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RH_CC110.h
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RH_CC110.h
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// RH_CC110.h
//
// Definitions for Texas Instruments CC110L transceiver.
// http://www.ti.com/lit/ds/symlink/cc110l.pdf
// As used in Anaren CC110L Air Module BoosterPack
// https://www.anaren.com/air/cc110l-air-module-boosterpack-embedded-antenna-module-anaren
//
// Author: Mike McCauley (mikem@airspayce.com)
// Copyright (C) 2016 Mike McCauley
// $Id: RH_CC110.h,v 1.9 2020/01/05 07:02:23 mikem Exp $
//
#ifndef RH_CC110_h
#define RH_CC110_h
#include <RHNRFSPIDriver.h>
// This is the maximum number of interrupts the driver can support
// Most Arduinos can handle 2, Megas can handle more
#define RH_CC110_NUM_INTERRUPTS 3
// Max number of octets the FIFO can hold
#define RH_CC110_FIFO_SIZE 64
// This is the maximum number of bytes that can be carried by the chip
// We use some for headers, keeping fewer for RadioHead messages
#define RH_CC110_MAX_PAYLOAD_LEN RH_CC110_FIFO_SIZE
// The length of the headers we add.
// The headers are inside the chip payload
#define RH_CC110_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
#ifndef RH_CC110_MAX_MESSAGE_LEN
#define RH_CC110_MAX_MESSAGE_LEN (RH_CC110_MAX_PAYLOAD_LEN - RH_CC110_HEADER_LEN - 1)
#endif
#define RH_CC110_SPI_READ_MASK 0x80
#define RH_CC110_SPI_BURST_MASK 0x40
// Register definitions from Table 5-22
#define RH_CC110_REG_00_IOCFG2 0x00
#define RH_CC110_REG_01_IOCFG1 0x01
#define RH_CC110_REG_02_IOCFG0 0x02
#define RH_CC110_REG_03_FIFOTHR 0x03
#define RH_CC110_REG_04_SYNC1 0x04
#define RH_CC110_REG_05_SYNC0 0x05
#define RH_CC110_REG_06_PKTLEN 0x06
#define RH_CC110_REG_07_PKTCTRL1 0x07
#define RH_CC110_REG_08_PKTCTRL0 0x08
#define RH_CC110_REG_09_ADDR 0x09
#define RH_CC110_REG_0A_CHANNR 0x0a
#define RH_CC110_REG_0B_FSCTRL1 0x0b
#define RH_CC110_REG_0C_FSCTRL0 0x0c
#define RH_CC110_REG_0D_FREQ2 0x0d
#define RH_CC110_REG_0E_FREQ1 0x0e
#define RH_CC110_REG_0F_FREQ0 0x0f
#define RH_CC110_REG_10_MDMCFG4 0x10
#define RH_CC110_REG_11_MDMCFG3 0x11
#define RH_CC110_REG_12_MDMCFG2 0x12
#define RH_CC110_REG_13_MDMCFG1 0x13
#define RH_CC110_REG_14_MDMCFG0 0x14
#define RH_CC110_REG_15_DEVIATN 0x15
#define RH_CC110_REG_16_MCSM2 0x16
#define RH_CC110_REG_17_MCSM1 0x17
#define RH_CC110_REG_18_MCSM0 0x18
#define RH_CC110_REG_19_FOCCFG 0x19
#define RH_CC110_REG_1A_BSCFG 0x1a
#define RH_CC110_REG_1B_AGCCTRL2 0x1b
#define RH_CC110_REG_1C_AGCCTRL1 0x1c
#define RH_CC110_REG_1D_AGCCTRL0 0x1d
#define RH_CC110_REG_1E_WOREVT1 0x1e
#define RH_CC110_REG_1F_WOREVT0 0x1f
#define RH_CC110_REG_20_WORCTRL 0x20
#define RH_CC110_REG_21_FREND1 0x21
#define RH_CC110_REG_22_FREND0 0x22
#define RH_CC110_REG_23_FSCAL3 0x23
#define RH_CC110_REG_24_FSCAL2 0x24
#define RH_CC110_REG_25_FSCAL1 0x25
#define RH_CC110_REG_26_FSCAL0 0x26
#define RH_CC110_REG_27_RCCTRL1 0x28
#define RH_CC110_REG_28_RCCTRL0 0x29
#define RH_CC110_REG_29_FSTEST 0x2a
#define RH_CC110_REG_2A_PTEST 0x2b
#define RH_CC110_REG_2B_AGCTEST 0x2c
#define RH_CC110_REG_2C_TEST2 0x2c
#define RH_CC110_REG_2D_TEST1 0x2d
#define RH_CC110_REG_2E_TEST0 0x2e
// Single byte read and write version of registers 0x30 to 0x3f. Strobes
// use spiCommand()
