687 lines
23 KiB
C++
687 lines
23 KiB
C++
//TODO:
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/*
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- reset Trip to 0 by button press or something. function: resetTrip()
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*/
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#include <Arduino.h>
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#include "definitions.h"
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//#include "structs.h"
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#include <TimeLib.h> //for teensy rtc
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#include "helpfunctions.h"
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#include "hoverboard-esc-serial-comm.h"
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#include "led.h"
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#include "temperature.h"
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String getLogFilename();
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bool getDatalogging();
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#include "display.h"
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#include "logging.h"
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#include "ADS1X15.h"
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ESCSerialComm escFront(Serial7);
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ESCSerialComm escRear(Serial2);
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ADS1115 ADS(0x48, &Wire); //Pins: https://www.pjrc.com/teensy/td_libs_Wire.html
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/*
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Serial Hoverboard Colors
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RX (Green) connect to TX on Teensy
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TX (Blue) connect to RX on Teensy
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*/
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void readADS();
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void readADC();
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void failChecks();
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//void sendCMD();
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void calculateSetSpeed(unsigned long timediff);
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void leds();
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void readButtons();
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void readADSButtons();
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uint16_t linearizeThrottle(uint16_t v, const uint16_t *pthrottleCurvePerMM, int arraysize,bool sorteddescending);
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time_t getTeensy3Time();
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// ########################## SETUP ##########################
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void setup()
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{
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Serial.begin(SERIAL_BAUD); //Debug and Program
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Serial1.begin(SERIAL_LOG_BAUD); //TX1=1, RX1=0
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pinMode(PIN_PWRBUTTON, INPUT_PULLUP); //Pressed=High
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if (!digitalRead(PIN_PWRBUTTON)) { //button is not pressed during startup means teensy is powered externally (usb)
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datalogging=false; //disable logging when connected via usb to not clutter up sd card
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Serial.println("PWRBUTTON not pressed. Logging disabled!");
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}
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pinMode(PIN_LED_START, OUTPUT); //Active High
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pinMode(PIN_FAN,OUTPUT);
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digitalWrite(PIN_FAN,HIGH); //Turn fan on during startup for debugging purposes
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pinMode(PIN_LATCH_ENABLE, OUTPUT);
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digitalWrite(PIN_LATCH_ENABLE,HIGH); //latch on
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init_led();
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led_testLEDSBlocking();
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delay(2000);
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Serial.println("Init Functions");
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led_simpeProgress(0,1);
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bool initResult=false;
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initResult=display_init();
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if (!initResult) {
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writeLogComment((unsigned long)millis(), "SSD1306 allocation failed");
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}
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led_simpeProgress(1,initResult);
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initResult=initLogging();
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led_simpeProgress(2,(initResult ? (datalogging ? 1:2):0)); //0=sd card fail, 1=sd ok and logging, 2(warn)=sd ok and logging off
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escFront.init();
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led_simpeProgress(3,true);
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escRear.init();
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led_simpeProgress(4,true);
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delay(2000);
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Serial.println("Wait finished. Booting..");
