GPSUBX_UART - GPS/GNSS UBX library for UART

HAPSRG » Code » GPSUBX_UART

GPS/GNSS UBX library for UART

Dependencies: Vector3

GPSUBX_UART.cpp@15:e77382079cd9, 2021-11-29 (annotated)

Committer:: osaka
Date:: Mon Nov 29 12:32:42 2021 +0000
Revision:: 15:e77382079cd9
Parent:: 14:1ed344c662d2
Child:: 16:8181909e88f8
Child:: 19:ae1a294cb30b

debugged

Who changed what in which revision?

User	Revision	Line number	New contents of line
cocorlow	0:cf7c726ec8a1	1	#include "GPSUBX_UART.hpp"
cocorlow	0:cf7c726ec8a1	2	#include "mbed.h"
cocorlow	0:cf7c726ec8a1	3	#include <math.h>
cocorlow	0:cf7c726ec8a1	4	#define M_PI 3.14159265358979f
cocorlow	0:cf7c726ec8a1	5
cocorlow	1:71f5168e48c8	6	GPSUBX_UART::GPSUBX_UART(PinName tx, PinName rx, int baud, int timezone)
cocorlow	1:71f5168e48c8	7	:serial(tx, rx, baud), TimeZone(timezone), receive_index(0)
cocorlow	0:cf7c726ec8a1	8	{
cocorlow	0:cf7c726ec8a1	9	}
cocorlow	0:cf7c726ec8a1	10
cocorlow	0:cf7c726ec8a1	11	void GPSUBX_UART::Checksum(char payload[], int n, char* ck_a, char* ck_b)
cocorlow	0:cf7c726ec8a1	12	{
cocorlow	0:cf7c726ec8a1	13	int ca = 0;
cocorlow	0:cf7c726ec8a1	14	int cb = 0;
cocorlow	0:cf7c726ec8a1	15	for (int i = 0; i < n+4; i++)
cocorlow	0:cf7c726ec8a1	16	{
cocorlow	0:cf7c726ec8a1	17	ca += (unsigned char)payload[i+2];
cocorlow	0:cf7c726ec8a1	18	cb += ca;
cocorlow	0:cf7c726ec8a1	19	}
cocorlow	0:cf7c726ec8a1	20	*ck_a = (char)(ca & 0xff);
cocorlow	0:cf7c726ec8a1	21	*ck_b = (char)(cb & 0xff);
cocorlow	0:cf7c726ec8a1	22	}
cocorlow	0:cf7c726ec8a1	23
cocorlow	0:cf7c726ec8a1	24	void GPSUBX_UART::Receive()
cocorlow	0:cf7c726ec8a1	25	{
cocorlow	0:cf7c726ec8a1	26	while (serial.readable())
cocorlow	0:cf7c726ec8a1	27	{
cocorlow	0:cf7c726ec8a1	28	char c;
cocorlow	0:cf7c726ec8a1	29	c = serial.getc();
cocorlow	0:cf7c726ec8a1	30	receive_buffer[receive_index] = c;
cocorlow	1:71f5168e48c8	31	receive_index = (receive_index + 1) % RECEIVE_SIZE;
cocorlow	1:71f5168e48c8	32	}
cocorlow	1:71f5168e48c8	33	}
cocorlow	1:71f5168e48c8	34
cocorlow	1:71f5168e48c8	35
cocorlow	1:71f5168e48c8	36	void GPSUBX_UART::Update()
cocorlow	1:71f5168e48c8	37	{
cocorlow	1:71f5168e48c8	38	volatile static int sentence_start = 0;
cocorlow	1:71f5168e48c8	39	volatile static int sentence_length = 0;
cocorlow	1:71f5168e48c8	40	volatile static int sentence_counter = 0;
cocorlow	1:71f5168e48c8	41	volatile static int read_index = 0;
cocorlow	1:71f5168e48c8	42