#define RH_CC110_STROBE_30_SRES 0x30
#define RH_CC110_STROBE_31_SFSTXON 0x31
#define RH_CC110_STROBE_32_SXOFF 0x32
#define RH_CC110_STROBE_33_SCAL 0x33
#define RH_CC110_STROBE_34_SRX 0x34
#define RH_CC110_STROBE_35_STX 0x35
#define RH_CC110_STROBE_36_SIDLE 0x36
#define RH_CC110_STROBE_39_SPWD 0x39
#define RH_CC110_STROBE_3A_SFRX 0x3a
#define RH_CC110_STROBE_3B_SFTX 0x3b
#define RH_CC110_STROBE_3D_SNOP 0x3d
// Burst read from these registers gives more data:
// use spiBurstReadRegister()
#define RH_CC110_REG_30_PARTNUM 0x30
#define RH_CC110_REG_31_VERSION 0x31
#define RH_CC110_REG_32_FREQEST 0x32
#define RH_CC110_REG_33_CRC_REG 0x33
#define RH_CC110_REG_34_RSSI 0x34
#define RH_CC110_REG_35_MARCSTATE 0x35
#define RH_CC110_REG_38_PKTSTATUS 0x38
#define RH_CC110_REG_3A_TXBYTES 0x3a
#define RH_CC110_REG_3B_RXBYTES 0x3b
// PATABLE, TXFIFO, RXFIFO also support burst
#define RH_CC110_REG_3E_PATABLE 0x3e
#define RH_CC110_REG_3F_FIFO 0x3f
// Status Byte
#define RH_CC110_STATUS_CHIP_RDY 0x80
#define RH_CC110_STATUS_STATE 0x70
#define RH_CC110_STATUS_IDLE 0x00
#define RH_CC110_STATUS_RX 0x10
#define RH_CC110_STATUS_TX 0x20
#define RH_CC110_STATUS_FSTXON 0x30
#define RH_CC110_STATUS_CALIBRATE 0x40
#define RH_CC110_STATUS_SETTLING 0x50
#define RH_CC110_STATUS_RXFIFO_OVERFLOW 0x60
#define RH_CC110_STATUS_TXFIFO_UNDERFLOW 0x70
#define RH_CC110_STATUS_FIFOBYTES_AVAILABLE 0x0f
// Register contents
// Chip Status Byte, read from header, data or command strobe
#define RH_CC110_CHIP_RDY 0x80
#define RH_CC110_STATE 0x70
#define RH_CC110_FIFO_BYTES_AVAILABLE 0x0f
// Register bit field definitions
// #define RH_CC110_REG_00_IOCFG2 0x00
// #define RH_CC110_REG_01_IOCFG1 0x01
// #define RH_CC110_REG_02_IOCFG0 0x02
#define RH_CC110_GDO_CFG_RX_FIFO_THR 0x00
#define RH_CC110_GDO_CFG_RX_FIFO_FULL 0x01
#define RH_CC110_GDO_CFG_TX_FIFO_THR 0x02
#define RH_CC110_GDO_CFG_TX_FIFO_EMPTY 0x03
#define RH_CC110_GDO_CFG_RX_FIFO_OVERFLOW 0x04
#define RH_CC110_GDO_CFG_TX_FIFO_UNDEFLOOW 0x05
#define RH_CC110_GDO_CFG_SYNC 0x06
#define RH_CC110_GDO_CFG_CRC_OK_AUTORESET 0x07
#define RH_CC110_GDO_CFG_CCA 0x09
#define RH_CC110_GDO_CFG_LOCK_DETECT 0x0a
#define RH_CC110_GDO_CFG_SERIAL_CLOCK 0x0b
#define RH_CC110_GDO_CFG_SYNCHRONOUS_SDO 0x0c
#define RH_CC110_GDO_CFG_SDO 0x0d
#define RH_CC110_GDO_CFG_CARRIER 0x0e
#define RH_CC110_GDO_CFG_CRC_OK 0x0f
#define RH_CC110_GDO_CFG_PA_PD 0x1b
#define RH_CC110_GDO_CFG_LNA_PD 0x1c
#define RH_CC110_GDO_CFG_CLK_32K 0x27
#define RH_CC110_GDO_CFG_CHIP_RDYN 0x29
#define RH_CC110_GDO_CFG_XOSC_STABLE 0x2b
#define RH_CC110_GDO_CFG_HIGH_IMPEDANCE 0x2e
#define RH_CC110_GDO_CFG_0 0x2f
#define RH_CC110_GDO_CFG_CLK_XOSC_DIV_1 0x30
#define RH_CC110_GDO_CFG_CLK_XOSC_DIV_1_5 0x31
#define RH_CC110_GDO_CFG_CLK_XOSC_DIV_2 0x32
#define RH_CC110_GDO_CFG_CLK_XOSC_DIV_3 0x33
#define RH_CC110_GDO_CFG_CLK_XOSC_DIV_4 0x34
#define RH_CC110_GDO_CFG_CLK_XOSC_DIV_6 0x35
#define RH_CC110_GDO_CFG_CLK_XOSC_DIV_8 0x36
#define RH_CC110_GDO_CFG_CLK_XOSC_DIV_12 0x37
#define RH_CC110_GDO_CFG_CLK_XOSC_DIV_16 0x38
#define RH_CC110_GDO_CFG_CLK_XOSC_DIV_24 0x39
#define RH_CC110_GDO_CFG_CLK_XOSC_DIV_32 0x3a
#define RH_CC110_GDO_CFG_CLK_XOSC_DIV_48 0x3b
#define RH_CC110_GDO_CFG_CLK_XOSC_DIV_64 0x3c
#define RH_CC110_GDO_CFG_CLK_XOSC_DIV_96 0x3d
#define RH_CC110_GDO_CFG_CLK_XOSC_DIV_128 0x3e
