UWB_SmallModule_F103.git

			@@ -28,6 +28,10 @@
			#include "led.h"
			#include "serial_at_cmd_app.h"
			#include "Usart.h"
			#include "global_param.h"
			#include "filters.h"
			#include <stdio.h>
			#include "beep.h"


			/------------------------------------ Marcos ------------------------------------------/
			@@ -47,13 +51,13 @@
			#define POLL_TX_TO_RESP_RX_DLY_UUS 150
			/* This is the delay from Frame RX timestamp to TX reply timestamp used for calculating/setting the DW1000's delayed TX function. This includes the
			* frame length of approximately 2.66 ms with above configuration. */
			#define RESP_RX_TO_FINAL_TX_DLY_UUS 4100
			#define RESP_RX_TO_FINAL_TX_DLY_UUS 1500
			/* Receive response timeout. See NOTE 5 below. */
			#define RESP_RX_TIMEOUT_UUS 14700
			#define RESP_RX_TIMEOUT_UUS 2700

			#define POLL_RX_TO_RESP_TX_DLY_UUS 3600
			#define POLL_RX_TO_RESP_TX_DLY_UUS 420
			/* This is the delay from the end of the frame transmission to the enable of the receiver, as programmed for the DW1000's wait for response feature. */
			#define RESP_TX_TO_FINAL_RX_DLY_UUS 500
			#define RESP_TX_TO_FINAL_RX_DLY_UUS 200
			/* Receive final timeout. See NOTE 5 below. */
			#define FINAL_RX_TIMEOUT_UUS 4300

			@@ -67,8 +71,10 @@
			#define FINAL_MSG_TS_LEN 4

			#define GROUP_ID_IDX 0
			#define SOURCE_ID_IDX 1
			#define MESSAGE_TYPE_IDX 3
			#define ANCHOR_ID_IDX 1
			#define TAG_ID_IDX 3
			#define MESSAGE_TYPE_IDX 5
			#define DIST_IDX 6

			#define POLL 0x01
			#define RESPONSE 0x02
			@@ -76,18 +82,17 @@

			/------------------------------------ Variables ------------------------------------------/
			/* Default communication configuration. We use here EVK1000's default mode (mode 3). */
			static dwt_config_t config =
			{
			2, /* Channel number. */
			DWT_PRF_64M, /* Pulse repetition frequency. */
			DWT_PLEN_1024, /* Preamble length. */
			DWT_PAC32, /* Preamble acquisition chunk size. Used in RX only. */
			9, /* TX preamble code. Used in TX only. */
			9, /* RX preamble code. Used in RX only. */
			1, /* Use non-standard SFD (Boolean) */
			DWT_BR_110K, /* Data rate. */
			DWT_PHRMODE_STD, /* PHY header mode. */
			(1025 + 64 - 32) /* SFD timeout (preamble length + 1 + SFD length - PAC size). Used in RX only. */
			static dwt_config_t config = {
			2, /* Channel number. */
			DWT_PRF_64M, /* Pulse repetition frequency. */
			DWT_PLEN_128, /* Preamble length. */
			DWT_PAC8, /* Preamble acquisition chunk size. Used in RX only. */
			9, /* TX preamble code. Used in TX only. */
			9, /* RX preamble code. Used in RX only. */
			0, /* Use non-standard SFD (Boolean) */
			DWT_BR_6M8, /* Data rate. */
			DWT_PHRMODE_STD, /* PHY header mode. */
			(129 + 8 - 8) /* SFD timeout (preamble length + 1 + SFD length - PAC size). Used in RX only. */
			};

			/* Frames used in the ranging process. See NOTE 2 below. */
			@@ -130,6 +135,12 @@

			double distance, dist_no_bias, dist_cm;

			uint32_t g_UWB_com_interval = 0;
			float dis_after_filter; //å½åè·ç¦»å¼
			LPFilter_Frac* p_Dis_Filter; //æµè·ç¨çä½éæ»¤æ³¢å¨

			uint16_t g_Tagdist[256];
			uint8_t g_flag_Taggetdist[256];
			/------------------------------------ Functions ------------------------------------------/


