microbit-dal - Revised to disable BLE for radio communication as…

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Revised to disable BLE for radio communication as needed.

Dependencies: BLE_API nRF51822 mbed-dev-bin

source/drivers/MicroBitCompassCalibrator.cpp@74:26717338739d, 2019-11-26 (annotated)

Committer:: tsfarber
Date:: Tue Nov 26 04:12:46 2019 +0000
Revision:: 74:26717338739d
Parent:: 1:8aa5cdb4ab67

This program combines samples programs radio TX and radio RX so that both units can send or receive depending on which unit's buttons are pressed. Tested successfully. MicroBitConfig.h has been edited to disable BLE.

Who changed what in which revision?

User	Revision	Line number	New contents of line
Jonathan Austin	1:8aa5cdb4ab67	1	/*
Jonathan Austin	1:8aa5cdb4ab67	2	The MIT License (MIT)
Jonathan Austin	1:8aa5cdb4ab67	3
Jonathan Austin	1:8aa5cdb4ab67	4	Copyright (c) 2016 British Broadcasting Corporation.
Jonathan Austin	1:8aa5cdb4ab67	5	This software is provided by Lancaster University by arrangement with the BBC.
Jonathan Austin	1:8aa5cdb4ab67	6
Jonathan Austin	1:8aa5cdb4ab67	7	Permission is hereby granted, free of charge, to any person obtaining a
Jonathan Austin	1:8aa5cdb4ab67	8	copy of this software and associated documentation files (the "Software"),
Jonathan Austin	1:8aa5cdb4ab67	9	to deal in the Software without restriction, including without limitation
Jonathan Austin	1:8aa5cdb4ab67	10	the rights to use, copy, modify, merge, publish, distribute, sublicense,
Jonathan Austin	1:8aa5cdb4ab67	11	and/or sell copies of the Software, and to permit persons to whom the
Jonathan Austin	1:8aa5cdb4ab67	12	Software is furnished to do so, subject to the following conditions:
Jonathan Austin	1:8aa5cdb4ab67	13
Jonathan Austin	1:8aa5cdb4ab67	14	The above copyright notice and this permission notice shall be included in
Jonathan Austin	1:8aa5cdb4ab67	15	all copies or substantial portions of the Software.
Jonathan Austin	1:8aa5cdb4ab67	16
Jonathan Austin	1:8aa5cdb4ab67	17	THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
Jonathan Austin	1:8aa5cdb4ab67	18	IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
Jonathan Austin	1:8aa5cdb4ab67	19	FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
Jonathan Austin	1:8aa5cdb4ab67	20	THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
Jonathan Austin	1:8aa5cdb4ab67	21	LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
Jonathan Austin	1:8aa5cdb4ab67	22	FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
Jonathan Austin	1:8aa5cdb4ab67	23	DEALINGS IN THE SOFTWARE.
Jonathan Austin	1:8aa5cdb4ab67	24	*/
Jonathan Austin	1:8aa5cdb4ab67	25
Jonathan Austin	1:8aa5cdb4ab67	26	#include "MicroBitConfig.h"
