remove unused folders

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interfisch 2022-03-27 09:34:37 +02:00
parent 92fbaf3ceb
commit 603e1b1de7
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@ -1,852 +0,0 @@
//https://github.com/rogerclarkmelbourne/Arduino_STM32 in arduino/hardware
//Board: Generic STM32F103C series
//Upload method: serial
//20k RAM 64k Flash
//may need 3v3 from usb ttl converter (hold down flash button while connecting). Holding down the power button is not needed in this case.
//Sometimes reconnecting the usb ttl converter to the pc helps just before pressing the upload button
/* TODO:
* Do not immediately drive backwards.
*/
// RX(green) is A10 , TX (blue) ist A9 (3v3 level)
//to flash set boot0 (the one further away from reset button) to 1 and press reset, flash, program executes immediately
//set boot0 back to 0 to run proPIN_GAMETRAK_VERTICALgram on powerup
// ########################## DEFINES ##########################
#define SERIAL_CONTROL_BAUD 38400 // [-] Baud rate for HoverSerial (used to communicate with the hoverboard)
#define SERIAL_BAUD 115200 // [-] Baud rate for built-in Serial (used for the Serial Monitor)
#define START_FRAME 0xAAAA // [-] Start frme definition for reliable serial communication
//#define DEBUG_RX // [-] Debug received data. Prints all bytes to serial (comment-out to disable)
//#define MAXADCVALUE 4095
#define ADC_CALIB_THROTTLE_LOWEST 1900 //a bit above adc value if throttle it not touched
#define ADC_CALIB_THROTTLE_MIN 2000 //minimum adc value that should correspond to 0 speed
#define ADC_CALIB_THROTTLE_MAX 3110 //maximum adc value that should correspond to full speed
#define ADC_CALIB_BRAKE_MIN 800 //minimum adc value that should correspond to 0 speed
#define ADC_CALIB_BRAKE_MAX 2400 //maximum adc value that should correspond to full speed
#define PIN_STARTLED PA0 //Red LED inside Engine Start Button. Powered with 5V via transistor
uint8_t startled=0;
#define PIN_STARTBUTTON PB8 //"Enginge Start" Button. connected To NC (=LOW). HIGH when pressed
#define STARTBUTTON_DOWN digitalRead(PIN_STARTBUTTON)
#define SENDPERIOD 50 //ms. delay for sending speed and steer data to motor controller via serial
#define PIN_THROTTLE PA4
#define PIN_BRAKE PA5
#define PIN_ENABLE PB9
#define PIN_MODESWITCH PB5 // LOW if pressed in ("down")
#define MODESWITCH_DOWN !digitalRead(PIN_MODESWITCH)
#define PIN_MODELED_GREEN PA12
#define PIN_MODELED_RED PA11
uint8_t modeled_green=0;
uint8_t modeled_red=0;
long last_ledupdate=0;
#define PIN_RELAISFRONT PB15 //connected to relais which presses the powerbutton of the hoverboard for the front wheels
#define PIN_RELAISREAR PB14 //connected to relais which presses the powerbutton of the hoverboard for the rear wheels
#define DEBOUNCETIME 20 //time to not check for inputs after key press
#define BUTTONTIMEHOLD 750 //time for button hold
long millis_lastinput=0; //for button debounce
long timebuttonpressed_start;
boolean button_start=false;
boolean button_hold_start=false;
#define TIME_AUTOPOWEROFF 600000 //600000 = 10 minutes
long loopmillis=0; //only use one millis reading each loop
long last_looptime=0; //for looptiming
#define LOOPTIME 10 //how often the loop(s) should run
long millis_lastchange=0; //for poweroff after some time with no movement
#define MAXBRAKERATE 7 //maximum rate for braking (loop timing)
String errormessage=""; //store some error message to print
//Mode change variables
uint8_t state_modechange=0;