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led_simpeProgress(5,true);
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//init ADS1115
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if (!ADS.begin()) {
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Serial.println("Error:"); delay(2000); Serial.println("ADS1115 Init Error!");
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led_simpeProgress(6,false);
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writeLogComment((unsigned long)millis(), "Error ADS1115 Init");
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}else{
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ADS.setGain(0);
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ADS.setDataRate(7);// Read Interval: 7-> 2ms, 6-> 3-4ms , 5-> 5-6ms, 4-> 9ms, 0-> 124ms
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// also set ADSREADPERIOD to at least the read interval
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ADS.requestADC(0); //Start requesting a channel
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led_simpeProgress(6,true);
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}
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delay(10);
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for (uint8_t i=0;i<4;i++){ //read all channels once to have adc readings ready in first loop (to prevent premature failsafe)
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readADS();
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delay(10);
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}
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setSyncProvider(getTeensy3Time); //See https://www.pjrc.com/teensy/td_libs_Time.html#teensy3
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if (timeStatus()!= timeSet) {
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Serial.println("Unable to sync with the RTC");
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writeLogComment((unsigned long)millis(), "Unable to sync with the RTC");
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led_simpeProgress(7,false);
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} else {
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Serial.println("RTC has set the system time");
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led_simpeProgress(7,true);
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}
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if (sdcard_available) { //sd init was successful
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initResult=loadTripSD();
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}else{
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initResult=false;
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}
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led_simpeProgress(8,initResult);
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initTemperature();
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led_simpeProgress(9,true);
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writeLogComment(millis(), "Setup Finished");
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led_simpleProgressWait(); //wait longer if any errors were displayed with led_simpeProgress()
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Serial.println("Ready");
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}
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// ########################## LOOP ##########################
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void loop() {
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//Serial.print("Loopduration="); Serial.println(); //loopduration is at max 11ms
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loopmillis=millis(); //read millis for this cycle
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if (ADS.isConnected() && (loopmillis - last_adsread > ADSREADPERIOD) ) { //read teensy adc and filter
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last_adsread=loopmillis;
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if (ADS.isBusy() == false) //reads a register on ads
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{
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readADS();
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}else{
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Serial.println("Unnecessary ADS poll. Increase ADSREADPERIOD");
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}
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}
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static unsigned long last_adcread=0;
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if (loopmillis - last_adcread > ADCREADPERIOD) { //read teensy adc and filter
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last_adcread=loopmillis;
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readADC();
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}
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static unsigned long last_buttonread=0;
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if (loopmillis - last_buttonread > BUTTONREADPERIOD) { //read digital input states
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last_buttonread=loopmillis;
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readButtons();
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readADSButtons();
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}
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failChecks();
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static unsigned long last_calculateSetSpeed=0;
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if (loopmillis - last_calculateSetSpeed > SENDPERIOD) {
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unsigned long _timediff=loopmillis-last_calculateSetSpeed;