Jonathan Austin	1:8aa5cdb4ab67	27	#include "MicroBitCompassCalibrator.h"
Jonathan Austin	1:8aa5cdb4ab67	28	#include "EventModel.h"
Jonathan Austin	1:8aa5cdb4ab67	29	#include "Matrix4.h"
Jonathan Austin	1:8aa5cdb4ab67	30
Jonathan Austin	1:8aa5cdb4ab67	31	/**
Jonathan Austin	1:8aa5cdb4ab67	32	* Constructor.
Jonathan Austin	1:8aa5cdb4ab67	33	*
Jonathan Austin	1:8aa5cdb4ab67	34	* Create an object capable of calibrating the compass.
Jonathan Austin	1:8aa5cdb4ab67	35	*
Jonathan Austin	1:8aa5cdb4ab67	36	* The algorithm uses an accelerometer to ensure that a broad range of sample data has been gathered
Jonathan Austin	1:8aa5cdb4ab67	37	* from the compass module, then performs a least mean squares optimisation of the
Jonathan Austin	1:8aa5cdb4ab67	38	* results to determine the calibration data for the compass.
Jonathan Austin	1:8aa5cdb4ab67	39	*
Jonathan Austin	1:8aa5cdb4ab67	40	* The LED matrix display is used to provide feedback to the user on the gestures required.
Jonathan Austin	1:8aa5cdb4ab67	41	*
Jonathan Austin	1:8aa5cdb4ab67	42	* @param compass The compass instance to calibrate.
Jonathan Austin	1:8aa5cdb4ab67	43	*
Jonathan Austin	1:8aa5cdb4ab67	44	* @param accelerometer The accelerometer to gather contextual data from.
Jonathan Austin	1:8aa5cdb4ab67	45	*
Jonathan Austin	1:8aa5cdb4ab67	46	* @param display The LED matrix to display user feedback on.
Jonathan Austin	1:8aa5cdb4ab67	47	*/
Jonathan Austin	1:8aa5cdb4ab67	48	MicroBitCompassCalibrator::MicroBitCompassCalibrator(MicroBitCompass& _compass, MicroBitAccelerometer& _accelerometer, MicroBitDisplay& _display) : compass(_compass), accelerometer(_accelerometer), display(_display)
Jonathan Austin	1:8aa5cdb4ab67	49	{
Jonathan Austin	1:8aa5cdb4ab67	50	if (EventModel::defaultEventBus)
Jonathan Austin	1:8aa5cdb4ab67	51	EventModel::defaultEventBus->listen(MICROBIT_ID_COMPASS, MICROBIT_COMPASS_EVT_CALIBRATE, this, &MicroBitCompassCalibrator::calibrate, MESSAGE_BUS_LISTENER_IMMEDIATE);
Jonathan Austin	1:8aa5cdb4ab67	52	}
Jonathan Austin	1:8aa5cdb4ab67	53
Jonathan Austin	1:8aa5cdb4ab67	54	/**
Jonathan Austin	1:8aa5cdb4ab67	55	* Performs a simple game that in parallel, calibrates the compass.
Jonathan Austin	1:8aa5cdb4ab67	56	*
Jonathan Austin	1:8aa5cdb4ab67	57	* This function is executed automatically when the user requests a compass bearing, and compass calibration is required.
Jonathan Austin	1:8aa5cdb4ab67	58	*
Jonathan Austin	1:8aa5cdb4ab67	59	* This function is, by design, synchronous and only returns once calibration is complete.
Jonathan Austin	1:8aa5cdb4ab67	60	*/
Jonathan Austin	1:8aa5cdb4ab67	61	void MicroBitCompassCalibrator::calibrate(MicroBitEvent)
