Karl Zweimüller
Library for HopeRF RFM22 / RFM22B transceiver module ported to mbed. Original Software from Mike McCauley (mikem@open.com.au) . See http://www.open.com.au/mikem/arduino/RF22/
Dependents: RF22_MAX_test_Send Geofence_receiver Geofence_sender Geofence_sender ... more
More Info about RFM22-modules like connecting and a demo-program see RF22-Notebook
RF22.h
- Committer:
- charly
- Date:
- 2013-09-02
- Revision:
- 9:4002a2c117cc
- Parent:
- 7:b86825b9d74b
File content as of revision 9:4002a2c117cc:
// RF22.h
// Author: Mike McCauley (mikem@open.com.au)
// Copyright (C) 2011 Mike McCauley
// $Id: RF22.h,v 1.23 2013/02/06 21:33:56 mikem Exp mikem $
//
// ported to mbed by Karl Zweimueller
/// \mainpage RF22 library for Arduino
///
/// This is the Arduino RF22 library.
/// It provides an object-oriented interface for sending and receiving data messages with Hope-RF
/// RF22B based radio modules, and compatible chips and modules,
/// including the RFM22B transceiver module such as
/// this bare module: http://www.sparkfun.com/products/10153
/// and this shield: https://www.sparkfun.com/products/11018
///
/// RF22 also supports some of the features of ZigBee and XBee,
/// (such as mesh routing and automatic route discovery),
/// but with a much less complicated system and less expensive radios.
///
/// The Hope-RF (http://www.hoperf.com) RFM22B (http://www.hoperf.com/rf_fsk/fsk/RFM22B.htm)
/// is a low-cost ISM transceiver module. It supports FSK, GFSK, OOK over a wide
/// range of frequencies and programmable data rates.
///
/// This library provides functions for sending and receiving messages of up to 255 octets on any
/// frequency supported by the RF22B, in a range of predefined data rates and frequency deviations.
/// Frequency can be set with 312Hz precision to any frequency from 240.0MHz to 960.0MHz.
///
/// Up to 2 RF22B modules can be connected to an Arduino, permitting the construction of translators
/// and frequency changers, etc.
///
/// This library provides classes for
/// - RF22: unaddressed, unreliable messages
/// - RF22Datagram: addressed, unreliable messages
/// - RF22ReliableDatagram: addressed, reliable, retransmitted, acknowledged messages.
/// - RF22Router: multi hop delivery from source node to destination node via 0 or more intermediate nodes
/// - RF22Mesh: multi hop delivery with automatic route discovery and rediscovery.
///
/// The following modulation types are suppported with a range of modem configurations for
/// common data rates and frequency deviations:
/// - GFSK Gaussian Frequency Shift Keying
/// - FSK Frequency Shift Keying
/// - OOK On-Off Keying
///
/// Support for other RF22B features such as on-chip temperature measurement, analog-digital
/// converter, transmitter power control etc is also provided.
///
/// The latest version of this documentation can be downloaded from
/// http://www.open.com.au/mikem/arduino/RF22
///
/// Example Arduino programs are included to show the main modes of use.
///
/// The version of the package that this documentation refers to can be downloaded
/// from http://www.open.com.au/mikem/arduino/RF22/RF22-1.25.zip
/// You can find the latest version at http://www.open.com.au/mikem/arduino/RF22
///
/// You can also find online help and disussion at http://groups.google.com/group/rf22-arduino
/// Please use that group for all questions and discussions on this topic.
/// Do not contact the author directly, unless it is to discuss commercial licensing.
///
/// Tested on Arduino Diecimila and Mega with arduino-0021
/// on OpenSuSE 11.1 and avr-libc-1.6.1-1.15,
/// cross-avr-binutils-2.19-9.1, cross-avr-gcc-4.1.3_20080612-26.5.
/// With HopeRF RFM22 modules that appear to have RF22B chips on board:
/// - Device Type Code = 0x08 (RX/TRX)
/// - Version Code = 0x06
/// It is known not to work on Diecimila. Dont bother trying.
///
/// \par Packet Format
///
/// All messages sent and received by this RF22 library must conform to this packet format:
///
/// - 8 nibbles (4 octets) PREAMBLE
/// - 2 octets SYNC 0x2d, 0xd4
/// - 4 octets HEADER: (TO, FROM, ID, FLAGS)
/// - 1 octet LENGTH (0 to 255), number of octets in DATA
/// - 0 to 255 octets DATA
/// - 2 octets CRC computed with CRC16(IBM), computed on HEADER, LENGTH and DATA
///
/// For technical reasons, the message format is not compatible with the
/// 'HopeRF Radio Transceiver Message Library for Arduino' http://www.open.com.au/mikem/arduino/HopeRF from the same author. Nor is it compatible with
/// 'Virtual Wire' http://www.open.com.au/mikem/arduino/VirtualWire.pdf also from the same author.
///
/// \par Connecting RFM-22 to Arduino
///
/// If you have the Sparkfun RFM22 Shield (https://www.sparkfun.com/products/11018)
/// the connections described below are done for you on the shield, no changes required,
/// just add headers and plug it in to an Arduino (but not and Arduino Mega, see below)
///
/// The physical connection between the RF22B and the Arduino require 3.3V, the 3 x SPI pins (SCK, SDI, SDO),
/// a Slave Select pin and an interrupt pin.
/// Note also that on the RFF22B, it is required to control the TX_ANT and X_ANT pins of the RFM22 in order to enable the
/// antenna connection. The RF22 library is configured so that GPIO0 and GPIO1 outputs can control TX_ANT and RX_ANT input pins
/// automatically. You must connect GPIO0 to TX_ANT and GPIO1 to RX_ANT for this automatic antenna switching to occur.
///
/// Connect the RFM-22 to most Arduino's like this (Caution, Arduino Mega has different pins for SPI,
/// see below):
/// \code
/// Arduino RFM-22B
/// GND----------GND-\ (ground in)
/// SDN-/ (shutdown in)
/// 3V3----------VCC (3.3V in)
/// interrupt 0 pin D2-----------NIRQ (interrupt request out)
/// SS pin D10----------NSEL (chip select in)
/// SCK pin D13----------SCK (SPI clock in)
/// MOSI pin D11----------SDI (SPI Data in)
/// MISO pin D12----------SDO (SPI data out)
/// /--GPIO0 (GPIO0 out to control transmitter antenna TX_ANT
/// \--TX_ANT (TX antenna control in)
/// /--GPIO1 (GPIO1 out to control receiver antenna RX_ANT
/// \--RX_ANT (RX antenna control in)
/// \endcode
/// For an Arduino Mega:
/// \code
/// Mega RFM-22B
/// GND----------GND-\ (ground in)
/// SDN-/ (shutdown in)
/// 3V3----------VCC (3.3V in)
/// interrupt 0 pin D2-----------NIRQ (interrupt request out)
/// SS pin D53----------NSEL (chip select in)
/// SCK pin D52----------SCK (SPI clock in)
/// MOSI pin D51----------SDI (SPI Data in)
/// MISO pin D50----------SDO (SPI data out)
/// /--GPIO0 (GPIO0 out to control transmitter antenna TX_ANT
/// \--TX_ANT (TX antenna control in)
/// /--GPIO1 (GPIO1 out to control receiver antenna RX_ANT
/// \--RX_ANT (RX antenna control in)
/// \endcode
/// and you can then use the default constructor RF22().
/// You can override the default settings for the SS pin and the interrupt
/// in the RF22 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.