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last_calculateSetSpeed=loopmillis;
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calculateSetSpeed(_timediff);
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//Update Statistics
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max_filtered_currentAll=max(max_filtered_currentAll,filtered_currentAll);
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min_filtered_currentAll=min(min_filtered_currentAll,filtered_currentAll);
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max_filtered_wattAll=max(max_filtered_wattAll,filtered_currentAll*(escFront.getFeedback_batVoltage()+escRear.getFeedback_batVoltage())/2.0);
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min_filtered_wattAll=min(min_filtered_wattAll,filtered_currentAll*(escFront.getFeedback_batVoltage()+escRear.getFeedback_batVoltage())/2.0);
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max_meanSpeed=max(max_meanSpeed,(escFront.getMeanSpeed()+escRear.getMeanSpeed())/2);
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if (!armed) { //reset statistics if disarmed
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max_filtered_currentAll=0;
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min_filtered_currentAll=0;
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max_filtered_wattAll=0;
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min_filtered_wattAll=0;
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max_meanSpeed=0;
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}
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}
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escFront.update(loopmillis);
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escRear.update(loopmillis);
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static unsigned long last_statsupdate=0;
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#define STATSUPDATEINTERVAL 100
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if (loopmillis-last_statsupdate>STATSUPDATEINTERVAL) {
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minSpeedms=min(escFront.getWheelspeed_L(),min(escFront.getWheelspeed_R(),min(escRear.getWheelspeed_L(),escRear.getWheelspeed_R()))); //take speed of slowest wheel
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float _tripincrease=abs(minSpeedms) * ((loopmillis-last_statsupdate)/1000.0);
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trip+=_tripincrease;
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overallTrip+=_tripincrease;
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float _currentIncrease=(escFront.getFiltered_curL()+escFront.getFiltered_curR()+escRear.getFiltered_curL()+escRear.getFiltered_curR())* ((loopmillis-last_statsupdate)/1000.0)/3600.0; //amp hours
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float _watthoursIncrease=((escFront.getFiltered_curL()+escFront.getFiltered_curR())*escFront.getFeedback_batVoltage()+(escRear.getFiltered_curL()+escRear.getFiltered_curR())*escRear.getFeedback_batVoltage())* ((loopmillis-last_statsupdate)/1000.0)/3600.0; //amp hours
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currentConsumed += _currentIncrease;
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overallCurrentConsumed += _currentIncrease;
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watthoursConsumed += _watthoursIncrease;
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overallWatthoursConsumed += _watthoursIncrease;
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last_statsupdate=loopmillis;
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}
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loggingLoop(loopmillis,escFront,escRear);
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if (!armed && !statswritten) { //write stats only once when disarmed
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statswritten=true;
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writeTrip(loopmillis,escFront,escRear);
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}
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if (statswritten && armed) {
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statswritten=false;
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}
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leds();
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led_update(loopmillis,escFront,escRear); //ws2812 led ring
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static unsigned long last_display_update=0;
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if (loopmillis - last_display_update > DISPLAYUPDATEPERIOD) {
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last_display_update=loopmillis;
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display_update(escFront,escRear);
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}
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//Temperature
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if (!temperatureLoop(loopmillis)){
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writeLogComment(loopmillis, "Request Temperatures Timeout!");
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}
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//Fan
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static unsigned long last_fan_update=0;
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#define FANUPDATEPERIOD 5000
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float fan_turn_on_temp=45;
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float fan_turn_off_temp=32;
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if (loopmillis - last_fan_update > FANUPDATEPERIOD) {
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last_fan_update=loopmillis;