			@@ -211,7 +222,23 @@
			ts += ts_field[i] << (i 8);
			}
			}

			void TagDistClear(void)
			{
			static uint16_t clear_judge_cnt;
			uint16_t i;
			if(clear_judge_cnt++>1000) //è®¾å®1Såé¢ï¼æ¯ç§è¿ä¸æ¬¡ãå¤ææ å¿ä½å¤§äºçäº2ï¼2sæ²¡æ¶å°æ°æ®å°±ææ°æ®åæ0xffffï¼ä¸è§¦åè¦æ¥ã
			{
			clear_judge_cnt=0;
			for(i=0;i<255;i++)
			{
			g_flag_Taggetdist[i]++;
			if(g_flag_Taggetdist[i]>=2)
			{
			g_Tagdist[i]=0xffff;
			}
			}
			}
			}
			void Dw1000_Init(void)
			{
			/* Reset and initialise DW1000.
			@@ -223,7 +250,9 @@

			/* Configure DW1000. See NOTE 6 below. */
			dwt_configure(&config);//éç½®DW1000



			/* Apply default antenna delay value. See NOTE 1 below. */
			dwt_setrxantennadelay(RX_ANT_DLY); //è®¾ç½®æ¥æ¶å¤©çº¿å»¶è¿
			dwt_settxantennadelay(TX_ANT_DLY); //è®¾ç½®åå°å¤©çº¿å»¶è¿
			@@ -233,11 +262,34 @@
			dwt_setrxaftertxdelay(POLL_TX_TO_RESP_RX_DLY_UUS); //è®¾ç½®åéåå¼å¯æ¥æ¶ï¼å¹¶è®¾å®å»¶è¿æ¶é´
			dwt_setrxtimeout(RESP_RX_TIMEOUT_UUS); //è®¾ç½®æ¥æ¶è¶æ¶æ¶é´
			}

			void Dw1000_App_Init(void)
			{
			//g_com_map[DEV_ID] = 0x0b;
			tx_poll_msg[MESSAGE_TYPE_IDX]=POLL;
			tx_resp_msg[MESSAGE_TYPE_IDX]=RESPONSE;
			tx_final_msg[MESSAGE_TYPE_IDX]=FINAL;
			memcpy(&tx_poll_msg[TAG_ID_IDX], &g_com_map[DEV_ID], 2);
			memcpy(&tx_final_msg[TAG_ID_IDX], &g_com_map[DEV_ID], 2);
			memcpy(&tx_resp_msg[ANCHOR_ID_IDX], &g_com_map[DEV_ID], 2);

			}
			void tag_sleep_configuraion(void)
			{
			dwt_configuresleep(0x940, 0x7);
			dwt_entersleep();
			}
			uint16_t g_Resttimer;
			uint8_t result;
			void Tag_App(void)//åéæ¨¡å¼(TAGæ ç¾)
			{
			uint32_t frame_len;
			uint32_t final_tx_time;

			g_Resttimer=0;
			UART_CheckReceive();
			GPIO_ResetBits(SPIx_GPIO, SPIx_CS);
			delay_us(2500);
			GPIO_SetBits(SPIx_GPIO, SPIx_CS);

			/* Write frame data to DW1000 and prepare transmission. See NOTE 7 below. */
			tx_poll_msg[ALL_MSG_SN_IDX] = frame_seq_nb;
			@@ -269,14 +321,14 @@
			/* Check that the frame is the expected response from the companion "DS TWR responder" example.
			* As the sequence number field of the frame is not relevant, it is cleared to simplify the validation of the frame. */
			rx_buffer[ALL_MSG_SN_IDX] = 0;
			if (rx_buffer[9] == 0x10) //å¤ææ¥æ¶å°çæ°æ®æ¯å¦æ¯responseæ°æ®
			if (rx_buffer[MESSAGE_TYPE_IDX] == RESPONSE) //å¤ææ¥æ¶å°çæ°æ®æ¯å¦æ¯responseæ°æ®
			{
			/* Retrieve poll transmission and response reception timestamp. */
			poll_tx_ts = get_tx_timestamp_u64(); //è·å¾POLLåéæ¶é´T1
			resp_rx_ts = get_rx_timestamp_u64(); //è·å¾RESPONSEæ¥æ¶æ¶é´T4

			memcpy(&anchor_dist_last_frm[tag_id], &rx_buffer[11], 2);