#define RH_CC110_GDO_CFG_CLK_XOSC_DIV_192 0x3f
// #define RH_CC110_REG_03_FIFOTHR 0x03
#define RH_CC110_ADC_RETENTION 0x80
#define RH_CC110_CLOSE_IN_RX 0x30
#define RH_CC110_CLOSE_IN_RX_0DB 0x00
#define RH_CC110_CLOSE_IN_RX_6DB 0x10
#define RH_CC110_CLOSE_IN_RX_12DB 0x20
#define RH_CC110_CLOSE_IN_RX_18DB 0x30
#define RH_CC110_FIFO_THR 0x0f
// #define RH_CC110_REG_04_SYNC1 0x04
// #define RH_CC110_REG_05_SYNC0 0x05
// #define RH_CC110_REG_06_PKTLEN 0x06
// #define RH_CC110_REG_07_PKTCTRL1 0x07
#define RH_CC110_CRC_AUTOFLUSH 0x08
#define RH_CC110_APPEND_STATUS 0x04
#define RH_CC110_ADDR_CHK 0x03
// can or the next 2:
#define RH_CC110_ADDR_CHK_ADDRESS 0x01
#define RH_CC110_ADDR_CHK_BROADCAST 0x02
// #define RH_CC110_REG_08_PKTCTRL0 0x08
#define RH_CC110_PKT_FORMAT 0x30
#define RH_CC110_PKT_FORMAT_NORMAL 0x00
#define RH_CC110_PKT_FORMAT_SYNC_SERIAL 0x10
#define RH_CC110_PKT_FORMAT_RANDOM_TX 0x20
#define RH_CC110_PKT_FORMAT_ASYNC_SERIAL 0x30
#define RH_CC110_CRC_EN 0x04
#define RH_CC110_LENGTH_CONFIG 0x03
#define RH_CC110_LENGTH_CONFIG_FIXED 0x00
#define RH_CC110_LENGTH_CONFIG_VARIABLE 0x01
#define RH_CC110_LENGTH_CONFIG_INFINITE 0x02
// #define RH_CC110_REG_09_ADDR 0x09
// #define RH_CC110_REG_0A_CHANNR 0x0a
// #define RH_CC110_REG_0B_FSCTRL1 0x0b
// #define RH_CC110_REG_0C_FSCTRL0 0x0c
// #define RH_CC110_REG_0D_FREQ2 0x0d
// #define RH_CC110_REG_0E_FREQ1 0x0e
// #define RH_CC110_REG_0F_FREQ0 0x0f
// #define RH_CC110_REG_10_MDMCFG4 0x10
#define RH_CC110_CHANBW_E 0xc0
#define RH_CC110_CHANBW_M 0x30
#define RH_CC110_DRATE_E 0x0f
// #define RH_CC110_REG_11_MDMCFG3 0x11
// #define RH_CC110_REG_12_MDMCFG2 0x12
#define RH_CC110_DEM_DCFILT_OFF 0x80
#define RH_CC110_MOD_FORMAT 0x70
#define RH_CC110_MOD_FORMAT_2FSK 0x00
#define RH_CC110_MOD_FORMAT_GFSK 0x10
#define RH_CC110_MOD_FORMAT_OOK 0x30
#define RH_CC110_MOD_FORMAT_4FSK 0x40
#define RH_CC110_MANCHESTER_EN 0x08
#define RH_CC110_SYNC_MODE 0x07
#define RH_CC110_SYNC_MODE_NONE 0x00
#define RH_CC110_SYNC_MODE_15_16 0x01
#define RH_CC110_SYNC_MODE_16_16 0x02
#define RH_CC110_SYNC_MODE_30_32 0x03
#define RH_CC110_SYNC_MODE_NONE_CARRIER 0x04
#define RH_CC110_SYNC_MODE_15_16_CARRIER 0x05
#define RH_CC110_SYNC_MODE_16_16_CARRIER 0x06
#define RH_CC110_SYNC_MODE_30_32_CARRIER 0x07
// #define RH_CC110_REG_13_MDMCFG1 0x13
#define RH_CC110_NUM_PREAMBLE 0x70
#define RH_CC110_NUM_PREAMBLE_2 0x00
#define RH_CC110_NUM_PREAMBLE_3 0x10
#define RH_CC110_NUM_PREAMBLE_4 0x20
#define RH_CC110_NUM_PREAMBLE_6 0x30
#define RH_CC110_NUM_PREAMBLE_8 0x40
#define RH_CC110_NUM_PREAMBLE_12 0x50
#define RH_CC110_NUM_PREAMBLE_16 0x60
#define RH_CC110_NUM_PREAMBLE_24 0x70
#define RH_CC110_CHANSPC_E 0x03
// #define RH_CC110_REG_14_MDMCFG0 0x14
// #define RH_CC110_REG_15_DEVIATN 0x15
#define RH_CC110_DEVIATION_E 0x70
#define RH_CC110_DEVIATION_M 0x07
// #define RH_CC110_REG_16_MCSM2 0x16
#define RH_CC110_RX_TIME_RSSI 0x10
// #define RH_CC110_REG_17_MCSM1 0x17
#define RH_CC110_CCA_MODE 0x30
#define RH_CC110_CCA_MODE_ALWAYS 0x00
#define RH_CC110_CCA_MODE_RSSI 0x10
#define RH_CC110_CCA_MODE_PACKET 0x20
#define RH_CC110_CCA_MODE_RSSI_PACKET 0x30
#define RH_CC110_RXOFF_MODE 0x0c
#define RH_CC110_RXOFF_MODE_IDLE 0x00
#define RH_CC110_RXOFF_MODE_FSTXON 0x04
#define RH_CC110_RXOFF_MODE_TX 0x08