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boolean fanstatus=digitalRead(PIN_FAN);
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//float temp=max(escFront.getFeedback_boardTemp(),escRear.getFeedback_boardTemp());
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float temp=max(temp_Front,temp_Rear);
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if (temp_Front==DEVICE_DISCONNECTED_C || temp_Rear==DEVICE_DISCONNECTED_C ) { //temperature error
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digitalWrite(PIN_FAN,HIGH); //force fan on
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}else{ //normal temperature control_currentIncrease
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if (!fanstatus) { //fan is off
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if (temp>=fan_turn_on_temp){
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digitalWrite(PIN_FAN,HIGH);
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}
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}else{ //fan is on
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if (temp<=fan_turn_off_temp){
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digitalWrite(PIN_FAN,LOW);
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}
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}
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}
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}
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serialCommandLoop(loopmillis,escFront,escRear);
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looptime_duration_min=min(looptime_duration_min,millis()-loopmillis);
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looptime_duration_max=max(looptime_duration_max,millis()-loopmillis);
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}
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time_t getTeensy3Time()
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{
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return Teensy3Clock.get();
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}
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void readADS() { //sequentially read ads and write to variable
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/*static unsigned long _lastReadADS=0;
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Serial.print("readADS Interval="); Serial.println(millis()-_lastReadADS);
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_lastReadADS=millis();*/
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static uint8_t ads_input_switch=0;
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int16_t ads_val = ADS.getValue(); //get value from last selected channel
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switch (ads_input_switch) {
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case 0: //Throttle Sensor A
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ads_throttle_A_raw=ads_val;
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break;
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case 1: //Throttle Sensor B
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ads_throttle_B_raw=ads_val;
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break;
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case 2: //Brake
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ads_brake_raw=ads_val;
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break;
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case 3: //Buttons
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ads_control_raw=ads_val;
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break;
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}
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ads_input_switch++;
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ads_input_switch%=4; //max 4 channels
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ADS.requestADC(ads_input_switch); // request a new one
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}
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// #### LOOPFUNCTIONS
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void readADC() {
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//Serial.print(ads_throttle_A_raw); Serial.print('\t');
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//Serial.print(ads_throttle_B_raw); Serial.print('\t');
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//Serial.print(ads_brake_raw); Serial.print('\t');
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//Serial.print(ads_control_raw); Serial.println();
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//throttle_raw = (ads_throttle_A_raw+ads_throttle_B_raw)/2.0*THROTTLE_ADC_FILTER + throttle_raw*(1-THROTTLE_ADC_FILTER); //apply filter
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throttle_rawA=ads_throttle_A_raw;
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throttle_rawB=ads_throttle_B_raw;
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//maps throttle curve to be linear
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//throttle_pos=max(0,min(1000,linearizeThrottle(throttle_raw))); //map and constrain
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throttle_posA=max(0,min(1000, linearizeThrottle(ads_throttle_A_raw, throttleCurvePerMM_A, sizeof(throttleCurvePerMM_A)/sizeof(throttleCurvePerMM_A[0]), throttleCurvePerMM_A_Descending ) )); //map and constrain
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throttle_posB=max(0,min(1000, linearizeThrottle(ads_throttle_B_raw, throttleCurvePerMM_B, sizeof(throttleCurvePerMM_B)/sizeof(throttleCurvePerMM_B[0]), throttleCurvePerMM_B_Descending ) )); //map and constrain
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//Serial.print(throttle_posA); Serial.print('\t');
