V148
Fork of RadioHead-148 by
RH_RF95.h
- Committer:
- davidr99
- Date:
- 2015-10-15
- Revision:
- 0:ab4e012489ef
File content as of revision 0:ab4e012489ef:
// RH_RF95.h // // Definitions for HopeRF LoRa radios per: // http://www.hoperf.com/upload/rf/RFM95_96_97_98W.pdf // http://www.hoperf.cn/upload/rfchip/RF96_97_98.pdf // // Author: Mike McCauley (mikem@airspayce.com) // Copyright (C) 2014 Mike McCauley // $Id: RH_RF95.h,v 1.7 2015/05/17 00:11:26 mikem Exp $ // #ifndef RH_RF95_h #define RH_RF95_h #include <RHSPIDriver.h> // This is the maximum number of interrupts the driver can support // Most Arduinos can handle 2, Megas can handle more #define RH_RF95_NUM_INTERRUPTS 3 // Max number of octets the LORA Rx/Tx FIFO can hold #define RH_RF95_FIFO_SIZE 255 // This is the maximum number of bytes that can be carried by the LORA. // We use some for headers, keeping fewer for RadioHead messages #define RH_RF95_MAX_PAYLOAD_LEN RH_RF95_FIFO_SIZE // The length of the headers we add. // The headers are inside the LORA's payload #define RH_RF95_HEADER_LEN 4 // This is the maximum message length that can be supported by this driver. // Can be pre-defined to a smaller size (to save SRAM) prior to including this header // Here we allow for 1 byte message length, 4 bytes headers, user data and 2 bytes of FCS #ifndef RH_RF95_MAX_MESSAGE_LEN #define RH_RF95_MAX_MESSAGE_LEN (RH_RF95_MAX_PAYLOAD_LEN - RH_RF95_HEADER_LEN) #endif // The crystal oscillator frequency of the module #define RH_RF95_FXOSC 32000000.0 // The Frequency Synthesizer step = RH_RF95_FXOSC / 2^^19 #define RH_RF95_FSTEP (RH_RF95_FXOSC / 524288) // Register names (LoRa Mode, from table 85) #define RH_RF95_REG_00_FIFO 0x00 #define RH_RF95_REG_01_OP_MODE 0x01 #define RH_RF95_REG_02_RESERVED 0x02 #define RH_RF95_REG_03_RESERVED 0x03 #define RH_RF95_REG_04_RESERVED 0x04 #define RH_RF95_REG_05_RESERVED 0x05 #define RH_RF95_REG_06_FRF_MSB 0x06 #define RH_RF95_REG_07_FRF_MID 0x07 #define RH_RF95_REG_08_FRF_LSB 0x08 #define RH_RF95_REG_09_PA_CONFIG 0x09 #define RH_RF95_REG_0A_PA_RAMP 0x0a #define RH_RF95_REG_0B_OCP 0x0b #define RH_RF95_REG_0C_LNA 0x0c #define RH_RF95_REG_0D_FIFO_ADDR_PTR 0x0d #define RH_RF95_REG_0E_FIFO_TX_BASE_ADDR 0x0e #define RH_RF95_REG_0F_FIFO_RX_BASE_ADDR 0x0f #define RH_RF95_REG_10_FIFO_RX_CURRENT_ADDR 0x10 #define RH_RF95_REG_11_IRQ_FLAGS_MASK 0x11 #define RH_RF95_REG_12_IRQ_FLAGS 0x12 #define RH_RF95_REG_13_RX_NB_BYTES 0x13 #define RH_RF95_REG_14_RX_HEADER_CNT_VALUE_MSB 0x14 #define RH_RF95_REG_15_RX_HEADER_CNT_VALUE_LSB 0x15 #define RH_RF95_REG_16_RX_PACKET_CNT_VALUE_MSB 0x16 #define RH_RF95_REG_17_RX_PACKET_CNT_VALUE_LSB 0x17 #define RH_RF95_REG_18_MODEM_STAT 0x18 #define RH_RF95_REG_19_PKT_SNR_VALUE 0x19 #define RH_RF95_REG_1A_PKT_RSSI_VALUE 0x1a #define RH_RF95_REG_1B_RSSI_VALUE 0x1b #define RH_RF95_REG_1C_HOP_CHANNEL 0x1c #define RH_RF95_REG_1D_MODEM_CONFIG1 0x1d #define RH_RF95_REG_1E_MODEM_CONFIG2 0x1e #define RH_RF95_REG_1F_SYMB_TIMEOUT_LSB 0x1f #define RH_RF95_REG_20_PREAMBLE_MSB 0x20 #define RH_RF95_REG_21_PREAMBLE_LSB 0x21 #define RH_RF95_REG_22_PAYLOAD_LENGTH 0x22 #define RH_RF95_REG_23_MAX_PAYLOAD_LENGTH 0x23 #define RH_RF95_REG_24_HOP_PERIOD 0x24 #define RH_RF95_REG_25_FIFO_RX_BYTE_ADDR 0x25 #define RH_RF95_REG_26_MODEM_CONFIG3 0x26 #define RH_RF95_REG_40_DIO_MAPPING1 0x40 #define RH_RF95_REG_41_DIO_MAPPING2 0x41 #define RH_RF95_REG_42_VERSION 0x42 #define RH_RF95_REG_4B_TCXO 0x4b #define RH_RF95_REG_4D_PA_DAC 0x4d #define RH_RF95_REG_5B_FORMER_TEMP 0x5b #define RH_RF95_REG_61_AGC_REF 0x61 #define RH_RF95_REG_62_AGC_THRESH1 0x62 #define RH_RF95_REG_63_AGC_THRESH2 0x63 #define