amiro-lld / include / DW1000 / v0 / deca_instance.h @ b6364b51
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/*! ----------------------------------------------------------------------------
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* @file instance.h
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* @brief DecaWave header for application level instance
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*
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* @attention
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*
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* Copyright 2015 (c) DecaWave Ltd, Dublin, Ireland.
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*
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* All rights reserved.
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*
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* @author DecaWave
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*/
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#ifndef DECAINSTANCE_H
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#define DECAINSTANCE_H
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#include <amiro-lld.h> |
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#if defined(AMIROLLD_CFG_USE_DW1000) || defined(__DOXYGEN__)
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#include <alld_dw1000.h> |
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#ifdef __cplusplus
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extern "C" { |
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#endif
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/******************************************************************************************************************
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********************* NOTES on TREK compile/build time features/options ***********************************************************
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*******************************************************************************************************************/
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#define DEEP_SLEEP (1) //To enable deep-sleep set this to 1 |
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//DEEP_SLEEP mode can be used, for example, by a Tag instance to put the DW1000 into low-power deep-sleep mode while it is
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//waiting for start of next ranging exchange
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#define CORRECT_RANGE_BIAS (1) // Compensate for small bias due to uneven accumulator growth at close up high power |
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#define ANCTOANCTWR (1) //if set to 1 then anchor to anchor two-way ranging will be done in the last 2 slots, this |
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//is used for TREK demo, to aid in anchor installation,
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#define TAG_HASTO_RANGETO_A0 (0) //if set to 1 then tag will only send the Final if the Response from A0 has been received |
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#define READ_EVENT_COUNTERS (0) //read event counters - can be used for debug to periodically output event counters |
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#define DISCOVERY (0) //set to 1 to enable tag discovery - tags starts by sending blinks (with own ID) and then |
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//anchor assigns a slot to it and gives it short address
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/******************************************************************************************************************
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*******************************************************************************************************************
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*******************************************************************************************************************/
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#define NUM_INST 1 // one instance (tag or anchor - controlling one DW1000) |
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#define SPEED_OF_LIGHT (299702547.0) // in m/s in air |
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#define MASK_40BIT (0x00FFFFFFFFFF) // DW1000 counter is 40 bits |
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#define MASK_TXDTS (0x00FFFFFFFE00) // The TX timestamp will snap to 8 ns resolution - mask lower 9 bits. |
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//! callback events
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#define DWT_SIG_RX_NOERR 0 |
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#define DWT_SIG_TX_DONE 1 // Frame has been sent |
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#define DWT_SIG_RX_OKAY 2 // Frame Received with Good CRC |
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#define DWT_SIG_RX_ERROR 3 // Frame Received but CRC is wrong |
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#define DWT_SIG_RX_TIMEOUT 4 // Timeout on receive has elapsed |
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#define DWT_SIG_TX_AA_DONE 6 // ACK frame has been sent (as a result of auto-ACK) |
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#define DWT_SIG_RX_BLINK 7 // Received ISO EUI 64 blink message |
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#define DWT_SIG_RX_PHR_ERROR 8 // Error found in PHY Header |
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#define DWT_SIG_RX_SYNCLOSS 9 // Un-recoverable error in Reed Solomon Decoder |
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#define DWT_SIG_RX_SFDTIMEOUT 10 // Saw preamble but got no SFD within configured time |
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#define DWT_SIG_RX_PTOTIMEOUT 11 // Got preamble detection timeout (no preamble detected) |
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#define DWT_SIG_TX_PENDING 12 // TX is pending |
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#define DWT_SIG_TX_ERROR 13 // TX failed |
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#define DWT_SIG_RX_PENDING 14 // RX has been re-enabled |
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#define DWT_SIG_DW_IDLE 15 // DW radio is in IDLE (no TX or RX pending) |
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#define SIG_RX_UNKNOWN 99 // Received an unknown frame |