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//Serial.print(throttle_posB); Serial.print('\t');
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int16_t throttle_posMean = (throttle_posA+throttle_posB)/2.0;
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throttle_pos = throttle_posMean*THROTTLE_ADC_FILTER + throttle_pos*(1-THROTTLE_ADC_FILTER); //apply filter
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brake_raw=ads_brake_raw;
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brake_pos=max(0,min(1000,map(brake_raw,calib_brake_min,calib_brake_max,0,1000))); //map and constrain
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//brake_pos = (int16_t)(pow((brake_pos/1000.0),2)*1000);
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if (throttle_pos>0 || ((escFront.getMeanSpeed()+escRear.getMeanSpeed())/2.0) >0.5 || (!reverse_enabled && brake_pos>0)) { //reset idle time on these conditions (disables reverse driving)
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last_notidle=loopmillis;
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reverse_enabled=false;
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}
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if (loopmillis-last_notidle > REVERSE_ENABLE_TIME) {
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reverse_enabled=true;
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}
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int16_t throttlebreak_pos = throttle_pos-brake_pos*2; //reduce throttle_when applying brake
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throttle_pos=constrain(throttlebreak_pos,0,1000);
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brake_pos=constrain(-throttlebreak_pos/2,0,1000); //rescale brake value from throttlebreak_pos
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}
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void failChecks() {
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static bool laststate_Front_getControllerConnected;
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if ( !escFront.getControllerConnected() && laststate_Front_getControllerConnected) { //controller got disconnected and was connected before
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laststate_Front_getControllerConnected=false;
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writeLogComment(loopmillis, "Controller Front feedback timeout");
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}else if( escFront.getControllerConnected() && !laststate_Front_getControllerConnected) { //controller was disconnected and is now connected
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laststate_Front_getControllerConnected=true;
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writeLogComment(loopmillis, "Controller Front connected");
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}
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static bool laststate_Rear_getControllerConnected;
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if ( !escRear.getControllerConnected() && laststate_Rear_getControllerConnected) { //controller got disconnected and was connected before
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laststate_Rear_getControllerConnected=false;
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writeLogComment(loopmillis, "Controller Rear feedback timeout");
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}else if( escRear.getControllerConnected() && !laststate_Rear_getControllerConnected) { //controller was disconnected and is now connected
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laststate_Rear_getControllerConnected=true;
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writeLogComment(loopmillis, "Controller Rear connected");
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}
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controllers_connected=escFront.getControllerConnected() & escRear.getControllerConnected();
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//ADC Range Check
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static unsigned long throttle_ok_time=0;
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if ((ads_throttle_A_raw >= failsafe_throttle_min_A) & (ads_throttle_A_raw <= failsafe_throttle_max_A) & (ads_throttle_B_raw >= failsafe_throttle_min_B) & (ads_throttle_B_raw <= failsafe_throttle_max_B)) { //inside safe range (to check if wire got disconnected)
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throttle_ok_time=loopmillis;
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}
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if (loopmillis>throttle_ok_time+ADC_OUTOFRANGE_TIME) { //not ok for too long
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if (!error_throttle_outofrange) {
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error_throttle_outofrange=true;
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writeLogComment(loopmillis, "Error Throttle ADC Out of Range. A="+(String)ads_throttle_A_raw+" B="+(String)ads_throttle_B_raw);
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}
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//Serial.print("Error Throttle ADC Out of Range="); Serial.println(throttle_raw);
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}
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static unsigned long throttlediff_ok_time=0;
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if (abs(throttle_posA-throttle_posB) <= failsafe_throttle_maxDiff) { //inside safe range (to check if wire got disconnected)
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throttlediff_ok_time=loopmillis;
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}
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if (loopmillis>throttlediff_ok_time+ADC_DIFFHIGH_TIME) { //not ok for too long
