "); } radio.write_reg(REG_LR_IRQFLAGS, lora.RegIrqFlags.octet); n_tries--; } printf("\r\n"); } void cmd_rx_timeout(uint8_t idx) { int symb_timeout; uint16_t reg_u16 = radio.read_u16(REG_LR_MODEMCONFIG2); if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &symb_timeout); reg_u16 &= 0xfc00; reg_u16 |= symb_timeout; radio.write_u16(REG_LR_MODEMCONFIG2, reg_u16); } reg_u16 = radio.read_u16(REG_LR_MODEMCONFIG2); printf("SymbTimeout:%d\r\n", reg_u16 & 0x3ff); } void cmd_rx_single(uint8_t idx) { lora.start_rx(RF_OPMODE_RECEIVER_SINGLE); } void preamble_without_sync() { printf("preamble_without_sync Afc:%dHz\r\n", (int)(FREQ_STEP_HZ * radio.read_s16(REG_FSK_AFCMSB))); fsk.RegRxConfig.bits.RestartRxWithoutPllLock = 1; radio.write_reg(REG_FSK_RXCONFIG, fsk.RegRxConfig.octet); } Timeout pd_timeout; Timeout sync_timeout; void preamble_detect_isr() { // only used between frames, on background noise pd_timeout.attach_us(&preamble_without_sync, 1500); // 122us per byte } void cmd_rx(uint8_t idx) { set_per_en(false); if (radio.RegOpMode.bits.LongRangeMode) lora.start_rx(RF_OPMODE_RECEIVER); else { if (poll_irq_en) { fsk_RegIrqFlags2_prev.octet = 0; fsk_RegIrqFlags1_prev.octet = 0; } rx_start_timer.start(); secs_rx_start = time(NULL); fsk.start_rx(); radio.RegDioMapping1.bits.Dio2Mapping = 3; // dio2 to syncadrs radio.write_reg(REG_DIOMAPPING1, radio.RegDioMapping1.octet); if (radio.HF) { fsk.RegRssiConfig.octet = radio.read_reg(REG_FSK_RSSICONFIG); fsk.RegRssiConfig.bits.RssiOffset = FSK_RSSI_OFFSET; fsk.RegRssiConfig.bits.RssiSmoothing = FSK_RSSI_SMOOTHING; radio.write_reg(REG_FSK_RSSICONFIG, fsk.RegRssiConfig.octet); } // sync shadow regsiters radio.RegDioMapping1.octet = radio.read_reg(REG_DIOMAPPING1); radio.RegDioMapping2.octet = radio.read_reg(REG_DIOMAPPING2); } } void cmd_radio_reg_read(uint8_t idx) { int i; sscanf(pcbuf+idx, "%x", &i); printf("%02x: %02x\r\n", i, radio.read_reg(i)); } void cmd_radio_reg_write(uint8_t idx) { int i, n; sscanf(pcbuf+idx, "%x %x", &i, &n); radio.write_reg(i, n); printf("%02x: %02x\r\n", i, radio.read_reg(i)); } void cmd_mod_shaping(uint8_t idx) { uint8_t s = fsk.get_modulation_shaping(); if (s == 3) s = 0; else s++; fsk.set_modulation_shaping(s); if (radio.RegOpMode.bits.ModulationType == 0) { printf("FSK "); switch (s) { case 0: printf("off"); break; case 1: printf("BT1.0 "); break; case 2: printf("BT0.5 "); break; case 3: printf("BT0.3 "); break; } } else if (radio.RegOpMode.bits.ModulationType == 1) { printf("OOK "); switch (s) { case 0: printf("off"); break; case 1: printf("Fcutoff=bitrate"); break; case 2: printf("Fcutoff=2*bitrate"); break; case 3: printf("?"); break; } } printf("\r\n"); } void cmd_MapPreambleDetect(uint8_t idx) { radio.RegDioMapping2.bits.MapPreambleDetect ^= 1; radio.write_reg(REG_DIOMAPPING2, radio.RegDioMapping2.octet); printf("MapPreambleDetect:"); if (radio.RegDioMapping2.bits.MapPreambleDetect) printf("preamble\r\n"); else printf("rssi\r\n"); } void cmd_bgr(uint8_t idx) { RegPdsTrim1_t pds_trim; uint8_t adr; if (radio.type == SX1276) adr = REG_PDSTRIM1_SX1276; else adr = REG_PDSTRIM1_SX1272; pds_trim.octet = radio.read_reg(adr); if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { int i; sscanf(&pcbuf[idx], "%d", &i); pds_trim.bits.prog_txdac = i; } radio.write_reg(adr, pds_trim.octet); printf("prog_txdac:%.1fuA\r\n", 2.5 + (pds_trim.bits.prog_txdac * 0.625)); /* increase OCP threshold to allow more power */ radio.RegOcp.octet = radio.read_reg(REG_OCP); if (radio.RegOcp.bits.OcpTrim < 16) { radio.RegOcp.bits.OcpTrim = 16; radio.write_reg(REG_OCP, radio.RegOcp.octet); } } void cmd_ook(uint8_t idx) { fsk.set_bitrate(32768); radio.write_u16(REG_FSK_PREAMBLEMSB, 0); // zero preamble length radio.RegOpMode.bits.ModulationType = 1; // to ook mode radio.write_reg(REG_OPMODE, radio.RegOpMode.octet); fsk.RegSyncConfig.bits.SyncOn = 0; radio.write_reg(REG_FSK_SYNCCONFIG, fsk.RegSyncConfig.octet); ook_test_en = true; printf("OOK\r\n"); } void cmd_ocp(uint8_t idx) { int i; if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &i); if (i < 130) radio.RegOcp.bits.OcpTrim = (i - 45) / 5; else radio.RegOcp.bits.OcpTrim = (i + 30) / 10; radio.write_reg(REG_OCP, radio.RegOcp.octet); } radio.RegOcp.octet = radio.read_reg(REG_OCP); if (radio.RegOcp.bits.OcpTrim < 16) i = 45 + (5 * radio.RegOcp.bits.OcpTrim); else if (radio.RegOcp.bits.OcpTrim < 28) i = (10 * radio.RegOcp.bits.OcpTrim) - 30; else i = 240; printf("Ocp: %dmA\r\n", i); } void cmd_op(uint8_t idx) { int i, dbm; RegPdsTrim1_t pds_trim; uint8_t adr; if (radio.type == SX1276) adr = REG_PDSTRIM1_SX1276; else adr = REG_PDSTRIM1_SX1272; pds_trim.octet = radio.read_reg(adr); if (pcbuf[idx] >= '0' && (pcbuf[idx] <= '9' || pcbuf[idx] == '-')) { sscanf(pcbuf+idx, "%d", &i); if (radio.RegPaConfig.bits.PaSelect) { /* PABOOST used: +2dbm to +17, or +20 */ if (i == 20) { printf("+20dBm PADAC bias\r\n"); i -= 3; pds_trim.bits.prog_txdac = 7; radio.write_reg(adr, pds_trim.octet); } if (i > 1) radio.RegPaConfig.bits.OutputPower = i - 2; } else { /* RFO used: -1 to +14dbm */ if (i < 15) radio.RegPaConfig.bits.OutputPower = i + 1; } radio.write_reg(REG_PACONFIG, radio.RegPaConfig.octet); } radio.RegPaConfig.octet = radio.read_reg(REG_PACONFIG); if (radio.RegPaConfig.bits.PaSelect) { printf("PA_BOOST "); dbm = radio.RegPaConfig.bits.OutputPower + pds_trim.bits.prog_txdac - 2; } else { printf("RFO "); dbm = radio.RegPaConfig.bits.OutputPower - 1; } printf("OutputPower:%ddBm\r\n", dbm); } void cmd_fsk_agcauto(uint8_t idx) { fsk.RegRxConfig.octet = radio.read_reg(REG_FSK_RXCONFIG); fsk.RegRxConfig.bits.AgcAutoOn ^= 1; printf("AgcAuto:"); if (fsk.RegRxConfig.bits.AgcAutoOn) printf("On\r\n"); else printf("OFF\r\n"); radio.write_reg(REG_FSK_RXCONFIG, fsk.RegRxConfig.octet); } void cmd_fsk_afcauto(uint8_t idx) { fsk.RegRxConfig.octet = radio.read_reg(REG_FSK_RXCONFIG); fsk.RegRxConfig.bits.AfcAutoOn ^= 1; radio.write_reg(REG_FSK_RXCONFIG, fsk.RegRxConfig.octet); printf("AfcAuto:"); if (fsk.RegRxConfig.bits.AfcAutoOn) printf("On\r\n"); else printf("OFF\r\n"); } void cmd_crc32(uint8_t idx) { crc32_en ^= true; printf("crc32_en:%u\r\n", crc32_en); } void cmd_crcOn(uint8_t idx) { if (radio.RegOpMode.bits.LongRangeMode) { lora.setRxPayloadCrcOn(!lora.getRxPayloadCrcOn()); lora_printRxPayloadCrcOn(); } else { printf("CrcOn:"); fsk.RegPktConfig1.bits.CrcOn ^= 1; radio.write_reg(REG_FSK_PACKETCONFIG1, fsk.RegPktConfig1.octet); if (fsk.RegPktConfig1.bits.CrcOn) printf("On\r\n"); else printf("Off\r\n"); if (fsk.RegPktConfig2.bits.DataModePacket && radio.RegOpMode.bits.Mode == RF_OPMODE_RECEIVER) { fsk.config_dio0_for_pktmode_rx(); } } printf("\r\n"); } #ifdef LORA_TX_TEST void cmd_lora_fixed_payload_symbol(uint8_t idx) // fixed payload, symbol test { int n, i; symbol_num = pcbuf[idx] - '0'; sscanf(pcbuf+idx+2, "%d", &i); n = i >> 2; // num nibbles printf("%d nibbles: ", n); lora.RegPayloadLength = byte_pad_length; while (n > 0) { lora.RegPayloadLength++; n -= 2; // one byte = two nibbles } printf("%d bytes\r\n", lora.RegPayloadLength); symbol_sweep_nbits = i >> 2; symbol_sweep_bit_counter = 0; symbol_sweep_bit_counter_stop = 1 << symbol_sweep_nbits; // one bit per nibble used in symbol (2bits per byte) printf("sweep symbol %d, length bytes:%d nbits:%d stop:0x%x\r\n", symbol_num, lora.RegPayloadLength, symbol_sweep_nbits, symbol_sweep_bit_counter_stop); txticker_state = TXTICKER_STATE_SYMBOL_SWEEP; radio.write_reg(REG_LR_PAYLOADLENGTH, lora.RegPayloadLength); tx_ticker.attach(&fp_cb, tx_ticker_rate); } void cmd_fixed_payload_offset(uint8_t idx) { int i; if (pcbuf[idx] >='0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &i); byte_pad_length = i; } printf("byte_pad_length:%d\r\n", byte_pad_length); } void cmd_lora_fixed_payload(uint8_t idx) { int n, a, i, d = 0; for (i = idx; i < pcbuf_len; ) { //printf("scan:\"%s\"\r\n", pcbuf+i); sscanf(pcbuf+i, "%x", &n); //printf("n:%x\r\n", n); radio.tx_buf[d] = n; printf("%02x ", n); while (pcbuf[i] == ' ') i++; //printf("%d pcbuf[i]:%x\r\n", i, pcbuf[i]); for (a = i; pcbuf[a] != ' '; a++) if (a >= pcbuf_len) break; i = a; while (pcbuf[i] == ' ') { i++; if (i >= pcbuf_len) break; } d++; } lora.RegPayloadLength = d; printf("\r\nlora.RegPayloadLength:%d\r\n", lora.RegPayloadLength); radio.write_reg(REG_LR_PAYLOADLENGTH, lora.RegPayloadLength); lora.start_tx(lora.RegPayloadLength); } void cmd_lora_toggle_crcOn(uint8_t idx) { /* test lora crc on/off */ lora.RegPayloadLength = 1; radio.write_reg(REG_LR_PAYLOADLENGTH, lora.RegPayloadLength); txticker_state = TXTICKER_STATE_TOG_CRC_ON; tx_ticker.attach(&fp_cb, tx_ticker_rate); } void lora_cycle_payload_length(uint8_t idx) { int i; if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &i); payload_length_stop = i; } txticker_state = TXTICKER_STATE_CYCLE_PAYLOAD_LENGTH; tx_ticker.attach(&fp_cb, tx_ticker_rate); } void cmd_lora_data_ramp(uint8_t idx) { // lora payload data ramping lora.RegPayloadLength = pcbuf[idx] - '0'; radio.write_reg(REG_LR_PAYLOADLENGTH, lora.RegPayloadLength); txticker_state = TXTICKER_STATE_RAMP_PAYLOAD_DATA_START; tx_ticker.attach(&fp_cb, tx_ticker_rate); } void cmd_lora_sync_lo_nibble(uint8_t idx) { lora_sync_byte = 0x00; on_txdone_state = ON_TXDONE_STATE_SYNC_LO_NIBBLE; on_txdone_delay = 0.100; txdone_timeout_cb(); //sync_sweep_timeout.attach(&txdone_timeout_cb, sync_sweep_delay); } void cmd_lora_toggle_header_mode(uint8_t idx) { lora.RegPayloadLength = 1; radio.write_reg(REG_LR_PAYLOADLENGTH, lora.RegPayloadLength); txticker_state = TXTICKER_STATE_TOG_HEADER_MODE; tx_ticker.attach(&fp_cb, tx_ticker_rate); } void cmd_lora_sync_sweep(uint8_t idx) { lora.RegPayloadLength = 1; radio.write_reg(REG_LR_PAYLOADLENGTH, lora.RegPayloadLength); txticker_sync_byte = 0x12; if (pcbuf[idx] == '1') txticker_state = TXTICKER_STATE_CYCLE_SYNC_1; else if (pcbuf[idx] == '2') txticker_state = TXTICKER_STATE_CYCLE_SYNC_2; tx_ticker.attach(&fp_cb, tx_ticker_rate); } void cmd_lora_all_payload_lengths(uint8_t idx) { on_txdone_repeat_cnt = 0; on_txdone_state = ON_TXDONE_STATE_PAYLOAD_LENGTH; on_txdone_delay = 0.200; txdone_timeout_cb(); lora.RegPayloadLength = 0; radio.write_reg(REG_LR_PAYLOADLENGTH, lora.RegPayloadLength); } void cmd_lora_toggle_all_bits(uint8_t idx) { lora.RegPayloadLength = (pcbuf[idx] - '0') + byte_pad_length; radio.write_reg(REG_LR_PAYLOADLENGTH, lora.RegPayloadLength); txticker_state = TXTICKER_STATE_TOGGLE_ALL_BITS_START; printf("tab byte length:%d\r\n", lora.RegPayloadLength); if (lora.RegPayloadLength > 0) tx_ticker.attach(&fp_cb, tx_ticker_rate); } void cmd_lora_cycle_codingrates(uint8_t idx) { lora.RegPayloadLength = 1; radio.write_reg(REG_LR_PAYLOADLENGTH, lora.RegPayloadLength); txticker_state = TXTICKER_STATE_CYCLE_CODING_RATE; tx_ticker.attach(&fp_cb, tx_ticker_rate); } #endif /* LORA_TX_TEST */ void cmd_codingRate(uint8_t idx) { if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') lora.setCodingRate(pcbuf[idx] - '0'); lora.RegModemConfig.octet = radio.read_reg(REG_LR_MODEMCONFIG); lora_printCodingRate(false); // false: transmitted printf("\r\n"); } void cmd_lora_header_mode(uint8_t idx) { lora.setHeaderMode(!lora.getHeaderMode()); lora.RegModemConfig.octet = radio.read_reg(REG_LR_MODEMCONFIG); lora_printHeaderMode(); printf("\r\n"); } void