Jonathan Austin	1:8aa5cdb4ab67	62	{
Jonathan Austin	1:8aa5cdb4ab67	63	struct Point
Jonathan Austin	1:8aa5cdb4ab67	64	{
Jonathan Austin	1:8aa5cdb4ab67	65	uint8_t x;
Jonathan Austin	1:8aa5cdb4ab67	66	uint8_t y;
Jonathan Austin	1:8aa5cdb4ab67	67	uint8_t on;
Jonathan Austin	1:8aa5cdb4ab67	68	};
Jonathan Austin	1:8aa5cdb4ab67	69
Jonathan Austin	1:8aa5cdb4ab67	70	const int PERIMETER_POINTS = 12;
Jonathan Austin	1:8aa5cdb4ab67	71	const int PIXEL1_THRESHOLD = 200;
Jonathan Austin	1:8aa5cdb4ab67	72	const int PIXEL2_THRESHOLD = 800;
Jonathan Austin	1:8aa5cdb4ab67	73
Jonathan Austin	1:8aa5cdb4ab67	74	wait_ms(100);
Jonathan Austin	1:8aa5cdb4ab67	75
Jonathan Austin	1:8aa5cdb4ab67	76	Matrix4 X(PERIMETER_POINTS, 4);
Jonathan Austin	1:8aa5cdb4ab67	77	Point perimeter[PERIMETER_POINTS] = {{1,0,0}, {2,0,0}, {3,0,0}, {4,1,0}, {4,2,0}, {4,3,0}, {3,4,0}, {2,4,0}, {1,4,0}, {0,3,0}, {0,2,0}, {0,1,0}};
Jonathan Austin	1:8aa5cdb4ab67	78	Point cursor = {2,2,0};
Jonathan Austin	1:8aa5cdb4ab67	79
Jonathan Austin	1:8aa5cdb4ab67	80	MicroBitImage img(5,5);
Jonathan Austin	1:8aa5cdb4ab67	81	MicroBitImage smiley("0,255,0,255,0\n0,255,0,255,0\n0,0,0,0,0\n255,0,0,0,255\n0,255,255,255,0\n");
Jonathan Austin	1:8aa5cdb4ab67	82	int samples = 0;
Jonathan Austin	1:8aa5cdb4ab67	83
Jonathan Austin	1:8aa5cdb4ab67	84	// Firstly, we need to take over the display. Ensure all active animations are paused.
Jonathan Austin	1:8aa5cdb4ab67	85	display.stopAnimation();
Jonathan Austin	1:8aa5cdb4ab67	86	display.scrollAsync("DRAW A CIRCLE");
Jonathan Austin	1:8aa5cdb4ab67	87
Jonathan Austin	1:8aa5cdb4ab67	88	for (int i=0; i<110; i++)
Jonathan Austin	1:8aa5cdb4ab67	89	wait_ms(100);
Jonathan Austin	1:8aa5cdb4ab67	90
Jonathan Austin	1:8aa5cdb4ab67	91	display.stopAnimation();
Jonathan Austin	1:8aa5cdb4ab67	92	display.clear();
Jonathan Austin	1:8aa5cdb4ab67	93
Jonathan Austin	1:8aa5cdb4ab67	94	while(samples < PERIMETER_POINTS)
Jonathan Austin	1:8aa5cdb4ab67	95	{
Jonathan Austin	1:8aa5cdb4ab67	96	// update our model of the flash status of the user controlled pixel.
Jonathan Austin	1:8aa5cdb4ab67	97	cursor.on = (cursor.on + 1) % 4;
Jonathan Austin	1:8aa5cdb4ab67	98
Jonathan Austin	1:8aa5cdb4ab67	99	// take a snapshot of the current accelerometer data.
Jonathan Austin	1:8aa5cdb4ab67	100	int x = accelerometer.getX();
Jonathan Austin	1:8aa5cdb4ab67	101	int y = accelerometer.getY();
Jonathan Austin	1:8aa5cdb4ab67	102
Jonathan Austin	1:8aa5cdb4ab67	103	// Wait a little whie for the button state to stabilise (one scheduler tick).
Jonathan Austin	1:8aa5cdb4ab67	104	wait_ms(10);
Jonathan Austin	1:8aa5cdb4ab67	105
Jonathan Austin	1:8aa5cdb4ab67	106	// Deterine the position of the user controlled pixel on the screen.