///
/// It is possible to have 2 radios conected to one arduino, provided each radio has its own
/// SS and interrupt line (SCK, SDI and SDO are common to both 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 RF22 module may be relevant in some circumstances:
/// RF22 modules are capable of pulling 80mA+ at full power, where Arduino's 3.3V line can
/// give 50mA. You may need to make provision for alternate power supply for
/// the RF22, especially if you wish to use full transmit power, and/or you have
/// other shields demanding power. Inadequate power for the RF22 is reported 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 RF22 library uses interrupts to react to events in the RF22 module,
/// such as the reception of a new packet, or the completion of transmission of a packet.
/// The RF22 library interrupt service routine reads status from and writes data
/// to the the RF22 module via the SPI interface. It is very important therefore,
/// that if you are using the RF22 library 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 RF22 library requires non-trivial amounts of memory. The sample programs above all compile to
/// about 9 to 14kbytes each, which will fit in the flash proram memory of most Arduinos. However,
/// the RAM requirements are more critical. Most sample programs above will run on Duemilanova,
/// but not on Diecimila. Even on Duemilanova, the RAM requirements are very close to the
/// available memory of 2kbytes. Therefore, you should be vary sparing with RAM use in programs that use
/// the RF22 library on Duemilanova.
///
/// The sample RF22Router and RF22Mesh programs compile to about 14kbytes,
/// and require more RAM than the others.
/// They will not run on Duemilanova or Diecimila, but will run on Arduino Mega.
///
/// 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
///
/// With an Arduino Mega, with 8 kbytes of SRAM, there is much more RAM headroom for
/// your own elaborate programs.
/// This library is reported to work with Arduino Pro Mini, but that has not been tested by me.
///
/// The Arduino UNO is now known to work with RF22.
///
/// \par Automatic Frequency Control (AFC)
///
/// The RF22M modules use an inexpensive crystal to control the frequency synthesizer, and therfore you can expect
/// the transmitter and receiver frequencies to be subject to the usual inaccuracies of such crystals. The RF22
/// contains an AFC circuit to compensate for differences in transmitter and receiver frequencies.
/// It does this by altering the receiver frequency during reception by up to the pull-in frequency range.
/// This RF22 library enables the AFC and by default sets the pull-in frequency range to
/// 0.05MHz, which should be sufficient to handle most situations. However, if you observe unexplained packet losses
/// or failure to operate correctly all the time it may be because your modules have a wider frequency difference, and
/// you may need to set the afcPullInRange to a differentvalue, using setFrequency();
///
/// \par Performance
///
/// Some simple speed performance tests have been conducted.
/// In general packet transmission rate will be limited by the modulation scheme.
/// Also, if your code does any slow operations like Serial printing it will also limit performance.
/// We disabled any printing in the tests below.
/// We tested with RF22::GFSK_Rb125Fd125, which is probably the fastest scheme available.
/// We tested with a 13 octet message length, over a very short distance of 10cm.
///
/// Transmission (no reply) tests with modulation RF22::GFSK_Rb125Fd125 and a
/// 13 octet message show about 330 messages per second transmitted.
///
/// Transmit-and-wait-for-a-reply tests with modulation RF22::GFSK_Rb125Fd125 and a
/// 13 octet message (send and receive) show about 160 round trips per second.
///
/// \par Installation
///
/// Install in the usual way: unzip the distribution zip file to the libraries
/// sub-folder of your sketchbook.
///
/// This software is Copyright (C) 2011 Mike McCauley. Use is subject to license
/// conditions. The main licensing options available are GPL V2 or Commercial:
///
/// \par Open Source Licensing GPL V2
///
/// This is the appropriate option if you want to share the source code of your
/// application with everyone you distribute it to, and you also want to give them
/// the right to share who uses it. If you wish to use this software under Open
/// Source Licensing, you must contribute all your source code to the open source
/// community in accordance with the GPL Version 2 when your application is
/// distributed. See http://www.gnu.org/copyleft/gpl.html
///
/// \par Commercial Licensing
///
/// This is the appropriate option if you are creating proprietary applications
/// and you are not prepared to distribute and share the source code of your
/// application. Contact info@open.com.au for details.
///
/// \par Revision History
///
/// \version 1.0 Initial release
///
/// \version 1.1 Added rf22_snoop and rf22_specan examples
///
/// \version 1.2 Changed default modulation to FSK_Rb2_4Fd36
/// Some internal reorganisation.
/// Added RF22Router and RF22Mesh classes plus sample programs to support multi-hop and
/// automatic route discovery.
/// \version 1.3 Removed some unnecessary debug messages. Added virtual doArp and isPhysicalAddress
/// functions to RF22Mesh to support other physical address interpretation schemes (IPV4/IPV6?)
/// \version 1.4 RF22Router and RF22Mesh were inadvertently left out of the distro.
/// \version 1.5 Improvements contributed by Peter Mousley: Modem config table is now in flash rather than SRAM,
/// saving 400 bytes of SRAM. Allow a user-defined buffer size. Thanks Peter.
/// \version 1.6 Fixed some minor typos on doc and clarified that this code is for the RF22B. Fixed errors in the
/// definition of the power output constants which were incorrectly set to the values for the RF22.
/// Reported by Fred Slamen. If you were using a previous version of RF22, you probably were not getting the output
/// power you thought.
/// \version 1.7 Added code to initialise GPIO0 and GPIO1 so they can automatically control the TX_ANT and RX_ANT
/// antenna switching inputs. You must connect GPIO0 to TX_ANT and GPIO1 to RX_ANT for this automatic
/// antenna switching to occur. Updated doc to reflect this new connection requirement
/// \version 1.8 Changed the name of RF22_ENLBD in RF22_REG_06_INTERRUPT_ENABLE2 to RF22_ENLBDI because it collided
/// with a define of the same name in RF22_REG_07_OPERATING_MODE. RF22_REG_05_INTERRUPT_ENABLE1 enable mask
/// incorrectly used RF22_IFFERROR instead of RF22_ENFFERR. Reported by Steffan Woltjer.
/// \version 1.9 Fixed typos in RF22_REG_21_CLOCk*. Reported by Steffan Woltjer.
/// \version 1.10 Fixed a problem where a IFFERR during transmission could cause an infinite loop and a hang.
/// Reported by Raymond Gilbert.
/// \version 1.11 Fixed an innocuous typo in RF22::handleInterrupt. Reported by Zhentao.
///
/// \version 1.12 Improvements to RF22::init from Guy Molinari to improve compatibility with some
/// Arduinos. Now reported to be working with official Mega 2560 and Uno.
/// Updated so compiles on Arduino 1.0.
///
/// \version 1.13 Announce google support group
///
/// \version 1.14 Added definitions for bits and masks in RF22_REG_1D_AFC_LOOP_GEARSHIFT_OVERRIDE
/// and RF22_REG_1E_AFC_TIMING_CONTROL
///
/// \version 1.15 Small alterations to initialisation code so that SS pin is not set to output: may cause
/// interference with other devices connected to the Arduino. Testing with Uno: OK.
///
/// \version 1.16 Fixed a problem that prevented building with arduino 0021
///
/// \version 1.17 Added optional AFC pull-in frequency range argument to setFrequency().
/// Default AFC pull-in range set to 0.05MHz
///
/// \version 1.18 Changed default value for slave slect pin in constructor to be SS, ie the normal one for
/// the compiled Arduino (D10 for Diecimila, Uno etc and D53 for Mega). This is because some Arduinos such as Mega 2560
/// reportedly use the type of the SS pin to determine whether to run in slave or master mode. Therfore it
/// is preferred that the slave select pin actually be the normal SS pin.
///
/// \version 1.19 Added new mode() function.