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//DecaRTLS frame function codes
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#define RTLS_DEMO_MSG_RNG_INIT (0x71) // Ranging initiation message |
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#define RTLS_DEMO_MSG_TAG_POLL (0x81) // Tag poll message |
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#define RTLS_DEMO_MSG_ANCH_RESP (0x70) // Anchor response to poll |
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#define RTLS_DEMO_MSG_ANCH_POLL (0x7A) // Anchor to anchor poll message |
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#define RTLS_DEMO_MSG_ANCH_RESP2 (0x7B) // Anchor response to poll from anchor |
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#define RTLS_DEMO_MSG_ANCH_FINAL (0x7C) // Anchor final massage back to Anchor |
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#define RTLS_DEMO_MSG_TAG_FINAL (0x82) // Tag final massage back to Anchor |
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//lengths including the Decaranging Message Function Code byte
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//absolute length = 17 +
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#define RANGINGINIT_MSG_LEN 5 // FunctionCode(1), Sleep Correction Time (2), Tag Address (2) |
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//absolute length = 11 +
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#define TAG_POLL_MSG_LEN 2 // FunctionCode(1), Range Num (1) |
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#define ANCH_RESPONSE_MSG_LEN 8 // FunctionCode(1), Sleep Correction Time (2), Measured_TOF_Time(4), Range Num (1) (previous) |
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#define TAG_FINAL_MSG_LEN 33 // FunctionCode(1), Range Num (1), Poll_TxTime(5), |
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// Resp0_RxTime(5), Resp1_RxTime(5), Resp2_RxTime(5), Resp3_RxTime(5), Final_TxTime(5), Valid Response Mask (1)
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#define ANCH_POLL_MSG_LEN_S 2 // FunctionCode(1), Range Num (1), |
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#define ANCH_POLL_MSG_LEN 4 // FunctionCode(1), Range Num (1), Next Anchor (2) |
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#define ANCH_FINAL_MSG_LEN 33 // FunctionCode(1), Range Num (1), Poll_TxTime(5), |
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// Resp0_RxTime(5), Resp1_RxTime(5), Resp2_RxTime(5), Resp3_RxTime(5), Final_TxTime(5), Valid Response Mask (1)
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#define MAX_MAC_MSG_DATA_LEN (TAG_FINAL_MSG_LEN) //max message len of the above |
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#define STANDARD_FRAME_SIZE 127 |
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#define ADDR_BYTE_SIZE_L (8) |
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#define ADDR_BYTE_SIZE_S (2) |
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#define FRAME_CONTROL_BYTES 2 |
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#define FRAME_SEQ_NUM_BYTES 1 |
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#define FRAME_PANID 2 |
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#define FRAME_CRC 2 |
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#define FRAME_SOURCE_ADDRESS_S (ADDR_BYTE_SIZE_S)
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#define FRAME_DEST_ADDRESS_S (ADDR_BYTE_SIZE_S)
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#define FRAME_SOURCE_ADDRESS_L (ADDR_BYTE_SIZE_L)
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#define FRAME_DEST_ADDRESS_L (ADDR_BYTE_SIZE_L)
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#define FRAME_CTRLP (FRAME_CONTROL_BYTES + FRAME_SEQ_NUM_BYTES + FRAME_PANID) //5 |
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#define FRAME_CRTL_AND_ADDRESS_L (FRAME_DEST_ADDRESS_L + FRAME_SOURCE_ADDRESS_L + FRAME_CTRLP) //21 bytes for 64-bit addresses) |
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#define FRAME_CRTL_AND_ADDRESS_S (FRAME_DEST_ADDRESS_S + FRAME_SOURCE_ADDRESS_S + FRAME_CTRLP) //9 bytes for 16-bit addresses) |
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#define FRAME_CRTL_AND_ADDRESS_LS (FRAME_DEST_ADDRESS_L + FRAME_SOURCE_ADDRESS_S + FRAME_CTRLP) //15 bytes for one 16-bit address and one 64-bit address) |
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#define MAX_USER_PAYLOAD_STRING_LL (STANDARD_FRAME_SIZE-FRAME_CRTL_AND_ADDRESS_L-TAG_FINAL_MSG_LEN-FRAME_CRC) //127 - 21 - 16 - 2 = 88 |
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#define MAX_USER_PAYLOAD_STRING_SS (STANDARD_FRAME_SIZE-FRAME_CRTL_AND_ADDRESS_S-TAG_FINAL_MSG_LEN-FRAME_CRC) //127 - 9 - 16 - 2 = 100 |
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#define MAX_USER_PAYLOAD_STRING_LS (STANDARD_FRAME_SIZE-FRAME_CRTL_AND_ADDRESS_LS-TAG_FINAL_MSG_LEN-FRAME_CRC) //127 - 15 - 16 - 2 = 94 |
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//NOTE: the user payload assumes that there are only 88 "free" bytes to be used for the user message (it does not scale according to the addressing modes)
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#define MAX_USER_PAYLOAD_STRING MAX_USER_PAYLOAD_STRING_LL
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#define BLINK_FRAME_CONTROL_BYTES (1) |
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#define BLINK_FRAME_SEQ_NUM_BYTES (1) |
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#define BLINK_FRAME_CRC (FRAME_CRC)
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#define BLINK_FRAME_SOURCE_ADDRESS (ADDR_BYTE_SIZE_L)
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#define BLINK_FRAME_CTRLP (BLINK_FRAME_CONTROL_BYTES + BLINK_FRAME_SEQ_NUM_BYTES) //2 |
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#define BLINK_FRAME_CRTL_AND_ADDRESS (BLINK_FRAME_SOURCE_ADDRESS + BLINK_FRAME_CTRLP) //10 bytes |
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#define BLINK_FRAME_LEN_BYTES (BLINK_FRAME_CRTL_AND_ADDRESS + BLINK_FRAME_CRC)
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#if (DISCOVERY == 0) |
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#define MAX_TAG_LIST_SIZE (8) |
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#else
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#define MAX_TAG_LIST_SIZE (100) |
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#endif
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#define MAX_ANCHOR_LIST_SIZE (4) //this is limited to 4 in this application |
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#define NUM_EXPECTED_RESPONSES (3) //e.g. MAX_ANCHOR_LIST_SIZE - 1 |
