Railway Challenge
Uncommenting of part that allow supercaps to charge up from the batteries
Diff: remoteControl.cpp
- Revision:
- 0:4788e1df7b55
diff -r 000000000000 -r 4788e1df7b55 remoteControl.cpp
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/remoteControl.cpp Fri Mar 13 11:48:04 2020 +0000
@@ -0,0 +1,181 @@
+#include <mbed.h>
+#include "remoteControl.h"
+#include "definitions.h"
+
+Remote::Remote(SPI& remoteControl, DigitalOut& remoteControlCS) : _remoteControl(remoteControl), _remoteControlCS(remoteControlCS) {
+ _remoteControl.format(8,0); // FORMAT SPI AS 8-BIT DATA, SPI CLOCK MODE 0
+ const long arduinoClock = 16000000;
+ long spiFrequency = arduinoClock / 4;
+ _remoteControl.frequency(spiFrequency); // SET SPI CLOCK FREQUENCY
+
+ _remoteControlCS = 1; // DISABLE SLAVE
+ spiDelay = 600; //DELAY BETWEEN SPI TRANSACTIONS (SO ARDUINO CAN KEEP UP WITH REQUESTS)
+
+ commsGood = false; // Successful Comms Between Nucleo and Remote Control
+ commsFailures = 0; // Number of consecutive remote comms failures
+ errorIndex = 0;
+
+// remoteSwitchStateTicker.attach(this, &Remote::getSwitchStates, 0.2);
+ commsCheckTicker.attach(this, &Remote::commsCheck, 0.2); // Run the commsCheck function every 0.1s with the commsCheckTicker. - &commsCheck = The address of the function to be attached and 0.1 = the interval
+}
+
+int Remote::sendData(int precursor, int data) {
+ int response = 0;
+
+ _remoteControlCS = 0; // ENABLE REMOTE SPI
+// pc.printf("Enabled \r\n");
+ _remoteControl.write(precursor); // Prepare arduino to receive data
+ wait_us(spiDelay);
+ _remoteControl.write(data); // SEND DATA
+ wait_us(spiDelay);
+ response = _remoteControl.write(255);
+ wait_us(spiDelay);
+
+ _remoteControlCS = 1; // DISABLE REMOTE SPI
+// pc.printf("Disabling\r\n");
+
+ return response;
+}
+
+void Remote::commsCheck() {
+ // Send a random number to the controller and expect its square in return for valid operation.
+
+ // Random number between 2 and 15. Reply should be the squared, and within the 1 byte size limit of 255 for SPI comms.
+ // Does not conflict with switch states as they use ASCII A, B C etc which are Decimal 65+
+ int randomNumber = rand() % (15 - 2 + 1) + 2; // rand()%(max-min + 1) + min inclusive of max and min
+ int expectedResponse = randomNumber * randomNumber;
+ int actualResponse = 0;
+
+ actualResponse = sendData(1, randomNumber);
+
+// pc.printf("Random Number: %d\r\n", randomNumber);
+// pc.printf("Expected: %d\r\n", expectedResponse);
+// pc.printf("Actual: %d\r\n", actualResponse);
+
+ if (actualResponse == expectedResponse) {
+ commsGood = true;
+ commsFailures = 0; // Reset consecutive failure count
+ }
+ else
+ {
+// pc.printf("Failed at: \r\n");
+// pc.printf("Random Number: %d\r\n", randomNumber);
+// pc.printf("Expected: %d\r\n", expectedResponse);
+// pc.printf("Actual: %d\r\n", actualResponse);
+
+ if (commsFailures++ > 3) { // Increment consecutive failure count
+ commsGood = false; // Flag comms failure after 3 failures (> 0.3 seconds)
+// pc.printf("Remote Comms Failure!\r\n");
+ }
+ }
+// pc.printf("commsGood: %d\r\n", commsGood);
+}
+
+// CONVERT BYTE TO BITS
+/*
+The received bytes from the remote control uses bitmapping.