long state_modechange_time=0;
long millis_lastadc=0;
#define ADC_READTIME 10 //time interval to read adc (for filtering)
#define ADC_THROTTLE_FILTER 0.4 //low value = slower change
#define ADC_BRAKE_FILTER 0.4 //low value = slower change
int adc_throttle_raw=0; //raw throttle value from adc
float adc_throttle=0; //filtered value
int adc_brake_raw=0; //raw throttle value from adc
float adc_brake=0; //filtered value
int16_t out_speedFL=0;
int16_t out_speedFR=0;
int16_t out_speedRL=0;
int16_t out_speedRR=0;
long last_send = 0;
boolean board1Enabled=false;
boolean board2Enabled=false;
// Global variables for serial communication
//Serial1 (Rear)
uint8_t idx1 = 0; // Index for new data pointer
uint16_t bufStartFrame1; // Buffer Start Frame
byte *p1; // Pointer declaration for the new received data
byte incomingByte1;
byte incomingBytePrev1;
long lastValidDataSerial1_time;
long board1lastPoweron=0; //mainly for failcheck
long board1lastPoweroff=0;
//Same for Serial2 (Front)
uint8_t idx2 = 0; // Index for new data pointer
uint16_t bufStartFrame2; // Buffer Start Frame
byte *p2; // Pointer declaration for the new received data
byte incomingByte2;
byte incomingBytePrev2;
long lastValidDataSerial2_time;
long board2lastPoweron=0; //mainly for failcheck
long board2lastPoweroff=0;
typedef struct{
uint16_t start;
int16_t speedLeft;
int16_t speedRight;
uint16_t checksum;
} SerialCommand;
SerialCommand Command1;
SerialCommand Command2;
typedef struct{
uint16_t start;
int16_t cmd1;
int16_t cmd2;
int16_t speedL;
int16_t speedR;
int16_t speedL_meas;
int16_t speedR_meas;
int16_t batVoltage;
int16_t boardTemp;
int16_t curL_DC;
int16_t curR_DC;
uint16_t checksum;
} SerialFeedback;
SerialFeedback Feedback1;
SerialFeedback NewFeedback1;
SerialFeedback Feedback2;
SerialFeedback NewFeedback2;
#define A2BIT_CONV 50 //divide curL_DC value by A2BIT_CONV to get current in amperes. Take this value from hoverboard firmware config.h
enum mode{booting, idle, on, error, off};
/*
* idle: controller is on, hoverboards are off
* on: hoverbaords are on and happy
* error: some error occured, stop everything and show errors
* off: shutdown triggered. will power down latch soon
*/
mode currentmode; //current active mode
mode requestmode; //change this variable to initiate a mode change
mode last_requestmode=off; //for printout
mode last_currentmode=off; //for printout
// ########################## SETUP ##########################
void setup()
{
Serial.begin(SERIAL_BAUD); //Debug and Program. A9=TX1, A10=RX1 (3v3 level)
Serial2.begin(SERIAL_CONTROL_BAUD); //control. A2=TX2, A3=RX2 (Serial1 is Usart 2). Marked with "1" on connector (Rear)
Serial3.begin(SERIAL_CONTROL_BAUD); //control. B10=TX3, B11=RX3 (Serial2 is Usart 3). Marked with "II" on connector (Front)
// Pin Setup
pinMode(PIN_STARTLED, OUTPUT); //MODE=PWM (needs testing, mcu locks up when using writePWM()
pinMode(PIN_ENABLE, OUTPUT);
digitalWrite(PIN_ENABLE, HIGH); //keep power on
pinMode(PIN_STARTBUTTON, INPUT_PULLUP);
pinMode(PIN_MODESWITCH, INPUT_PULLUP);
pinMode(PIN_MODELED_GREEN, OUTPUT);
pinMode(PIN_MODELED_RED, OUTPUT);
pinMode(PIN_RELAISFRONT, OUTPUT);
pinMode(PIN_RELAISREAR, OUTPUT);
pinMode(PIN_THROTTLE, INPUT);
pinMode(PIN_BRAKE, INPUT);
Serial.println("Initialized Serial");
Serial2.println("Initialized Serial1");
Serial3.println("Initialized Serial2");
currentmode = booting; //start in idle mode
requestmode = currentmode;
millis_lastchange=millis();
}