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#define NUM_EXPECTED_RESPONSES_ANC0 (2) //anchor A0 expects response from A1 and A2 |
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#define NUM_EXPECTED_RESPONSES_ANC1 (1) //anchor A1 expects response from A2 |
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#define GATEWAY_ANCHOR_ADDR (0x8000) |
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#define A1_ANCHOR_ADDR (0x8001) |
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#define A2_ANCHOR_ADDR (0x8002) |
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#define A3_ANCHOR_ADDR (0x8003) |
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#define WAIT4TAGFINAL 2 |
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#define WAIT4ANCFINAL 1 |
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// !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
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// NOTE: the maximum RX timeout is ~ 65ms
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// !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
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#define INST_DONE_WAIT_FOR_NEXT_EVENT 1 //this signifies that the current event has been processed and instance is ready for next one |
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#define INST_DONE_WAIT_FOR_NEXT_EVENT_TO 2 //this signifies that the current event has been processed and that instance is waiting for next one with a timeout |
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//which will trigger if no event coming in specified time
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#define INST_NOT_DONE_YET 0 //this signifies that the instance is still processing the current event |
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//application data message byte offsets
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#define FCODE 0 // Function code is 1st byte of messageData |
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#define PTXT 2 // Poll TX time |
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#define RRXT0 7 // A0 Response RX time |
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#define RRXT1 12 // A1 Response RX time |
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#define RRXT2 17 // A2 Response RX time |
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#define RRXT3 22 // A3 Response RX time |
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#define FTXT 27 // Final TX time |
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#define VRESP 32 // Mask of valid response times (e.g. if bit 1 = A0's response time is valid) |
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#define RES_TAG_SLP0 1 // Response tag sleep correction LSB |
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#define RES_TAG_SLP1 2 // Response tag sleep correction MSB |
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#define TOFR 3 // ToF (n-1) 4 bytes |
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#define TOFRN 7 // range number 1 byte |
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#define POLL_RNUM 1 // Poll message range number |
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#define POLL_NANC 2 // Address of next anchor to send a poll message (e.g. A1) |
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#define RES_TAG_ADD0 3 // Tag's short address (slot num) LSB |
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#define RES_TAG_ADD1 4 // Tag's short address (slot num) MSB |
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#define BLINK_PERIOD (2000) //ms (Blink at 2Hz initially) |
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#define DW_RX_ON_DELAY (16) //us - the DW RX has 16 us RX on delay before it will receive any data |
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//this it the delay used for configuring the receiver on delay (wait for response delay)
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//NOTE: this RX_RESPONSE_TURNAROUND is dependent on the microprocessor and code optimisations
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#define RX_RESPONSE_TURNAROUND (300) //this takes into account any turnaround/processing time (reporting received poll and sending the response) |
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#define PTO_PACS (3) //tag will use PTO to reduce power consumption (if no response coming stop RX) |
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//Tag will range to 3 or 4 anchors
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//Each ranging exchange will consist of minimum of 3 messages (Poll, Response, Final)
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//and a maximum of 6 messages (Poll, Response x 4, Final)
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//Thus the ranging exchange will take either 28 ms for 110 kbps and 5 ms for 6.81 Mbps.
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//NOTE: the above times are for 110k rate with 64 symb non-standard SFD and 1024 preamble length
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//Anchor to Anchor Ranging
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//1. A0 sends a Poll
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//2. A1 responds (to A0's Poll) after RX_RESPONSE_TURNAROUND (300 us) + response frame length = fixedReplyDelayAnc1 ~= 480 us
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//3. A0 turns its receiver on (after 300 us) expecting A1's response (this is done automatically in 1. by using WAIT4RESP)
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//4. A2 responds (to A0's Poll) after 2*fixedReplyDelayAnc1 ~= 960 us.
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//5. A0 turns its receiver on (last Rx on time + fixedReplyDelayAnc1) expecting A2's response (this is done after reception of A1's response using delayed RX)
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//6. A0 sends a Final this is timed from the Poll TX time = pollTx2FinalTxDelayAnc ~= 1550 us (1250+300)
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//7. A1 and A2 turn on their receivers to expect this Final frame (this is done automatically in 2. AND 4. by using WAIT4RESP)
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//Tag to Anchor Ranging
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//1. Tag sends a Poll
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//2. A0 responds (delayed response) after fixedReplyDelayAnc1, A0 will re-enable its receiver automatically (by using WAIT4RESP)