/// Fixed a potential race condition in RF22Datagram::recvfrom which might cause corrupt from, to, id or flags
/// under extreme circumstances. Improvements to interrupt hygeine by adding cli()_/sei() around all
/// RF22 register acceses. Found that 0 length transmit packets confuses the RF22, so they are now forbidden.
/// Added IPGateway example, which routes UDP messages from an internet connection using an
/// Ethernet Shield and sends them
/// to a radio whose ID is based on the UDP port. Replies are sent back to the originating UDP
/// address and port.
///
/// \version 1.20 _mode is now volatile.
/// RF22::send() now waits until any previous transmission is complete before sending.
/// RF22::waitPacketSent() now waits for the RF22 to not be in _mode == RF22_MODE_TX
/// _txPacketSent member is now redundant and removed.
/// Improvements to interrupt handling and blocking. Now use ATOMIC_BLOCK(ATOMIC_RESTORESTATE)
/// to prevent reenabling interrupts too soon. Thanks to Roland Mieslinger for this suggestion.
/// Added some performance measurements to documentation.
///
/// \version 1.21 Fixed a case where a receiver buffer overflow could occur. Reported by Joe Tuttle.
///
/// \version 1.22 Added documentation after testing with Sparkfun RFM22 Shield DEV-11018.
/// Fixed incorrect link to register calculator excel file, reported by Joey Morin.
///
/// \version 1.23 Added support for alternative SPI interfaces, with default implementation for the standard
/// Arduino hardware SPI interface. Contributed by Joanna Rutkowska.
///
/// \version 1.24 Fixed a problem that could cause corrupted receive messages if a transmit interrupted
/// a partial receive (as was common with eg ReliableDatagram with poor reception.
/// Also fixed possible receive buffer overrun.
/// \version 1.25 More rigorous use of const, additional register defines (RF22_CRCHDRS RF22_VARPKLEN)
/// and two methods (setPreambleLength()
/// and setSyncWords())made public. Patch provided by
/// Matthijs Kooijman.
/// \author Mike McCauley (mikem@open.com.au)
#ifndef RF22_h
#define RF22_h
#include "mbed.h"
#define boolean bool
//#include <wiring.h>
// These defs cause trouble on some versions of Arduino
#undef round
#undef double
// This is the bit in the SPI address that marks it as a write
#define RF22_SPI_WRITE_MASK 0x80
// This is the maximum message length that can be supported by this library. Limited by
// the single message length octet in the header.
// Yes, 255 is correct even though the FIFO size in the RF22 is only
// 64 octets. We use interrupts to refill the Tx FIFO during transmission and to empty the
// Rx FIFO during reception
// Can be pre-defined to a smaller size (to save SRAM) prior to including this header
#ifndef RF22_MAX_MESSAGE_LEN
#define RF22_MAX_MESSAGE_LEN 255
//#define RF22_MAX_MESSAGE_LEN 50
#endif
// Max number of octets the RF22 Rx and Tx FIFOs can hold
#define RF22_FIFO_SIZE 64
// Keep track of the mode the RF22 is in
#define RF22_MODE_IDLE 0
#define RF22_MODE_RX 1
#define RF22_MODE_TX 2
// These values we set for FIFO thresholds are actually the same as the POR values
#define RF22_TXFFAEM_THRESHOLD 4
#define RF22_RXFFAFULL_THRESHOLD 55
// This is the default node address,
#define RF22_DEFAULT_NODE_ADDRESS 0
// This address in the TO addreess signifies a broadcast
#define RF22_BROADCAST_ADDRESS 0xff
// Number of registers to be passed to setModemConfig()
#define RF22_NUM_MODEM_CONFIG_REGS 18
// Register names
#define RF22_REG_00_DEVICE_TYPE 0x00
#define RF22_REG_01_VERSION_CODE 0x01
#define RF22_REG_02_DEVICE_STATUS 0x02
#define RF22_REG_03_INTERRUPT_STATUS1 0x03
#define RF22_REG_04_INTERRUPT_STATUS2 0x04
#define RF22_REG_05_INTERRUPT_ENABLE1 0x05
#define RF22_REG_06_INTERRUPT_ENABLE2 0x06
#define RF22_REG_07_OPERATING_MODE1 0x07
#define RF22_REG_08_OPERATING_MODE2 0x08
#define RF22_REG_09_OSCILLATOR_LOAD_CAPACITANCE 0x09
#define RF22_REG_0A_UC_OUTPUT_CLOCK 0x0a
#define RF22_REG_0B_GPIO_CONFIGURATION0 0x0b
#define RF22_REG_0C_GPIO_CONFIGURATION1 0x0c
#define RF22_REG_0D_GPIO_CONFIGURATION2 0x0d
#define RF22_REG_0E_IO_PORT_CONFIGURATION 0x0e
#define RF22_REG_0F_ADC_CONFIGURATION 0x0f
#define RF22_REG_10_ADC_SENSOR_AMP_OFFSET 0x10
#define RF22_REG_11_ADC_VALUE 0x11
#define RF22_REG_12_TEMPERATURE_SENSOR_CALIBRATION 0x12
#define RF22_REG_13_TEMPERATURE_VALUE_OFFSET 0x13
#define RF22_REG_14_WAKEUP_TIMER_PERIOD1 0x14
#define RF22_REG_15_WAKEUP_TIMER_PERIOD2 0x15
#define RF22_REG_16_WAKEUP_TIMER_PERIOD3 0x16
#define RF22_REG_17_WAKEUP_TIMER_VALUE1 0x17
#define RF22_REG_18_WAKEUP_TIMER_VALUE2 0x18
#define RF22_REG_19_LDC_MODE_DURATION 0x19
#define RF22_REG_1A_LOW_BATTERY_DETECTOR_THRESHOLD 0x1a
#define RF22_REG_1B_BATTERY_VOLTAGE_LEVEL 0x1b
#define RF22_REG_1C_IF_FILTER_BANDWIDTH 0x1c
#define RF22_REG_1D_AFC_LOOP_GEARSHIFT_OVERRIDE 0x1d
#define RF22_REG_1E_AFC_TIMING_CONTROL 0x1e