#define RH_CC110_RXOFF_MODE_RX 0x0c
#define RH_CC110_TXOFF_MODE 0x03
#define RH_CC110_TXOFF_MODE_IDLE 0x00
#define RH_CC110_TXOFF_MODE_FSTXON 0x01
#define RH_CC110_TXOFF_MODE_TX 0x02
#define RH_CC110_TXOFF_MODE_RX 0x03
// #define RH_CC110_REG_18_MCSM0 0x18
#define RH_CC110_FS_AUTOCAL 0x30
#define RH_CC110_FS_AUTOCAL_NEVER 0x00
#define RH_CC110_FS_AUTOCAL_FROM_IDLE 0x10
#define RH_CC110_FS_AUTOCAL_TO_IDLE 0x20
#define RH_CC110_FS_AUTOCAL_TO_IDLE_4 0x30
#define RH_CC110_PO_TIMEOUT 0x0c
#define RH_CC110_PO_TIMEOUT_1 0x00
#define RH_CC110_PO_TIMEOUT_16 0x04
#define RH_CC110_PO_TIMEOUT_64 0x08
#define RH_CC110_PO_TIMEOUT_256 0x0c
#define RH_CC110_XOSC_FORCE_ON 0x01
// #define RH_CC110_REG_19_FOCCFG 0x19
#define RH_CC110_FOC_BS_CS_GATE 0x20
#define RH_CC110_FOC_PRE_K 0x18
#define RH_CC110_FOC_PRE_K_0 0x00
#define RH_CC110_FOC_PRE_K_1 0x08
#define RH_CC110_FOC_PRE_K_2 0x10
#define RH_CC110_FOC_PRE_K_3 0x18
#define RH_CC110_FOC_POST_K 0x04
#define RH_CC110_FOC_LIMIT 0x03
#define RH_CC110_FOC_LIMIT_0 0x00
#define RH_CC110_FOC_LIMIT_8 0x01
#define RH_CC110_FOC_LIMIT_4 0x02
#define RH_CC110_FOC_LIMIT_2 0x03
// #define RH_CC110_REG_1A_BSCFG 0x1a
#define RH_CC110_BS_PRE_K 0xc0
#define RH_CC110_BS_PRE_K_1 0x00
#define RH_CC110_BS_PRE_K_2 0x40
#define RH_CC110_BS_PRE_K_3 0x80
#define RH_CC110_BS_PRE_K_4 0xc0
#define RH_CC110_BS_PRE_KP 0x30
#define RH_CC110_BS_PRE_KP_1 0x00
#define RH_CC110_BS_PRE_KP_2 0x10
#define RH_CC110_BS_PRE_KP_3 0x20
#define RH_CC110_BS_PRE_KP_4 0x30
#define RH_CC110_BS_POST_KI 0x08
#define RH_CC110_BS_POST_KP 0x04
#define RH_CC110_BS_LIMIT 0x03
#define RH_CC110_BS_LIMIT_0 0x00
#define RH_CC110_BS_LIMIT_3 0x01
#define RH_CC110_BS_LIMIT_6 0x02
#define RH_CC110_BS_LIMIT_12 0x03
// #define RH_CC110_REG_1B_AGCCTRL2 0x1b
#define RH_CC110_MAX_DVA_GAIN 0xc0
#define RH_CC110_MAX_DVA_GAIN_ALL 0x00
#define RH_CC110_MAX_DVA_GAIN_ALL_LESS_1 0x40
#define RH_CC110_MAX_DVA_GAIN_ALL_LESS_2 0x80
#define RH_CC110_MAX_DVA_GAIN_ALL_LESS_3 0xc0
#define RH_CC110_MAX_LNA_GAIN 0x38
#define RH_CC110_MAGN_TARGET 0x07
#define RH_CC110_MAGN_TARGET_24DB 0x00
#define RH_CC110_MAGN_TARGET_27DB 0x01
#define RH_CC110_MAGN_TARGET_30DB 0x02
#define RH_CC110_MAGN_TARGET_33DB 0x03
#define RH_CC110_MAGN_TARGET_36DB 0x04
#define RH_CC110_MAGN_TARGET_38DB 0x05
#define RH_CC110_MAGN_TARGET_40DB 0x06
#define RH_CC110_MAGN_TARGET_42DB 0x07
// #define RH_CC110_REG_1C_AGCCTRL1 0x1c
#define RH_CC110_AGC_LNA_PRIORITY 0x40
#define RH_CC110_CARRIER_SENSE_REL_THR 0x30
#define RH_CC110_CARRIER_SENSE_REL_THR_0DB 0x00
#define RH_CC110_CARRIER_SENSE_REL_THR_6DB 0x10
#define RH_CC110_CARRIER_SENSE_REL_THR_10DB 0x20
#define RH_CC110_CARRIER_SENSE_REL_THR_14DB 0x30
#define RH_CC110_CARRIER_SENSE_ABS_THR 0x0f
// #define RH_CC110_REG_1D_AGCCTRL0 0x1d
#define RH_CC110_HYST_LEVEL 0xc0
#define RH_CC110_HYST_LEVEL_NONE 0x00
#define RH_CC110_HYST_LEVEL_LOW 0x40
#define RH_CC110_HYST_LEVEL_MEDIUM 0x80
#define RH_CC110_HYST_LEVEL_HIGH 0xc0
#define RH_CC110_WAIT_TIME 0x30
#define RH_CC110_WAIT_TIME_8 0x00
#define RH_CC110_WAIT_TIME_16 0x10
#define RH_CC110_WAIT_TIME_24 0x20
#define RH_CC110_WAIT_TIME_32 0x30
#define RH_CC110_AGC_FREEZE 0x0c
#define RH_CC110_AGC_FILTER_LENGTH 0x03
#define RH_CC110_AGC_FILTER_LENGTH_8 0x00
#define RH_CC110_AGC_FILTER_LENGTH_16 0x01