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//3. A1, A2, A3 re-enble the receiver to receive A0's response
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//4. A1 responds and will re-enable its receiver automatically (by using WAIT4RESP)
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//5. A2, A3 re-enble the receiver to receive A1's response
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//6. A2 responds and will re-enable its receiver automatically (by using WAIT4RESP)
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//7. A0, A3 re-enable the receiver to receive A2's response
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//9. A3 responds and will re-enable its receiver automatically (by using WAIT4RESP)
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//10. A0, A1, A2, A3 - all receive the Final from the tag
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//Tag Discovery mode
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//1. Tag sends a Blink
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//2. A0 responds with Ranging Init giving it short address and slot time correction
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//3. Tag sleeps until the next period and then starts ranging exchange
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typedef enum instanceModes{TAG, ANCHOR, ANCHOR_RNG, NUM_MODES} INST_MODE; |
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//Tag = Exchanges DecaRanging messages (Poll-Response-Final) with Anchor and enabling Anchor to calculate the range between the two instances
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//Anchor = see above
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//Anchor_Rng = the anchor (assumes a tag function) and ranges to another anchor - used in Anchor to Anchor TWR for auto positioning function
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// instance sending a poll (starting TWR) is INITIATOR
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// instance which receives a poll (and will be involved in the TWR) is RESPONDER
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// instance which does not receive a poll (default state) will be a LISTENER - will send no responses
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typedef enum instanceTWRModes{INITIATOR, RESPONDER_A, RESPONDER_B, RESPONDER_T, LISTENER, GREETER, ATWR_MODES} ATWR_MODE; |
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#define TOF_REPORT_NUL 0 |
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#define TOF_REPORT_T2A 1 |
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#define TOF_REPORT_A2A 2 |
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#define INVALID_TOF (0xABCDFFFF) |
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typedef enum inst_states |
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{ |
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TA_INIT, //0
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TA_TXE_WAIT, //1 - state in which the instance will enter sleep (if ranging finished) or proceed to transmit a message
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TA_TXBLINK_WAIT_SEND, //2 - configuration and sending of Blink message
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TA_TXPOLL_WAIT_SEND, //2 - configuration and sending of Poll message
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TA_TXFINAL_WAIT_SEND, //3 - configuration and sending of Final message
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TA_TXRESPONSE_WAIT_SEND, //4 - a place holder - response is sent from call back
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TA_TX_WAIT_CONF, //5 - confirmation of TX done message
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TA_RXE_WAIT, //6
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TA_RX_WAIT_DATA, //7
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TA_SLEEP_DONE, //8
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TA_TXRESPONSE_SENT_POLLRX, //9
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TA_TXRESPONSE_SENT_RESPRX, //10
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TA_TXRESPONSE_SENT_TORX, //11
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TA_TXRESPONSE_SENT_APOLLRX, //12
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TA_TXRESPONSE_SENT_ARESPRX //13
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} INST_STATES; |
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// This file defines data and functions for access to Parameters in the Device
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//message structure for Poll, Response and Final message
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typedef struct |
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{ |
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uint8_t frameCtrl[2]; // frame control bytes 00-01 |
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uint8_t seqNum; // sequence_number 02
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uint8_t panID[2]; // PAN ID 03-04 |
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uint8_t destAddr[ADDR_BYTE_SIZE_L]; // 05-12 using 64 bit addresses
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uint8_t sourceAddr[ADDR_BYTE_SIZE_L]; // 13-20 using 64 bit addresses
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uint8_t messageData[MAX_USER_PAYLOAD_STRING_LL] ; // 22-124 (application data and any user payload)
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uint8_t fcs[2] ; // 125-126 we allow space for the CRC as it is logically part of the message. However ScenSor TX calculates and adds these bytes. |
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} srd_msg_dlsl ; |
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typedef struct |
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{ |
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uint8_t frameCtrl[2]; // frame control bytes 00-01 |
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uint8_t seqNum; // sequence_number 02
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uint8_t panID[2]; // PAN ID 03-04 |
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uint8_t destAddr[ADDR_BYTE_SIZE_S]; // 05-06
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uint8_t sourceAddr[ADDR_BYTE_SIZE_S]; // 07-08
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uint8_t messageData[MAX_USER_PAYLOAD_STRING_SS] ; // 09-124 (application data and any user payload)