#define RF22_REG_1F_CLOCK_RECOVERY_GEARSHIFT_OVERRIDE 0x1f
#define RF22_REG_20_CLOCK_RECOVERY_OVERSAMPLING_RATE 0x20
#define RF22_REG_21_CLOCK_RECOVERY_OFFSET2 0x21
#define RF22_REG_22_CLOCK_RECOVERY_OFFSET1 0x22
#define RF22_REG_23_CLOCK_RECOVERY_OFFSET0 0x23
#define RF22_REG_24_CLOCK_RECOVERY_TIMING_LOOP_GAIN1 0x24
#define RF22_REG_25_CLOCK_RECOVERY_TIMING_LOOP_GAIN0 0x25
#define RF22_REG_26_RSSI 0x26
#define RF22_REG_27_RSSI_THRESHOLD 0x27
#define RF22_REG_28_ANTENNA_DIVERSITY1 0x28
#define RF22_REG_29_ANTENNA_DIVERSITY2 0x29
#define RF22_REG_2A_AFC_LIMITER 0x2a
#define RF22_REG_2B_AFC_CORRECTION_READ 0x2b
#define RF22_REG_2C_OOK_COUNTER_VALUE_1 0x2c
#define RF22_REG_2D_OOK_COUNTER_VALUE_2 0x2d
#define RF22_REG_2E_SLICER_PEAK_HOLD 0x2e
#define RF22_REG_30_DATA_ACCESS_CONTROL 0x30
#define RF22_REG_31_EZMAC_STATUS 0x31
#define RF22_REG_32_HEADER_CONTROL1 0x32
#define RF22_REG_33_HEADER_CONTROL2 0x33
#define RF22_REG_34_PREAMBLE_LENGTH 0x34
#define RF22_REG_35_PREAMBLE_DETECTION_CONTROL1 0x35
#define RF22_REG_36_SYNC_WORD3 0x36
#define RF22_REG_37_SYNC_WORD2 0x37
#define RF22_REG_38_SYNC_WORD1 0x38
#define RF22_REG_39_SYNC_WORD0 0x39
#define RF22_REG_3A_TRANSMIT_HEADER3 0x3a
#define RF22_REG_3B_TRANSMIT_HEADER2 0x3b
#define RF22_REG_3C_TRANSMIT_HEADER1 0x3c
#define RF22_REG_3D_TRANSMIT_HEADER0 0x3d
#define RF22_REG_3E_PACKET_LENGTH 0x3e
#define RF22_REG_3F_CHECK_HEADER3 0x3f
#define RF22_REG_40_CHECK_HEADER2 0x40
#define RF22_REG_41_CHECK_HEADER1 0x41
#define RF22_REG_42_CHECK_HEADER0 0x42
#define RF22_REG_43_HEADER_ENABLE3 0x43
#define RF22_REG_44_HEADER_ENABLE2 0x44
#define RF22_REG_45_HEADER_ENABLE1 0x45
#define RF22_REG_46_HEADER_ENABLE0 0x46
#define RF22_REG_47_RECEIVED_HEADER3 0x47
#define RF22_REG_48_RECEIVED_HEADER2 0x48
#define RF22_REG_49_RECEIVED_HEADER1 0x49
#define RF22_REG_4A_RECEIVED_HEADER0 0x4a
#define RF22_REG_4B_RECEIVED_PACKET_LENGTH 0x4b
#define RF22_REG_50_ANALOG_TEST_BUS_SELECT 0x50
#define RF22_REG_51_DIGITAL_TEST_BUS_SELECT 0x51
#define RF22_REG_52_TX_RAMP_CONTROL 0x52
#define RF22_REG_53_PLL_TUNE_TIME 0x53
#define RF22_REG_55_CALIBRATION_CONTROL 0x55
#define RF22_REG_56_MODEM_TEST 0x56
#define RF22_REG_57_CHARGE_PUMP_TEST 0x57
#define RF22_REG_58_CHARGE_PUMP_CURRENT_TRIMMING 0x58
#define RF22_REG_59_DIVIDER_CURRENT_TRIMMING 0x59
#define RF22_REG_5A_VCO_CURRENT_TRIMMING 0x5a
#define RF22_REG_5B_VCO_CALIBRATION 0x5b
#define RF22_REG_5C_SYNTHESIZER_TEST 0x5c
#define RF22_REG_5D_BLOCK_ENABLE_OVERRIDE1 0x5d
#define RF22_REG_5E_BLOCK_ENABLE_OVERRIDE2 0x5e
#define RF22_REG_5F_BLOCK_ENABLE_OVERRIDE3 0x5f
#define RF22_REG_60_CHANNEL_FILTER_COEFFICIENT_ADDRESS 0x60
#define RF22_REG_61_CHANNEL_FILTER_COEFFICIENT_VALUE 0x61
#define RF22_REG_62_CRYSTAL_OSCILLATOR_POR_CONTROL 0x62
#define RF22_REG_63_RC_OSCILLATOR_COARSE_CALIBRATION 0x63
#define RF22_REG_64_RC_OSCILLATOR_FINE_CALIBRATION 0x64
#define RF22_REG_65_LDO_CONTROL_OVERRIDE 0x65
#define RF22_REG_66_LDO_LEVEL_SETTINGS 0x66
#define RF22_REG_67_DELTA_SIGMA_ADC_TUNING1 0x67
#define RF22_REG_68_DELTA_SIGMA_ADC_TUNING2 0x68
#define RF22_REG_69_AGC_OVERRIDE1 0x69
#define RF22_REG_6A_AGC_OVERRIDE2 0x6a
#define RF22_REG_6B_GFSK_FIR_FILTER_COEFFICIENT_ADDRESS 0x6b
#define RF22_REG_6C_GFSK_FIR_FILTER_COEFFICIENT_VALUE 0x6c
#define RF22_REG_6D_TX_POWER 0x6d
#define RF22_REG_6E_TX_DATA_RATE1 0x6e
#define RF22_REG_6F_TX_DATA_RATE0 0x6f
#define RF22_REG_70_MODULATION_CONTROL1 0x70
#define RF22_REG_71_MODULATION_CONTROL2 0x71
#define RF22_REG_72_FREQUENCY_DEVIATION 0x72
#define RF22_REG_73_FREQUENCY_OFFSET1 0x73
#define RF22_REG_74_FREQUENCY_OFFSET2 0x74
#define RF22_REG_75_FREQUENCY_BAND_SELECT 0x75
#define RF22_REG_76_NOMINAL_CARRIER_FREQUENCY1 0x76
#define RF22_REG_77_NOMINAL_CARRIER_FREQUENCY0 0x77
#define RF22_REG_79_FREQUENCY_HOPPING_CHANNEL_SELECT 0x79
#define RF22_REG_7A_FREQUENCY_HOPPING_STEP_SIZE 0x7a
#define RF22_REG_7C_TX_FIFO_CONTROL1 0x7c
#define RF22_REG_7D_TX_FIFO_CONTROL2 0x7d
#define RF22_REG_7E_RX_FIFO_CONTROL 0x7e
#define RF22_REG_7F_FIFO_ACCESS 0x7f
// These register masks etc are named wherever possible
// corresponding to the bit and field names in the RF-22 Manual
// RF22_REG_00_DEVICE_TYPE 0x00
#define RF22_DEVICE_TYPE_RX_TRX 0x08
#define RF22_DEVICE_TYPE_TX 0x07
// RF22_REG_02_DEVICE_STATUS 0x02
#define RF22_FFOVL 0x80
#define RF22_FFUNFL 0x40
#define RF22_RXFFEM 0x20
#define RF22_HEADERR 0x10
#define RF22_FREQERR 0x08
#define RF22_LOCKDET 0x04
#define RF22_CPS 0x03
#define RF22_CPS_IDLE 0x00
#define RF22_CPS_RX 0x01
#define RF22_CPS_TX 0x10
// RF22_REG_03_INTERRUPT_STATUS1 0x03
#define RF22_IFFERROR 0x80
#define RF22_ITXFFAFULL 0x40
#define RF22_ITXFFAEM 0x20
#define RF22_IRXFFAFULL 0x10
#define RF22_IEXT 0x08
#define RF22_IPKSENT 0x04
#define RF22_IPKVALID 0x02
#define RF22_ICRCERROR 0x01
// RF22_REG_04_INTERRUPT_STATUS2 0x04
#define RF22_ISWDET 0x80
#define RF22_IPREAVAL 0x40
#define RF22_IPREAINVAL 0x20