// ########################## LOOP ##########################
void loop() {
loopmillis=millis(); //read millis for this cycle
ReceiveSerial1(); // Check for new received data
ReceiveSerial2(); // Check for new received data
handleInputs();
if (button_start) {
Serial.println("button_start");
}
if (button_hold_start) {
Serial.println("button_hold_start");
}
handleModeChange(); //mode changes
if (last_requestmode!=requestmode) {
Serial.print("requestmode="); Serial.println(modeToString(requestmode));
last_requestmode=requestmode;
}
if (last_currentmode!=currentmode) {
Serial.print("currentmode="); Serial.println(modeToString(currentmode));
last_currentmode=currentmode;
}
ledUpdate();
modeloops();
if (loopmillis - last_send > SENDPERIOD) {
last_send=loopmillis;
if (currentmode!=off || currentmode!=idle) { //if boards should be powered on
SendSerial2(out_speedFL,out_speedFR); //Front
SendSerial1(out_speedRL,out_speedRR); //Rear
}
if (currentmode==on) {
/*Serial.print("lastData1="); Serial.print(loopmillis-lastValidDataSerial1_time); Serial.print(", lastData2=");Serial.print(loopmillis-lastValidDataSerial2_time);
Serial.print(", speedFL="); Serial.print(out_speedFL);
float _current = (Feedback1.curL_DC+Feedback1.curR_DC+Feedback2.curL_DC+Feedback2.curR_DC)/4.0 / 50;
Serial.print(", current="); Serial.print(_current);*/
float _current = (Feedback1.curL_DC+Feedback1.curR_DC+Feedback2.curL_DC+Feedback2.curR_DC)/4.0 / 50;
Serial.print(Feedback1.curL_DC); Serial.print(", "); //1 is rear
Serial.print(Feedback1.curR_DC); Serial.print(", ");
Serial.print(Feedback2.curL_DC); Serial.print(", "); //2 is front
Serial.print(Feedback2.curR_DC);
Serial.print(", mean="); Serial.print(_current);
Serial.println();
}
}
if (currentmode!=error) { //keep last errormessage
failChecks();
}
}
void handleInputs()
{
//Short press (true when button short pressed, on release)
button_start=false;
//long press (true when button is held down for BUTTONTIMEHOLD, on time elapsed)
button_hold_start=false;
if (loopmillis-millis_lastinput>DEBOUNCETIME) //Button debouncing
{
//Trigger
if (timebuttonpressed_start == 0 && STARTBUTTON_DOWN){ //first time pressed down. (low when pressed)
timebuttonpressed_start=loopmillis; //set time of button press
millis_lastinput=loopmillis;
}else if(timebuttonpressed_start != 0 && !STARTBUTTON_DOWN){ //button released (was pressed)
if (loopmillis-timebuttonpressed_start < BUTTONTIMEHOLD){ //short press
button_start=true;
}
timebuttonpressed_start=0; //re-enable after short press and release from hold
millis_lastinput=loopmillis;
}else if(loopmillis-timebuttonpressed_start >= BUTTONTIMEHOLD && timebuttonpressed_start>0){ //held down long enough and not already hold triggered
button_hold_start=true;
timebuttonpressed_start=-1; //-1 as flag for hold triggered
}
}
if ( button_start || button_hold_start) {
millis_lastchange=loopmillis; //for auto poweroff
millis_lastinput=loopmillis; //for debouncing
}
if (loopmillis-millis_lastadc>ADC_READTIME) {
adc_throttle_raw = analogRead(PIN_THROTTLE);
adc_throttle = adc_throttle*(1-ADC_THROTTLE_FILTER) + adc_throttle_raw*ADC_THROTTLE_FILTER;
adc_brake_raw = analogRead(PIN_BRAKE);
adc_brake = adc_brake*(1-ADC_BRAKE_FILTER) + adc_brake_raw*ADC_BRAKE_FILTER;
if (adc_throttle_raw >= ADC_CALIB_THROTTLE_MIN || adc_brake_raw >= ADC_CALIB_BRAKE_MIN) { //throttle or brake pressed
millis_lastchange=loopmillis;
}
millis_lastadc=loopmillis;
}
if (loopmillis-millis_lastchange>TIME_AUTOPOWEROFF){