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uint8_t fcs[2] ; // 125-126 we allow space for the CRC as it is logically part of the message. However ScenSor TX calculates and adds these bytes. |
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} srd_msg_dsss ; |
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typedef struct |
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{ |
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uint8_t frameCtrl[2]; // frame control bytes 00-01 |
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uint8_t seqNum; // sequence_number 02
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uint8_t panID[2]; // PAN ID 03-04 |
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uint8_t destAddr[ADDR_BYTE_SIZE_L]; // 05-12 using 64 bit addresses
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uint8_t sourceAddr[ADDR_BYTE_SIZE_S]; // 13-14
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uint8_t messageData[MAX_USER_PAYLOAD_STRING_LS] ; // 15-124 (application data and any user payload)
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uint8_t fcs[2] ; // 125-126 we allow space for the CRC as it is logically part of the message. However ScenSor TX calculates and adds these bytes. |
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} srd_msg_dlss ; |
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typedef struct |
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{ |
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uint8_t frameCtrl[2]; // frame control bytes 00-01 |
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uint8_t seqNum; // sequence_number 02
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uint8_t panID[2]; // PAN ID 03-04 |
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uint8_t destAddr[ADDR_BYTE_SIZE_S]; // 05-06
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uint8_t sourceAddr[ADDR_BYTE_SIZE_L]; // 07-14 using 64 bit addresses
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uint8_t messageData[MAX_USER_PAYLOAD_STRING_LS] ; // 15-124 (application data and any user payload)
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uint8_t fcs[2] ; // 125-126 we allow space for the CRC as it is logically part of the message. However ScenSor TX calculates and adds these bytes. |
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} srd_msg_dssl ; |
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//12 octets for Minimum IEEE ID blink
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typedef struct |
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{ |
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uint8_t frameCtrl; // frame control bytes 00
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uint8_t seqNum; // sequence_number 01
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uint8_t tagID[BLINK_FRAME_SOURCE_ADDRESS]; // 02-09 64 bit address
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uint8_t fcs[2] ; // 10-11 we allow space for the CRC as it is logically part of the message. However ScenSor TX calculates and adds these bytes. |
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} iso_IEEE_EUI64_blink_msg ; |
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typedef struct |
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{ |
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uint8_t channelNumber ; // valid range is 1 to 11
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uint8_t preambleCode ; // 00 = use NS code, 1 to 24 selects code
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uint8_t pulseRepFreq ; // NOMINAL_4M, NOMINAL_16M, or NOMINAL_64M
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uint8_t dataRate ; // DATA_RATE_1 (110K), DATA_RATE_2 (850K), DATA_RATE_3 (6M81)
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uint8_t preambleLen ; // values expected are 64, (128), (256), (512), 1024, (2048), and 4096
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uint8_t pacSize ; |
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uint8_t nsSFD ; |
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uint16_t sfdTO; //!< SFD timeout value (in symbols) e.g. preamble length (128) + SFD(8) - PAC + some margin ~ 135us... DWT_SFDTOC_DEF; //default value
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} instanceConfig_t ; |
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typedef struct |
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{ |
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uint16_t slotDuration_ms ; //slot duration (time for 1 tag to range to 4 anchors)
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uint16_t numSlots ; // number of slots in one superframe (number of tags supported)
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uint16_t sfPeriod_ms ; // superframe period in ms
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uint16_t tagPeriod_ms ; // the time during which tag ranges to anchors and then sleeps, should be same as FRAME PERIOD so that tags don't interfere
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uint16_t pollTxToFinalTxDly_us ; //response delay time (Poll to Final delay)
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} sfConfig_t ; |
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/******************************************************************************************************************
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*******************************************************************************************************************
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*******************************************************************************************************************/
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//size of the event queue, in this application there should be at most 2 unprocessed events,
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//i.e. if there is a transmission with wait for response then the TX callback followed by RX callback could be executed
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//in turn and the event queued up before the instance processed the TX event.
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#define MAX_EVENT_NUMBER (4) |
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typedef struct |
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{ |
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uint8_t type; // event type - if 0 there is no event in the queue