#define RF22_IRSSI 0x10
#define RF22_IWUT 0x08
#define RF22_ILBD 0x04
#define RF22_ICHIPRDY 0x02
#define RF22_IPOR 0x01
// RF22_REG_05_INTERRUPT_ENABLE1 0x05
#define RF22_ENFFERR 0x80
#define RF22_ENTXFFAFULL 0x40
#define RF22_ENTXFFAEM 0x20
#define RF22_ENRXFFAFULL 0x10
#define RF22_ENEXT 0x08
#define RF22_ENPKSENT 0x04
#define RF22_ENPKVALID 0x02
#define RF22_ENCRCERROR 0x01
// RF22_REG_06_INTERRUPT_ENABLE2 0x06
#define RF22_ENSWDET 0x80
#define RF22_ENPREAVAL 0x40
#define RF22_ENPREAINVAL 0x20
#define RF22_ENRSSI 0x10
#define RF22_ENWUT 0x08
#define RF22_ENLBDI 0x04
#define RF22_ENCHIPRDY 0x02
#define RF22_ENPOR 0x01
// RF22_REG_07_OPERATING_MODE 0x07
#define RF22_SWRES 0x80
#define RF22_ENLBD 0x40
#define RF22_ENWT 0x20
#define RF22_X32KSEL 0x10
#define RF22_TXON 0x08
#define RF22_RXON 0x04
#define RF22_PLLON 0x02
#define RF22_XTON 0x01
// RF22_REG_08_OPERATING_MODE2 0x08
#define RF22_ANTDIV 0xc0
#define RF22_RXMPK 0x10
#define RF22_AUTOTX 0x08
#define RF22_ENLDM 0x04
#define RF22_FFCLRRX 0x02
#define RF22_FFCLRTX 0x01
// RF22_REG_0F_ADC_CONFIGURATION 0x0f
#define RF22_ADCSTART 0x80
#define RF22_ADCDONE 0x80
#define RF22_ADCSEL 0x70
#define RF22_ADCSEL_INTERNAL_TEMPERATURE_SENSOR 0x00
#define RF22_ADCSEL_GPIO0_SINGLE_ENDED 0x10
#define RF22_ADCSEL_GPIO1_SINGLE_ENDED 0x20
#define RF22_ADCSEL_GPIO2_SINGLE_ENDED 0x30
#define RF22_ADCSEL_GPIO0_GPIO1_DIFFERENTIAL 0x40
#define RF22_ADCSEL_GPIO1_GPIO2_DIFFERENTIAL 0x50
#define RF22_ADCSEL_GPIO0_GPIO2_DIFFERENTIAL 0x60
#define RF22_ADCSEL_GND 0x70
#define RF22_ADCREF 0x0c
#define RF22_ADCREF_BANDGAP_VOLTAGE 0x00
#define RF22_ADCREF_VDD_ON_3 0x08
#define RF22_ADCREF_VDD_ON_2 0x0c
#define RF22_ADCGAIN 0x03
// RF22_REG_10_ADC_SENSOR_AMP_OFFSET 0x10
#define RF22_ADCOFFS 0x0f
// RF22_REG_12_TEMPERATURE_SENSOR_CALIBRATION 0x12
#define RF22_TSRANGE 0xc0
#define RF22_TSRANGE_M64_64C 0x00
#define RF22_TSRANGE_M64_192C 0x40
#define RF22_TSRANGE_0_128C 0x80
#define RF22_TSRANGE_M40_216F 0xc0
#define RF22_ENTSOFFS 0x20
#define RF22_ENTSTRIM 0x10
#define RF22_TSTRIM 0x0f
// RF22_REG_14_WAKEUP_TIMER_PERIOD1 0x14
#define RF22_WTR 0x3c
#define RF22_WTD 0x03
// RF22_REG_1D_AFC_LOOP_GEARSHIFT_OVERRIDE 0x1d
#define RF22_AFBCD 0x80
#define RF22_ENAFC 0x40
#define RF22_AFCGEARH 0x38
#define RF22_AFCGEARL 0x07
// RF22_REG_1E_AFC_TIMING_CONTROL 0x1e
#define RF22_SWAIT_TIMER 0xc0
#define RF22_SHWAIT 0x38
#define RF22_ANWAIT 0x07
// RF22_REG_30_DATA_ACCESS_CONTROL 0x30
#define RF22_ENPACRX 0x80
#define RF22_MSBFRST 0x00
#define RF22_LSBFRST 0x40
#define RF22_CRCHDRS 0x00
#define RF22_CRCDONLY 0x20
#define RF22_ENPACTX 0x08
#define RF22_ENCRC 0x04
#define RF22_CRC 0x03
#define RF22_CRC_CCITT 0x00
#define RF22_CRC_CRC_16_IBM 0x01
#define RF22_CRC_IEC_16 0x02
#define RF22_CRC_BIACHEVA 0x03
// RF22_REG_32_HEADER_CONTROL1 0x32
#define RF22_BCEN 0xf0
#define RF22_BCEN_NONE 0x00
#define RF22_BCEN_HEADER0 0x10
#define RF22_BCEN_HEADER1 0x20
#define RF22_BCEN_HEADER2 0x40
#define RF22_BCEN_HEADER3 0x80
#define RF22_HDCH 0x0f
#define RF22_HDCH_NONE 0x00
#define RF22_HDCH_HEADER0 0x01
#define RF22_HDCH_HEADER1 0x02
#define RF22_HDCH_HEADER2 0x04
#define RF22_HDCH_HEADER3 0x08
// RF22_REG_33_HEADER_CONTROL2 0x33
#define RF22_HDLEN 0x70
#define RF22_HDLEN_0 0x00
#define RF22_HDLEN_1 0x10
#define RF22_HDLEN_2 0x20
#define RF22_HDLEN_3 0x30
#define RF22_HDLEN_4 0x40
#define RF22_VARPKLEN 0x00
#define RF22_FIXPKLEN 0x08
#define RF22_SYNCLEN 0x06
#define RF22_SYNCLEN_1 0x00
#define RF22_SYNCLEN_2 0x02
#define RF22_SYNCLEN_3 0x04
#define RF22_SYNCLEN_4 0x06
#define RF22_PREALEN8 0x01
// RF22_REG_6D_TX_POWER 0x6d
#define RF22_TXPOW 0x07
#define RF22_TXPOW_4X31 0x08 // Not used in RFM22B
#define RF22_TXPOW_1DBM 0x00
#define RF22_TXPOW_2DBM 0x01
#define RF22_TXPOW_5DBM 0x02
#define RF22_TXPOW_8DBM 0x03
#define RF22_TXPOW_11DBM 0x04
#define RF22_TXPOW_14DBM 0x05
#define RF22_TXPOW_17DBM 0x06
#define RF22_TXPOW_20DBM 0x07
// IN RFM23B
#define RF22_TXPOW_LNA_SW 0x08
// RF22_REG_71_MODULATION_CONTROL2 0x71
#define RF22_TRCLK 0xc0
#define RF22_TRCLK_NONE 0x00
#define RF22_TRCLK_GPIO 0x40
#define RF22_TRCLK_SDO 0x80
#define RF22_TRCLK_NIRQ 0xc0
#define RF22_DTMOD 0x30
#define RF22_DTMOD_DIRECT_GPIO 0x00
#define RF22_DTMOD_DIRECT_SDI 0x10
#define RF22_DTMOD_FIFO 0x20
#define RF22_DTMOD_PN9 0x30
#define RF22_ENINV 0x08
#define RF22_FD8 0x04
#define RF22_MODTYP 0x30
#define RF22_MODTYP_UNMODULATED 0x00
#define RF22_MODTYP_OOK 0x01
#define RF22_MODTYP_FSK 0x02
#define RF22_MODTYP_GFSK 0x03
// RF22_REG_75_FREQUENCY_BAND_SELECT 0x75
#define RF22_SBSEL 0x40
#define RF22_HBSEL 0x20
#define RF22_FB 0x1f
// Define this to include Serial printing in diagnostic routines
//#define RF22_HAVE_SERIAL
//#include <GenericSPI.h>
//#include <HardwareSPI.h>
/////////////////////////////////////////////////////////////////////
/// \class RF22 RF22.h <RF22.h>
/// \brief Send and receive unaddressed, unreliable datagrams.