Jonathan Austin	1:8aa5cdb4ab67	107	if (x < -PIXEL2_THRESHOLD)
Jonathan Austin	1:8aa5cdb4ab67	108	cursor.x = 0;
Jonathan Austin	1:8aa5cdb4ab67	109	else if (x < -PIXEL1_THRESHOLD)
Jonathan Austin	1:8aa5cdb4ab67	110	cursor.x = 1;
Jonathan Austin	1:8aa5cdb4ab67	111	else if (x > PIXEL2_THRESHOLD)
Jonathan Austin	1:8aa5cdb4ab67	112	cursor.x = 4;
Jonathan Austin	1:8aa5cdb4ab67	113	else if (x > PIXEL1_THRESHOLD)
Jonathan Austin	1:8aa5cdb4ab67	114	cursor.x = 3;
Jonathan Austin	1:8aa5cdb4ab67	115	else
Jonathan Austin	1:8aa5cdb4ab67	116	cursor.x = 2;
Jonathan Austin	1:8aa5cdb4ab67	117
Jonathan Austin	1:8aa5cdb4ab67	118	if (y < -PIXEL2_THRESHOLD)
Jonathan Austin	1:8aa5cdb4ab67	119	cursor.y = 0;
Jonathan Austin	1:8aa5cdb4ab67	120	else if (y < -PIXEL1_THRESHOLD)
Jonathan Austin	1:8aa5cdb4ab67	121	cursor.y = 1;
Jonathan Austin	1:8aa5cdb4ab67	122	else if (y > PIXEL2_THRESHOLD)
Jonathan Austin	1:8aa5cdb4ab67	123	cursor.y = 4;
Jonathan Austin	1:8aa5cdb4ab67	124	else if (y > PIXEL1_THRESHOLD)
Jonathan Austin	1:8aa5cdb4ab67	125	cursor.y = 3;
Jonathan Austin	1:8aa5cdb4ab67	126	else
Jonathan Austin	1:8aa5cdb4ab67	127	cursor.y = 2;
Jonathan Austin	1:8aa5cdb4ab67	128
Jonathan Austin	1:8aa5cdb4ab67	129	img.clear();
Jonathan Austin	1:8aa5cdb4ab67	130
Jonathan Austin	1:8aa5cdb4ab67	131	// Turn on any pixels that have been visited.
Jonathan Austin	1:8aa5cdb4ab67	132	for (int i=0; i<PERIMETER_POINTS; i++)
Jonathan Austin	1:8aa5cdb4ab67	133	if (perimeter[i].on)
Jonathan Austin	1:8aa5cdb4ab67	134	img.setPixelValue(perimeter[i].x, perimeter[i].y, 255);
Jonathan Austin	1:8aa5cdb4ab67	135
Jonathan Austin	1:8aa5cdb4ab67	136	// Update the pixel at the users position.
Jonathan Austin	1:8aa5cdb4ab67	137	img.setPixelValue(cursor.x, cursor.y, 255);
Jonathan Austin	1:8aa5cdb4ab67	138
Jonathan Austin	1:8aa5cdb4ab67	139	// Update the buffer to the screen.
Jonathan Austin	1:8aa5cdb4ab67	140	display.image.paste(img,0,0,0);
Jonathan Austin	1:8aa5cdb4ab67	141
Jonathan Austin	1:8aa5cdb4ab67	142	// test if we need to update the state at the users position.
Jonathan Austin	1:8aa5cdb4ab67	143	for (int i=0; i<PERIMETER_POINTS; i++)
Jonathan Austin	1:8aa5cdb4ab67	144	{
Jonathan Austin	1:8aa5cdb4ab67	145	if (cursor.x == perimeter[i].x && cursor.y == perimeter[i].y && !perimeter[i].on)
Jonathan Austin	1:8aa5cdb4ab67	146	{
Jonathan Austin	1:8aa5cdb4ab67	147	// Record the sample data for later processing...
Jonathan Austin	1:8aa5cdb4ab67	148	X.set(samples, 0, compass.getX(RAW));
Jonathan Austin	1:8aa5cdb4ab67	149	X.set(samples, 1, compass.getY(RAW));
Jonathan Austin	1:8aa5cdb4ab67	150	X.set(samples, 2, compass.getZ(RAW));
Jonathan Austin	1:8aa5cdb4ab67	151	X.set(samples, 3, 1);