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//uint8_t typeSave; // holds the event type - does not clear (used to show what event has been processed)
|
360 |
uint8_t typePend; // set if there is a pending event (i.e. DW is not in IDLE (TX/RX pending)
|
361 |
uint16_t rxLength ; // length of RX data (does not apply to TX events)
|
362 |
|
363 |
uint64_t timeStamp ; // last timestamp (Tx or Rx) - 40 bit DW1000 time
|
364 |
|
365 |
uint32_t timeStamp32l ; // last tx/rx timestamp - low 32 bits of the 40 bit DW1000 time
|
366 |
uint32_t timeStamp32h ; // last tx/rx timestamp - high 32 bits of the 40 bit DW1000 time
|
367 |
|
368 |
uint32_t uTimeStamp ; //32 bit system counter (ms) - STM32 tick time (at time of IRQ)
|
369 |
|
370 |
union {
|
371 |
//holds received frame (after a good RX frame event)
|
372 |
uint8_t frame[STANDARD_FRAME_SIZE]; |
373 |
srd_msg_dlsl rxmsg_ll ; //64 bit addresses
|
374 |
srd_msg_dssl rxmsg_sl ; |
375 |
srd_msg_dlss rxmsg_ls ; |
376 |
srd_msg_dsss rxmsg_ss ; //16 bit addresses
|
377 |
iso_IEEE_EUI64_blink_msg rxblinkmsg; |
378 |
}msgu; |
379 |
|
380 |
//uint8_t gotit; //stores the instance function which processed the event (used for debug)
|
381 |
}event_data_t ; |
382 |
|
383 |
// TX power and PG delay configuration structure
|
384 |
typedef struct { |
385 |
uint8_t pgDelay; |
386 |
|
387 |
//TX POWER
|
388 |
//31:24 BOOST_0.125ms_PWR
|
389 |
//23:16 BOOST_0.25ms_PWR-TX_SHR_PWR
|
390 |
//15:8 BOOST_0.5ms_PWR-TX_PHR_PWR
|
391 |
//7:0 DEFAULT_PWR-TX_DATA_PWR
|
392 |
uint32_t txPwr[2]; // |
393 |
}tx_struct; |
394 |
|
395 |
typedef struct |
396 |
{ |
397 |
INST_MODE mode; //instance mode (tag or anchor)
|
398 |
ATWR_MODE twrMode; |
399 |
INST_STATES testAppState ; //state machine - current state
|
400 |
INST_STATES nextState ; //state machine - next state
|
401 |
INST_STATES previousState ; //state machine - previous state
|
402 |
|
403 |
//configuration structures
|
404 |
dwt_config_t configData ; //DW1000 channel configuration
|
405 |
dwt_txconfig_t configTX ; //DW1000 TX power configuration
|
406 |
uint16_t txAntennaDelay ; //DW1000 TX antenna delay
|
407 |
uint16_t rxAntennaDelay ; //DW1000 RX antenna delay
|
408 |
uint32_t txPower ; //DW1000 TX power
|
409 |
uint8_t txPowerChanged; //power has been changed - update the register on next TWR exchange
|
410 |
uint8_t antennaDelayChanged; //antenna delay has been changed - update the register on next TWR exchange
|
411 |
|
412 |
uint16_t instanceAddress16; //contains tag/anchor 16 bit address
|
413 |
|
414 |
//timeouts and delays
|
415 |
int32_t tagPeriod_ms; // in ms, tag ranging + sleeping period
|
416 |
int32_t tagSleepTime_ms; //in milliseconds - defines the nominal Tag sleep time period
|
417 |
int32_t tagSleepRnd_ms; //add an extra slot duration to sleep time to avoid collision before getting synced by anchor 0
|
418 |
|
419 |
//this is the delay used for the delayed transmit
|
420 |
uint64_t pollTx2FinalTxDelay ; //this is delay from Poll Tx time to Final Tx time in DW1000 units (40-bit)
|
421 |
uint64_t pollTx2FinalTxDelayAnc ; //this is delay from Poll Tx time to Final Tx time in DW1000 units (40-bit) for Anchor to Anchor ranging
|
422 |
uint32_t fixedReplyDelayAnc32h ; //this is a delay used for calculating delayed TX/delayed RX on time (units: 32bit of 40bit DW time)
|
423 |
uint16_t anc1RespTx2FinalRxDelay_sy ; //This is delay for RX on when A1 expecting Final form A0 or A2 expecting Final from A1
|
424 |
uint16_t anc2RespTx2FinalRxDelay_sy ; //This is delay for RX on when A2 waiting for A0's final (anc to anc ranging)
|
425 |
uint32_t preambleDuration32h ; //preamble duration in device time (32 MSBs of the 40 bit time)
|
426 |
uint32_t tagRespRxDelay_sy ; //TX to RX delay time when tag is awaiting response message an another anchor
|
427 |
uint32_t ancRespRxDelay_sy ; //TX to RX delay time when anchor is awaiting response message an another anchor
|
428 |
|
429 |
int fwtoTime_sy ; //this is FWTO for response message (used by initiating anchor in anchor to anchor ranging) |
430 |
int fwto4RespFrame_sy ; //this is a frame wait timeout used when awaiting reception of Response frames (used by both tag/anchor) |
431 |
int fwto4FinalFrame_sy ; //this is a frame wait timeout used when awaiting reception of Final frames |
432 |
uint32_t delayedTRXTime32h; // time at which to do delayed TX or delayed RX (note TX time is time of SFD, RX time is RX on time)
|
433 |
|
434 |
//message structure used for holding the data of the frame to transmit before it is written to the DW1000
|
435 |
srd_msg_dsss msg_f ; // ranging message frame with 16-bit addresses
|
436 |
iso_IEEE_EUI64_blink_msg blinkmsg ; // frame structure (used for tx blink message)
|
437 |
srd_msg_dlss rng_initmsg ; // ranging init message (destination long, source short)
|
438 |
|
439 |
//Tag function address/message configuration
|
440 |
uint8_t shortAdd_idx ; // device's 16-bit address low byte (used as index into arrays [0 - 3])
|
441 |
uint8_t eui64[8]; // device's EUI 64-bit address |
442 |
uint16_t psduLength ; // used for storing the TX frame length
|
443 |
uint8_t frameSN; // modulo 256 frame sequence number - it is incremented for each new frame transmission
|
444 |
uint16_t panID ; // panid used in the frames
|
445 |
|
446 |
//64 bit timestamps
|
447 |
//union of TX timestamps
|
448 |
union {
|
449 |
uint64_t txTimeStamp ; // last tx timestamp
|
450 |
uint64_t tagPollTxTime ; // tag's poll tx timestamp
|
451 |
uint64_t anchorRespTxTime ; // anchor's reponse tx timestamp
|
452 |
}txu; |
453 |
uint32_t tagPollTxTime32h ; |
454 |
uint64_t tagPollRxTime ; // receive time of poll message
|
455 |
|
456 |
|
457 |
//application control parameters
|
458 |
uint8_t wait4ack ; // if this is set to DWT_RESPONSE_EXPECTED, then the receiver will turn on automatically after TX completion
|
459 |
uint8_t wait4final ; |
460 |
|
461 |
uint8_t instToSleep; // if set the instance will go to sleep before sending the blink/poll message
|
462 |
uint8_t instanceTimerEn; // enable/start a timer
|
463 |
uint32_t instanceWakeTime_ms; // micro time at which the tag was waken up
|
464 |
uint32_t nextWakeUpTime_ms; // micro time at which to wake up tag
|
465 |
|
466 |
uint8_t rxResponseMaskAnc; // bit mask - bit 0 not used;
|
467 |
// bit 1 = received response from anchor ID = 1;
|
468 |
// bit 2 from anchor ID = 2,
|
469 |
// bit 3 set if two responses (from Anchor 1 and Anchor 2) received and A0 got third response (from A2)
|
470 |
|
471 |
uint8_t rxResponseMask; // bit mask - bit 0 = received response from anchor ID = 0, bit 1 from anchor ID = 1 etc...