cmd_fsk_AfcAutoClearOn(uint8_t idx) { fsk.RegAfcFei.bits.AfcAutoClearOn ^= 1; printf("AfcAutoClearOn: "); radio.write_reg(REG_FSK_AFCFEI, fsk.RegAfcFei.octet); if (fsk.RegAfcFei.bits.AfcAutoClearOn) printf("ON\r\n"); else printf("off\r\n"); } void cmd_fsk_AutoRestartRxMode(uint8_t idx) { fsk.RegSyncConfig.bits.AutoRestartRxMode++; radio.write_reg(REG_FSK_SYNCCONFIG, fsk.RegSyncConfig.octet); fsk.RegSyncConfig.octet = radio.read_reg(REG_FSK_SYNCCONFIG); printf("AutoRestartRxMode:"); switch (fsk.RegSyncConfig.bits.AutoRestartRxMode) { case 0: printf("off "); break; case 1: printf("no-pll-wait "); break; case 2: printf("pll-wait "); break; case 3: printf("3 "); break; } printf("\r\n"); } void cmd_AfcClear(uint8_t idx) { printf("clear afc: "); fsk.RegAfcFei.bits.AfcClear = 1; radio.write_reg(REG_FSK_AFCFEI, fsk.RegAfcFei.octet); fsk.RegAfcFei.bits.AfcClear = 0; printf("%dHz\r\n", (int)(FREQ_STEP_HZ * radio.read_s16(REG_FSK_AFCMSB))); } void cmd_fsk_bitrate(uint8_t idx) { if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { float kbits; sscanf(&pcbuf[idx], "%f", &kbits); fsk.set_bitrate((int)(kbits*1000)); } printf("%fkbps\r\n", fsk.get_bitrate()/(float)1000.0); } void cmd_bandwidth(uint8_t idx) { int i; float f; if (radio.RegOpMode.bits.LongRangeMode) { if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { radio.set_opmode(RF_OPMODE_STANDBY); sscanf(&pcbuf[idx], "%d", &i); lora.setBw_KHz(i); } else lora_printAllBw(); lora.RegModemConfig.octet = radio.read_reg(REG_LR_MODEMCONFIG); printf("current "); lora_printBw(); printf("\r\n"); } else { // FSK: if (pcbuf[idx] == 'a') { idx++; if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { radio.set_opmode(RF_OPMODE_STANDBY); sscanf(&pcbuf[idx], "%f", &f); fsk.set_rx_dcc_bw_hz((int)(f*(float)1000.0), 1); } printf("afcbw:%.3fkHz\r\n", fsk.get_rx_bw_hz(REG_FSK_AFCBW)/1000.0); } else { if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { radio.set_opmode(RF_OPMODE_STANDBY); sscanf(&pcbuf[idx], "%f", &f); fsk.set_rx_dcc_bw_hz((int)(f*(float)1000.0), 0); } printf("rxbw:%.3fkHz\r\n", fsk.get_rx_bw_hz(REG_FSK_RXBW)/1000.0); } } } void cmd_lora_poll_validHeader(uint8_t idx) { lora.poll_vh ^= 1; printf("poll_vh:%d\r\n", lora.poll_vh); } void cmd_fsk_syncword(uint8_t idx) { int i, d = 0; uint8_t reg_addr = REG_FSK_SYNCVALUE1; fsk.RegSyncConfig.octet = radio.read_reg(REG_FSK_SYNCCONFIG); if (pcbuf_len != idx) { // something to write? for (i = idx; i < pcbuf_len; ) { int a, n; sscanf(pcbuf+i, "%x", &n); radio.write_reg(reg_addr++, n); //printf("%02x ", n); while (pcbuf[i] == ' ') i++; for (a = i; pcbuf[a] != ' '; a++) if (a >= pcbuf_len) break; i = a; while (pcbuf[i] == ' ') { i++; if (i >= pcbuf_len) break; } d++; } fsk.RegSyncConfig.bits.SyncSize = reg_addr - REG_FSK_SYNCVALUE1 - 1; radio.write_reg(REG_FSK_SYNCCONFIG, fsk.RegSyncConfig.octet); } printf("%d: ", fsk.RegSyncConfig.bits.SyncSize); for (i = 0; i <= fsk.RegSyncConfig.bits.SyncSize; i++) printf("%02x ", radio.read_reg(REG_FSK_SYNCVALUE1+i)); printf("\r\n"); } void cmd_fsk_syncOn(uint8_t idx) { fsk.RegSyncConfig.bits.SyncOn ^= 1; radio.write_reg(REG_FSK_SYNCCONFIG, fsk.RegSyncConfig.octet); printf("SyncOn:%d\r\n", fsk.RegSyncConfig.bits.SyncOn); } void cmd_fsk_bitsync(uint8_t idx) { fsk.RegOokPeak.octet = radio.read_reg(REG_FSK_OOKPEAK); fsk.RegOokPeak.bits.BitSyncOn ^= 1; radio.write_reg(REG_FSK_OOKPEAK, fsk.RegOokPeak.octet); if (fsk.RegOokPeak.bits.BitSyncOn) printf("BitSyncOn\r\n"); else printf("BitSync Off\r\n"); } void cmd_lora_sf(uint8_t idx) { int i; if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &i); lora.setSf(i); if (i == 6 && !lora.getHeaderMode()) { printf("SF6: to implicit header mode\r\n"); lora.setHeaderMode(true); } } lora.RegModemConfig2.octet = radio.read_reg(REG_LR_MODEMCONFIG2); lora_printSf(); printf("\r\n"); } void cmd_fsk_TxStartCondition(uint8_t idx) { fsk.RegFifoThreshold.bits.TxStartCondition ^= 1; radio.write_reg(REG_FSK_FIFOTHRESH, fsk.RegFifoThreshold.octet); printf("TxStartCondition:"); if (fsk.RegFifoThreshold.bits.TxStartCondition) printf("!FifoEmpty\r\n"); else printf("FifoLevel\r\n"); } void cmd_fsk_read_fei(uint8_t idx) { printf("fei:%dHz\r\n", (int)(FREQ_STEP_HZ * radio.read_s16(REG_FSK_FEIMSB))); } void cmd_fsk_fdev(uint8_t idx) { if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { float khz; sscanf(pcbuf+idx, "%f", &khz); fsk.set_tx_fdev_hz((int)(khz*1000)); } printf("fdev:%fKHz\r\n", fsk.get_tx_fdev_hz()/(float)1000.0); } void cmd_spifreq(uint8_t idx) { if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { int hz, MHz; sscanf(pcbuf+idx, "%d", &MHz); hz = MHz * 1000000; printf("spi hz:%u\r\n", hz); radio.m_spi.frequency(hz); } } void cmd_frf(uint8_t idx) { if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { float MHz; sscanf(pcbuf+idx, "%f", &MHz); //printf("MHz:%f\r\n", MHz); radio.set_frf_MHz(MHz); } printf("%fMHz\r\n", radio.get_frf_MHz()); #if !defined(TARGET_MTS_MDOT_F411RE) && !defined(TYPE_ABZ) radio.RegPaConfig.octet = radio.read_reg(REG_PACONFIG); if (shield_type == SHIELD_TYPE_LAS) { // LAS HF=PA_BOOST LF=RFO if (radio.HF) radio.RegPaConfig.bits.PaSelect = 1; else radio.RegPaConfig.bits.PaSelect = 0; } radio.write_reg(REG_PACONFIG, radio.RegPaConfig.octet); #endif /* !TARGET_MTS_MDOT_F411RE */ } void cmd_fsk_PacketFormat(uint8_t idx) { printf("PacketFormat:"); fsk.RegPktConfig1.bits.PacketFormatVariable ^= 1; radio.write_reg(REG_FSK_PACKETCONFIG1, fsk.RegPktConfig1.octet); if (fsk.RegPktConfig1.bits.PacketFormatVariable) printf("variable\r\n"); else printf("fixed\r\n"); } void cmd_payload_length(uint8_t idx) { int i; if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &i); if (radio.RegOpMode.bits.LongRangeMode) { lora.RegPayloadLength = i; radio.write_reg(REG_LR_PAYLOADLENGTH, lora.RegPayloadLength); } else { fsk.RegPktConfig2.bits.PayloadLength = i; radio.write_u16(REG_FSK_PACKETCONFIG2, fsk.RegPktConfig2.word); } } if (radio.RegOpMode.bits.LongRangeMode) { lora.RegPayloadLength = radio.read_reg(REG_LR_PAYLOADLENGTH); printf("PayloadLength:%d\r\n", lora.RegPayloadLength); } else { printf("PayloadLength:%d\r\n", fsk_get_PayloadLength()); } } void cmd_paRamp(uint8_t idx) { int i; uint8_t reg_par = radio.read_reg(REG_PARAMP); uint8_t PaRamp = reg_par & 0x0f; reg_par &= 0xf0; if (PaRamp == 15) PaRamp = 0; else PaRamp++; radio.write_reg(REG_PARAMP, reg_par | PaRamp); printf("PaRamp:"); switch (PaRamp) { case 0: i = 3400; break; case 1: i = 2000; break; case 2: i = 1000; break; case 3: i = 500; break; case 4: i = 250; break; case 5: i = 125; break; case 6: i = 100; break; case 7: i = 62; break; case 8: i = 50; break; case 9: i = 40; break; case 10: i = 31; break; case 11: i = 25; break; case 12: i = 20; break; case 13: i = 15; break; case 14: i = 12; break; case 15: i = 10; break; } printf("%dus\r\n", i); } void cmd_paSelect(uint8_t idx) { radio.RegPaConfig.bits.PaSelect ^= 1; radio.write_reg(REG_PACONFIG, radio.RegPaConfig.octet); printPa(); printf("\r\n"); } void cmd_poll_irq_en(uint8_t idx) { poll_irq_en ^= 1; printf("poll_irq_en:"); if (poll_irq_en) { printf("irqFlags register\r\n"); fsk_RegIrqFlags1_prev.octet = 0; fsk_RegIrqFlags2_prev.octet = 0; } else printf("DIO pin interrupt\r\n"); } void cmd_per_id(uint8_t idx) { if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &per_id); } printf("PER device ID:%d\r\n", per_id); } void cmd_pertx(uint8_t idx) { int i; if (cadper_enable) cadper_enable = false; set_per_en(true); if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &i); PacketTxCntEnd = i; } PacketTxCnt = 0; per_timeout.attach(&per_cb, per_tx_delay); } void cmd_perrx(uint8_t idx) { set_per_en(true); PacketNormalCnt = 0; PacketRxSequencePrev = 0; // transmitter side PacketTxCnt is 1 at first TX PacketPerKoCnt = 0; PacketPerOkCnt = 0; //dio3.rise(&dio3_cb); if (radio.RegOpMode.bits.LongRangeMode) lora.start_rx(RF_OPMODE_RECEIVER); else { fsk.start_rx(); radio.RegDioMapping1.bits.Dio2Mapping = 3; // dio2 to syncadrs radio.write_reg(REG_DIOMAPPING1, radio.RegDioMapping1.octet); if (radio.HF) { fsk.RegRssiConfig.octet = radio.read_reg(REG_FSK_RSSICONFIG); fsk.RegRssiConfig.bits.RssiOffset = FSK_RSSI_OFFSET; fsk.RegRssiConfig.bits.RssiSmoothing = FSK_RSSI_SMOOTHING; radio.write_reg(REG_FSK_RSSICONFIG, fsk.RegRssiConfig.octet); } } } void cmd_fsk_PreambleDetectorOn(uint8_t idx) { fsk.RegPreambleDetect.bits.PreambleDetectorOn ^= 1; radio.write_reg(REG_FSK_PREAMBLEDETECT, fsk.RegPreambleDetect.octet); printf("PreambleDetector:"); if (fsk.RegPreambleDetect.bits.PreambleDetectorOn) printf("On\r\n"); else printf("OFF\r\n"); } void cmd_fsk_PreambleDetectorSize(uint8_t idx) { int i; if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &i); fsk.RegPreambleDetect.bits.PreambleDetectorSize = i; } printf("PreambleDetectorSize:%d\r\n", fsk.RegPreambleDetect.bits.PreambleDetectorSize); radio.write_reg(REG_FSK_PREAMBLEDETECT, fsk.RegPreambleDetect.octet); } void cmd_fsk_PreambleDetectorTol(uint8_t idx) { int i; if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &i); fsk.RegPreambleDetect.bits.PreambleDetectorTol = i; } printf("PreambleDetectorTol:%d\r\n", fsk.RegPreambleDetect.bits.PreambleDetectorTol); radio.write_reg(REG_FSK_PREAMBLEDETECT, fsk.RegPreambleDetect.octet); } void cmd_PreambleSize(uint8_t idx) { int i; if (radio.RegOpMode.bits.LongRangeMode) { if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &i); radio.write_u16(REG_LR_PREAMBLEMSB, i); } lora.RegPreamble = radio.read_u16(REG_LR_PREAMBLEMSB); printf("lora PreambleLength:%d\r\n", lora.RegPreamble); } else { if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &i); radio.write_u16(REG_FSK_PREAMBLEMSB, i); } printf("PreambleSize:%d\r\n", radio.read_u16(REG_FSK_PREAMBLEMSB)); } } void cmd_fsk_PreamblePolarity(uint8_t idx) { fsk.RegSyncConfig.octet = radio.read_reg(REG_FSK_SYNCCONFIG); fsk.RegSyncConfig.bits.PreamblePolarity ^= 1; radio.write_reg(REG_FSK_SYNCCONFIG, fsk.RegSyncConfig.octet); if (fsk.RegSyncConfig.bits.PreamblePolarity) printf("0x55\r\n"); else printf("0xaa\r\n"); } void cmd_pllbw(uint8_t idx) { RegPll_t pll; if (radio.type == SX1272) { // 0x5c and 0x5e registers pll.octet = radio.read_reg(REG_PLL_SX1272); if (pll.bits.PllBandwidth == 3) pll.bits.PllBandwidth = 0; else pll.bits.PllBandwidth++; radio.write_reg(REG_PLL_SX1272, pll.octet); pll.octet = radio.read_reg(REG_PLL_LOWPN_SX1272); if (pll.bits.PllBandwidth == 3) pll.bits.PllBandwidth = 0; else pll.bits.PllBandwidth++; radio.write_reg(REG_PLL_LOWPN_SX1272, pll.octet); } else if (radio.type == SX1276) { // 0x70 register pll.octet = radio.read_reg(REG_PLL_SX1276); if (pll.bits.PllBandwidth == 3) pll.bits.PllBandwidth = 0; else pll.bits.PllBandwidth++; radio.write_reg(REG_PLL_SX1276, pll.octet); } switch (pll.bits.PllBandwidth) { case 0: printf("75"); break; case 1: printf("150"); break; case 2: printf("225"); break; case 3: printf("300"); break; } printf("KHz\r\n"); } void cmd_lna_boost(uint8_t idx) { radio.RegLna.octet = radio.read_reg(REG_LNA); if (radio.RegLna.bits.LnaBoostHF == 3) radio.RegLna.bits.LnaBoostHF = 0; else radio.RegLna.bits.LnaBoostHF++; radio.write_reg(REG_LNA, radio.RegLna.octet); printf("LNA-boost:%d\r\n", radio.RegLna.bits.LnaBoostHF); } void cmd_LowDataRateOptimize(uint8_t idx) { if (radio.type == SX1272) { lora.RegModemConfig.octet = radio.read_reg(REG_LR_MODEMCONFIG); lora.RegModemConfig.sx1272bits.LowDataRateOptimize ^= 1; printf("LowDataRateOptimize:%d\r\n", lora.RegModemConfig.sx1272bits.LowDataRateOptimize); radio.write_reg(REG_LR_MODEMCONFIG, lora.RegModemConfig.octet); } else if (radio.type == SX1276) { lora.RegModemConfig3.octet = radio.read_reg(REG_LR_MODEMCONFIG3); lora.RegModemConfig3.sx1276bits.LowDataRateOptimize ^= 1; printf("LowDataRateOptimize:%d\r\n", lora.RegModemConfig3.sx1276bits.LowDataRateOptimize); radio.write_reg(REG_LR_MODEMCONFIG3, lora.RegModemConfig3.octet); } } void cmd_fsk_FifoThreshold(uint8_t idx) { int i; fsk.RegFifoThreshold.octet = radio.read_reg(REG_FSK_FIFOTHRESH); if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &i); fsk.RegFifoThreshold.bits.FifoThreshold = i; } radio.write_reg(REG_FSK_FIFOTHRESH, fsk.RegFifoThreshold.octet); printf("FifoThreshold:%d\r\n", fsk.RegFifoThreshold.bits.FifoThreshold); fsk.RegFifoThreshold.octet = radio.read_reg(REG_FSK_FIFOTHRESH); } void cmd_tx_ticker_rate(uint8_t idx) { if (pcbuf[idx] != 0) { sscanf(pcbuf+idx, "%f", &tx_ticker_rate); } printf("tx_ticker_rate:%f\r\n", tx_ticker_rate); } void cmd_lora_tx_invert(uint8_t idx) { lora.invert_tx(lora.RegTest33.bits.chirp_invert_tx); printf("chirp_invert_tx :%d\r\n", lora.RegTest33.bits.chirp_invert_tx); } void cmd_lora_rx_invert(uint8_t idx) { lora.invert_rx(!lora.RegTest33.bits.invert_i_q); printf("rx invert_i_q:%d\r\n", lora.RegTest33.bits.invert_i_q); } void cmd_fsk_dcfree(uint8_t idx) { fsk.RegPktConfig1.octet = radio.read_reg(REG_FSK_PACKETCONFIG1); if (fsk.RegPktConfig1.bits.DcFree == 3) fsk.RegPktConfig1.bits.DcFree = 0; else fsk.RegPktConfig1.bits.DcFree++; printf(" dcFree:"); switch (fsk.RegPktConfig1.bits.DcFree) { case 0: printf("none "); break; case 1: printf("Manchester "); break; case 2: printf("Whitening "); break; case 3: printf("[41mreserved[0m "); break; } radio.write_reg(REG_FSK_PACKETCONFIG1, fsk.RegPktConfig1.octet); printf("\r\n"); } void cmd_bt(uint8_t idx) { radio.RegOpMode.octet = radio.read_reg(REG_OPMODE); if (radio.RegOpMode.bits.ModulationType != 0) { printf("!fsk\r\n"); return; } if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { float bt; sscanf(pcbuf+idx, "%f", &bt); if (bt > 1.0) radio.RegOpMode.bits.ModulationShaping = 0; // 0 = no shaping else if (bt > 0.6) radio.RegOpMode.bits.ModulationShaping = 1; // 1 = BT1.0 else if (bt > 0.4) radio.RegOpMode.bits.ModulationShaping = 2; // 2 = BT0.5 else radio.RegOpMode.bits.ModulationShaping = 3; // 3 = BT0.3 } radio.write_reg(REG_OPMODE, radio.RegOpMode.octet); switch (radio.RegOpMode.bits.ModulationShaping) { case 0: printf("no-shaping "); break; case 1: printf("BT1.0 "); break; case 2: printf("BT0.5 "); break; case 3: printf("BT0.3 "); break; } printf("\r\n"); } void cmd_fsk_DataMode(uint8_t idx) { fsk.RegPktConfig2.word = radio.read_u16(REG_FSK_PACKETCONFIG2); fsk.RegPktConfig2.bits.DataModePacket ^= 1; radio.write_u16(REG_FSK_PACKETCONFIG2, fsk.RegPktConfig2.word); printf("datamode:"); if (fsk.RegPktConfig2.bits.DataModePacket) printf("packet\r\n"); else printf("continuous\r\n"); } void cmd_show_dio(uint8_t idx) { if (radio.RegOpMode.bits.LongRangeMode) lora_print_dio(); else fsk_print_dio(); } void cmd_set_dio(uint8_t idx) { switch (pcbuf[idx]) { case '0': radio.RegDioMapping1.bits.Dio0Mapping++; radio.write_reg(REG_DIOMAPPING1, radio.RegDioMapping1.octet); break; case '1': radio.RegDioMapping1.bits.Dio1Mapping++; radio.write_reg(REG_DIOMAPPING1, radio.RegDioMapping1.octet); break; case '2': radio.RegDioMapping1.bits.Dio2Mapping++; radio.write_reg(REG_DIOMAPPING1, radio.RegDioMapping1.octet); break; case '3': radio.RegDioMapping1.bits.Dio3Mapping++; radio.write_reg(REG_DIOMAPPING1, radio.RegDioMapping1.octet); break; case '4': radio.RegDioMapping2.bits.Dio4Mapping++; radio.write_reg(REG_DIOMAPPING2, radio.RegDioMapping2.octet); break; case '5': radio.RegDioMapping2.bits.Dio5Mapping++; radio.write_reg(REG_DIOMAPPING2, radio.RegDioMapping2.octet); break; } // ...switch (pcbuf[idx]) if (radio.RegOpMode.bits.LongRangeMode) lora_print_dio(); else fsk_print_dio(); } void cmd_mode_standby(uint8_t idx) { radio.set_opmode(RF_OPMODE_STANDBY); printf("standby\r\n"); } void cmd_mode_sleep(uint8_t idx) { radio.set_opmode(RF_OPMODE_SLEEP); printf("sleep\r\n"); } void cmd_mode_fstx(uint8_t idx) { radio.set_opmode(RF_OPMODE_SYNTHESIZER_TX); printf("fstx\r\n"); } void cmd_mode_fsrx(uint8_t idx) { radio.set_opmode(RF_OPMODE_SYNTHESIZER_RX); printf("fsrx\r\n"); } void cmd_chat(uint8_t idx) { app = APP_CHAT; lora.start_rx(RF_OPMODE_RECEIVER); printf("chat start\r\n"); } void cmd_OokThreshType(uint8_t idx) { fsk.RegOokPeak.octet = radio.read_reg(REG_FSK_OOKPEAK); if (fsk.RegOokPeak.bits.OokThreshType == 2) fsk.RegOokPeak.bits.OokThreshType = 0; else fsk.RegOokPeak.bits.OokThreshType++; radio.write_reg(REG_FSK_OOKPEAK, fsk.RegOokPeak.octet); printf("OokThreshType:"); switch (fsk.RegOokPeak.bits.OokThreshType) { case 0: printf("fixed"); break; case 1: printf("peak"); break; case 2: printf("average"); break; case 3: printf("?"); break; } printf("\r\n"); } void cmd_OokPeakTheshStep(uint8_t idx) { float f; fsk.RegOokPeak.octet = radio.read_reg(REG_FSK_OOKPEAK); if (fsk.RegOokPeak.bits.OokPeakThreshStep == 7) fsk.RegOokPeak.bits.OokPeakThreshStep = 0; else fsk.RegOokPeak.bits.OokPeakThreshStep++; radio.write_reg(REG_FSK_OOKPEAK, fsk.RegOokPeak.octet); switch (fsk.RegOokPeak.bits.OokPeakThreshStep) { case 0: f = 0.5; break; case 1: f = 1; break; case 2: f = 1.5; break; case 3: f = 2; break; case 4: f = 3; break; case 5: f = 4; break; case 6: f = 5; break; case 7: f = 6; break; } printf("OokPeakThreshStep:%.1fdB\r\n", f); } void cmd_OokFixedThresh(uint8_t idx) { int i; if (pcbuf[idx] >= '0' && pcbuf[idx] <= '9') { sscanf(pcbuf+idx, "%d", &i); radio.write_reg(REG_FSK_OOKFIX, i); } i = radio.read_reg(REG_FSK_OOKFIX); printf("OokFixedThreshold:%d\r\n", i); } void cmd_clkout(uint8_t idx) { RegOsc_t reg_osc; reg_osc.octet = radio.read_reg(REG_FSK_OSC); if (reg_osc.bits.ClkOut == 7) reg_osc.bits.ClkOut = 0; else reg_osc.bits.ClkOut++; printf("ClkOut:%d\r\n", reg_osc.bits.ClkOut); radio.write_reg(REG_FSK_OSC, reg_osc.octet); } void cmd_ook_tx_test(uint8_t idx) { radio.set_frf_MHz(915.0); radio.RegOpMode.octet = radio.read_reg(REG_OPMODE); if (radio.RegOpMode.bits.LongRangeMode) cmd_toggle_modem(0); fsk.RegPktConfig1.octet = radio.read_reg(REG_FSK_PACKETCONFIG1); fsk.RegPktConfig1.bits.CrcOn = 0; radio.write_reg(REG_FSK_PACKETCONFIG1, fsk.RegPktConfig1.octet); radio.RegDioMapping2.octet = radio.read_reg(REG_DIOMAPPING2); radio.RegDioMapping2.bits.Dio5Mapping = 2; // Data radio.write_reg(REG_DIOMAPPING2, radio.RegDioMapping2.octet); radio.RegDioMapping1.octet = radio.read_reg(REG_DIOMAPPING1); radio.RegDioMapping1.bits.Dio3Mapping = 1; // TxReady radio.write_reg(REG_DIOMAPPING1, radio.RegDioMapping1.octet); //radio.write_reg(REG_FSK_SYNCCONFIG, 0); cmd_ook(0); radio.write_reg(REG_FSK_SYNCCONFIG, 0); /* radio.write_u16(REG_FSK_PREAMBLEMSB, 4); // preamble length fsk.RegSyncConfig.octet = radio.read_reg(REG_FSK_SYNCCONFIG); fsk.RegSyncConfig.bits.SyncOn = 1; radio.write_reg(REG_FSK_SYNCCONFIG, fsk.RegSyncConfig.octet); // 0123456 sprintf(pcbuf, "syncw a9 66 69 65"); cmd_fsk_syncword(6);*/ tx_ticker.attach(&callback_ook_tx_test, tx_ticker_rate); } void cmd_help(uint8_t args_at); typedef enum { MODEM_BOTH, MODEM_FSK, MODEM_LORA } modem_e; typedef struct { modem_e modem; const char* const cmd; void (*handler)(uint8_t args_at); const char* const arg_descr; const char* const description; } menu_item_t; const menu_item_t menu_items[] = { /* after first character, command names must be [A-Za-z] */ { MODEM_BOTH, "chat", cmd_chat, "","start keyboard chat"}, { MODEM_BOTH, "rssi", cmd_read_current_rssi, "","(RX) read instantaneous RSSI"}, { MODEM_BOTH, "prssi", cmd_rssi_polling, "<%d>","dbm of rssi polling, 0 = off"}, { MODEM_BOTH, "txpd", cmd_per_tx_delay, "<%d>","get/set PER tx delay (in milliseconds)"}, { MODEM_BOTH, "pertx", cmd_pertx, "<%d pkt count>","start Eiger PER TX"}, { MODEM_BOTH, "perrx", cmd_perrx, "","start Eiger PER RX"}, { MODEM_BOTH, "pres", cmd_PreambleSize, "<%d>", "get/set PreambleSize"}, { MODEM_BOTH, "pllbw", cmd_pllbw, "", "increment pllbw"}, { MODEM_BOTH, "lnab", cmd_lna_boost, "", "(RX) increment LNA boost"}, { MODEM_BOTH, "stby", cmd_mode_standby, "", "set chip mode to standby"}, { MODEM_BOTH, "sleep", cmd_mode_sleep, "", "set chip mode to sleep"}, { MODEM_BOTH, "fstx", cmd_mode_fstx, "", "set chip mode to fstx"}, { MODEM_BOTH, "fsrx", cmd_mode_fsrx, "", "set chip mode to fsrx"}, { MODEM_BOTH, "crcon", cmd_crcOn, "","toggle crcOn"}, { MODEM_BOTH, "ethcrc", cmd_crc32, "","toggle enable software crc32"}, { MODEM_BOTH, "spif", cmd_spifreq, "<MHz>","change SPI clock frequency"}, { MODEM_BOTH, "payl", cmd_payload_length, "<%d>","get/set payload length"}, { MODEM_BOTH, "bgr", cmd_bgr, "<%d>","(TX) get/set reference for TX DAC"}, { MODEM_BOTH, "ocp", cmd_ocp, "<%d>","(TX) get/set milliamps current limit"}, { MODEM_BOTH, "frf", cmd_frf, "<MHz>","get/set RF center frequency"}, { MODEM_BOTH, "pas", cmd_paSelect, "","(TX) toggle RFO/PA_BOOST"}, { MODEM_BOTH, "pid", cmd_per_id, "<%d>","get/set ID number in Eiger PER packet"}, { MODEM_BOTH, "dio", cmd_show_dio, "","print dio mapping"}, { MODEM_FSK, "clkout", cmd_clkout, "","increment ClkOut divider"}, { MODEM_FSK, "ookt", cmd_OokThreshType, "","(RX) increment OokThreshType"}, { MODEM_FSK, "ooks", cmd_OokPeakTheshStep, "","(RX) increment OokPeakTheshStep"}, { MODEM_FSK, "sqlch", cmd_OokFixedThresh, "<%d>","(RX) get/set OokFixedThresh"}, { MODEM_FSK, "rssit", cmd_rssi_threshold, "<-dBm>","(RX) get/set rssi threshold"}, { MODEM_FSK, "rssis", cmd_rssi_smoothing, "<%d>","(RX) get/set rssi smoothing"}, { MODEM_FSK, "rssio", cmd_rssi_offset, "<%d>","(RX) get/set rssi offset"}, { MODEM_FSK, "mods", cmd_mod_shaping, "", "(TX) increment modulation shaping"}, { MODEM_FSK, "agcauto", cmd_fsk_agcauto, "", "(RX) toggle AgcAutoOn"}, { MODEM_FSK, "afcauto", cmd_fsk_afcauto, "", "(RX) toggle AfcAutoOn"}, { MODEM_FSK, "syncw", cmd_fsk_syncword, "<hex bytes>", "get/set syncword"}, { MODEM_FSK, "syncon", cmd_fsk_syncOn, "", "toggle SyncOn (frame sync, SFD enable)"}, { MODEM_FSK, "bitsync", cmd_fsk_bitsync, "", "toggle BitSyncOn (continuous mode only)"}, { MODEM_FSK, "fifot", cmd_fsk_TxStartCondition, "", "(TX) toggle TxStartCondition"}, { MODEM_FSK, "pktf", cmd_fsk_PacketFormat, "", "toggle PacketFormat fixed/variable length"}, { MODEM_FSK, "poll", cmd_poll_irq_en, "", "toggle poll_irq_en"}, { MODEM_FSK, "prep", cmd_fsk_PreamblePolarity, "", "toggle PreamblePolarity"}, { MODEM_FSK, "datam", cmd_fsk_DataMode, "", "toggle DataMode (packet/continuous)"}, { MODEM_FSK, "rxt", cmd_rx_trigger, "","(RX) increment RxTrigger"}, { MODEM_FSK, "ook", cmd_ook, "","enter OOK mode"}, { MODEM_FSK, "otx", cmd_ook_tx_test, "","start ook tx repeat"}, { MODEM_FSK, "fei", cmd_fsk_read_fei, "","(RX) read FEI"}, { MODEM_FSK, "fdev", cmd_fsk_fdev, "<kHz>","(TX) get/set fdev"}, { MODEM_FSK, "par", cmd_paRamp, "","(TX) increment paRamp"}, { MODEM_FSK, "pde", cmd_fsk_PreambleDetectorOn, "","(RX) toggle PreambleDetectorOn"}, { MODEM_FSK, "pds", cmd_fsk_PreambleDetectorSize, "<%d>","(RX) get/set