LabmbedV30 - Labmbed device drivers

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malcolm lear / Mbed 2 deprecated LabmbedV30

Labmbed device drivers

main.cpp@6:9ad19444c9ce, 2017-09-26 (annotated)

Committer:: malcolmlear
Date:: Tue Sep 26 08:09:38 2017 +0000
Revision:: 6:9ad19444c9ce
Parent:: 5:7eea83fb1cb4

New Lab Board Test

Who changed what in which revision?

User	Revision	Line number	New contents of line
malcolmlear	5:7eea83fb1cb4	1	// Device Drivers for Labmbed Board
malcolmlear	0:416329806e55	2
malcolmlear	0:416329806e55	3	#include "mbed.h"
malcolmlear	0:416329806e55	4	#include "TextLCD.h"
malcolmlear	0:416329806e55	5
malcolmlear	5:7eea83fb1cb4	6	TextLCD lcd(p15, p16, p17, p18, p19, p20); // LCD: RS, E, D4-D7
malcolmlear	5:7eea83fb1cb4	7	SPI spi(p5, p6, p7); // SPI: MOSI, MISO, SCLK (MISO not used with LCD)
malcolmlear	5:7eea83fb1cb4	8	DigitalOut lat(p8); // data latch for LED driver TLC59281
malcolmlear	5:7eea83fb1cb4	9	DigitalOut Sel0(p26); // input select bits:
malcolmlear	5:7eea83fb1cb4	10	DigitalOut Sel1(p25); // "
malcolmlear	5:7eea83fb1cb4	11	DigitalOut Sel2(p24); // "
malcolmlear	5:7eea83fb1cb4	12	DigitalIn In0(p14); // input from switches, keypad etc
malcolmlear	5:7eea83fb1cb4	13	DigitalIn In1(p13); // "
malcolmlear	5:7eea83fb1cb4	14	DigitalIn In2(p12); // "
malcolmlear	5:7eea83fb1cb4	15	DigitalIn In3(p11); // "
malcolmlear	5:7eea83fb1cb4	16	I2C i2c(p9, p10); // I2C: SDA, SCL
malcolmlear	0:416329806e55	17
malcolmlear	5:7eea83fb1cb4	18	// global variables
malcolmlear	5:7eea83fb1cb4	19	short LEDbits = 0; // global led status used for readback
malcolmlear	5:7eea83fb1cb4	20	const int TMP102Addr = 0x92; // TMP102 temperature I2C address
malcolmlear	5:7eea83fb1cb4	21	const int MPU6050Addr = 0xd0; // MPU-6050 accelerometer and Gyro I2C address
malcolmlear	5:7eea83fb1cb4	22	float Acceleration[3]; // MPU-6050 x,y,z acceleration values in 1G floating point
malcolmlear	5:7eea83fb1cb4	23	float GyroRate[3]; // MPU-6050 x,y,z gyrorates in degrees per second
malcolmlear	5:7eea83fb1cb4	24	float GyroOffset[3]; // MPU-6050 x,y,z gyrorates compensation
malcolmlear	5:7eea83fb1cb4	25	char AReg[] = { 0x3b, 0x3d, 0x3f }; // MPU-6050 I2C x,y,z accelerometer data registers
malcolmlear	5:7eea83fb1cb4	26	char GReg[] = { 0x43, 0x45, 0x47 }; // MPU-6050 I2C x,y,z gyro data registers
malcolmlear	0:416329806e55	27
malcolmlear	0:416329806e55	28
malcolmlear	5:7eea83fb1cb4	29	void InitLEDs() {
malcolmlear	5:7eea83fb1cb4	30	lat = 0; // latch must start low
malcolmlear	5:7eea83fb1cb4	31	spi.format(16,0); // SPI 16 bit data, low state, high going clock