requestmode = off;
}
}
void handleModeChange() {
if (currentmode==requestmode) { //## Not currently changing modes ##
switch (currentmode) { //mode dependant
case booting: //on startup. active while start button is still pressed
if (button_start) { //button first release
requestmode=idle; //start in idle state
state_modechange=0; //reset state for safety
}//TODO else if (button_hold_start) { requestmode=on; }
break;
case idle:
if (button_hold_start){ //long press
requestmode=on; //long press switches betweeen idle and on
state_modechange=0; //start at state 0
}
if (button_start) { //short press
requestmode=off;
state_modechange=0;
}
break;
case on:
if (button_hold_start){ //long press
requestmode=idle; //long press switches betweeen idle and on
state_modechange=0; //start at state 0
}
if (button_start) { //short press
requestmode=off;
state_modechange=0;
}
break;
case error:
if (button_start) { //short press
requestmode=off;
state_modechange=0;
}
break;
case off:
break;
default:
currentmode=error; //something else? -> error
}
}else{ // ## Change requested ##
switch (requestmode) { //mode changes
case booting:
requestmode=error;
currentmode=requestmode;
errormessage="Change to booting mode cannot be requested";
break;
case idle: case on: case off: //similar for on, idle and off
if (currentmode == booting) { //coming from booting mode
currentmode=idle; //switch directly without powering boards
requestmode=currentmode; //make shure it stay in this mode
state_modechange=0;
break;
}
if ( (state_modechange>0 || (requestmode==idle && boardsPowered()) || (requestmode==off && boardsPowered()) || (requestmode==on && !boardsPowered()) )) { //power cylce in progress OR need to power on/off boards
//Hoverboard powering
switch(state_modechange) {
case 0:
if (requestmode==on && (adc_throttle > ADC_CALIB_THROTTLE_LOWEST || adc_brake > ADC_CALIB_BRAKE_MIN) ) { //requested to turn on but throttle or brake is pressed
state_modechange=0;
requestmode=currentmode; //abort modechange
//TODO: led show aborted modechange
}else{ //everythings fine, turn on/off
digitalWrite(PIN_RELAISFRONT,HIGH); //simulate hoverboard power button press
//Front board is Serial2
if (requestmode==on) {
board2Enabled=true; //assume board is online
board2lastPoweron=loopmillis; //save time at which board was powered on
// ### Request Idle or Off ###
}else if(requestmode==idle || requestmode==off) {
board2Enabled=false; //assume board is offline
board2lastPoweroff=loopmillis; //save time at which board was powered off
}
state_modechange++;
state_modechange_time=loopmillis; //set to current time
Serial.println("PIN_RELAISFRONT,HIGH");
}
break;
case 1:
if (loopmillis - state_modechange_time > 200) { //wait some time
digitalWrite(PIN_RELAISFRONT,LOW); //release simulated button
state_modechange++;
state_modechange_time=loopmillis; //set to current time
Serial.println("PIN_RELAISFRONT,LOW");
}
break;
case 2:
if (loopmillis - state_modechange_time > 200) { //wait some time
digitalWrite(PIN_RELAISREAR,HIGH); //simulate hoverboard power button press
//Rear board is Serial1
if (requestmode==on) {
board1Enabled=true; //assume board is online
board1lastPoweron=loopmillis; //save time at which board was powered on
// ### Request Idle or Off ###
}else if(requestmode==idle || requestmode==off) {
board1Enabled=false; //assume board is offline
board1lastPoweroff=loopmillis; //save time at which board was powered off
}
state_modechange++;
state_modechange_time=loopmillis; //set to current time