RH_RF95_REG_64_AGC_THRESH3 0x64 // RH_RF95_REG_01_OP_MODE 0x01 #define RH_RF95_LONG_RANGE_MODE 0x80 #define RH_RF95_ACCESS_SHARED_REG 0x40 #define RH_RF95_MODE 0x07 #define RH_RF95_MODE_SLEEP 0x00 #define RH_RF95_MODE_STDBY 0x01 #define RH_RF95_MODE_FSTX 0x02 #define RH_RF95_MODE_TX 0x03 #define RH_RF95_MODE_FSRX 0x04 #define RH_RF95_MODE_RXCONTINUOUS 0x05 #define RH_RF95_MODE_RXSINGLE 0x06 #define RH_RF95_MODE_CAD 0x07 // RH_RF95_REG_09_PA_CONFIG 0x09 #define RH_RF95_PA_SELECT 0x80 #define RH_RF95_OUTPUT_POWER 0x0f // RH_RF95_REG_0A_PA_RAMP 0x0a #define RH_RF95_LOW_PN_TX_PLL_OFF 0x10 #define RH_RF95_PA_RAMP 0x0f #define RH_RF95_PA_RAMP_3_4MS 0x00 #define RH_RF95_PA_RAMP_2MS 0x01 #define RH_RF95_PA_RAMP_1MS 0x02 #define RH_RF95_PA_RAMP_500US 0x03 #define RH_RF95_PA_RAMP_250US 0x0 #define RH_RF95_PA_RAMP_125US 0x05 #define RH_RF95_PA_RAMP_100US 0x06 #define RH_RF95_PA_RAMP_62US 0x07 #define RH_RF95_PA_RAMP_50US 0x08 #define RH_RF95_PA_RAMP_40US 0x09 #define RH_RF95_PA_RAMP_31US 0x0a #define RH_RF95_PA_RAMP_25US 0x0b #define RH_RF95_PA_RAMP_20US 0x0c #define RH_RF95_PA_RAMP_15US 0x0d #define RH_RF95_PA_RAMP_12US 0x0e #define RH_RF95_PA_RAMP_10US 0x0f // RH_RF95_REG_0B_OCP 0x0b #define RH_RF95_OCP_ON 0x20 #define RH_RF95_OCP_TRIM 0x1f // RH_RF95_REG_0C_LNA 0x0c #define RH_RF95_LNA_GAIN 0xe0 #define RH_RF95_LNA_BOOST 0x03 #define RH_RF95_LNA_BOOST_DEFAULT 0x00 #define RH_RF95_LNA_BOOST_150PC 0x11 // RH_RF95_REG_11_IRQ_FLAGS_MASK 0x11 #define RH_RF95_RX_TIMEOUT_MASK 0x80 #define RH_RF95_RX_DONE_MASK 0x40 #define RH_RF95_PAYLOAD_CRC_ERROR_MASK 0x20 #define RH_RF95_VALID_HEADER_MASK 0x10 #define RH_RF95_TX_DONE_MASK 0x08 #define RH_RF95_CAD_DONE_MASK 0x04 #define RH_RF95_FHSS_CHANGE_CHANNEL_MASK 0x02 #define RH_RF95_CAD_DETECTED_MASK 0x01 // RH_RF95_REG_12_IRQ_FLAGS 0x12 #define RH_RF95_RX_TIMEOUT 0x80 #define RH_RF95_RX_DONE 0x40 #define RH_RF95_PAYLOAD_CRC_ERROR 0x20 #define RH_RF95_VALID_HEADER 0x10 #define RH_RF95_TX_DONE 0x08 #define RH_RF95_CAD_DONE 0x04 #define RH_RF95_FHSS_CHANGE_CHANNEL 0x02 #define RH_RF95_CAD_DETECTED 0x01 // RH_RF95_REG_18_MODEM_STAT 0x18 #define RH_RF95_RX_CODING_RATE 0xe0 #define RH_RF95_MODEM_STATUS_CLEAR 0x10 #define RH_RF95_MODEM_STATUS_HEADER_INFO_VALID 0x08 #define RH_RF95_MODEM_STATUS_RX_ONGOING 0x04 #define RH_RF95_MODEM_STATUS_SIGNAL_SYNCHRONIZED 0x02 #define RH_RF95_MODEM_STATUS_SIGNAL_DETECTED 0x01 // RH_RF95_REG_1C_HOP_CHANNEL 0x1c #define RH_RF95_PLL_TIMEOUT 0x80 #define RH_RF95_RX_PAYLOAD_CRC_IS_ON 0x40 #define RH_RF95_FHSS_PRESENT_CHANNEL 0x3f // RH_RF95_REG_1D_MODEM_CONFIG1 0x1d #define RH_RF95_BW 0xc0 #define RH_RF95_BW_125KHZ 0x00 #define RH_RF95_BW_250KHZ 0x40 #define RH_RF95_BW_500KHZ 0x80 #define RH_RF95_BW_RESERVED 0xc0 #define RH_RF95_CODING_RATE 0x38 #define RH_RF95_CODING_RATE_4_5 0x00 #define RH_RF95_CODING_RATE_4_6 0x08 #define RH_RF95_CODING_RATE_4_7 0x10 #define RH_RF95_CODING_RATE_4_8 0x18 #define RH_RF95_IMPLICIT_HEADER_MODE_ON 0x04 #define RH_RF95_RX_PAYLOAD_CRC_ON 0x02 #define RH_RF95_LOW_DATA_RATE_OPTIMIZE 0x01 // RH_RF95_REG_1E_MODEM_CONFIG2 0x1e #define RH_RF95_SPREADING_FACTOR 0xf0 #define RH_RF95_SPREADING_FACTOR_64CPS 0x60 #define RH_RF95_SPREADING_FACTOR_128CPS 0x70 #define RH_RF95_SPREADING_FACTOR_256CPS 0x80 #define RH_RF95_SPREADING_FACTOR_512CPS 0x90 #define RH_RF95_SPREADING_FACTOR_1024CPS 0xa0 #define RH_RF95_SPREADING_FACTOR_2048CPS 0xb0 #define RH_RF95_SPREADING_FACTOR_4096CPS 0xc0 #define RH_RF95_TX_CONTINUOUS_MOE 0x08 #define RH_RF95_AGC_AUTO_ON 0x04 #define RH_RF95_SYM_TIMEOUT_MSB 0x03 // RH_RF95_REG_4D_PA_DAC 0x4d #define RH_RF95_PA_DAC_DISABLE 0x04 #define RH_RF95_PA_DAC_ENABLE 0x07 ///////////////////////////////////////////////////////////////////// /// \class RH_RF95 RH_RF95.h <RH_RF95.h> /// \brief Driver to send and receive unaddressed, unreliable datagrams via a LoRa /// capable radio transceiver. /// /// For Semtech SX1276/77/78 and HopeRF RFM95/96/97/98 and other similar LoRa capable radios. /// Based on http://www.hoperf.com/upload/rf/RFM95_96_97_98W.pdf /// and http://www.hoperf.cn/upload/rfchip/RF96_97_98.pdf /// and http://www.semtech.com/images/datasheet/LoraDesignGuide_STD.pdf /// and http://www.semtech.com/images/datasheet/sx1276.pdf /// FSK/GFSK/OOK modes are not (yet) supported. /// /// Works with /// - the excellent MiniWirelessLoRa from Anarduino http://www.anarduino.com/miniwireless /// /// \par Overview /// /// This class provides basic functions for sending and receiving unaddressed, /// unreliable datagrams of arbitrary length to 251 octets per packet. /// /// Manager classes may use this class to implement reliable, addressed datagrams and streams, /// mesh routers, repeaters, translators etc. /// /// Naturally, for any 2 radios to communicate that must be configured to use the same frequency and /// modulation scheme. /// /// This Driver provides an object-oriented interface for sending and receiving data messages with Hope-RF /// RFM95/96/97/98(W) and compatible radio modules in LoRa mode. /// /// The Hope-RF (http://www.hoperf.com) RFM95/96/97/98(W) is a low-cost ISM transceiver /// chip. It supports FSK, GFSK, OOK over a wide range of frequencies and /// programmable data rates, and it also supports the proprietary LoRA (Long Range) mode, which /// is the only mode supported in this RadioHead driver. /// /// This Driver provides functions for sending and receiving messages of up /// to 251 octets on any frequency supported by the radio, in a range of /// predefined Bandwidths, Spreading Factors and Coding Rates. Frequency can be set with /// 61Hz precision to any frequency from 240.0MHz to 960.0MHz. Caution: most modules only support a more limited /// range of frequencies due to antenna tuning. /// /// Up to 2 RFM95/96/97/98(W) modules can be connected to an Arduino (3 on a Mega), /// permitting the construction of translators and frequency changers, etc. /// /// Support for other features such as transmitter power control etc is /// also provided. /// /// Tested on MinWirelessLoRa with arduino-1.0.5 /// on OpenSuSE 13.1 /// /// \par Packet Format /// /// All messages sent and received by this RH_RF95 Driver conform to this packet format: /// /// - LoRa mode: /// - 8 symbol PREAMBLE /// - Explicit header with header CRC (handled internally by the radio) /// - 4 octets HEADER: (TO, FROM, ID, FLAGS) /// - 0 to 251 octets DATA /// - CRC (handled internally by the radio) /// /// \par Connecting RFM95/96/97/98 to Arduino /// /// We tested with Anarduino MiniWirelessLoRA, which is an Arduino Duemilanove compatible with a RFM96W /// module on-board. Therefore it needs no connections other than the USB /// programming connection and an antenna to make it work. /// /// If you have a bare RFM95/96/97/98 that you want to connect to an Arduino, you /// might use these connections (untested): CAUTION: you must use a 3.3V type /// Arduino, otherwise you will also need voltage level shifters between the /// Arduino and the RFM95. CAUTION, you must also ensure you connect an /// antenna. /// /// \code /// Arduino RFM95/96/97/98 /// GND----------GND (ground in) /// 3V3----------3.3V (3.3V in) /// interrupt 0 pin D2-----------DIO0 (interrupt request out) /// SS pin D10----------NSS (chip select in) /// SCK pin D13----------SCK (SPI clock in) /// MOSI