PreambleDetectorSize"}, { MODEM_FSK, "pdt", cmd_fsk_PreambleDetectorTol, "<%d>","(RX) get/set PreambleDetectorTol"}, { MODEM_FSK, "thr", cmd_fsk_FifoThreshold, "<%d>","get/set FifoThreshold"}, { MODEM_FSK, "dcf", cmd_fsk_dcfree, "","(RX) increment DcFree"}, { MODEM_FSK, "br", cmd_fsk_bitrate, "<%f kbps>","get/set bitrate"}, { MODEM_FSK, "ac", cmd_AfcClear, "","(RX) AfcClear"}, { MODEM_FSK, "ar", cmd_fsk_AutoRestartRxMode, "","(RX) increment AutoRestartRxMode"}, { MODEM_FSK, "alc", cmd_fsk_AfcAutoClearOn, "","(RX) toggle AfcAutoClearOn"}, { MODEM_FSK, "mp", cmd_MapPreambleDetect, "","(RX) toggle MapPreambleDetect"}, { MODEM_FSK, "rrx", cmd_restart_rx, "","restart RX"}, { MODEM_BOTH, "op", cmd_op, "<dBm>","(TX) get/set TX power"}, { MODEM_FSK, "bt", cmd_bt, "","get/set BT"}, { MODEM_FSK, "ltx", cmd_long_tx, "<%d>","long tx"}, #ifdef LORA_TX_TEST { MODEM_LORA, "apl", cmd_lora_all_payload_lengths, "","(TXTEST) sweep payload lengths 0->255"}, { MODEM_LORA, "csn", cmd_lora_sync_sweep, "[12]","(TXTEST) sweep ppg symbol"}, { MODEM_LORA, "ss", cmd_lora_sync_lo_nibble, "","(TXTEST) ppg low nibble"}, { MODEM_LORA, "cpl", lora_cycle_payload_length, "[%d stop]","(TXTEST) sweep payload length"}, { MODEM_LORA, "ro", cmd_lora_data_ramp, "[%d bytes]","(TXTEST) sweep payload data"}, { MODEM_LORA, "ccr", cmd_lora_cycle_codingrates, "","(TXTEST) cycle coding rates"}, { MODEM_LORA, "fps", cmd_lora_fixed_payload_symbol, "[symbol_num n_bits]","(TXTEST) sweep symbol, n_bits=bits per symbol set (sf8=24, sf9=28, etc)"}, { MODEM_LORA, "fpo", cmd_fixed_payload_offset, "<nbytes>","(TXTEST) padding offset for fp tests"}, { MODEM_LORA, "fp", cmd_lora_fixed_payload, "[bytes]","(TXTEST) fixed payload"}, { MODEM_LORA, "tab", cmd_lora_toggle_all_bits, "[byte length]","(TXTEST) toggle all bits"}, { MODEM_LORA, "tcrc", cmd_lora_toggle_crcOn, "","(TXTEST) toggle crcOn"}, { MODEM_LORA, "thm", cmd_lora_toggle_header_mode, "","(TXTEST) toggle explicit/implicit"}, #endif /* LORA_TX_TEST */ { MODEM_BOTH, "ttr", cmd_tx_ticker_rate, "<%f seconds>","(TXTEST) get/set tx_ticker rate"}, { MODEM_LORA, "cadper", cmd_cadper, "","Eiger PER RX using CAD" }, { MODEM_LORA, "cad", cmd_cad, "<%d num tries>","(RX) run channel activity detection" }, { MODEM_LORA, "iqinv", cmd_lora_rx_invert, "","(RX) toggle RX IQ invert" }, { MODEM_LORA, "cin", cmd_lora_tx_invert, "","(TX) toggle TX IQ invert" }, { MODEM_LORA, "lhp", cmd_hop_period, "<%d>","(RX) get/set hop period"}, { MODEM_LORA, "sync", cmd_lora_ppg, "<%x>","get/set sync (post-preamble gap)"}, { MODEM_LORA, "cr", cmd_codingRate, "<1-4>","get/set codingRate"}, { MODEM_LORA, "lhm", cmd_lora_header_mode, "","toggle explicit/implicit"}, { MODEM_LORA, "vh", cmd_lora_poll_validHeader, "","toggle polling of validHeader"}, { MODEM_LORA, "sf", cmd_lora_sf, "<%d>","get/set spreadingFactor"}, { MODEM_LORA, "ldr", cmd_LowDataRateOptimize, "","toggle LowDataRateOptimize"}, { MODEM_LORA, "txc", cmd_lora_continuous_tx, "","(TX) toggle TxContinuousMode"}, { MODEM_BOTH, "tx", cmd_tx, "<%d>","transmit packet. optional payload length"}, { MODEM_BOTH, "bw", cmd_bandwidth, "<kHz>","get/set bandwith"}, { MODEM_LORA, "rxt", cmd_rx_timeout, "<%d>","(RX) get/set SymbTimeout"}, { MODEM_LORA, "rxs", cmd_rx_single, "","start RX_SINGLE"}, { MODEM_BOTH, "rx", cmd_rx, "","start RX"}, { MODEM_BOTH, "h", cmd_hw_reset, "","hardware reset"}, { MODEM_BOTH, "i", cmd_init, "","initialize radio driver"}, { MODEM_BOTH, "R", cmd_read_all_regs, "","read all radio registers"}, { MODEM_BOTH, "r", cmd_radio_reg_read, "[%x]","read single radio register"}, { MODEM_BOTH, "w", cmd_radio_reg_write, "[%x %x]","write single radio register"}, { MODEM_BOTH, "L", cmd_toggle_modem, "","toggle between LoRa / FSK"}, { MODEM_FSK, "E", cmd_empty_fifo, "","empty out FIFO"}, { MODEM_FSK, "c", cmd_fsk_test_case, "<%d>","get/set test cases"}, { MODEM_BOTH, "d", cmd_set_dio, "<%d pin num>","increment dio mapping"}, { MODEM_BOTH, ".", cmd_print_status, "","print status"}, { MODEM_BOTH, "?", cmd_help, "","this list of commands"}, { MODEM_BOTH, NULL, NULL, NULL, NULL } }; void cmd_help(uint8_t args_at) { int i; for (i = 0; menu_items[i].cmd != NULL ; i++) { if (menu_items[i].modem == MODEM_BOTH) printf("%s%s\t%s\r\n", menu_items[i].cmd, menu_items[i].arg_descr, menu_items[i].description); } if (radio.RegOpMode.bits.LongRangeMode) { for (i = 0; menu_items[i].cmd != NULL ; i++) { if (menu_items[i].modem == MODEM_LORA) printf("%s%s\t(LoRa) %s\r\n", menu_items[i].cmd, menu_items[i].arg_descr, menu_items[i].description); } } else { for (i = 0; menu_items[i].cmd != NULL ; i++) { if (menu_items[i].modem == MODEM_FSK) printf("%s%s\t(FSK) %s\r\n", menu_items[i].cmd, menu_items[i].arg_descr, menu_items[i].description); } } } void console() { int i; uint8_t user_cmd_len; if (poll_irq_en) poll_service_radio(); else service_radio(); if (pcbuf_len < 0) { printf("abort\r\n"); rx_payloadReady_int_en = false; cadper_enable = false; per_en = false; pcbuf_len = 0; if ((radio.RegOpMode.bits.Mode != RF_OPMODE_SLEEP) && (radio.RegOpMode.bits.Mode != RF_OPMODE_STANDBY)) { radio.set_opmode(RF_OPMODE_STANDBY); } on_txdone_state = ON_TXDONE_STATE_NONE; tx_ticker.detach(); return; } if (pcbuf_len == 0) return; printf("\r\n"); /* get end of user-entered command */ user_cmd_len = 1; // first character can be any character for (i = 1; i <= pcbuf_len; i++) { if (pcbuf[i] < 'A' || (pcbuf[i] > 'Z' && pcbuf[i] < 'a') || pcbuf[i] > 'z') { user_cmd_len = i; break; } } for (i = 0; menu_items[i].cmd != NULL ; i++) { int mi_len = strlen(menu_items[i].cmd); if (radio.RegOpMode.bits.LongRangeMode) { if (menu_items[i].modem == MODEM_FSK) continue; // FSK commands not used in LoRa } else { if (menu_items[i].modem == MODEM_LORA) continue; // LoRa commands not used in FSK } if (menu_items[i].handler && user_cmd_len == mi_len && (strncmp(pcbuf, menu_items[i].cmd, mi_len) == 0)) { while (pcbuf[mi_len] == ' ') // skip past spaces mi_len++; menu_items[i].handler(mi_len); break; } } pcbuf_len = 0; printf("> "); fflush(stdout); } void rx_callback() { static uint8_t pcbuf_idx = 0; static uint8_t prev_len = 0;; char c = pc.getc(); /*if (kermit.uart_rx_enabled) { kermit.rx_callback(c); } else*/ { if (c == 8) { if (pcbuf_idx > 0) { pc.putc(8); pc.putc(' '); pc.putc(8); pcbuf_idx--; } } else if (c == 3) { // ctrl-C pcbuf_len = -1; } else if (c == '\r') { if (pcbuf_idx == 0) { pcbuf_len = prev_len; } else { pcbuf[pcbuf_idx] = 0; // null terminate prev_len = pcbuf_idx; pcbuf_idx = 0; pcbuf_len = prev_len; } }/* else if (c == SOH) { kermit.uart_rx_enable(); }*/ else if (pcbuf_idx < sizeof(pcbuf)) { pcbuf[pcbuf_idx++] = c; pc.putc(c); } } } int main() { #if defined(TARGET_NUCLEO_L152RE) && defined(USE_DEBUGGER) DBGMCU_Config(DBGMCU_SLEEP, ENABLE); DBGMCU_Config(DBGMCU_STOP, ENABLE); DBGMCU_Config(DBGMCU_STANDBY, ENABLE); #endif pc.baud(57600); printf("\r\nmain()\r\n"); pc.attach(rx_callback); make_crc_table(); #if !defined(TARGET_MTS_MDOT_F411RE) && !defined(TYPE_ABZ) rfsw.input(); if (rfsw.read()) { shield_type = SHIELD_TYPE_LAS; printf("LAS\r\n"); } else { shield_type = SHIELD_TYPE_MAS; printf("MAS\r\n"); } rfsw.output(); #endif /* !TARGET_MTS_MDOT_F411RE */ radio.rf_switch.attach(rfsw_callback); #ifdef FSK_PER fsk.enable(false); fsk.RegSyncConfig.octet = radio.read_reg(REG_FSK_SYNCCONFIG); fsk.RegSyncConfig.bits.SyncSize = 2; radio.write_reg(REG_FSK_SYNCCONFIG, fsk.RegSyncConfig.octet); radio.write_reg(REG_FSK_SYNCVALUE3, 0x90); radio.write_reg(REG_FSK_SYNCVALUE2, 0x4e); radio.write_reg(REG_FSK_SYNCVALUE1, 0x63); fsk.RegPreambleDetect.bits.PreambleDetectorOn = 1; fsk.RegPreambleDetect.bits.PreambleDetectorSize = 1; fsk.RegPreambleDetect.bits.PreambleDetectorTol = 10; radio.write_reg(REG_FSK_PREAMBLEDETECT, fsk.RegPreambleDetect.octet); fsk.RegRxConfig.octet = radio.read_reg(REG_FSK_RXCONFIG); fsk.RegRxConfig.bits.AfcAutoOn = 1; fsk.RegRxConfig.bits.AgcAutoOn = 1; fsk.RegRxConfig.bits.RxTrigger = 7; radio.write_reg(REG_FSK_RXCONFIG, fsk.RegRxConfig.octet); radio.set_opmode(RF_OPMODE_STANDBY); fsk.set_rx_dcc_bw_hz(41666, 1); // afcbw fsk.set_rx_dcc_bw_hz(20833, 0); // rxbw fsk.set_tx_fdev_hz(10000); radio.write_u16(REG_FSK_PREAMBLEMSB, 8); fsk.RegPktConfig2.bits.PayloadLength = 64; radio.write_u16(REG_FSK_PACKETCONFIG2, fsk.RegPktConfig2.word); radio.RegDioMapping2.octet = radio.read_reg(REG_DIOMAPPING2); radio.RegDioMapping2.bits.Dio5Mapping = 2; // data output to observation radio.RegDioMapping2.bits.Dio4Mapping = 3; // output preamble detect indication radio.RegDioMapping2.bits.MapPreambleDetect = 1; radio.write_reg(REG_DIOMAPPING2, radio.RegDioMapping2.octet); RegPreambleDetect.bits.PreambleDetectorOn = 1; RegPreambleDetect.bits.PreambleDetectorSize = 1; RegPreambleDetect.bits.PreambleDetectorTol = 10; write_reg(REG_FSK_PREAMBLEDETECT, RegPreambleDetect.octet); #endif /* FSK_PER */ #ifdef START_EIGER_TX uint8_t addr; radio.set_frf_MHz(915.0); radio.RegOcp.octet = radio.read_reg(REG_OCP); radio.RegOcp.bits.OcpTrim = 20; radio.write_reg(REG_OCP, radio.RegOcp.octet); RegPdsTrim1_t pds_trim; if (radio.type == SX1276) addr = REG_PDSTRIM1_SX1276; else addr = REG_PDSTRIM1_SX1272; pds_trim.octet = radio.read_reg(addr); pds_trim.bits.prog_txdac = 7; radio.write_reg(addr, pds_trim.octet); #ifndef FSK_PER lora.enable(); lora.setSf(10); if (radio.type == SX1276) lora.setBw(7); // 7 == 125khz #endif toggle_per_en(); PacketTxCnt = 0; per_timeout.attach(&per_cb, per_tx_delay); #endif /* START_EIGER_TX */ #ifdef START_EIGER_RX radio.set_frf_MHz(915.0); radio.RegPaConfig.bits.PaSelect = 1; // 0: use RFO for sx1276 shield, 1==PA_BOOST radio.write_reg(REG_PACONFIG, radio.RegPaConfig.octet); toggle_per_en(); PacketNormalCnt = 0; PacketRxSequencePrev = 0; PacketPerKoCnt = 0; PacketPerOkCnt = 0; #ifndef FSK_PER lora.enable(); lora.setSf(10); if (radio.type == SX1276) lora.setBw(7); // 7 == 125khz lora.start_rx(); #else fsk.start_rx(); radio.RegDioMapping1.bits.Dio2Mapping = 3; // dio2 to syncadrs radio.write_reg(REG_DIOMAPPING1, radio.RegDioMapping1.octet); if (radio.HF) { fsk.RegRssiConfig.octet = radio.read_reg(REG_FSK_RSSICONFIG); fsk.RegRssiConfig.bits.RssiOffset = FSK_RSSI_OFFSET; fsk.RegRssiConfig.bits.RssiSmoothing = FSK_RSSI_SMOOTHING; radio.write_reg(REG_FSK_RSSICONFIG, fsk.RegRssiConfig.octet); } #endif if (radio.HF) { radio.RegLna.bits.LnaBoostHF = 3; radio.write_reg(REG_LNA, radio.RegLna.octet); } #endif /* START_EIGER_RX */ (void)radio.get_frf_MHz(); radio.RegPaConfig.octet = radio.read_reg(REG_PACONFIG); #if defined(TARGET_MTS_MDOT_F411RE) || defined(TYPE_ABZ) radio.RegPaConfig.bits.PaSelect = 1; // mDot uses PA_BOOST #else if (shield_type == SHIELD_TYPE_LAS) { // LAS HF=PA_BOOST LF=RFO if (radio.HF) radio.RegPaConfig.bits.PaSelect = 1; else radio.RegPaConfig.bits.PaSelect = 0; } else if (shield_type == SHIELD_TYPE_MAS) { // MAS HF=RFO LF=RFO radio.RegPaConfig.bits.PaSelect = 0; } #endif radio.RegPaConfig.bits.OutputPower = 15; radio.write_reg(REG_PACONFIG, radio.RegPaConfig.octet); #ifdef START_OOK_TX_TEST cmd_ook_tx_test(0); #endif /* START_OOK_TX_TEST */ while(1) { switch (app) { case APP_NONE: console(); break; case APP_CHAT: console_chat(); break; } // ...switch (app) #if TARGET_NUCLEO_L152RE //sleep(); #endif } // ...while(1) }