Serial.println("PIN_RELAISREAR,HIGH");
}
break;
case 3:
if (loopmillis - state_modechange_time > 200) { //wait some time
digitalWrite(PIN_RELAISREAR,LOW); //release simulated button
state_modechange++;
state_modechange_time=loopmillis; //set to current time
Serial.println("PIN_RELAISREAR,LOW");
}
break;
case 4:
if (loopmillis - state_modechange_time > 1000) { //wait some time after turning on/off
state_modechange++;
state_modechange_time=loopmillis; //set to current time
Serial.println("Waiting finished");
}
break;
default: //finished modechange
currentmode=requestmode;
state_modechange=0;
break;
}
}else{
currentmode=requestmode;
state_modechange=0; //for safety
//Should not happen
Serial.print("Warning: power cycle not needed. board1Enabled="); Serial.print(board1Enabled); Serial.print("board2Enabled="); Serial.println(board2Enabled);
}
break;
case error:
currentmode=error; //stay in this mode
break;
default:
currentmode=error;
}
}
}
void modeloops() {
if (loopmillis - last_looptime >= LOOPTIME) {
last_looptime=loopmillis;
//loop_test(); //for testing (adc calibration prints). comment out following switch case
switch (currentmode) { //mode changes
case booting:
break;
case idle:
loop_idle();
break;
case on:
loop_on();
break;
case error:
loop_error();
break;
case off:
loop_off();
break;
}
}
}
void loop_idle() {
out_speedFL=out_speedFR=out_speedRR=out_speedRL=0; //stop motors
}
void loop_on() {
int _maxspeed=1000;
int _maxbrake=400;
if (MODESWITCH_DOWN) {
_maxspeed=200;
_maxbrake=200;
}
/*
uint16_t throttlevalue=constrain( map(adc_throttle, ADC_CALIB_THROTTLE_MIN, ADC_CALIB_THROTTLE_MAX, 0, _maxspeed ) ,0, _maxspeed);
int16_t brakevalue=constrain( map(adc_brake, ADC_CALIB_BRAKE_MIN, ADC_CALIB_BRAKE_MAX, 0, _maxbrake ) ,0, _maxbrake); //positive value for braking
int16_t speedvalue=throttlevalue*(1- (((float)brakevalue)/_maxbrake)) - (brakevalue*(1- (((float)throttlevalue)/_maxspeed)) ); //brake reduces throttle and adds negative torque
*/
int16_t speedvalue = (out_speedFL+out_speedFR+out_speedRL+out_speedRR)/4; //generate last speedvalue from individual motor speeds
uint16_t throttlevalue=constrain( map(adc_throttle, ADC_CALIB_THROTTLE_MIN, ADC_CALIB_THROTTLE_MAX, 0, _maxspeed ) ,0, _maxspeed);
int16_t brakevalue=constrain( map(adc_brake, ADC_CALIB_BRAKE_MIN, ADC_CALIB_BRAKE_MAX, 0, _maxbrake ) ,0, _maxbrake); //positive value for braking
int16_t combthrottlevalue=throttlevalue*(1- (((float)brakevalue)/_maxbrake)) - (brakevalue*(1- (((float)throttlevalue)/_maxspeed)) ); //brake reduces throttle and adds negative torque
int16_t combthrottlevalue_positive = max((int16_t)0,combthrottlevalue); //only positive
#define CURRENTBRAKE_P 5.0 //proportional brake when throttle is lower than current speed. Depends on LOOPTIME
#define BRAKE_P 0.02 //speed-=brakevalue*brake_p . depends on LOOPTIME
//serial2 is Front. serial1 is Rear
float _current = (Feedback1.curL_DC+Feedback1.curR_DC+Feedback2.curL_DC+Feedback2.curR_DC)/4.0 / A2BIT_CONV;
if (combthrottlevalue_positive>=speedvalue) { //if throttle higher then apply immediately
speedvalue = combthrottlevalue_positive;
}else{ //throttle lever is lower than current set speedvalue
if (_current > 0) { //is consuming current when it shouldnt
speedvalue = max( (int16_t)(speedvalue-_current*CURRENTBRAKE_P) ,combthrottlevalue_positive); //not lower than throttlevalue
}
}
if (combthrottlevalue<0){ //throttle off and brake pressed