pin D11----------MOSI (SPI Data in) /// MISO pin D12----------MISO (SPI Data out) /// \endcode /// /// With these connections, you can then use the default constructor RH_RF95(). /// You can override the default settings for the SS pin and the interrupt in /// the RH_RF95 constructor if you wish to connect the slave select SS to other /// than the normal one for your Arduino (D10 for Diecimila, Uno etc and D53 /// for Mega) or the interrupt request to other than pin D2 (Caution, /// different processors have different constraints as to the pins available /// for interrupts). /// /// It is possible to have 2 or more radios connected to one Arduino, provided /// each radio has its own SS and interrupt line (SCK, SDI and SDO are common /// to all radios) /// /// Caution: on some Arduinos such as the Mega 2560, if you set the slave /// select pin to be other than the usual SS pin (D53 on Mega 2560), you may /// need to set the usual SS pin to be an output to force the Arduino into SPI /// master mode. /// /// Caution: Power supply requirements of the RFM module may be relevant in some circumstances: /// RFM95/96/97/98 modules are capable of pulling 120mA+ at full power, where Arduino's 3.3V line can /// give 50mA. You may need to make provision for alternate power supply for /// the RFM module, especially if you wish to use full transmit power, and/or you have /// other shields demanding power. Inadequate power for the RFM is likely to cause symptoms such as: /// - reset's/bootups terminate with "init failed" messages /// - random termination of communication after 5-30 packets sent/received /// - "fake ok" state, where initialization passes fluently, but communication doesn't happen /// - shields hang Arduino boards, especially during the flashing /// /// \par Interrupts /// /// The RH_RF95 driver uses interrupts to react to events in the RFM module, /// such as the reception of a new packet, or the completion of transmission /// of a packet. The RH_RF95 driver interrupt service routine reads status from /// and writes data to the the RFM module via the SPI interface. It is very /// important therefore, that if you are using the RH_RF95 driver with another /// SPI based deviced, that you disable interrupts while you transfer data to /// and from that other device. Use cli() to disable interrupts and sei() to /// reenable them. /// /// \par Memory /// /// The RH_RF95 driver requires non-trivial amounts of memory. The sample /// programs all compile to about 8kbytes each, which will fit in the /// flash proram memory of most Arduinos. However, the RAM requirements are /// more critical. Therefore, you should be vary sparing with RAM use in /// programs that use the RH_RF95 driver. /// /// It is often hard to accurately identify when you are hitting RAM limits on Arduino. /// The symptoms can include: /// - Mysterious crashes and restarts /// - Changes in behaviour when seemingly unrelated changes are made (such as adding print() statements) /// - Hanging /// - Output from Serial.print() not appearing /// /// \par Range /// /// We have made some simple range tests under the following conditions: /// - rf95_client base station connected to a VHF discone antenna at 8m height above ground /// - rf95_server mobile connected to 17.3cm 1/4 wavelength antenna at 1m height, no ground plane. /// - Both configured for 13dBm, 434MHz, Bw = 125 kHz, Cr = 4/8, Sf = 4096chips/symbol, CRC on. Slow+long range /// - Minimum reported RSSI seen for successful comms was about -91 /// - Range over flat ground through heavy trees and vegetation approx 2km. /// - At 20dBm (100mW) otherwise