///
/// This base class provides basic functions for sending and receiving unaddressed,
/// unreliable datagrams of arbitrary length to 255 octets per packet.
///
/// Subclasses may use this class to implement reliable, addressed datagrams and streams,
/// mesh routers, repeaters, translators etc.
///
/// On transmission, the TO and FROM addresses default to 0x00, unless changed by a subclass.
/// On reception the TO addressed is checked against the node address (defaults to 0x00) or the
/// broadcast address (which is 0xff). The ID and FLAGS are set to 0, and not checked by this class.
/// This permits use of the this base RF22 class as an
/// unaddresed, unreliable datagram service. Subclasses are expected to change this behaviour to
/// add node address, ids, retransmission etc
///
/// Naturally, for any 2 radios to communicate that must be configured to use the same frequence and
/// modulation scheme.
class RF22
{
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 setModemConfig()
/// if none of the choices in ModemConfigChoice suit your need
/// setModemConfig() writes the register values to the appropriate RF22 registers
/// to set the desired modulation type, data rate and deviation/bandwidth.
/// Suitable values for these registers can be computed using the register calculator at
/// http://www.hoperf.com/upload/rf/RF22B%2023B%2031B%2042B%2043B%20Register%20Settings_RevB1-v5.xls
typedef struct
{
uint8_t reg_1c; ///< Value for register RF22_REG_1C_IF_FILTER_BANDWIDTH
uint8_t reg_1f; ///< Value for register RF22_REG_1F_CLOCK_RECOVERY_GEARSHIFT_OVERRIDE
uint8_t reg_20; ///< Value for register RF22_REG_20_CLOCK_RECOVERY_OVERSAMPLING_RATE
uint8_t reg_21; ///< Value for register RF22_REG_21_CLOCK_RECOVERY_OFFSET2
uint8_t reg_22; ///< Value for register RF22_REG_22_CLOCK_RECOVERY_OFFSET1
uint8_t reg_23; ///< Value for register RF22_REG_23_CLOCK_RECOVERY_OFFSET0
uint8_t reg_24; ///< Value for register RF22_REG_24_CLOCK_RECOVERY_TIMING_LOOP_GAIN1
uint8_t reg_25; ///< Value for register RF22_REG_25_CLOCK_RECOVERY_TIMING_LOOP_GAIN0
uint8_t reg_2c; ///< Value for register RF22_REG_2C_OOK_COUNTER_VALUE_1
uint8_t reg_2d; ///< Value for register RF22_REG_2D_OOK_COUNTER_VALUE_2
uint8_t reg_2e; ///< Value for register RF22_REG_2E_SLICER_PEAK_HOLD
uint8_t reg_58; ///< Value for register RF22_REG_58_CHARGE_PUMP_CURRENT_TRIMMING
uint8_t reg_69; ///< Value for register RF22_REG_69_AGC_OVERRIDE1
uint8_t reg_6e; ///< Value for register RF22_REG_6E_TX_DATA_RATE1
uint8_t reg_6f; ///< Value for register RF22_REG_6F_TX_DATA_RATE0
uint8_t reg_70; ///< Value for register RF22_REG_70_MODULATION_CONTROL1
uint8_t reg_71; ///< Value for register RF22_REG_71_MODULATION_CONTROL2
uint8_t reg_72; ///< Value for register RF22_REG_72_FREQUENCY_DEVIATION
} ModemConfig;
/// Choices for setModemConfig() for a selected subset of common modulation types,
/// and data rates. If you need another configuration, use the register calculator.
/// and call setModemRegisters() with your desired settings
/// These are indexes into _modemConfig
typedef enum
{
UnmodulatedCarrier = 0, ///< Unmodulated carrier for testing
FSK_PN9_Rb2Fd5, ///< FSK, No Manchester, Rb = 2kbs, Fd = 5kHz, PN9 random modulation for testing
FSK_Rb2Fd5, ///< FSK, No Manchester, Rb = 2kbs, Fd = 5kHz
FSK_Rb2_4Fd36, ///< FSK, No Manchester, Rb = 2.4kbs, Fd = 36kHz
FSK_Rb4_8Fd45, ///< FSK, No Manchester, Rb = 4.8kbs, Fd = 45kHz
FSK_Rb9_6Fd45, ///< FSK, No Manchester, Rb = 9.6kbs, Fd = 45kHz
FSK_Rb19_2Fd9_6, ///< FSK, No Manchester, Rb = 19.2kbs, Fd = 9.6kHz
FSK_Rb38_4Fd19_6, ///< FSK, No Manchester, Rb = 38.4kbs, Fd = 19.6kHz
FSK_Rb57_6Fd28_8, ///< FSK, No Manchester, Rb = 57.6kbs, Fd = 28.8kHz
FSK_Rb125Fd125, ///< FSK, No Manchester, Rb = 125kbs, Fd = 125kHz
GFSK_Rb2Fd5, ///< GFSK, No Manchester, Rb = 2kbs, Fd = 5kHz
GFSK_Rb2_4Fd36, ///< GFSK, No Manchester, Rb = 2.4kbs, Fd = 36kHz
GFSK_Rb4_8Fd45, ///< GFSK, No Manchester, Rb = 4.8kbs, Fd = 45kHz
GFSK_Rb9_6Fd45, ///< GFSK, No Manchester, Rb = 9.6kbs, Fd = 45kHz
GFSK_Rb19_2Fd9_6, ///< GFSK, No Manchester, Rb = 19.2kbs, Fd = 9.6kHz
GFSK_Rb38_4Fd19_6, ///< GFSK, No Manchester, Rb = 38.4kbs, Fd = 19.6kHz
GFSK_Rb57_6Fd28_8, ///< GFSK, No Manchester, Rb = 57.6kbs, Fd = 28.8kHz
GFSK_Rb125Fd125, ///< GFSK, No Manchester, Rb = 125kbs, Fd = 125kHz
OOK_Rb1_2Bw75, ///< OOK, No Manchester, Rb = 1.2kbs, Rx Bandwidth = 75kHz
OOK_Rb2_4Bw335, ///< OOK, No Manchester, Rb = 2.4kbs, Rx Bandwidth = 335kHz
OOK_Rb4_8Bw335, ///< OOK, No Manchester, Rb = 4.8kbs, Rx Bandwidth = 335kHz
OOK_Rb9_6Bw335, ///< OOK, No Manchester, Rb = 9.6kbs, Rx Bandwidth = 335kHz
OOK_Rb19_2Bw335, ///< OOK, No Manchester, Rb = 19.2kbs, Rx Bandwidth = 335kHz
OOK_Rb38_4Bw335, ///< OOK, No Manchester, Rb = 38.4kbs, Rx Bandwidth = 335kHz
OOK_Rb40Bw335 ///< OOK, No Manchester, Rb = 40kbs, Rx Bandwidth = 335kHz
} 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 intnerface
/// and the radio module
/// \param[in] slaveSelectPin the Arduino pin number of the output to use to select the RF22 before
/// accessing it. Defaults to the normal SS pin for your Arduino (D10 for Diecimila, Uno etc, D53 for Mega)
/// \param[in] interrupt The interrupt number to use. Default is interrupt 0 (Arduino input pin 2)
RF22(PinName slaveSelectPin , PinName mosi, PinName miso, PinName sclk, PinName interrupt );
/// Initialises this instance and the radio module connected to it.