speedvalue= max((int16_t)(speedvalue + combthrottlevalue*BRAKE_P),(int16_t)0); //not negative = not backwards
}
speedvalue = throttlevalue; //TEST OVERRIDE
out_speedFL=speedvalue;
out_speedFR=speedvalue;
out_speedRL=speedvalue;
out_speedRR=speedvalue;
}
void loop_error() {
out_speedFL=out_speedFR=out_speedRR=out_speedRL=0; //stop motors
Serial.print("Error:"); Serial.println(errormessage);
}
void loop_test() {
Serial.print("adc_throttle_raw="); Serial.print(adc_throttle_raw);
Serial.print(", adc_brake_raw="); Serial.print(adc_brake_raw);
int _maxspeed=1000;
int _maxbrake=400;
if (MODESWITCH_DOWN) {
_maxspeed=200;
_maxbrake=200;
}
int16_t throttlevalue=constrain( map(adc_throttle, ADC_CALIB_THROTTLE_MIN, ADC_CALIB_THROTTLE_MAX, 0, _maxspeed ) ,0, _maxspeed);
int16_t brakevalue=constrain( map(adc_brake, ADC_CALIB_BRAKE_MIN, ADC_CALIB_BRAKE_MAX, 0, _maxbrake ) ,0, _maxbrake); //positive value for braking
int16_t speedvalue=throttlevalue*(1- (((float)brakevalue)/_maxbrake)) - (brakevalue*(1- (((float)throttlevalue)/_maxspeed)) ); //brake reduces throttle and adds negative torque
Serial.print(", throttle="); Serial.print(throttlevalue); Serial.print(", brake="); Serial.print(brakevalue); Serial.print(", speed="); Serial.println(speedvalue);
}
void loop_off() {
//loop enters when boards are sucessfully turned off
digitalWrite(PIN_ENABLE, LOW); //cut own power
}
boolean boardsPowered()
{
return (board1Enabled && board2Enabled); //true if both boards enabled
}
void failChecks()
{
#define FAILCHECK_WAITCHECK_AFTER_POWEROFF_TIME 1000 //time to start failchecking boardpower after board poweroff
#define FAILCHECK_RECEIVERECENT_TIME 100 //timeout .should be less than FAILCHECK_WAITCHECK_AFTER_POWEROFF_TIME and greater than send delay from mainboard
// ## Check if board is really offline ##
if (!board1Enabled) { //board should be offline
if (loopmillis-board1lastPoweroff > FAILCHECK_WAITCHECK_AFTER_POWEROFF_TIME){ //wait some time before checking if board did power off
if (loopmillis-lastValidDataSerial1_time < FAILCHECK_RECEIVERECENT_TIME) { //new message received recently?
errormessage="Board 1 should be offline but feedback received";
Serial.println(errormessage);
requestmode=error;
}
}
}
if (!board2Enabled) { //board should be offline
if (loopmillis-board2lastPoweroff > FAILCHECK_WAITCHECK_AFTER_POWEROFF_TIME){ //wait some time before checking if board did power off
if (loopmillis-lastValidDataSerial2_time < FAILCHECK_RECEIVERECENT_TIME) { //new message received recently?
errormessage="Board 2 should be offline but feedback received";
Serial.println(errormessage);
requestmode=error;
}
}
}
#define FAILCHECK_WAITCHECK_AFTER_POWERON_TIME 2000 //time to start failchecking boardpower after startup
// ## Check if board is online (when it should send feedback) ##
if (board1Enabled) { //board should be online
if (loopmillis-board1lastPoweron > FAILCHECK_WAITCHECK_AFTER_POWERON_TIME) { //wait some time before checking
if (loopmillis-lastValidDataSerial1_time > FAILCHECK_RECEIVERECENT_TIME) { //speed still high enough but no new messages recently received?
errormessage="Board 1 should be online and give feedback but didnt";
Serial.println(errormessage);
requestmode=error;
}
}
}
if (board2Enabled) { //board should be online
if (loopmillis-board2lastPoweron > FAILCHECK_WAITCHECK_AFTER_POWERON_TIME) { //wait some time before checking
if (loopmillis-lastValidDataSerial2_time > FAILCHECK_RECEIVERECENT_TIME) { //no new messages recently received?