identical conditions approx 3km. /// - At 20dBm, along salt water flat sandy beach, 3.2km. /// /// It should be noted that at this data rate, a 12 octet message takes 2 seconds to transmit. /// /// At 20dBm (100mW) with Bw = 125 kHz, Cr = 4/5, Sf = 128chips/symbol, CRC on. /// (Default medium range) in the conditions described above. /// - Range over flat ground through heavy trees and vegetation approx 2km. /// /// \par Transmitter Power /// /// You can control the transmitter power on the RF transceiver /// with the RH_RF95::setTxPower() function. The argument can be any of /// +5 to +23 /// The default is 13. Eg: /// \code /// driver.setTxPower(10); /// \endcode /// /// We have made some actual power measurements against /// programmed power for Anarduino MiniWirelessLoRa (which has RFM96W-433Mhz installed) /// - MiniWirelessLoRa RFM96W-433Mhz, USB power /// - 30cm RG316 soldered direct to RFM96W module ANT and GND /// - SMA connector /// - 12db attenuator /// - SMA connector /// - MiniKits AD8307 HF/VHF Power Head (calibrated against Rohde&Schwartz 806.2020 test set) /// - Tektronix TDS220 scope to measure the Vout from power head /// \code /// Program power Measured Power /// dBm dBm /// 5 5 /// 7 7 /// 9 8 /// 11 11 /// 13 13 /// 15 15 /// 17 16 /// 19 18 /// 20 20 /// 21 21 /// 22 22 /// 23 23 /// \endcode /// (Caution: we dont claim laboratory accuracy for these measurements) /// You would not expect to get anywhere near these powers to air with a simple 1/4 wavelength wire antenna. class RH_RF95 : public RHSPIDriver { public: /// \brief Defines register values for a set of modem configuration registers /// /// Defines register values for a set of modem configuration registers /// that can be passed to setModemRegisters() if none of the choices in /// ModemConfigChoice suit your need setModemRegisters() writes the /// register values from this structure to the appropriate registers /// to set the desired spreading factor, coding rate and bandwidth typedef struct { uint8_t reg_1d; ///< Value for register RH_RF95_REG_1D_MODEM_CONFIG1 uint8_t reg_1e; ///< Value for register RH_RF95_REG_1E_MODEM_CONFIG2 uint8_t reg_26; ///< Value for register RH_RF95_REG_26_MODEM_CONFIG3 } ModemConfig; /// Choices for setModemConfig() for a selected subset of common /// data rates. If you need another configuration, /// determine the necessary settings and call setModemRegisters() with your /// desired settings. It might be helpful to use the LoRa calculator mentioned in /// http://www.semtech.com/images/datasheet/LoraDesignGuide_STD.pdf /// These are indexes into MODEM_CONFIG_TABLE. We strongly recommend you use these symbolic /// definitions and not their integer equivalents: its possible that new values will be /// introduced in later versions (though we will try to avoid it). typedef enum { Bw125Cr45Sf128 = 0, ///< Bw = 125 kHz, Cr = 4/5, Sf = 128chips/symbol, CRC on. Default medium range Bw500Cr45Sf128, ///< Bw = 500 kHz, Cr = 4/5, Sf = 128chips/symbol, CRC on. Fast+short range Bw31_25Cr48Sf512, ///< Bw = 31.25 kHz, Cr = 4/8, Sf = 512chips/symbol, CRC on. Slow+long range Bw125Cr48Sf4096, ///< Bw = 125 kHz, Cr = 4/8, Sf = 4096chips/symbol, CRC on. Slow+long range } ModemConfigChoice; /// Constructor. You can have multiple instances, but each instance must have its own /// interrupt and slave select pin. After constructing, you must call init() to initialise the interface /// and the radio module. A maximum of 3 instances can co-exist on one processor, provided there are sufficient /// distinct interrupt lines, one for each instance. /// \param[in] slaveSelectPin the Arduino pin