cocorlow	1:71f5168e48c8	43	volatile static char m_class = 0x00;
cocorlow	1:71f5168e48c8	44	volatile static char m_id = 0x00;
cocorlow	1:71f5168e48c8	45
cocorlow	1:71f5168e48c8	46	while (read_index != receive_index)
cocorlow	1:71f5168e48c8	47	{
cocorlow	1:71f5168e48c8	48	char c;
cocorlow	1:71f5168e48c8	49	c = receive_buffer[read_index];
cocorlow	0:cf7c726ec8a1	50	if (sentence_counter >= 2)
cocorlow	0:cf7c726ec8a1	51	{
cocorlow	0:cf7c726ec8a1	52	sentence_counter++;
cocorlow	0:cf7c726ec8a1	53	if (sentence_counter == 3)
cocorlow	0:cf7c726ec8a1	54	{
cocorlow	0:cf7c726ec8a1	55	m_class = c;
cocorlow	0:cf7c726ec8a1	56	}
cocorlow	0:cf7c726ec8a1	57	else if (sentence_counter == 4)
cocorlow	0:cf7c726ec8a1	58	{
cocorlow	0:cf7c726ec8a1	59	m_id = c;
cocorlow	0:cf7c726ec8a1	60	}
cocorlow	0:cf7c726ec8a1	61	else if (sentence_counter == 5)
cocorlow	0:cf7c726ec8a1	62	{
cocorlow	0:cf7c726ec8a1	63	}
cocorlow	0:cf7c726ec8a1	64	else if (sentence_counter == 6)
cocorlow	0:cf7c726ec8a1	65	{
cocorlow	1:71f5168e48c8	66	int sss = (read_index+RECEIVE_SIZE-1)%RECEIVE_SIZE;
cocorlow	0:cf7c726ec8a1	67	sentence_length = (int)(c << 8 \| receive_buffer[sss]);
cocorlow	0:cf7c726ec8a1	68	}
cocorlow	0:cf7c726ec8a1	69	else if (sentence_counter >= sentence_length+8)
cocorlow	0:cf7c726ec8a1	70	{
cocorlow	0:cf7c726ec8a1	71	for (int i = 0; i < sentence_length+8; i++)
cocorlow	0:cf7c726ec8a1	72	{
cocorlow	0:cf7c726ec8a1	73	sentence_buffer[i] = receive_buffer[(sentence_start+i)%RECEIVE_SIZE];
cocorlow	0:cf7c726ec8a1	74	}
cocorlow	0:cf7c726ec8a1	75	char ca, cb;
cocorlow	0:cf7c726ec8a1	76	Checksum(sentence_buffer, sentence_length, &ca, &cb);
cocorlow	0:cf7c726ec8a1	77	if (ca == sentence_buffer[sentence_length+6] && cb == sentence_buffer[sentence_length+7])
cocorlow	0:cf7c726ec8a1	78	{
cocorlow	0:cf7c726ec8a1	79	Decode(sentence_buffer, m_class, m_id);
cocorlow	0:cf7c726ec8a1	80	}
cocorlow	0:cf7c726ec8a1	81	sentence_start = 0;
cocorlow	0:cf7c726ec8a1	82	sentence_length = 0;
cocorlow	0:cf7c726ec8a1	83	sentence_counter = 0;
cocorlow	0:cf7c726ec8a1	84	m_class = 0x00;
cocorlow	0:cf7c726ec8a1	85	m_id = 0x00;
cocorlow	0:cf7c726ec8a1	86	}
cocorlow	0:cf7c726ec8a1	87	}
cocorlow	0:cf7c726ec8a1	88
cocorlow	1:71f5168e48c8	89	int ss = (read_index+RECEIVE_SIZE-1)%RECEIVE_SIZE;
cocorlow	0:cf7c726ec8a1	90	if (c == 0x62 && receive_buffer[ss] == 0xb5)
cocorlow	0:cf7c726ec8a1	91	{
cocorlow	0:cf7c726ec8a1	92	sentence_start = ss;