#define RH_CC110_AGC_FILTER_LENGTH_32 0x02
#define RH_CC110_AGC_FILTER_LENGTH_64 0x03
// #define RH_CC110_REG_1E_WOREVT1 0x1e
// #define RH_CC110_REG_1F_WOREVT0 0x1f
// #define RH_CC110_REG_20_WORCTRL 0x20
// #define RH_CC110_REG_21_FREND1 0x21
#define RH_CC110_LNA_CURRENT 0xc0
#define RH_CC110_LNA2MIX_CURRENT 0x30
#define RH_CC110_LODIV_BUF_CURRENT_RX 0x0c
#define RH_CC110_MIX_CURRENT 0x03
// #define RH_CC110_REG_22_FREND0 0x22
#define RH_CC110_LODIV_BUF_CURRENT_TX 0x30
#define RH_CC110_PA_POWER 0x07
// #define RH_CC110_REG_23_FSCAL3 0x23
#define RH_CC110_FSCAL3_7_6 0xc0
#define RH_CC110_CHP_CURR_CAL_EN 0x30
#define RH_CC110_FSCAL3_3_0 0x0f
// #define RH_CC110_REG_24_FSCAL2 0x24
#define RH_CC110_VCO_CORE_H_EN 0x20
#define RH_CC110_FSCAL2 0x1f
// #define RH_CC110_REG_25_FSCAL1 0x25
#define RH_CC110_FSCAL1 0x3f
// #define RH_CC110_REG_26_FSCAL0 0x26
#define RH_CC110_FSCAL0 0x7f
// #define RH_CC110_REG_27_RCCTRL1 0x28
// #define RH_CC110_REG_28_RCCTRL0 0x29
// #define RH_CC110_REG_29_FSTEST 0x2a
// #define RH_CC110_REG_2A_PTEST 0x2b
// #define RH_CC110_REG_2B_AGCTEST 0x2c
// #define RH_CC110_REG_2C_TEST2 0x2c
// #define RH_CC110_REG_2D_TEST1 0x2d
// #define RH_CC110_REG_2E_TEST0 0x2e
#define RH_CC110_TEST0_7_2 0xfc
#define RH_CC110_VCO_SEL_CAL_EN 0x02
#define RH_CC110_TEST0_0 0x01
// #define RH_CC110_REG_30_PARTNUM 0x30
// #define RH_CC110_REG_31_VERSION 0x31
// #define RH_CC110_REG_32_FREQEST 0x32
// #define RH_CC110_REG_33_CRC_REG 0x33
#define RH_CC110_CRC_REG_CRC_OK 0x80
// #define RH_CC110_REG_34_RSSI 0x34
// #define RH_CC110_REG_35_MARCSTATE 0x35
#define RH_CC110_MARC_STATE 0x1f
#define RH_CC110_MARC_STATE_SLEEP 0x00
#define RH_CC110_MARC_STATE_IDLE 0x01
#define RH_CC110_MARC_STATE_XOFF 0x02
#define RH_CC110_MARC_STATE_VCOON_MC 0x03
#define RH_CC110_MARC_STATE_REGON_MC 0x04
#define RH_CC110_MARC_STATE_MANCAL 0x05
#define RH_CC110_MARC_STATE_VCOON 0x06
#define RH_CC110_MARC_STATE_REGON 0x07
#define RH_CC110_MARC_STATE_STARTCAL 0x08
#define RH_CC110_MARC_STATE_BWBOOST 0x09
#define RH_CC110_MARC_STATE_FS_LOCK 0x0a
#define RH_CC110_MARC_STATE_IFADCON 0x0b
#define RH_CC110_MARC_STATE_ENDCAL 0x0c
#define RH_CC110_MARC_STATE_RX 0x0d
#define RH_CC110_MARC_STATE_RX_END 0x0e
#define RH_CC110_MARC_STATE_RX_RST 0x0f
#define RH_CC110_MARC_STATE_TXRX_SWITCH 0x10
#define RH_CC110_MARC_STATE_RXFIFO_OVERFLOW 0x11
#define RH_CC110_MARC_STATE_FSTXON 0x12
#define RH_CC110_MARC_STATE_TX 0x13
#define RH_CC110_MARC_STATE_TX_END 0x14
#define RH_CC110_MARC_STATE_RXTX_SWITCH 0x15
#define RH_CC110_MARC_STATE_TXFIFO_UNDERFLOW 0x16
// #define RH_CC110_REG_38_PKTSTATUS 0x38
#define RH_CC110_PKTSTATUS_CRC_OK 0x80
#define RH_CC110_PKTSTATUS_CS 0x40
#define RH_CC110_PKTSTATUS_CCA 0x10
#define RH_CC110_PKTSTATUS_SFD 0x08
#define RH_CC110_PKTSTATUS_GDO2 0x04
#define RH_CC110_PKTSTATUS_GDO0 0x01
// #define RH_CC110_REG_3A_TXBYTES 0x3a
#define RH_CC110_TXFIFO_UNDERFLOW 0x80
#define RH_CC110_NUM_TXBYTES 0x7f
// #define RH_CC110_REG_3B_RXBYTES 0x3b
#define RH_CC110_RXFIFO_UNDERFLOW 0x80
#define RH_CC110_NUM_RXBYTES 0x7f
/////////////////////////////////////////////////////////////////////
/// \class RH_CC110 RH_CC110.h <RH_CC110.h>
/// \brief Send and receive unaddressed, unreliable, datagrams by Texas Instruments CC110L and compatible transceivers and modules.