/// The following steps are taken:
/// - Initialise the slave select pin and the SPI interface library
/// - Software reset the RF22 module
/// - Checks the connected RF22 module is either a RF22_DEVICE_TYPE_RX_TRX or a RF22_DEVICE_TYPE_TX
/// - Attaches an interrupt handler
/// - Configures the RF22 module
/// - Sets the frequncy to 434.0 MHz
/// - Sets the modem data rate to FSK_Rb2_4Fd36
/// \return true if everything was successful
boolean init();
/// Issues a software reset to the
/// RF22 module. Blocks for 1ms to ensure the reset is complete.
void reset();
/// Reads a single register from the RF22
/// \param[in] reg Register number, one of RF22_REG_*
/// \return The value of the register
uint8_t spiRead(uint8_t reg);
/// Writes a single byte to the RF22
/// \param[in] reg Register number, one of RF22_REG_*
/// \param[in] val The value to write
void spiWrite(uint8_t reg, uint8_t val);
/// Reads a number of consecutive registers from the RF22 using burst read mode
/// \param[in] reg Register number of the first register, one of RF22_REG_*
/// \param[in] dest Array to write the register values to. Must be at least len bytes
/// \param[in] len Number of bytes to read
void spiBurstRead(uint8_t reg, uint8_t* dest, uint8_t len);
/// Write a number of consecutive registers using burst write mode
/// \param[in] reg Register number of the first register, one of RF22_REG_*
/// \param[in] src Array of new register values to write. Must be at least len bytes
/// \param[in] len Number of bytes to write
void spiBurstWrite(uint8_t reg, const uint8_t* src, uint8_t len);
/// Reads and returns the device status register RF22_REG_02_DEVICE_STATUS
/// \return The value of the device status register
uint8_t statusRead();
/// Reads a value from the on-chip analog-digital converter
/// \param[in] adcsel Selects the ADC input to measure. One of RF22_ADCSEL_*. Defaults to the
/// internal temperature sensor
/// \param[in] adcref Specifies the refernce voltage to use. One of RF22_ADCREF_*.
/// Defaults to the internal bandgap voltage.
/// \param[in] adcgain Amplifier gain selection.
/// \param[in] adcoffs Amplifier offseet (0 to 15).
/// \return The analog value. 0 to 255.
uint8_t adcRead(uint8_t adcsel = RF22_ADCSEL_INTERNAL_TEMPERATURE_SENSOR,
uint8_t adcref = RF22_ADCREF_BANDGAP_VOLTAGE,
uint8_t adcgain = 0,
uint8_t adcoffs = 0);
/// Reads the on-chip temperature sensoer
/// \param[in] tsrange Specifies the temperature range to use. One of RF22_TSRANGE_*
/// \param[in] tvoffs Specifies the temperature value offset. This is actually signed value
/// added to the measured temperature value
/// \return The measured temperature.
uint8_t temperatureRead(uint8_t tsrange = RF22_TSRANGE_M64_64C, uint8_t tvoffs = 0);
/// Reads the wakeup timer value in registers RF22_REG_17_WAKEUP_TIMER_VALUE1
/// and RF22_REG_18_WAKEUP_TIMER_VALUE2
/// \return The wakeup timer value
uint16_t wutRead();
/// Sets the wakeup timer period registers RF22_REG_14_WAKEUP_TIMER_PERIOD1,
/// RF22_REG_15_WAKEUP_TIMER_PERIOD2 and RF22_R<EG_16_WAKEUP_TIMER_PERIOD3
/// \param[in] wtm Wakeup timer mantissa value
/// \param[in] wtr Wakeup timer exponent R value
/// \param[in] wtd Wakeup timer exponent D value
void setWutPeriod(uint16_t wtm, uint8_t wtr = 0, uint8_t wtd = 0);
/// Sets the transmitter and receiver centre frequency
/// \param[in] centre Frequency in MHz. 240.0 to 960.0. Caution, some versions of RF22 and derivatives
/// implemented more restricted frequency ranges.
/// \param[in] afcPullInRange Sets the AF Pull In Range in MHz. Defaults to 0.05MHz (50kHz). Range is 0.0 to 0.159375
/// for frequencies 240.0 to 480MHz, and 0.0 to 0.318750MHz for frequencies 480.0 to 960MHz,
/// \return true if the selected frquency centre + (fhch * fhs) is within range and the afcPullInRange is within range
boolean setFrequency(float centre, float afcPullInRange = 0.05);
/// Sets the frequency hopping step size.
/// \param[in] fhs Frequency Hopping step size in 10kHz increments
/// \return true if centre + (fhch * fhs) is within limits
boolean setFHStepSize(uint8_t fhs);
/// Sets the frequncy hopping channel. Adds fhch * fhs to centre frequency
/// \param[in] fhch The channel number
/// \return true if the selected frquency centre + (fhch * fhs) is within range
boolean setFHChannel(uint8_t fhch);
/// Reads and returns the current RSSI value from register RF22_REG_26_RSSI. If you want to find the RSSI
/// of the last received message, use lastRssi() instead.
/// \return The current RSSI value
uint8_t rssiRead();
/// Reads and returns the current EZMAC value from register RF22_REG_31_EZMAC_STATUS
/// \return The current EZMAC value
uint8_t ezmacStatusRead();
/// Sets the parameters for the RF22 Idle mode in register RF22_REG_07_OPERATING_MODE.
/// Idle mode is the mode the RF22 will be in when not transmitting or receiving. The default idle mode
/// is RF22_XTON ie READY mode.
/// \param[in] mode Mask of mode bits, using RF22_SWRES, RF22_ENLBD, RF22_ENWT,
/// RF22_X32KSEL, RF22_PLLON, RF22_XTON.
void setMode(uint8_t mode);
/// 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 RF22.
void setModeRx();
/// If current mode is Rx or Idle, changes it to Rx.
/// Starts the transmitter in the RF22.
void setModeTx();
/// Returns the operating mode of the library.
/// \return the current mode, one of RF22_MODE_*
uint8_t mode();
/// Sets the transmitter power output level in register RF22_REG_6D_TX_POWER.
/// Be a good neighbour and set the lowest power level you need.
/// After init(), the power wil be set to RF22_TXPOW_8DBM.
/// Caution: In some countries you may only select RF22_TXPOW_17DBM if you
/// are also using frequency hopping.
/// \param[in] power Transmitter power level, one of RF22_TXPOW_*
void setTxPower(uint8_t power);
/// Sets all the registered required to configure the data modem in the RF22, including the data rate,
/// bandwidths etc. You cas use this to configure the modem with custom configuraitons 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.
boolean setModemConfig(ModemConfigChoice index);
/// Starts the receiver and checks whether a received message is available.
/// This can be called multiple times in a timeout loop
/// \return true if a complete, valid message has been received and is able to be retrieved by
/// recv()
boolean available();
/// Starts the receiver and blocks until a valid received
/// message is available.
void waitAvailable();
/// Starts the receiver and blocks until a received message is available or a timeout
/// \param[in] timeout Maximum time to wait in milliseconds.
/// \return true if a message is available
bool waitAvailableTimeout(uint16_t timeout);
/// 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
boolean 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 NOT permitted.
/// \param[in] data Array of data to be sent
/// \param[in] len Number of bytes of data to send (> 0)
/// \return true if the message length was valid and it was correctly queued for transmit
boolean send(const uint8_t* data, uint8_t len);
/// Blocks until the RF22 is not in mode RF22_MODE_TX (ie until the RF22 is not transmitting).