cocorlow	0:cf7c726ec8a1	93	sentence_counter = 2;
cocorlow	0:cf7c726ec8a1	94	}
cocorlow	1:71f5168e48c8	95	read_index = (read_index + 1) % RECEIVE_SIZE;
cocorlow	0:cf7c726ec8a1	96	}
cocorlow	0:cf7c726ec8a1	97	}
cocorlow	0:cf7c726ec8a1	98
cocorlow	0:cf7c726ec8a1	99	void GPSUBX_UART::Attach()
cocorlow	0:cf7c726ec8a1	100	{
cocorlow	0:cf7c726ec8a1	101	serial.attach(this, &GPSUBX_UART::Receive, Serial::RxIrq);
cocorlow	0:cf7c726ec8a1	102	}
cocorlow	0:cf7c726ec8a1	103
cocorlow	0:cf7c726ec8a1	104	void GPSUBX_UART::Decode(char buffer[], int mc, int mi)
cocorlow	0:cf7c726ec8a1	105	{
cocorlow	0:cf7c726ec8a1	106	// POSLLH
cocorlow	0:cf7c726ec8a1	107	if (mc == 0x01 && mi == 0x02)
cocorlow	0:cf7c726ec8a1	108	{
cocorlow	0:cf7c726ec8a1	109	POSLLH posllh;
cocorlow	0:cf7c726ec8a1	110	for (int i = 0; i < POSLLH_LEN; i++)
cocorlow	0:cf7c726ec8a1	111	{
cocorlow	0:cf7c726ec8a1	112	posllh.byte_data[i] = buffer[i+6];
cocorlow	0:cf7c726ec8a1	113	}
cocorlow	0:cf7c726ec8a1	114	iTOW_POSLLH = posllh.data.iTOW;
cocorlow	0:cf7c726ec8a1	115	Longitude = (float)posllh.data.lon * 1e-7f;
cocorlow	0:cf7c726ec8a1	116	Latitude = (float)posllh.data.lat * 1e-7f;
cocorlow	0:cf7c726ec8a1	117	Height = (float)posllh.data.height / 1000.0f;
cocorlow	2:6218fe8e54f4	118	// pc.printf("!%d, %f, %f, %f\r\n", iTOW_POSLLH, Longitude, Latitude, Height);
cocorlow	0:cf7c726ec8a1	119	}
NaotoMorita	13:facd8e54f2eb	120	// STATUS
NaotoMorita	13:facd8e54f2eb	121	if (mc == 0x01 && mi == 0x03)
cocorlow	10:a90d07e4c34d	122	{
NaotoMorita	13:facd8e54f2eb	123	STATUS status;
NaotoMorita	13:facd8e54f2eb	124	for (int i = 0; i < STATUS_LEN; i++)
cocorlow	10:a90d07e4c34d	125	{
NaotoMorita	14:1ed344c662d2	126	status.byte_data[i] = buffer[i+6];
cocorlow	10:a90d07e4c34d	127	}
NaotoMorita	14:1ed344c662d2	128	iTOW_STATUS = status.data.iTOW;
NaotoMorita	14:1ed344c662d2	129	gpsFix = status.data.gpsFix;
cocorlow	10:a90d07e4c34d	130	}
cocorlow	0:cf7c726ec8a1	131	// TIMEUTC
cocorlow	0:cf7c726ec8a1	132	else if (mc == 0x01 && mi == 0x21)
cocorlow	0:cf7c726ec8a1	133	{
cocorlow	0:cf7c726ec8a1	134	TIMEUTC timeutc;
cocorlow	0:cf7c726ec8a1	135	for (int i = 0; i < TIMEUTC_LEN; i++)
cocorlow	0:cf7c726ec8a1	136	{
cocorlow	0:cf7c726ec8a1	137	timeutc.byte_data[i] = buffer[i+6];
cocorlow	0:cf7c726ec8a1	138	}
cocorlow	0:cf7c726ec8a1	139	Year = timeutc.data.year;
cocorlow	0:cf7c726ec8a1	140	Month = timeutc.data.month;