+Each 0/1 bit represents the on/ off state of a switch.
+This function takes each bit and assigned it to a switch variable.
+*/
+void Remote::ByteToBits(unsigned char character, bool *boolArray)
+{
+ for (int i=0; i < 8; ++i) {
+ boolArray[i] = (character & (1<<i)) != 0;
+ }
+}
+
+void Remote::getSwitchStates() {
+ // GET THE SWITCH STATES FROM THE REMOTE CONTROL
+
+
+ bool bitGroupA[8] = {1, 1, 1, 1, 1, 1, 1, 1};
+ bool bitGroupB[8] = {1, 1, 1, 1, 1, 1, 1, 1};
+
+ char slaveReceivedA, slaveReceivedB; // BYTE RECEIVED FROM REMOTE CONTROL
+
+ slaveReceivedA = sendData(3, 3);
+ slaveReceivedB = sendData(4, 4);
+ throttle = sendData(5, 5);
+ braking = sendData(6, 6);
+
+ ByteToBits(slaveReceivedA, bitGroupA); // CONVERT GROUP A BYTE TO BITS
+ ByteToBits(slaveReceivedB, bitGroupB); // CONVERT GROUP B BYTE TO BITS
+
+ // ASSIGN VARIABLES FROM BIT GROUPS
+
+ start = bitGroupA[0];
+ forward = bitGroupA[1];
+ park = bitGroupA[2];
+ reverse = bitGroupA[3];
+ compressor = bitGroupA[4];
+ autoStop = bitGroupA[5];
+ regenBrake = bitGroupA[6];
+ regenThrottle = bitGroupA[7];
+
+ whistle = bitGroupB[0];
+ innovation = bitGroupB[1];
+
+// pc.printf("Start: %d\n\r", start);
+// pc.printf("Forward: %d\n\r", forward);
+// pc.printf("Park: %d\n\r", park);
+// pc.printf("Reverse: %d\n\r", reverse);
+// pc.printf("Compressor: %d\n\r", compressor);
+// pc.printf("AutoStop: %d\n\r", autoStop);
+// pc.printf("Regen Brake: %d\n\r", regenBrake);
+// pc.printf("Regen Throttle: %d\n\r", regenThrottle);
+// pc.printf("Whistle: %d\n\r", whistle);
+// pc.printf("Innovation: %d\n\r", innovation);
+// pc.printf("Throttle: %d\n\r", throttle);
+// pc.printf("Brake: %d\n\r", braking);
+
+}
+
+void Remote::setTime(int hr, int min, int sec, int day, int mon, int yr) {
+ _remoteControlCS = 0;
+
+ _remoteControl.write(7);
+ wait_us(spiDelay);
+ _remoteControl.write(hr);
+ wait_us(spiDelay);
+ _remoteControl.write(min);
+ wait_us(spiDelay);
+ _remoteControl.write(sec);
+ wait_us(spiDelay);
+ _remoteControl.write(day);
+ wait_us(spiDelay);
+ _remoteControl.write(mon);
+ wait_us(spiDelay);
+ _remoteControl.write(yr);
+ wait_us(spiDelay);
+ _remoteControl.write(255);
+
+ _remoteControlCS = 1; // DISABLE REMOTE SPI
+}
+
+void Remote::sendError(int error) {
+
+ bool errorInBuffer = false;
+
+ for (int index = 0; index < errorIndex; index++) {
+ if (errorBuffer[index] == error) {
+ errorInBuffer == true;
+ break;
+ }
+ }
+
+ if (errorInBuffer == false) {
+ errorBuffer[errorIndex++] = error;
+ }
+ else {
+ errorInBuffer = false; // reset
+ }
+
+ sendData(8, errorBuffer[0]);
+
+ for (int index = 0; index < errorIndex; index++) {
+ errorBuffer[index] = errorBuffer[index + 1];
+ }
+ errorIndex--;
+
+ wait_ms(100);
+}
\ No newline at end of file