malcolmlear	5:7eea83fb1cb4	32	spi.frequency(1000000); // 1MHz clock rate
malcolmlear	5:7eea83fb1cb4	33	}
malcolmlear	5:7eea83fb1cb4	34
malcolmlear	5:7eea83fb1cb4	35	void SetLEDs(short ledall) {
malcolmlear	5:7eea83fb1cb4	36	LEDbits = ledall; // update global led status
malcolmlear	5:7eea83fb1cb4	37	spi.write((LEDbits & 0x03ff) \| ((LEDbits & 0xa800) >> 1) \| ((LEDbits & 0x5400) << 1));
malcolmlear	5:7eea83fb1cb4	38	lat = 1; // latch pulse start
malcolmlear	5:7eea83fb1cb4	39	lat = 0; // latch pulse end
malcolmlear	0:416329806e55	40	}
malcolmlear	0:416329806e55	41
malcolmlear	5:7eea83fb1cb4	42	void SetLED(short LEDNo, short LEDState) {
malcolmlear	5:7eea83fb1cb4	43	LEDNo = ((LEDNo - 1) & 0x0007) + 1; // limit led number
malcolmlear	6:9ad19444c9ce	44	LEDState = LEDState & 0x0003; // limit led state
malcolmlear	5:7eea83fb1cb4	45	LEDNo = (8 - LEDNo) * 2; // offset of led state in 'LEDbits'
malcolmlear	5:7eea83fb1cb4	46	LEDState = LEDState << LEDNo;
malcolmlear	5:7eea83fb1cb4	47	short statemask = ((0x0003 << LEDNo) ^ 0xffff); // mask used to clear led state
malcolmlear	5:7eea83fb1cb4	48	LEDbits = ((LEDbits & statemask) \| LEDState); // clear and set led state
malcolmlear	5:7eea83fb1cb4	49	SetLEDs(LEDbits);
malcolmlear	5:7eea83fb1cb4	50	}
malcolmlear	5:7eea83fb1cb4	51
malcolmlear	5:7eea83fb1cb4	52	short ReadLED(short LEDNo) {
malcolmlear	5:7eea83fb1cb4	53	LEDNo = ((LEDNo - 1) & 0x0007) + 1; // limit led number
malcolmlear	5:7eea83fb1cb4	54	LEDNo = (8 - LEDNo) * 2; // offset of led state in 'LEDbits'
malcolmlear	6:9ad19444c9ce	55	short LEDState = (LEDbits >> LEDNo) & 0x0003; // shift selected led state into ls 2 bits
malcolmlear	6:9ad19444c9ce	56	return LEDState; // return led state
malcolmlear	5:7eea83fb1cb4	57	}
malcolmlear	5:7eea83fb1cb4	58
malcolmlear	5:7eea83fb1cb4	59	short ReadLEDs() {
malcolmlear	5:7eea83fb1cb4	60	return LEDbits; // return led status
malcolmlear	0:416329806e55	61	}
malcolmlear	0:416329806e55	62
malcolmlear	5:7eea83fb1cb4	63	void SelInput(short Input) {
malcolmlear	5:7eea83fb1cb4	64	Sel0 = Input & 0x0001; // set sel[0:2] pins
malcolmlear	5:7eea83fb1cb4	65	Sel1 = (Input >> 1) & 0x0001; //
malcolmlear	5:7eea83fb1cb4	66	Sel2 = (Input >> 2) & 0x0001; //
malcolmlear	5:7eea83fb1cb4	67	}
malcolmlear	5:7eea83fb1cb4	68
malcolmlear	5:7eea83fb1cb4	69	short ReadSwitches() {
malcolmlear	5:7eea83fb1cb4	70	SelInput(5); // select least significant 4 switches in[3:0]
malcolmlear	5:7eea83fb1cb4	71	short Switches = In0 + (In1 << 1) + (In2 << 2) + (In3 << 3);
malcolmlear	5:7eea83fb1cb4	72	SelInput(4); // select most significant 4 switches in[3:0]