			memcpy(&anchor_dist_last_frm[tag_id], &rx_buffer[DIST_IDX], 2);
			memcpy(&tx_final_msg[ANCHOR_ID_IDX], &rx_buffer[ANCHOR_ID_IDX], 2);
			/* Compute final message transmission time. See NOTE 9 below. */
			final_tx_time = (resp_rx_ts + (RESP_RX_TO_FINAL_TX_DLY_UUS * UUS_TO_DWT_TIME)) >> 8;//è®¡ç®finalååéæ¶é´ï¼T5=T4+Treply2
			dwt_setdelayedtrxtime(final_tx_time);//è®¾ç½®finalååéæ¶é´T5
			@@ -293,12 +345,14 @@
			tx_final_msg[ALL_MSG_SN_IDX] = frame_seq_nb;
			dwt_writetxdata(sizeof(tx_final_msg), tx_final_msg, 0);//å°åéæ°æ®åå¥DW1000
			dwt_writetxfctrl(sizeof(tx_final_msg), 0);//è®¾å®åéæ°æ®é¿åº¦
			dwt_starttx(DWT_START_TX_DELAYED);//è®¾å®ä¸ºå»¶è¿åé
			result=dwt_starttx(DWT_START_TX_DELAYED);//è®¾å®ä¸ºå»¶è¿åé


			/* Poll DW1000 until TX frame sent event set. See NOTE 8 below. */
			while (!(dwt_read32bitreg(SYS_STATUS_ID) & SYS_STATUS_TXFRS))//ä¸ææ¥è¯¢è¯çç¶æç´å°åéå®æ
			if(result==0)
			{while (!(dwt_read32bitreg(SYS_STATUS_ID) & SYS_STATUS_TXFRS))//ä¸ææ¥è¯¢è¯çç¶æç´å°åéå®æ
			{ };

			}
			/* Clear TXFRS event. */
			dwt_write32bitreg(SYS_STATUS_ID, SYS_STATUS_TXFRS);//æ¸é¤æ å¿ä½

			@@ -319,9 +373,10 @@
			}
			LED0_BLINK;
			/* Execute a delay between ranging exchanges. */
			deca_sleep(RNG_DELAY_MS + random_delay_tim); //ä¼ç åºå®æ¶é´
			dwt_entersleep();

			}

			extern uint8_t g_pairstart;
			void Anchor_App(void)
			{
			uint32_t frame_len;
			@@ -337,7 +392,7 @@
			while (!((status_reg = dwt_read32bitreg(SYS_STATUS_ID)) & (SYS_STATUS_RXFCG \| SYS_STATUS_ALL_RX_ERR)))//ä¸ææ¥è¯¢è¯çç¶æç´å°æ¥æ¶æåæèåºç°éè¯¯
			{
			UART_CheckReceive();
			UART_CheckSend();
			g_Resttimer=0;
			};

			if (status_reg & SYS_STATUS_RXFCG)//æåæ¥æ¶
			@@ -356,11 +411,11 @@
			rx_buffer[ALL_MSG_SN_IDX] = 0;

			//å°æ¶å°çtag_idåå«åå¥åæ¬¡éè®¯çåä¸ï¼ä¸ºå¤æ ç¾éè®¯æå¡ï¼é²æ¢ä¸æ¬¡éè®¯ä¸æ¥æ¶å°ä¸åIDæ ç¾çæ°æ®
			tag_id_recv = rx_buffer[5];
			tx_resp_msg[5] = tag_id_recv;
			tag_id_recv = rx_buffer[TAG_ID_IDX];
			tx_resp_msg[TAG_ID_IDX] = tag_id_recv;


			if (rx_buffer[9] == 0x21) //å¤ææ¯å¦æ¯pollåæ°æ®
			if (rx_buffer[MESSAGE_TYPE_IDX] == POLL&&tag_id_recv!= g_com_map[PAIR_ID]) //å¤ææ¯å¦æ¯pollåæ°æ®
			{
			/* Retrieve poll reception timestamp. */
			poll_rx_ts = get_rx_timestamp_u64();//è·å¾Pollåæ¥æ¶æ¶é´T2
			@@ -374,17 +429,19 @@
			dwt_setrxtimeout(FINAL_RX_TIMEOUT_UUS);//æ¥æ¶è¶æ¶æ¶é´