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if (!error_throttle_difftoohigh) {
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error_throttle_difftoohigh=true;
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writeLogComment(loopmillis, "Error Throttle Diff too High. A="+(String)ads_throttle_A_raw+" B="+(String)ads_throttle_B_raw);
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}
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//Serial.print("Error Throttle ADC Out of Range="); Serial.println(throttle_raw);
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}
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static unsigned long brake_ok_time=0;
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if ((brake_raw >= failsafe_brake_min) & (brake_raw <= failsafe_brake_max)) { //outside safe range. maybe wire got disconnected
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brake_ok_time=loopmillis;
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}
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if (loopmillis>brake_ok_time+ADC_OUTOFRANGE_TIME) { //not ok for too long
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if(!error_brake_outofrange) {
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error_brake_outofrange=true;
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writeLogComment(loopmillis, "Error Brake ADC Out of Range. ADC="+(String)brake_raw);
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}
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//Serial.print("Error Brake ADC Out of Range="); Serial.println(brake_raw);
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}
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#define ADS_MAX_READ_INTERVAL 100
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if (loopmillis-last_adsread > ADS_MAX_READ_INTERVAL) {
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if (!error_ads_max_read_interval) {
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error_ads_max_read_interval=true;
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writeLogComment(loopmillis, "Error ADS Max read interval");
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}
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//Serial.print("Error ADS Max read interval="); Serial.println(loopmillis-last_adsread);
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}
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boolean logged_error_sdfile_unavailable=false;
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if (error_sdfile_unavailable && !logged_error_sdfile_unavailable) {
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logged_error_sdfile_unavailable=true;
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writeLogComment(loopmillis, "Error SDFile Unavailable");
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}
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|
|
|
if (!controllers_connected || error_brake_outofrange || error_throttle_outofrange || error_throttle_difftoohigh || error_ads_max_read_interval) { //any errors?
|
|
armed=false; //disarm
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|
throttle_pos=0;
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|
brake_pos=0;
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}
|
|
}
|
|
|
|
void calculateSetSpeed(unsigned long timediff){
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|
|
|
int16_t adjusted_throttle_pos=constrain(throttle_pos*(throttle_max/1000.0),0,throttle_max);
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|
|
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int16_t brake_pos_expo = (int16_t)(pow((brake_pos/1000.0),2)*1000);
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|
|
|
float brakepedal_current_multiplier=startbrakecurrent/1000.0; //how much breaking (in Ampere) for unit of brake_pos (0<=brake_pos<=1000)
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|
|
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int16_t cmdreduce_constant=map(brake_pos_expo,0,1000,0,(int16_t)(brake_cmdreduce_proportional*timediff/1000)); //reduce cmd value every cycle
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|
|
|
float freewheel_current=startbrakecurrent_offset-brake_pos_expo*brakepedal_current_multiplier; //above which driving current cmd send will be reduced more. increase value to decrease breaking. values <0 increases breaking above freewheeling
|
|
|
|
|
|
float filtered_currentFront=max(escFront.getFiltered_curL(),escFront.getFiltered_curR());
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float filtered_currentRear=max(escRear.getFiltered_curL(),escRear.getFiltered_curR());
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|
|
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filtered_currentAll=filtered_currentFront+filtered_currentRear; //positive value is current Drawn from battery. negative value is braking current
|
|
|
|
|
|
if(adjusted_throttle_pos<last_cmd_send){ //freewheeling or braking
|
|
if (filtered_currentAll>freewheel_current) { //drive current too high
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|
cmd_send-= max(0, (filtered_currentAll-freewheel_current)*freewheel_break_factor*(timediff/1000.0)); //how much current over freewheel current, multiplied by factor. reduces cmd_send value
|
|
}
|
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cmd_send-=max(minimum_constant_cmd_reduce,cmdreduce_constant); //reduce slowly anyways
|
|
|
|
}
|
|
|
|
//acceleration
|
|
cmd_send += constrain(adjusted_throttle_pos-cmd_send,0,(int16_t)(max_acceleration_rate*(timediff/1000.0)) ); //if throttle higher than last applied value, apply throttle directly
|
|
|
|
cmd_send=constrain(cmd_send,0,throttle_max);
|
|
|
|
last_cmd_send=cmd_send;
|
|
|
|