number of the output to use to select the RH_RF22 before /// accessing it. Defaults to the normal SS pin for your Arduino (D10 for Diecimila, Uno etc, D53 for Mega, D10 for Maple) /// \param[in] interruptPin The interrupt Pin number that is connected to the RFM DIO0 interrupt line. /// Defaults to pin 2, as required by Anarduino MinWirelessLoRa module. /// Caution: You must specify an interrupt capable pin. /// On many Arduino boards, there are limitations as to which pins may be used as interrupts. /// On Leonardo pins 0, 1, 2 or 3. On Mega2560 pins 2, 3, 18, 19, 20, 21. On Due and Teensy, any digital pin. /// On other Arduinos pins 2 or 3. /// See http://arduino.cc/en/Reference/attachInterrupt for more details. /// On Chipkit Uno32, pins 38, 2, 7, 8, 35. /// On other boards, any digital pin may be used. /// \param[in] spi Pointer to the SPI interface object to use. /// Defaults to the standard Arduino hardware SPI interface RH_RF95(PINS slaveSelectPin, PINS interruptPin, RHGenericSPI& spi = hardware_spi); /// Initialise the Driver transport hardware and software. /// Make sure the Driver is properly configured before calling init(). /// \return true if initialisation succeeded. virtual bool init(); /// Prints the value of all chip registers /// to the Serial device if RH_HAVE_SERIAL is defined for the current platform /// For debugging purposes only. /// \return true on success bool printRegisters(); /// Sets all the registered required to configure the data modem in the RF95/96/97/98, including the bandwidth, /// spreading factor etc. You can use this to configure the modem with custom configurations if none of the /// canned configurations in ModemConfigChoice suit you. /// \param[in] config A ModemConfig structure containing values for the modem configuration registers. void setModemRegisters(const ModemConfig* config); /// Select one of the predefined modem configurations. If you need a modem configuration not provided /// here, use setModemRegisters() with your own ModemConfig. /// \param[in] index The configuration choice. /// \return true if index is a valid choice. bool setModemConfig(ModemConfigChoice index); /// Tests whether a new message is available /// from the Driver. /// On most drivers, this will also put the Driver into RHModeRx mode until /// a message is actually received by the transport, when it wil be returned to RHModeIdle. /// This can be called multiple times in a timeout loop /// \return true if a new, complete, error-free uncollected message is available to be retreived by recv() virtual bool available(); /// Turns the receiver on if it not already on. /// If there is a valid message available, copy it to buf and return true /// else return false. /// If a message is copied, *len is set to the length (Caution, 0 length messages are permitted). /// You should be sure to call this function frequently enough to not miss any messages /// It is recommended that you call it in your main loop. /// \param[in] buf Location to copy the received message /// \param[in,out] len Pointer to available space in buf. Set to the actual number of octets copied. /// \return true if a valid message was copied to buf virtual bool recv(uint8_t* buf, uint8_t* len); /// Waits until any previous transmit packet is finished being transmitted with waitPacketSent(). /// Then loads a message into the transmitter and starts the transmitter. Note that a message length /// of 0 is permitted. /// \param[in] data Array of data to be sent /// \param[in] len Number of bytes of data to send /// \return true if the message length was valid and it was correctly queued for transmit virtual bool send(const uint8_t* data, uint8_t len); /// Sets the length of the preamble /// in bytes. /// Caution: this should be set to the same /// value on all nodes in your network. Default is 8. /// Sets the message preamble length in RH_RF95_REG_??