			/* Write and send the response message. See NOTE 9 below.*/
			memcpy(&tx_resp_msg[11], &anchor_dist_last_frm[tag_id_recv], 2);
			memcpy(&tx_resp_msg[DIST_IDX], &anchor_dist_last_frm[tag_id_recv], 2);
			tx_resp_msg[ALL_MSG_SN_IDX] = frame_seq_nb;
			dwt_writetxdata(sizeof(tx_resp_msg), tx_resp_msg, 0);//åå¥åéæ°æ®
			dwt_writetxfctrl(sizeof(tx_resp_msg), 0);//è®¾å®åéé¿åº¦
			dwt_starttx(DWT_START_TX_DELAYED \| DWT_RESPONSE_EXPECTED);//å»¶è¿åéï¼çå¾æ¥æ¶
			result = dwt_starttx(DWT_START_TX_DELAYED \| DWT_RESPONSE_EXPECTED);//å»¶è¿åéï¼çå¾æ¥æ¶

			/* We assume that the transmission is achieved correctly, now poll for reception of expected "final" frame or error/timeout.
			* See NOTE 7 below. */
			while (!((status_reg = dwt_read32bitreg(SYS_STATUS_ID)) & (SYS_STATUS_RXFCG \| SYS_STATUS_ALL_RX_ERR)))///ä¸ææ¥è¯¢è¯çç¶æç´å°æ¥æ¶æåæèåºç°éè¯¯
			if(result==0)
			{
			while (!((status_reg = dwt_read32bitreg(SYS_STATUS_ID)) & (SYS_STATUS_RXFCG \| SYS_STATUS_ALL_RX_ERR)))///ä¸ææ¥è¯¢è¯çç¶æç´å°æ¥æ¶æåæèåºç°éè¯¯
			{ };

			}
			/* Increment frame sequence number after transmission of the response message (modulo 256). */
			frame_seq_nb++;

			@@ -402,7 +459,7 @@
			/* Check that the frame is a final message sent by "DS TWR initiator" example.
			* As the sequence number field of the frame is not used in this example, it can be zeroed to ease the validation of the frame. */
			rx_buffer[ALL_MSG_SN_IDX] = 0;
			if (rx_buffer[9] == 0x23) //å¤ææ¯å¦ä¸ºFinalå
			if (rx_buffer[MESSAGE_TYPE_IDX] == FINAL&&rx_buffer[TAG_ID_IDX]==tag_id_recv&&rx_buffer[ANCHOR_ID_IDX]==g_com_map[DEV_ID]) //å¤ææ¯å¦ä¸ºFinalå
			{
			uint32_t poll_tx_ts, resp_rx_ts, final_tx_ts;
			uint32_t poll_rx_ts_32, resp_tx_ts_32, final_rx_ts_32;
			@@ -435,7 +492,23 @@
			dist_cm = dist_no_bias * 100; //dis ä¸ºåä½ä¸ºcmçè·ç¦»
			// dist[TAG_ID] = LP(dis, TAG_ID); //LP ä¸ºä½éæ»¤æ³¢å¨ï¼è®©æ°æ®æ´ç¨³å®

			/--------------------------ä»¥ä¸ä¸ºéæµè·é»è¾------------------------/
			LED0_BLINK; //æ¯æåä¸æ¬¡éè®¯åéªçä¸æ¬¡
			g_UWB_com_interval = 0;
			dis_after_filter=dist_cm;
			g_Tagdist[tag_id_recv]=dist_cm;
			if(g_pairstart==1&&dist_cm<20)
			{
			g_pairstart=0;
			g_com_map[PAIR_ID]=tag_id_recv;
			save_com_map_to_flash();
			BEEP2_ON;
			delay_ms(1000);
			printf("Pair Finish PairID: %d. \r\n",g_com_map[PAIR_ID]);
			}
			g_flag_Taggetdist[tag_id_recv]=0;
			printf("Anchor ID: %d, Tag ID: %d, Dist = %d cm\n", g_com_map[DEV_ID], tag_id_recv, (uint16_t)dis_after_filter);
			//dis_after_filter = LP_Frac_Update(p_Dis_Filter, dist_cm);

			}
			}