malcolmlear	6:9ad19444c9ce	73	return (Switches + (In0 << 4) + (In1 << 5) + (In2 << 6) + (In3 << 7));
malcolmlear	0:416329806e55	74	}
malcolmlear	0:416329806e55	75
malcolmlear	5:7eea83fb1cb4	76	short ReadSwitch(short SwitchNo) {
malcolmlear	5:7eea83fb1cb4	77	SwitchNo = ((SwitchNo - 1) & 0x0007) + 1; // limit switch number
malcolmlear	5:7eea83fb1cb4	78	SwitchNo = 8 - SwitchNo; // offset of switch state in ReadSwitches()
malcolmlear	5:7eea83fb1cb4	79	short SwitchState = ReadSwitches(); // read switch states
malcolmlear	5:7eea83fb1cb4	80	SwitchState = SwitchState >> SwitchNo; // shift selected switch state into ls bit
malcolmlear	5:7eea83fb1cb4	81	return (SwitchState & 0x0001); // mask out and return switch state
malcolmlear	0:416329806e55	82	}
malcolmlear	0:416329806e55	83
malcolmlear	5:7eea83fb1cb4	84	short ReadKeys() {
malcolmlear	5:7eea83fb1cb4	85	SelInput(0); // select Keypad top row
malcolmlear	5:7eea83fb1cb4	86	short Keys = (In0 << 15) + (In1 << 14) + (In2 << 13) + (In3 << 12);
malcolmlear	5:7eea83fb1cb4	87	SelInput(1); // select Keypad second row
malcolmlear	6:9ad19444c9ce	88	Keys += (In0 << 3) + (In1 << 6) + (In2 << 9) + (In3 << 11);
malcolmlear	5:7eea83fb1cb4	89	SelInput(2); // select Keypad third row
malcolmlear	6:9ad19444c9ce	90	Keys += (In0 << 2) + (In1 << 5) + (In2 << 8) + In3;
malcolmlear	5:7eea83fb1cb4	91	SelInput(3); // select Keypad forth row
malcolmlear	6:9ad19444c9ce	92	Keys += (In0 << 1) + (In1 << 4) + (In2 << 7) + (In3 << 10);
malcolmlear	5:7eea83fb1cb4	93	return (Keys ^ 0xffff); // return inverted (Key press active high)
malcolmlear	0:416329806e55	94	}
malcolmlear	0:416329806e55	95
malcolmlear	5:7eea83fb1cb4	96	short ReadKey(short KeyNo) {
malcolmlear	5:7eea83fb1cb4	97	KeyNo = KeyNo & 0x000f; // limit key number 0 to 15 (0 to F)
malcolmlear	5:7eea83fb1cb4	98	short KeyState = ReadKeys(); // read key states
malcolmlear	5:7eea83fb1cb4	99	KeyState = KeyState >> KeyNo; // shift selected key state into ls bit
malcolmlear	5:7eea83fb1cb4	100	return (KeyState & 0x0001); // mask out and return key state
malcolmlear	3:8eee79f59b30	101	}
malcolmlear	0:416329806e55	102
malcolmlear	5:7eea83fb1cb4	103	int FindKeyNo() {
malcolmlear	5:7eea83fb1cb4	104	short KeyNo;
malcolmlear	5:7eea83fb1cb4	105	short KeyPressed = -1; // set KeyPressed to -1 (no key pressed)
malcolmlear	5:7eea83fb1cb4	106	short KeyState = ReadKeys(); // read key states
malcolmlear	5:7eea83fb1cb4	107	for (KeyNo= 0; KeyNo < 16; KeyNo++ ) { // check all 16 Keys
malcolmlear	5:7eea83fb1cb4	108	if (KeyState & 0x0001) { // check key state
malcolmlear	5:7eea83fb1cb4	109	if (KeyPressed == -1) { // check if key already found