cocorlow	0:cf7c726ec8a1	141	Day = timeutc.data.day;
cocorlow	1:71f5168e48c8	142	Hours = (int)timeutc.data.hour + TimeZone;
cocorlow	0:cf7c726ec8a1	143	if (Hours >= 24)
cocorlow	0:cf7c726ec8a1	144	{
cocorlow	0:cf7c726ec8a1	145	Hours -= 24;
cocorlow	0:cf7c726ec8a1	146	Day += 1;
cocorlow	0:cf7c726ec8a1	147	}
cocorlow	0:cf7c726ec8a1	148	else if (Hours < 0)
cocorlow	0:cf7c726ec8a1	149	{
cocorlow	0:cf7c726ec8a1	150	Hours += 24;
cocorlow	0:cf7c726ec8a1	151	Day -= 1;
cocorlow	0:cf7c726ec8a1	152	}
cocorlow	0:cf7c726ec8a1	153	Minutes = timeutc.data.min;
cocorlow	0:cf7c726ec8a1	154	Seconds = timeutc.data.sec;
cocorlow	2:6218fe8e54f4	155	// pc.printf("&%4d/%2d/%2d %2d:%2d %2d\r\n", Year, Month, Day, Hours, Minutes, Seconds);
cocorlow	0:cf7c726ec8a1	156	}
cocorlow	0:cf7c726ec8a1	157	// VELNED
cocorlow	0:cf7c726ec8a1	158	if (mc == 0x01 && mi == 0x12)
cocorlow	0:cf7c726ec8a1	159	{
cocorlow	0:cf7c726ec8a1	160	VELNED velned;
cocorlow	0:cf7c726ec8a1	161	for (int i = 0; i < VELNED_LEN; i++)
cocorlow	0:cf7c726ec8a1	162	{
cocorlow	0:cf7c726ec8a1	163	velned.byte_data[i] = buffer[i+6];
cocorlow	0:cf7c726ec8a1	164	}
cocorlow	0:cf7c726ec8a1	165	iTOW_VELNED = velned.data.iTOW;
cocorlow	0:cf7c726ec8a1	166	VelocityNED.x = (float)velned.data.velN / 100.0f;
cocorlow	0:cf7c726ec8a1	167	VelocityNED.y = (float)velned.data.velE / 100.0f;
cocorlow	0:cf7c726ec8a1	168	VelocityNED.z = (float)velned.data.velD / 100.0f;
cocorlow	0:cf7c726ec8a1	169	Speed = (float)velned.data.speed / 100.0f;
cocorlow	0:cf7c726ec8a1	170	GroundSpeed = (float)velned.data.gSpeed / 100.0f;
cocorlow	0:cf7c726ec8a1	171	Heading = (float)velned.data.heading * 1e-5f;
cocorlow	2:6218fe8e54f4	172	// pc.printf("#%d, %f, %f, %f\r\n", iTOW_VELNED, VelocityNED.x, VelocityNED.y, VelocityNED.z);
cocorlow	0:cf7c726ec8a1	173	}
cocorlow	0:cf7c726ec8a1	174	}
cocorlow	0:cf7c726ec8a1	175
cocorlow	0:cf7c726ec8a1	176	Vector3 GPSUBX_UART::ToUniversalUnit()
cocorlow	0:cf7c726ec8a1	177	{
cocorlow	0:cf7c726ec8a1	178	// 東経180度、北緯0度で精度最大
cocorlow	0:cf7c726ec8a1	179	float pi_2_theta = Latitude * M_PI / 180.0f;
cocorlow	0:cf7c726ec8a1	180	float pi_phi = ((Longitude > 0.0f) ? (Longitude - 180.0f) : (Longitude + 180.0f)) * M_PI / 180.0f;
cocorlow	0:cf7c726ec8a1	181	float x = - cosf(pi_2_theta) * cosf(pi_phi);
cocorlow	0:cf7c726ec8a1	182	float y = - cosf(pi_2_theta) * sinf(pi_phi);
cocorlow	0:cf7c726ec8a1	183	float z = sinf(pi_2_theta);