///
/// The TI CC110L is a low cost tranceiver chip capable of 300 to 928MHz and with a wide range of modulation types and speeds.
/// The chip is typically provided on a module that also includes the antenna and coupling hardware
/// and is therefore capable of a more restricted frequency range.
///
/// Supported modules include:
/// - Anaren AIR BoosterPack 430BOOST-CC110L
///
/// This base class provides basic functions for sending and receiving unaddressed, unreliable datagrams
/// of arbitrary length to 59 octets per packet at a selected data rate and modulation type.
/// Use one of the Manager classes to get addressing and
/// acknowledgement reliability, routing, meshes etc.
///
/// Naturally, for any 2 radios to communicate that must be configured to use the same frequency and
/// data rate, and with identical network addresses.
///
/// Several CC110L modules can be connected to an Arduino, permitting the construction of translators
/// and frequency changers, etc.
///
/// Several GFSK modulation schemes are provided and may be selected by calling setModemConfig(). No FSK or OOK
/// modulation schemes are provided though the implementor may configure the mnodem characteristics directly
/// by calling setModemRegisters().
///
/// Implementation based on:
/// http://www.ti.com/lit/ds/symlink/cc110l.pdf
/// and
/// https://www.anaren.com/air/cc110l-air-module-boosterpack-embedded-antenna-module-anaren
///
/// \par Crystal Frequency
///
/// Modules based on the CC110L may contain a crystal oscillator with one of 2 possible frequencies: 26MHz or 27MHz.
/// A number of radio configuration parameters (including carrier frequency and data rates) depend on the
/// crystal oscillator frequency. The chip has no knowledge of the frequency, so it is up to the implementer
/// to tell the driver the oscillator frequency by passing in the appropriate value of is27MHz to the constructor (default 26MHz)
/// or by calling setIs27MHz() before calling init().
/// Failure to correctly set this flag will cause incorrect frequency and modulation
/// characteristics to be used.
///
/// Caution: it is not easy to determine what the actual crystal frequency is on some modules. For example,
/// the documentation for the Anaren BoosterPack indictes a 26MHz crystal, but measurements on the devices delivered here
/// indicate a 27MHz crystal is actually installed. TI recommend 27MHz for
///
/// \par Packet Format
///
/// - 2 octets sync (a configurable network address)
/// - 1 octet message length
/// - 4 to 63 octets of payload consisting of:
/// - 1 octet TO header
/// - 1 octet FROM header
/// - 1 octet ID header
/// - 1 octet FLAGS header
/// - 0 to 59 octets of user message
/// - 2 octets CRC
///
/// \par Connecting CC110L to Arduino
///
/// Warning: the CC110L is a 3.3V part, and exposing it to 5V on any pin will damage it. Ensure you are using a 3.3V
/// MCU or use level shifters. We tested with Teensy 3.1.
///
/// The electrical connection between a CC110L module and the Arduino or other processor
/// require 3.3V, the 3 x SPI pins (SCK, SDI, SDO),
/// a Chip Select pin and an Interrupt pin.
/// Examples below assume the Anaren BoosterPack. Caution: the pin numbering on the Anaren BoosterPack
/// is a bit counter-intuitive: the direction of number on J1 is the reverse of J2. Check the pin numbers
/// stenciled on the front of the board to be sure.
///
/// \code
/// Teensy 3.1 CC110L pin name Anaren BoosterPack pin
/// 3.3V---------VDD (3.3V in) J1-1
/// SS pin D10----------CSn (chip select in) J2-8
/// SCK pin D13----------SCLK (SPI clock in) J1-7
/// MOSI pin D11----------MOSI (SPI data in) J2-5
/// MISO pin D12----------MISO (SPI data out) J2-4
/// D2-----------GDO0 (Interrupt output) J2-9
/// GND----------GND (ground in) J2-10
/// \endcode
/// and use the default RH_CC110 constructor. You can use other pins by passing the appropriate arguments
/// to the RH_CC110 constructor, depending on what your MCU supports.
///
/// For the Particle Photon:
/// \code
/// Photon CC110L pin name Anaren BoosterPack pin
/// 3.3V---------VDD (3.3V in) J1-1
/// SS pin A2-----------CSn (chip select in) J2-8
/// SCK pin A3-----------SCLK (SPI clock in) J1-7
/// MOSI pin A5-----------MOSI (SPI data in) J2-5
/// MISO pin A4-----------MISO (SPI data out) J2-4
/// D2-----------GDO0 (Interrupt output) J2-9
/// GND----------GND (ground in) J2-10
/// \endcode
/// and use the default RH_CC110 constructor. You can use other pins by passing the appropriate arguments
/// to the RH_CC110 constructor, depending on what your MCU supports.
///
/// \par Example programs
///
/// Several example programs are provided.
///
/// \par Radio operating strategy and defaults
///
/// The radio is enabled at all times and switched between RX, TX and IDLE modes.
/// When RX is enabled (by calling available() or setModeRx()) the radio will stay in RX mode until a
/// valid CRC correct message addressed to thiis node is received, when it will transition to IDLE.
/// When TX is enabled (by calling send()) it will stay in TX mode until the message has ben sent
/// and waitPacketSent() is called when it wil transition to IDLE
///(this radio has no 'packet sent' interrupt that could be used, so polling
/// with waitPacketSent() is required
///
/// The modulation schemes supported include the GFSK schemes provided by default in the TI SmartRF Suite.