malcolmlear	5:7eea83fb1cb4	110	KeyPressed = KeyNo; // update KeyPressed
malcolmlear	5:7eea83fb1cb4	111	}
malcolmlear	5:7eea83fb1cb4	112	else {
malcolmlear	5:7eea83fb1cb4	113	return -1; // 2 or more keys pressed
malcolmlear	5:7eea83fb1cb4	114	}
malcolmlear	5:7eea83fb1cb4	115	}
malcolmlear	5:7eea83fb1cb4	116	KeyState = KeyState >> 1; // shift to check next key
malcolmlear	5:7eea83fb1cb4	117	}
malcolmlear	5:7eea83fb1cb4	118	return KeyPressed; // return KeyPressed
malcolmlear	3:8eee79f59b30	119	}
malcolmlear	0:416329806e55	120
malcolmlear	5:7eea83fb1cb4	121	char FindKeyChar() {
malcolmlear	5:7eea83fb1cb4	122	short KeyNo;
malcolmlear	5:7eea83fb1cb4	123	char KeyChar = ' '; // set KeyChar to ' ' (no key pressed)
malcolmlear	5:7eea83fb1cb4	124	KeyNo = FindKeyNo(); // find key pressed
malcolmlear	5:7eea83fb1cb4	125	if (KeyNo < 10 && KeyNo >= 0) {
malcolmlear	5:7eea83fb1cb4	126	KeyChar = (char) KeyNo + 0x30; // convert char 0-9 to ascii string '0'-'9'
malcolmlear	5:7eea83fb1cb4	127	}
malcolmlear	5:7eea83fb1cb4	128	if (KeyNo > 9 && KeyNo < 16) {
malcolmlear	5:7eea83fb1cb4	129	KeyChar = (char) KeyNo + 0x37; // convert char 10-15 to ascii string 'A'-'F'
malcolmlear	5:7eea83fb1cb4	130	}
malcolmlear	5:7eea83fb1cb4	131	return KeyChar; // return key pressed
malcolmlear	3:8eee79f59b30	132	}
malcolmlear	0:416329806e55	133
malcolmlear	5:7eea83fb1cb4	134	float ReadTemp() {
malcolmlear	5:7eea83fb1cb4	135	char Cmd[3];
malcolmlear	5:7eea83fb1cb4	136	Cmd[0] = 0x01; // pointer register value
malcolmlear	5:7eea83fb1cb4	137	Cmd[1] = 0x60; // byte 1 of the configuration register
malcolmlear	5:7eea83fb1cb4	138	Cmd[2] = 0xa0; // byte 2 of the configuration register
malcolmlear	5:7eea83fb1cb4	139	i2c.write(TMP102Addr, Cmd, 3); // select configuration register and write 0x60a0 to it
malcolmlear	5:7eea83fb1cb4	140	wait(0.5); // ensure conversion time
malcolmlear	5:7eea83fb1cb4	141	Cmd[0] = 0x00; // pointer register value
malcolmlear	5:7eea83fb1cb4	142	i2c.write(TMP102Addr, Cmd, 1); // select temperature register
malcolmlear	5:7eea83fb1cb4	143	i2c.read(TMP102Addr, Cmd, 2); // read 16-bit temperature register
malcolmlear	5:7eea83fb1cb4	144	return (float((Cmd[0] << 8) \| Cmd[1]) / 256); // divide by 256 and return temperature
malcolmlear	5:7eea83fb1cb4	145	}
malcolmlear	5:7eea83fb1cb4	146
malcolmlear	5:7eea83fb1cb4	147	signed short ReadMPU6050(int RegAddr) {
malcolmlear	5:7eea83fb1cb4	148	char Cmd[3];
malcolmlear	5:7eea83fb1cb4	149	Cmd[0] = RegAddr; // register address
malcolmlear	5:7eea83fb1cb4	150	i2c.write(MPU6050Addr, Cmd, 1); // select register to read