|
472 |
uint8_t rxResponseMaskReport; // this will be set before outputting range reports to signify which are valid
|
473 |
uint8_t rangeNum; // incremented for each sequence of ranges (each slot)
|
474 |
uint8_t rangeNumA[MAX_TAG_LIST_SIZE]; // array which holds last range number from each tag
|
475 |
uint8_t rangeNumAnc; // incremented for each sequence of ranges (each slot) - anchor to anchor ranging
|
476 |
uint8_t rangeNumAAnc[MAX_ANCHOR_LIST_SIZE]; //array which holds last range number for each anchor
|
477 |
|
478 |
int8_t rxResps; // how many responses were received to a poll (in current ranging exchange)
|
479 |
int8_t remainingRespToRx ; // how many responses remain to be received (in current ranging exchange)
|
480 |
|
481 |
uint16_t sframePeriod_ms; // superframe period in ms
|
482 |
uint16_t slotDuration_ms; // slot duration in ms
|
483 |
uint16_t numSlots; |
484 |
uint32_t a0SlotTime_ms; // relative time in superframe at which A0 starts ranging (this is start of 2nd last slot)
|
485 |
uint32_t a1SlotTime_ms; // absolute time in superframe at which A1 starts ranging
|
486 |
uint32_t a2aStartTime_ms; // absolute time in superframe at which A0 starts ranging
|
487 |
int32_t tagSleepCorrection_ms; // tag's sleep correction to keep it in it's assigned slot
|
488 |
|
489 |
//diagnostic counters/data, results and logging
|
490 |
uint32_t tof[MAX_TAG_LIST_SIZE]; //this is an array which holds last ToF from particular tag (ID 0-(MAX_TAG_LIST_SIZE-1))
|
491 |
|
492 |
//this is an array which holds last ToF to each anchor it should
|
493 |
uint32_t tofArray[MAX_ANCHOR_LIST_SIZE]; //contain 4 ToF to 4 anchors all relating to same range number sequence
|
494 |
|
495 |
uint32_t tofAnc[MAX_ANCHOR_LIST_SIZE]; //this is an array which holds last ToFs from particular anchors (0, 0-1, 0-2, 1-2)
|
496 |
|
497 |
//this is an array which holds last ToFs of the Anchor to Anchor ranging
|
498 |
uint32_t tofArrayAnc[MAX_ANCHOR_LIST_SIZE]; //it contains 3 ToFs relating to same range number sequence (0, 0-1, 0-2, 1-2)
|
499 |
|
500 |
#if (DISCOVERY ==1) |
501 |
uint8_t tagListLen ; |
502 |
uint8_t tagList[MAX_TAG_LIST_SIZE][8];
|
503 |
#endif
|
504 |
|
505 |
//debug counters
|
506 |
//int txMsgCount; //number of transmitted messages
|
507 |
//int rxMsgCount; //number of received messages
|
508 |
//int rxTimeouts ; //number of received timeout events
|
509 |
//int lateTX; //number of "LATE" TX events
|
510 |
//int lateRX; //number of "LATE" RX events
|
511 |
|
512 |
|
513 |
//ranging counters
|
514 |
int longTermRangeCount ; //total number of ranges |
515 |
|
516 |
int newRange; //flag set when there is a new range to report TOF_REPORT_A2A or TOF_REPORT_T2A |
517 |
int newRangeAncAddress; //last 4 bytes of anchor address - used for printing/range output display |
518 |
int newRangeTagAddress; //last 4 bytes of tag address - used for printing/range output display |
519 |
int newRangeTime;
|
520 |
|
521 |
uint8_t gatewayAnchor ; //set to TRUE = 1 if anchor address == GATEWAY_ANCHOR_ADDR
|
522 |
|
523 |
//event queue - used to store DW1000 events as they are processed by the dw_isr/callback functions
|
524 |
event_data_t dwevent[MAX_EVENT_NUMBER]; //this holds any TX/RX events and associated message data
|
525 |
uint8_t dweventIdxOut; |
526 |
uint8_t dweventIdxIn; |
527 |
uint8_t dweventPeek; |
528 |
uint8_t monitor; |
529 |
uint32_t timeofTx ; |
530 |
|
531 |
uint8_t smartPowerEn; |
532 |
|
533 |
#if (READ_EVENT_COUNTERS == 1) |
534 |
dwt_deviceentcnts_t ecounters; |
535 |
#endif
|
536 |
|
537 |
} instance_data_t ; |
538 |
|
539 |
//-------------------------------------------------------------------------------------------------------------
|
540 |
//
|
541 |
// Functions used in logging/displaying range and status data
|
542 |
//
|
543 |
//-------------------------------------------------------------------------------------------------------------
|
544 |
|
545 |
// function to calculate and the range from given Time of Flight
|
546 |
int instance_calculate_rangefromTOF(int idx, uint32_t tofx); |
547 |
|
548 |
void instance_cleardisttable(int idx); |
549 |
void instance_set_tagdist(int tidx, int aidx); |
550 |
double instance_get_tagdist(int idx); |
551 |
|
552 |
double instance_get_idist(int idx); |
553 |
double instance_get_idistraw(int idx); |
554 |
int instance_get_idist_mm(int idx); |
555 |
int instance_get_idistraw_mm(int idx); |
556 |
uint8_t instance_validranges(void);
|
557 |
|
558 |
int instance_get_rnum(void); |
559 |
int instance_get_rnuma(int idx); |
560 |
int instance_get_rnumanc(int idx); |
561 |
int instance_get_lcount(void); |
562 |
|
563 |
int instance_newrangeancadd(void); |
564 |
int instance_newrangetagadd(void); |
565 |
int instance_newrangepolltim(void); |
566 |
int instance_newrange(void); |
567 |
int instance_newrangetim(void); |
568 |
|
569 |
int instance_calc_ranges(uint32_t *array, uint16_t size, int reportRange, uint8_t* mask); |
570 |
|
571 |
// clear the status/ranging data
|
572 |
void instance_clearcounts(void) ; |
573 |
|
574 |
void instance_cleardisttableall(void); |
575 |
//-------------------------------------------------------------------------------------------------------------
|
576 |
//
|
577 |
// Functions used in driving/controlling the ranging application
|
578 |
//
|
579 |
//-------------------------------------------------------------------------------------------------------------
|
580 |
|
581 |
// Call init, then call config, then call run.