/// This software allows you to get the correct register values for diferent modulation schemes. All the modulation
/// schemes prvided in the driver are based on the recommended register values given by SmartRF.
/// Other schemes such a 2-FSK, 4-FSK and OOK are suported by the chip, but canned configurations are not provided with this driver.
/// The implementer may choose to create their own modem configurations and pass them to setModemRegisters().
///
class RH_CC110 : public RHNRFSPIDriver
{
public:
/// \brief Defines register configuration values for a desired modulation
///
/// Defines values for various configuration fields and registers to
/// achieve a desired modulation speed and frequency deviation.
typedef struct
{
uint8_t reg_0b; ///< RH_CC110_REG_0B_FSCTRL1
uint8_t reg_0c; ///< RH_CC110_REG_0C_FSCTRL0
uint8_t reg_10; ///< RH_CC110_REG_10_MDMCFG4
uint8_t reg_11; ///< RH_CC110_REG_11_MDMCFG3
uint8_t reg_12; ///< RH_CC110_REG_12_MDMCFG2
uint8_t reg_15; ///< RH_CC110_REG_15_DEVIATN
uint8_t reg_19; ///< RH_CC110_REG_19_FOCCFG
uint8_t reg_1a; ///< RH_CC110_REG_1A_BSCFG
uint8_t reg_1b; ///< RH_CC110_REG_1B_AGCCTRL2
uint8_t reg_1c; ///< RH_CC110_REG_1C_AGCCTRL1
uint8_t reg_1d; ///< RH_CC110_REG_1D_AGCCTRL0
uint8_t reg_21; ///< RH_CC110_REG_21_FREND1
uint8_t reg_22; ///< RH_CC110_REG_22_FREND0
uint8_t reg_23; ///< RH_CC110_REG_23_FSCAL3
uint8_t reg_24; ///< RH_CC110_REG_24_FSCAL2
uint8_t reg_25; ///< RH_CC110_REG_25_FSCAL1
uint8_t reg_26; ///< RH_CC110_REG_26_FSCAL0
uint8_t reg_2c; ///< RH_CC110_REG_2C_TEST2
uint8_t reg_2d; ///< RH_CC110_REG_2D_TEST1
uint8_t reg_2e; ///< RH_CC110_REG_2E_TEST0
} 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 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).
/// All configs use SYNC_MODE = RH_CC110_SYNC_MODE_16_16 (2 byte sync)
typedef enum
{
GFSK_Rb1_2Fd5_2 = 0, ///< GFSK, Data Rate: 1.2kBaud, Dev: 5.2kHz, RX BW 58kHz, optimised for sensitivity
GFSK_Rb2_4Fd5_2, ///< GFSK, Data Rate: 2.4kBaud, Dev: 5.2kHz, RX BW 58kHz, optimised for sensitivity
GFSK_Rb4_8Fd25_4, ///< GFSK, Data Rate: 4.8kBaud, Dev: 25.4kHz, RX BW 100kHz, optimised for sensitivity
GFSK_Rb10Fd19, ///< GFSK, Data Rate: 10kBaud, Dev: 19kHz, RX BW 100kHz, optimised for sensitivity
GFSK_Rb38_4Fd20, ///< GFSK, Data Rate: 38.4kBaud, Dev: 20kHz, RX BW 100kHz, optimised for sensitivity
GFSK_Rb76_8Fd32, ///< GFSK, Data Rate: 76.8kBaud, Dev: 32kHz, RX BW 232kHz, optimised for sensitivity
GFSK_Rb100Fd47, ///< GFSK, Data Rate: 100kBaud, Dev: 47kHz, RX BW 325kHz, optimised for sensitivity
GFSK_Rb250Fd127, ///< GFSK, Data Rate: 250kBaud, Dev: 127kHz, RX BW 540kHz, optimised for sensitivity
} ModemConfigChoice;
/// These power outputs are based on the suggested optimum values for
/// multilayer inductors in the 915MHz frequency band. Per table 5-15.
/// Caution: these enum values are indexes into PaPowerValues.
/// Do not change one without changing the other. Use the symbolic names, not the integer values
typedef enum
{
TransmitPowerM30dBm = 0, ///< -30dBm
TransmitPowerM20dBm, ///< -20dBm
TransmitPowerM15dBm, ///< -15dBm
TransmitPowerM10dBm, ///< -10dBm
TransmitPower0dBm, ///< 0dBm
TransmitPower5dBm, ///< 5dBm
TransmitPower7dBm, ///< 7dBm
TransmitPower10dBm, ///< 10dBm
} TransmitPower;
/// 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 CC110L 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 CC110L GDO0 interrupt line.
/// Defaults to pin 2.
/// 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] is27MHz Set to true if your CC110 is equipped with a 27MHz crystal oscillator. Defaults to false.
/// \param[in] spi Pointer to the SPI interface object to use.
/// Defaults to the standard Arduino hardware SPI interface
RH_CC110(uint8_t slaveSelectPin = SS, uint8_t interruptPin = 2, bool is27MHz = false, RHGenericSPI& spi = hardware_spi);
/// Initialise the Driver transport hardware and software.
/// Make sure the Driver is properly configured before calling init().
/// In particular, ensure you have called setIs27MHz(true) if your module has a 27MHz crystal oscillator.