malcolmlear	5:7eea83fb1cb4	151	i2c.read(MPU6050Addr, Cmd, 2); // read 2 bytes from register
malcolmlear	5:7eea83fb1cb4	152	return ((Cmd[0] << 8) \| Cmd[1]); // return signed 16 bit value
malcolmlear	3:8eee79f59b30	153	}
malcolmlear	0:416329806e55	154
malcolmlear	5:7eea83fb1cb4	155	void CalibrateGyros() {
malcolmlear	5:7eea83fb1cb4	156	short a,b;
malcolmlear	5:7eea83fb1cb4	157	for(a=0; a<3; a++) {
malcolmlear	5:7eea83fb1cb4	158	GyroOffset[a] = 0; // clear gyro calibration offsets
malcolmlear	5:7eea83fb1cb4	159	for(b=0; b<1000; b++) {
malcolmlear	5:7eea83fb1cb4	160	GyroOffset[a] = GyroOffset[a] + (float)ReadMPU6050(GReg[a]);
malcolmlear	5:7eea83fb1cb4	161	wait_ms(1); // wait for next sample
malcolmlear	5:7eea83fb1cb4	162	}
malcolmlear	5:7eea83fb1cb4	163	GyroOffset[a] = GyroOffset[a]/1000; // find average over 1000 samples
malcolmlear	5:7eea83fb1cb4	164	}
malcolmlear	5:7eea83fb1cb4	165	}
malcolmlear	5:7eea83fb1cb4	166
malcolmlear	5:7eea83fb1cb4	167	void InitMotion() {
malcolmlear	5:7eea83fb1cb4	168	char Cmd[3];
malcolmlear	5:7eea83fb1cb4	169	Cmd[0] = 0xa1; // config register address
malcolmlear	5:7eea83fb1cb4	170	Cmd[1] = 0x06; // accelerometer and gyro bandwidth = 5Hz
malcolmlear	5:7eea83fb1cb4	171	i2c.write(MPU6050Addr, Cmd, 2); // write data to config register
malcolmlear	5:7eea83fb1cb4	172	Cmd[0] = 0x6b; // power management register address
malcolmlear	5:7eea83fb1cb4	173	Cmd[1] = 0x00; // data
malcolmlear	5:7eea83fb1cb4	174	i2c.write(MPU6050Addr, Cmd, 2); // write data to power management register
malcolmlear	5:7eea83fb1cb4	175	Cmd[0] = 0x1b; // gyro configuration register address
malcolmlear	5:7eea83fb1cb4	176	Cmd[1] = 0x08; // no gyro self test, +-500 full scale
malcolmlear	5:7eea83fb1cb4	177	i2c.write(MPU6050Addr, Cmd, 2); // write data to gyro configuration register
malcolmlear	5:7eea83fb1cb4	178	Cmd[0] = 0x19; // sample rate register address
malcolmlear	5:7eea83fb1cb4	179	Cmd[1] = 0x07; // sample rate = gyro output rate / 8
malcolmlear	5:7eea83fb1cb4	180	i2c.write(MPU6050Addr, Cmd, 2); // write data to sample rate register
malcolmlear	5:7eea83fb1cb4	181	CalibrateGyros();
malcolmlear	3:8eee79f59b30	182	}
malcolmlear	0:416329806e55	183
malcolmlear	5:7eea83fb1cb4	184	void ReadMotion() {
malcolmlear	5:7eea83fb1cb4	185	short a; // Acceleration is in G where 1G = 9.81 ms/s
malcolmlear	5:7eea83fb1cb4	186	for(a=0; a<3; a++) { // GyroRate is in degrees per second
malcolmlear	5:7eea83fb1cb4	187	Acceleration[a] = (float)ReadMPU6050(AReg[a]) / 16384;
malcolmlear	5:7eea83fb1cb4	188	GyroRate[a] = ((float)ReadMPU6050(GReg[a]) - GyroOffset[a]) / 66.5;