int16_t cmd_send_toMotor=constrain(cmd_send* (1.0-(brake_pos*0.5/1000.0) ) ,0,throttle_max); //brake "ducking"
|
|
|
|
|
|
if (reverse_enabled) {
|
|
cmd_send_toMotor-=brake_pos*reverse_speed;
|
|
}
|
|
|
|
if (!controllers_connected || !armed) { //controllers not connected or not armed
|
|
cmd_send=0;
|
|
cmd_send_toMotor=0; //safety off
|
|
}
|
|
|
|
escFront.setSpeed(cmd_send_toMotor,cmd_send_toMotor);
|
|
escRear.setSpeed(cmd_send_toMotor,cmd_send_toMotor);
|
|
|
|
log_update=true;
|
|
}
|
|
|
|
|
|
|
|
|
|
void leds() {
|
|
//Start LED
|
|
if (!armed) { //disarmed
|
|
digitalWrite(PIN_LED_START,((loopmillis/1000)%2 == 0)); //high is on for LED_START. blink every second. loopmillis 0 - 1000 led is on.
|
|
}else{ //armed
|
|
digitalWrite(PIN_LED_START,HIGH); //LED On
|
|
}
|
|
|
|
|
|
}
|
|
|
|
void readButtons() {
|
|
bool button_start_longpress_flag=false;
|
|
bool button_start_shortpress_flag=false;
|
|
|
|
static bool button_start_wait_release_flag=false;
|
|
bool last_button_start_state=button_start_state;
|
|
|
|
|
|
if (loopmillis > button_start_lastchange+DEBOUNCE_TIME) { //wait some time after last change
|
|
if (digitalRead(PIN_PWRBUTTON) && !button_start_state) { //start engine button pressed and was not pressed before
|
|
button_start_state=true; //pressed
|
|
button_start_lastchange=loopmillis; //save time for debouncing
|
|
}else if (!digitalRead(PIN_PWRBUTTON) && button_start_state) { //released an was pressed before
|
|
button_start_state=false; // not pressed
|
|
button_start_lastchange=loopmillis; //save time for debouncing
|
|
}
|
|
}
|
|
|
|
if (!button_start_wait_release_flag) { //action not prohibited currently
|
|
if (button_start_state) { //button is pressed
|
|
if ( (loopmillis> button_start_lastchange + LONG_PRESS_ARMING_TIME)) { //pressed long
|
|
button_start_longpress_flag=true;
|
|
button_start_wait_release_flag=true; //do not trigger again until button released
|
|
}
|
|
}else if(!button_start_state && last_button_start_state) { //just released
|
|
button_start_shortpress_flag=true;
|
|
}
|
|
}
|
|
|
|
if (!button_start_state) { //release wait flag at end if button released
|
|
button_start_wait_release_flag=false;
|
|
}
|
|
|
|
|
|
if (button_start_shortpress_flag) {
|
|
armed=false; //disarm
|
|
writeLogComment(loopmillis, "Disarmed by button");
|
|
}
|
|
if (button_start_longpress_flag) {
|
|
if (escFront.getControllerConnected() && escRear.getControllerConnected()) {
|
|
armed=true; //arm if button pressed long enough
|
|
writeLogComment(loopmillis, "Armed by button");
|
|
if (control_buttonA) { //button A is held down during start button press
|
|
throttle_max=1000;
|
|
reverse_speed=0.25;
|
|
}else if (control_buttonB) { //button B is held down during start button press
|
|
throttle_max=750;
|
|
reverse_speed=0.25;
|
|
}else { //no control button pressed during start
|
|
throttle_max=250;
|
|
reverse_speed=0.15;
|
|
}
|
|
|
|
}else{
|
|
writeLogComment(loopmillis, "Unable to arm");
|
|
}
|
|
|
|
}
|
|
|
|
}
|
|
|
|
void readADSButtons() {
|
|
bool last_control_buttonA=control_buttonA;
|
|
bool last_control_buttonB=control_buttonB;
|
|
if ( (ads_control_raw > (calib_control_buttonA-calib_control_treshold)) && (ads_control_raw < (calib_control_buttonA+calib_control_treshold) ) ) {
|
|
control_buttonA=true;
|
|
control_buttonB=false;
|
|
}else if ( (ads_control_raw > (calib_control_buttonB-calib_control_treshold)) && (ads_control_raw < (calib_control_buttonB+calib_control_treshold) ) ) {
|
|
control_buttonA=false;
|
|
control_buttonB=true;
|
|
}else if ( (ads_control_raw > (calib_control_buttonAB-calib_control_treshold)) && (ads_control_raw < (calib_control_buttonAB+calib_control_treshold) ) ) {
|
|
control_buttonA=true;
|
|
control_buttonB=true;
|
|
}else if ( ads_control_raw > calib_control_max){
|
|
control_buttonA=false;
|
|
control_buttonB=false;
|
|
}
|
|
|
|
if (control_buttonA && !last_control_buttonA) { //button A was just pressed
|
|
writeLogComment(loopmillis, "Button A Pressed");
|
|
|
|
if (!armed) { //standing disarmed display is showing
|
|
if (standingDisplayScreen<NUM_STANDINGDISPLAYSCREEN-1){
|
|
standingDisplayScreen++;
|
|
}
|
|
}
|
|
}
|
|
|
|
if (control_buttonB && !last_control_buttonB) { //button B was just pressed
|
|
writeLogComment(loopmillis, "Button B Pressed");
|
|
|
|
if (!armed) { //standing disarmed display is showing
|
|
if (standingDisplayScreen>0){
|
|
standingDisplayScreen--;
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
|
|
uint16_t linearizeThrottle(uint16_t v, const uint16_t *pthrottleCurvePerMM, int arraysize,bool sorteddescending) {
|
|
//input is raw adc value from hall sensor
|
|
//uses pthrottleCurvePerMM array to find linear approximation of actual throttle travel
|
|
//array has to be sorted ! if sorteddescending=false then sorted ascending, if true then array should be sorted descending
|
|
uint8_t _searchpos=0;
|
|
//uint8_t arraysize = sizeof(pthrottleCurvePerMM)/sizeof(pthrottleCurvePerMM[0]);
|
|
while (_searchpos < arraysize && v>pthrottleCurvePerMM[(sorteddescending?(arraysize-1-_searchpos):_searchpos)]) { //find arraypos with value above input value
|
|
_searchpos++; //try next value
|
|
}
|
|
|
|
if (_searchpos <=0) { //lower limit
|
|
return (sorteddescending?1000:0);
|
|
}
|
|
if (_searchpos >= arraysize) { //upper limit
|
|
return (sorteddescending?0:1000);
|
|
}
|
|
|
|
uint16_t nextLower=pthrottleCurvePerMM[(sorteddescending?(arraysize-1-_searchpos):_searchpos)-(sorteddescending?0:1)];
|
|
uint16_t nextHigher=pthrottleCurvePerMM[(sorteddescending?(arraysize-1-_searchpos):_searchpos)-(sorteddescending?1:0)];
|
|
float _linearThrottle = _searchpos+map(v*1.0,nextLower,nextHigher,0.0,1.0);
|
|
_linearThrottle/=arraysize; //scale to 0-1
|
|
_linearThrottle*=1000; //scale to 0-1000
|
|
if (sorteddescending){
|
|
_linearThrottle=1000-_linearThrottle; //invert result
|
|
}
|
|
return (uint16_t)_linearThrottle;
|
|
} |