cocorlow	0:cf7c726ec8a1	184	Vector3 v(x, y, z);
NaotoMorita	12:2ffb2fcaac23	185
cocorlow	0:cf7c726ec8a1	186	return v;
cocorlow	0:cf7c726ec8a1	187	}
cocorlow	0:cf7c726ec8a1	188
cocorlow	0:cf7c726ec8a1	189	Vector3 GPSUBX_UART::ToUniversal()
cocorlow	0:cf7c726ec8a1	190	{
cocorlow	0:cf7c726ec8a1	191	Vector3 v = ToUniversalUnit();
cocorlow	0:cf7c726ec8a1	192	return (Radius + Height) * v;
cocorlow	0:cf7c726ec8a1	193	}
cocorlow	0:cf7c726ec8a1	194
cocorlow	0:cf7c726ec8a1	195	void GPSUBX_UART::CalculateUnit()
cocorlow	0:cf7c726ec8a1	196	{
cocorlow	0:cf7c726ec8a1	197	Vector3 _d = -1.0f * ToUniversalUnit();
cocorlow	0:cf7c726ec8a1	198
cocorlow	0:cf7c726ec8a1	199	UniversalZeroPosition = -(Radius+Height)*_d;
cocorlow	0:cf7c726ec8a1	200	Vector3 _z(0.0f, 0.0f, 1.0f);
cocorlow	0:cf7c726ec8a1	201	Vector3 _e = _d * _z;
cocorlow	0:cf7c726ec8a1	202	Vector3 _n = _e * _d;
osaka	15:e77382079cd9	203	UniversalZeroUnitN = _n / _n.Norm();
osaka	15:e77382079cd9	204	UniversalZeroUnitE = _e / _e.Norm();
cocorlow	0:cf7c726ec8a1	205	UniversalZeroUnitD = _d;
NaotoMorita	12:2ffb2fcaac23	206	//twelite.printf("%f %f %f \r\n",_n,_e,_d);
cocorlow	0:cf7c726ec8a1	207	}
cocorlow	0:cf7c726ec8a1	208
cocorlow	0:cf7c726ec8a1	209	void GPSUBX_UART::Calculate()
cocorlow	0:cf7c726ec8a1	210	{
cocorlow	0:cf7c726ec8a1	211	UniversalPosition = ToUniversal();
cocorlow	0:cf7c726ec8a1	212	Vector3 relative = UniversalPosition - UniversalZeroPosition;
cocorlow	0:cf7c726ec8a1	213	Vector3 _position(relative % UniversalZeroUnitN, relative % UniversalZeroUnitE, relative % UniversalZeroUnitD);
cocorlow	0:cf7c726ec8a1	214	PositionNED = _position;
cocorlow	0:cf7c726ec8a1	215	}
cocorlow	0:cf7c726ec8a1	216
cocorlow	0:cf7c726ec8a1	217	Vector3 GPSUBX_UART::Calculate(Vector3 position)
cocorlow	0:cf7c726ec8a1	218	{
cocorlow	0:cf7c726ec8a1	219	UniversalPosition = ToUniversal();
cocorlow	0:cf7c726ec8a1	220	Vector3 relative = position - UniversalZeroPosition;
cocorlow	0:cf7c726ec8a1	221	Vector3 _position(relative % UniversalZeroUnitN, relative % UniversalZeroUnitE, relative % UniversalZeroUnitD);
cocorlow	0:cf7c726ec8a1	222	return _position;
cocorlow	0:cf7c726ec8a1	223	}

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Type:	Library
Created:	13 Sep 2021
Imports:	5
Forks:	0
Commits:	22
Dependents:	3
Dependencies:	1
Followers:	25

GPSUBX_UART.cpp@15:e77382079cd9, 2021-11-29 (annotated)

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