malcolmlear	5:7eea83fb1cb4	189	}
malcolmlear	5:7eea83fb1cb4	190	}
malcolmlear	0:416329806e55	191
malcolmlear	0:416329806e55	192	int main() {
malcolmlear	0:416329806e55	193
malcolmlear	5:7eea83fb1cb4	194	InitLEDs();
malcolmlear	5:7eea83fb1cb4	195	InitMotion();
malcolmlear	0:416329806e55	196
malcolmlear	0:416329806e55	197	while(1) {
malcolmlear	1:04e1ee8faa04	198	int a,b;
malcolmlear	5:7eea83fb1cb4	199	for (b = 0; b < 4; b++ ) { // select all 4 led states
malcolmlear	5:7eea83fb1cb4	200	for (a = 1; a < 9; a++ ) { // set all 8 leds to selected state
malcolmlear	5:7eea83fb1cb4	201	SetLED (a,b); // set led 'a' to state 'b'
malcolmlear	5:7eea83fb1cb4	202	wait(.05); // wait 0.05 second
malcolmlear	1:04e1ee8faa04	203	}
malcolmlear	1:04e1ee8faa04	204	}
malcolmlear	5:7eea83fb1cb4	205	for (a= 1; a < 9; a++ ) { // map Switch states to led's
malcolmlear	5:7eea83fb1cb4	206	SetLED (a,(ReadSwitch(a) + 1)); //
malcolmlear	5:7eea83fb1cb4	207	wait(.05); // wait 0.05 second
malcolmlear	3:8eee79f59b30	208	}
malcolmlear	5:7eea83fb1cb4	209	float temp = ReadTemp(); // get temperature
malcolmlear	5:7eea83fb1cb4	210	lcd.cls(); // clear lcd
malcolmlear	5:7eea83fb1cb4	211	lcd.printf("Temp = %f\n", temp); // print temperature
malcolmlear	5:7eea83fb1cb4	212	wait(1); // wait 1 second
malcolmlear	5:7eea83fb1cb4	213	lcd.cls(); // clear lcd
malcolmlear	5:7eea83fb1cb4	214	int swch = ReadSwitches(); // look at Switch states
malcolmlear	5:7eea83fb1cb4	215	lcd.printf("Switches = %d\n", swch); // print result
malcolmlear	5:7eea83fb1cb4	216	char Key = FindKeyChar(); // look for Key pressed
malcolmlear	5:7eea83fb1cb4	217	lcd.printf("Key = %c\n", Key); // print result
malcolmlear	5:7eea83fb1cb4	218	wait(1); // wait 1 second
malcolmlear	5:7eea83fb1cb4	219	ReadMotion(); // read new data in from the MPU-6050
malcolmlear	5:7eea83fb1cb4	220	lcd.cls(); // clear lcd
malcolmlear	5:7eea83fb1cb4	221	lcd.locate(0,0);
malcolmlear	5:7eea83fb1cb4	222	lcd.printf("x%.1f y%.1f z%.1f", Acceleration[0], Acceleration[1], Acceleration[2]);
malcolmlear	5:7eea83fb1cb4	223	lcd.locate(0,1);
malcolmlear	5:7eea83fb1cb4	224	lcd.printf("x%.1f y%.1f z%.1f", GyroRate[0], GyroRate[1], GyroRate[2]);
malcolmlear	5:7eea83fb1cb4	225	wait(.4);
malcolmlear	0:416329806e55	226	}
malcolmlear	0:416329806e55	227	}

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Type:	Program
Mbed OS support:	Mbed 2 deprecated
Created:	27 Jan 2017
Imports:	0
Forks:	1
Commits:	7
Dependents:	0
Dependencies:	2
Followers:	1

main.cpp@6:9ad19444c9ce, 2017-09-26 (annotated)

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