/// After init(), the following default characteristics are set:
/// TxPower: TransmitPower5dBm
/// Frequency: 915.0
/// Modulation: GFSK_Rb1_2Fd5_2 (GFSK, Data Rate: 1.2kBaud, Dev: 5.2kHz, RX BW 58kHz, optimised for sensitivity)
/// Sync Words: 0xd3, 0x91
/// \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();
/// Blocks until the current message (if any)
/// has been transmitted
/// \return true on success, false if the chip is not in transmit mode or other transmit failure
virtual bool waitPacketSent();
/// 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 will be returned to RHModeIdle
/// and available() will return true.
/// 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 (after wiaint gor any currenly transmitting message to complete).
/// 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. The message cannot be retreived again.
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);
/// Returns the maximum message length
/// available in this Driver.
/// \return The maximum legal message length
virtual uint8_t maxMessageLength();
/// If current mode is Sleep, 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. The radio will stay in Rx mode until a CRC correct message addressed to this node
/// is received, or the ode is changed to Tx, Idle or Sleep.
void setModeRx();
/// If current mode is Rx or Idle, changes it to Tx.
/// Starts the transmitter sending the current message.
void setModeTx();
/// Sets the radio into low-power sleep mode.
/// If successful, the transport will stay in sleep mode until woken by
/// changing mode to 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.
/// Caution: waking up from sleep loses values from registers 0x29 through 0x2e
/// \return true if sleep mode was successfully entered.
virtual bool sleep();
/// Set the Power Amplifier power setting.
/// The PaTable settings are based on are based on the suggested optimum values for
/// multilayer inductors in the 915MHz frequency band. Per table 5-15.
/// If these values are not suitable, use setPaTable() directly.
/// Caution: be a good neighbour and use the lowest power setting compatible with your application.
/// Caution: Permissable power settings for your area may depend on frequency and modulation characteristics:
/// consult local authorities.
/// param[in] power One of TransmitPower enum values
bool setTxPower(TransmitPower power);
/// Indicates the presence of 27MHz crystal oscillator.
/// You must indicate to the driver if your CC110L is equipped with a 27MHz crystal oscillator (26MHz is the default
/// in the constructor).
/// This should be called before calling init() if you have a 27MHz crystal.
/// It can be called after calling init() but you must reset the frequency (with setFrequency()) and modulation
/// (with setModemConfig()) afterwards.
/// \param[in] is27MHz Pass true if the CC110L has a 27MHz crystal (default is true).
void setIs27MHz(bool is27MHz = true);
/// Sets the transmitter and receiver
/// centre frequency.
/// Caution: permissable frequency bands will depend on you country and area: consult local authorities.
/// \param[in] centre Frequency in MHz. 300.0 to 928.0
/// \return true if the selected frquency centre is within range
bool setFrequency(float centre);
/// Sets all the registers required to configure the data modem in the CC110, 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.
bool setModemConfig(ModemConfigChoice index);
/// Sets the sync words for transmit and receive in registers RH_CC110_REG_04_SYNC1 and RH_CC110_REG_05_SYNC0.
/// Caution: SyncWords should be set to the same
/// value on all nodes in your network. Nodes with different SyncWords set will never receive
/// each others messages, so different SyncWords can be used to isolate different
/// networks from each other. Default is { 0xd3, 0x91 }.
/// \param[in] syncWords Array of sync words, 2 octets long
/// \param[in] len Number of sync words to set. MUST be 2.
void setSyncWords(const uint8_t* syncWords, uint8_t len);
/// Sets the PaTable registers directly.
/// Ensure you use suitable PATABLE values per Tbale 5-15 or 5-16
/// You may need to do this to implement an OOK modulation scheme.
void setPaTable(uint8_t* patable, uint8_t patablesize);
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();
/// Reads a single register from the CC110L
/// \param[in] reg Register number, one of RH_CC110_REG
/// \return The value of the register
uint8_t spiReadRegister(uint8_t reg);
/// Reads a single register in burst mode.
/// On the CC110L, some registers yield different data when read in burst mode
/// as opposed to single byte mode.
/// \param[in] reg Register number, one of RH_CC110_REG (burst mode readable)
/// \return The value of the register after a burst read
uint8_t spiBurstReadRegister(uint8_t reg);
/// Writes to a single single register on the CC110L
/// \param[in] reg Register number, one of RH_CC110L_REG_*
/// \param[in] val The value to write
/// \return returns the chip status byte per table 5.2
uint8_t spiWriteRegister(uint8_t reg, uint8_t val);
/// Write a number of bytes to a burst capable register
/// \param[in] reg Register number of the first register, one of RH_CC110L_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
/// \return the chip status byte per table 5.2
uint8_t spiBurstWriteRegister(uint8_t reg, const uint8_t* src, uint8_t len);
/// Examine the receive buffer to determine whether the message is for this node
/// Sets _rxBufValid.
void validateRxBuf();
/// Clear our local receive buffer
void clearRxBuf();
/// Reads and returns the status byte by issuing the SNOP strobe
/// \return The value of the status byte per Table 5-2
uint8_t statusRead();
/// Handle the TX or RX overflow state of the given status
/// \param status The status byte read from the last SPI command
/// \return void
void handleOverFlows(uint8_t status);
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_CC110* _deviceForInterrupt[];
/// Index of next interrupt number to use in _deviceForInterrupt
static uint8_t _interruptCount;
/// The configured interrupt pin connected to this instance
uint8_t _interruptPin;
/// 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_CC110_MAX_PAYLOAD_LEN];
/// True when there is a valid message in the buffer
volatile bool _rxBufValid;
/// True if crystal oscillator is 26 MHz, not 26MHz.
bool _is27MHz;
};
/// @example cc110_client.pde
/// @example cc110_server.pde
#endif