|
582 |
// initialise the instance (application) structures and DW1000 device
|
583 |
int instance_init(int role, DW1000Driver* drv); |
584 |
// configure the instance and DW1000 device
|
585 |
void instance_config(instanceConfig_t *config, sfConfig_t *sfconfig) ;
|
586 |
|
587 |
// configure the MAC address
|
588 |
void instance_set_16bit_address(uint16_t address) ;
|
589 |
void instance_config_frameheader_16bit(instance_data_t *inst);
|
590 |
|
591 |
void tag_process_rx_timeout(instance_data_t *inst);
|
592 |
|
593 |
// called (periodically or from and interrupt) to process any outstanding TX/RX events and to drive the ranging application
|
594 |
int tag_run(void) ; |
595 |
int anch_run(void) ; // returns indication of status report change |
596 |
|
597 |
// configure TX/RX callback functions that are called from DW1000 ISR
|
598 |
void rx_ok_cb_tag(const dwt_cb_data_t *cb_data); |
599 |
void rx_to_cb_tag(const dwt_cb_data_t *cb_data); |
600 |
void rx_err_cb_tag(const dwt_cb_data_t *cb_data); |
601 |
//void tx_conf_cb_tag(const dwt_cb_data_t *cb_data);
|
602 |
|
603 |
void rx_ok_cb_anch(const dwt_cb_data_t *cb_data); |
604 |
void rx_to_cb_anch(const dwt_cb_data_t *cb_data); |
605 |
void rx_err_cb_anch(const dwt_cb_data_t *cb_data); |
606 |
void tx_conf_cb(const dwt_cb_data_t *cb_data); |
607 |
|
608 |
void instance_set_replydelay(int delayms); |
609 |
|
610 |
// set/get the instance roles e.g. Tag/Anchor
|
611 |
// done though instance_init void instance_set_role(int mode) ; //
|
612 |
int instance_get_role(void) ; |
613 |
// get the DW1000 device ID (e.g. 0xDECA0130 for DW1000)
|
614 |
uint32_t instance_readdeviceid(void) ; // Return Device ID reg, enables validation of physical device presence |
615 |
|
616 |
void rnganch_change_back_to_anchor(instance_data_t *inst);
|
617 |
int instance_send_delayed_frame(instance_data_t *inst, int delayedTx); |
618 |
|
619 |
uint64_t instance_convert_usec_to_devtimeu (double microsecu);
|
620 |
|
621 |
|
622 |
void instance_seteventtime(event_data_t *dw_event, uint8_t* timeStamp);
|
623 |
|
624 |
int instance_peekevent(void); |
625 |
|
626 |
void instance_saveevent(event_data_t newevent, uint8_t etype);
|
627 |
|
628 |
event_data_t instance_getsavedevent(void);
|
629 |
|
630 |
void instance_putevent(event_data_t newevent, uint8_t etype);
|
631 |
|
632 |
event_data_t* instance_getevent(int x);
|
633 |
|
634 |
void instance_clearevents(void); |
635 |
|
636 |
void instance_notify_DW1000_inIDLE(int idle); |
637 |
|
638 |
// configure the antenna delays
|
639 |
void instance_config_antennadelays(uint16_t tx, uint16_t rx);
|
640 |
void instance_set_antennadelays(void); |
641 |
uint16_t instance_get_txantdly(void);
|
642 |
uint16_t instance_get_rxantdly(void);
|
643 |
|
644 |
// configure the TX power
|
645 |
void instance_config_txpower(uint32_t txpower);
|
646 |
void instance_set_txpower(void); |
647 |
int instance_starttxtest(int framePeriod); |
648 |
|
649 |
|
650 |
instance_data_t* instance_get_local_structure_ptr(unsigned int x); |
651 |
|
652 |
#ifdef __cplusplus
|
653 |
} |
654 |
#endif
|
655 |
|
656 |
#endif /* defined(AMIROLLD_CFG_USE_DW1000) */ |
657 |
|
658 |
#endif /* DECAINSTANCE_H */ |