Jonathan Austin	1:8aa5cdb4ab67	152
Jonathan Austin	1:8aa5cdb4ab67	153	// Record that this pixel has been visited.
Jonathan Austin	1:8aa5cdb4ab67	154	perimeter[i].on = 1;
Jonathan Austin	1:8aa5cdb4ab67	155	samples++;
Jonathan Austin	1:8aa5cdb4ab67	156	}
Jonathan Austin	1:8aa5cdb4ab67	157	}
Jonathan Austin	1:8aa5cdb4ab67	158
Jonathan Austin	1:8aa5cdb4ab67	159	wait_ms(100);
Jonathan Austin	1:8aa5cdb4ab67	160	}
Jonathan Austin	1:8aa5cdb4ab67	161
Jonathan Austin	1:8aa5cdb4ab67	162	// We have enough sample data to make a fairly accurate calibration.
Jonathan Austin	1:8aa5cdb4ab67	163	// We use a Least Mean Squares approximation, as detailed in Freescale application note AN2426.
Jonathan Austin	1:8aa5cdb4ab67	164
Jonathan Austin	1:8aa5cdb4ab67	165	// Firstly, calculate the square of each sample.
Jonathan Austin	1:8aa5cdb4ab67	166	Matrix4 Y(X.height(), 1);
Jonathan Austin	1:8aa5cdb4ab67	167	for (int i = 0; i < X.height(); i++)
Jonathan Austin	1:8aa5cdb4ab67	168	{
Jonathan Austin	1:8aa5cdb4ab67	169	float v = X.get(i, 0)X.get(i, 0) + X.get(i, 1)X.get(i, 1) + X.get(i, 2)*X.get(i, 2);
Jonathan Austin	1:8aa5cdb4ab67	170	Y.set(i, 0, v);
Jonathan Austin	1:8aa5cdb4ab67	171	}
Jonathan Austin	1:8aa5cdb4ab67	172
Jonathan Austin	1:8aa5cdb4ab67	173	// Now perform a Least Squares Approximation.
Jonathan Austin	1:8aa5cdb4ab67	174	Matrix4 Alpha = X.multiplyT(X).invert();
Jonathan Austin	1:8aa5cdb4ab67	175	Matrix4 Gamma = X.multiplyT(Y);
Jonathan Austin	1:8aa5cdb4ab67	176	Matrix4 Beta = Alpha.multiply(Gamma);
Jonathan Austin	1:8aa5cdb4ab67	177
Jonathan Austin	1:8aa5cdb4ab67	178	// The result contains the approximate zero point of each axis, but doubled.
Jonathan Austin	1:8aa5cdb4ab67	179	// Halve each sample, and record this as the compass calibration data.
Jonathan Austin	1:8aa5cdb4ab67	180	CompassSample cal ((int)(Beta.get(0,0) / 2), (int)(Beta.get(1,0) / 2), (int)(Beta.get(2,0) / 2));
Jonathan Austin	1:8aa5cdb4ab67	181	compass.setCalibration(cal);
Jonathan Austin	1:8aa5cdb4ab67	182
Jonathan Austin	1:8aa5cdb4ab67	183	// Show a smiley to indicate that we're done, and continue on with the user program.
Jonathan Austin	1:8aa5cdb4ab67	184	display.clear();
Jonathan Austin	1:8aa5cdb4ab67	185	display.printAsync(smiley, 0, 0, 0, 1500);
Jonathan Austin	1:8aa5cdb4ab67	186	wait_ms(1000);
Jonathan Austin	1:8aa5cdb4ab67	187	display.clear();
Jonathan Austin	1:8aa5cdb4ab67	188	}

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Type:	Library
Created:	26 Nov 2019
Imports:	17
Forks:	0
Commits:	75
Dependents:	1
Dependencies:	3
Followers:	2

source/drivers/MicroBitCompassCalibrator.cpp@74:26717338739d, 2019-11-26 (annotated)

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