/// This effectively waits until any previous transmit packet is finished being transmitted.
void waitPacketSent();
/// Tells the receiver to accept messages with any TO address, not just messages
/// addressed to this node or the broadcast address
/// \param[in] promiscuous true if you wish to receive messages with any TO address
void setPromiscuous(boolean promiscuous);
/// Returns the TO header of the last received message
/// \return The TO header
uint8_t headerTo();
/// Returns the FROM header of the last received message
/// \return The FROM header
uint8_t headerFrom();
/// Returns the ID header of the last received message
/// \return The ID header
uint8_t headerId();
/// Returns the FLAGS header of the last received message
/// \return The FLAGS header
uint8_t headerFlags();
/// Returns the RSSI (Receiver Signal Strength Indicator)
/// of the last received message. This measurement is taken when
/// the preamble has been received. It is a (non-linear) measure of the received signal strength.
/// \return The RSSI
uint8_t lastRssi();
/// Prints a data buffer in HEX.
/// For diagnostic use
/// \param[in] prompt string to preface the print
/// \param[in] buf Location of the buffer to print
/// \param[in] len Length of the buffer in octets.
static void printBuffer(const char* prompt, const uint8_t* buf, uint8_t len);
/// Sets the length of the preamble
/// in 4-bit nibbles.
/// Caution: this should be set to the same
/// value on all nodes in your network. Default is 8.
/// Sets the message preamble length in RF22_REG_34_PREAMBLE_LENGTH
/// \param[in] nibbles Preamble length in nibbles of 4 bits each.
void setPreambleLength(uint8_t nibbles);
/// Sets the sync words for transmit and receive in registers RF22_REG_36_SYNC_WORD3
/// to RF22_REG_39_SYNC_WORD0
/// Caution: this should be set to the same
/// value on all nodes in your network. Default is { 0x2d, 0xd4 }
/// \param[in] syncWords Array of sync words
/// \param[in] len Number of sync words to set
void setSyncWords(const uint8_t* syncWords, uint8_t len);
protected:
/// This is a low level function to handle the interrupts for one instance of RF22.
/// Called automatically by isr0() and isr1()
/// Should not need to be called.
void handleInterrupt();
/// Clears the receiver buffer.
/// Internal use only
void clearRxBuf();
/// Clears the transmitter buffer
/// Internal use only
void clearTxBuf();
/// Fills the transmitter buffer with the data of a mesage to be sent
/// \param[in] data Array of data bytes to be sent (1 to 255)
/// \param[in] len Number of data bytes in data (> 0)
/// \return true if the message length is valid
boolean fillTxBuf(const uint8_t* data, uint8_t len);
/// Appends the transmitter buffer with the data of a mesage to be sent
/// \param[in] data Array of data bytes to be sent (0 to 255)
/// \param[in] len Number of data bytes in data
/// \return false if the resulting message would exceed RF22_MAX_MESSAGE_LEN, else true
boolean appendTxBuf(const uint8_t* data, uint8_t len);
/// Internal function to load the next fragment of
/// the current message into the transmitter FIFO
/// Internal use only
void sendNextFragment();
/// function to copy the next fragment from
/// the receiver FIF) into the receiver buffer
void readNextFragment();
/// Clears the RF22 Rx and Tx FIFOs
/// Internal use only
void resetFifos();
/// Clears the RF22 Rx FIFO
/// Internal use only
void resetRxFifo();
/// Clears the RF22 Tx FIFO
/// Internal use only
void resetTxFifo();
/// This function will be called by handleInterrupt() if an RF22 external interrupt occurs.
/// This can only happen if external interrupts are enabled in the RF22
/// (which they are not by default).
/// Subclasses may override this function to get control when an RF22 external interrupt occurs.
virtual void handleExternalInterrupt();
/// This function will be called by handleInterrupt() if an RF22 wakeup timer interrupt occurs.
/// This can only happen if wakeup timer interrupts are enabled in the RF22
/// (which they are not by default).
/// Subclasses may override this function to get control when an RF22 wakeup timer interrupt occurs.
virtual void handleWakeupTimerInterrupt();
/// Sets the TO header to be sent in all subsequent messages
/// \param[in] to The new TO header value
void setHeaderTo(uint8_t to);
/// Sets the FROM header to be sent in all subsequent messages
/// \param[in] from The new FROM header value
void setHeaderFrom(uint8_t from);
/// Sets the ID header to be sent in all subsequent messages
/// \param[in] id The new ID header value
void setHeaderId(uint8_t id);
/// Sets the FLAGS header to be sent in all subsequent messages
/// \param[in] flags The new FLAGS header value
void setHeaderFlags(uint8_t flags);
/// Start the transmission of the contents
/// of the Tx buffer
void startTransmit();
/// ReStart the transmission of the contents
/// of the Tx buffer after a atransmission failure
void restartTransmit();
protected:
//GenericSPIClass* _spi;
/// Low level interrupt service routine for RF22 connected to interrupt 0
//static void isr0();
void isr0();
/// Low level interrupt service routine for RF22 connected to interrupt 1
//static void isr1();
private:
/// Array of instances connected to interrupts 0 and 1
//static RF22* _RF22ForInterrupt[];
volatile uint8_t _mode; // One of RF22_MODE_*
uint8_t _idleMode;
DigitalOut _slaveSelectPin;
SPI _spi;
InterruptIn _interrupt;
uint8_t _deviceType;
//DigitalOut led1;
//DigitalOut led2;
//DigitalOut led3;
//DigitalOut led4;
// These volatile members may get changed in the interrupt service routine
volatile uint8_t _bufLen;
uint8_t _buf[RF22_MAX_MESSAGE_LEN];
volatile boolean _rxBufValid;
volatile boolean _txPacketSent;
volatile uint8_t _txBufSentIndex;
volatile uint16_t _rxBad;
volatile uint16_t _rxGood;
volatile uint16_t _txGood;
volatile uint8_t _lastRssi;
};
/// @example rf22_client.pde
/// Client side of simple client/server pair using RF22 class
/// @example rf22_server.pde
/// Server side of simple client/server pair using RF22 class
/// @example rf22_datagram_client.pde
/// Client side of simple client/server pair using RF22Datagram class
/// @example rf22_datagram_server.pde
/// Server side of simple client/server pair using RF22Datagram class
/// @example rf22_reliable_datagram_client.pde
/// Client side of simple client/server pair using RF22ReliableDatagram class
/// @example rf22_reliable_datagram_server.pde
/// Server side of simple client/server pair using RF22ReliableDatagram class
/// @example rf22_router_client.pde
/// Client side of RF22Router network chain
/// @example rf22_router_server1.pde
/// Server node for RF22Router network chain
/// @example rf22_router_server2.pde
/// Server node for RF22Router network chain
/// @example rf22_router_server3.pde
/// Server node for RF22Router network chain
/// @example rf22_mesh_client.pde
/// Client side of RF22Mesh network chain
/// @example rf22_mesh_server1.pde
/// Server node for RF22Mesh network chain
/// @example rf22_mesh_server2.pde
/// Server node for RF22Mesh network chain
/// @example rf22_mesh_server3.pde
/// Server node for RF22Mesh network chain
/// @example rf22_test.pde
/// Test suite for RF22 library
/// @example rf22_snoop.pde
/// Capture and print RF22 packet from the air
/// @example rf22_specan.pde
/// Simple spectrum analyser using the RSSI measurements of the RF22
/// (see <a href="specan1.png">Sample output</a> showing a plot from 395.0MHz to 396.0MHz of a
/// signal generator at 395.5MHz amplitude modulated at 100% 1kHz)
///
/// @example IPGateway.pde
/// Sketch to provide an IP gateway for a set of RF22 radios (Datagram, ReliableDatagram, Router or Mesh)
/// Routes UDP messages from an internet connection using an Ethernet Shield and sends them
/// to a radio whose ID is based on the UDP port. Replies are sent back to the originating UDP
/// address and port
#endif