_PREAMBLE_?SB /// \param[in] bytes Preamble length in bytes. void setPreambleLength(uint16_t bytes); /// Returns the maximum message length /// available in this Driver. /// \return The maximum legal message length virtual uint8_t maxMessageLength(); /// Sets the transmitter and receiver /// centre frequency /// \param[in] centre Frequency in MHz. 137.0 to 1020.0. Caution: RFM95/96/97/98 comes in several /// different frequency ranges, and setting a frequency outside that range of your radio will probably not work /// \return true if the selected frquency centre is within range bool setFrequency(float centre); /// If current mode is Rx or Tx changes it to Idle. If the transmitter or receiver is running, /// disables them. void setModeIdle(); /// If current mode is Tx or Idle, changes it to Rx. /// Starts the receiver in the RF95/96/97/98. void setModeRx(); /// If current mode is Rx or Idle, changes it to Rx. F /// Starts the transmitter in the RF95/96/97/98. void setModeTx(); /// Sets the transmitter power output level. /// Be a good neighbour and set the lowest power level you need. /// Caution: legal power limits may apply in certain countries. At powers above 20dBm, PA_DAC is enabled. /// After init(), the power will be set to 13dBm. /// \param[in] power Transmitter power level in dBm. For RFM95/96/97/98 LORA, valid values are from +5 to +23 void setTxPower(int8_t power); /// Sets the radio into low-power sleep mode. /// If successful, the transport will stay in sleep mode until woken by /// changing mode it idle, transmit or receive (eg by calling send(), recv(), available() etc) /// Caution: there is a time penalty as the radio takes a finite time to wake from sleep mode. /// \return true if sleep mode was successfully entered. virtual bool sleep(); protected: /// This is a low level function to handle the interrupts for one instance of RH_RF95. /// Called automatically by isr*() /// Should not need to be called by user code. void handleInterrupt(); /// Examine the revceive buffer to determine whether the message is for this node void validateRxBuf(); /// Clear our local receive buffer void clearRxBuf(); private: /// Low level interrupt service routine for device connected to interrupt 0 static void isr0(); /// Low level interrupt service routine for device connected to interrupt 1 static void isr1(); /// Low level interrupt service routine for device connected to interrupt 1 static void isr2(); /// Array of instances connected to interrupts 0 and 1 static RH_RF95* _deviceForInterrupt[]; /// Index of next interrupt number to use in _deviceForInterrupt static uint8_t _interruptCount; #if (RH_PLATFORM == RH_PLATFORM_MBED) /// The configured interrupt pin connected to this instance InterruptIn _interruptPin; #else /// The configured interrupt pin connected to this instance uint8_t _interruptPin; #endif /// The index into _deviceForInterrupt[] for this device (if an interrupt is already allocated) /// else 0xff uint8_t _myInterruptIndex; /// Number of octets in the buffer volatile uint8_t _bufLen; /// The receiver/transmitter buffer uint8_t _buf[RH_RF95_MAX_PAYLOAD_LEN]; /// True when there is a valid message in the buffer volatile bool _rxBufValid; }; /// @example rf95_client.pde /// @example rf95_server.pde /// @example rf95_reliable_datagram_client.pde /// @example rf95_reliable_datagram_server.pde #endif