errormessage="Board 2 should be online and give feedback but didnt";
Serial.println(errormessage);
requestmode=error;
}
}
}
}
String modeToString(uint8_t m) {
if (m==idle) return "idle";
if (m==off) return "off";
if (m==error) return "error";
if (m==on) return "on";
if (m==booting) return "booting";
}
void ledUpdate() {
#define LEDUPDATETIME 20
#define FASTERRORBLINKDELAY 100 //period for startled to blink on error
if (loopmillis - last_ledupdate >= LEDUPDATETIME) {
last_ledupdate=loopmillis;
// ## StartLed ##
uint8_t _ledbrightness;
switch (currentmode) { //modeLed for different currentmodes
case booting:
startled=255;
break;
case idle: //Breathing Startled
_ledbrightness=uint8_t( (loopmillis/10)%(512) );
startled=_ledbrightness<=255 ? _ledbrightness : (512)-_ledbrightness; //reverse if >255 to go down again
break;
case on: //Startled on
startled=255;
break;
case error: //Startled blink
startled=(loopmillis/FASTERRORBLINKDELAY)%2==0 ? 0 : 255; // Blink led
break;
case off: //Startled off
startled=0;
break;
}
// ## ModeLed ##
if (currentmode!=requestmode) { //ongoing modechange
modeled_green=0; modeled_red=0; //ModeLed=Off
}else{
switch (currentmode) { //modeLed for different currentmodes
case booting:
modeled_green=255; modeled_red=0; //ModeLed=Green
break;
case idle:
modeled_green=255; modeled_red=255; //ModeLed=Yellow
break;
case on:
modeled_green=255; modeled_red=0; //ModeLed=Green
break;
case error:
modeled_green=0; modeled_red=(loopmillis/FASTERRORBLINKDELAY)%2==0 ? 0 : 255; // Blink led , ModeLed=Red
break;
case off:
modeled_green=255; modeled_red=255; //ModeLed=Yellow
break;
}
}
/*
pwmWrite(PIN_MODELED_GREEN, map(modeled_green, 0, 255, 0, 65535));
pwmWrite(PIN_MODELED_RED, map(modeled_red, 0, 255, 0, 65535));
pwmWrite(PIN_STARTLED, map(startled, 0, 255, 0, 65535));
*/
digitalWrite(PIN_MODELED_GREEN, modeled_green<127? true:false); //red and green inverted (common anode)
digitalWrite(PIN_MODELED_RED, modeled_red<127? true:false); //red and green inverted (common anode)
digitalWrite(PIN_STARTLED, startled>127? true:false);
}
}
/*
// Old loop
void loopold() {
//selfTest(); //start selftest, does not return
ReceiveSerial1(); // Check for new received data
if (millis()>2000 && STARTBUTTON_DOWN) {
poweronBoards();
}
if (millis() - last_send > SENDPERIOD) {
//Serial.print("powerbutton="); Serial.print(STARTBUTTON_DOWN); Serial.print(" modeswitch down="); Serial.println(MODESWITCH_DOWN);
int _read=analogRead(PIN_THROTTLE);
int16_t speedvalue=constrain( map(_read, ADC_CALIB_THROTTLE_MIN, ADC_CALIB_THROTTLE_MAX, 0, 1000 ) ,0, 1000);
if (MODESWITCH_DOWN) {
SendSerial1(speedvalue,0);
SendSerial2(speedvalue,0);
Serial.print("L_");
}else{
SendSerial1(0,speedvalue);
SendSerial2(0,speedvalue);
Serial.print("R_");
}
Serial.print("millis="); Serial.print(millis()); Serial.print(", adcthrottle="); Serial.print(_read);
Serial.print(", 1.L="); Serial.print(Command1.speedLeft); Serial.print(", 1.R="); Serial.print(Command1.speedRight);
Serial.print(", 2.L="); Serial.print(Command2.speedLeft); Serial.print(", 2.R="); Serial.println(Command2.speedRight);
last_send = millis();
digitalWrite(PIN_STARTLED, !digitalRead(PIN_STARTLED));
if (testcounter%3==0) {
digitalWrite(PIN_MODELED_GREEN, !digitalRead(PIN_MODELED_GREEN));
}
if (testcounter%5==0) {
digitalWrite(PIN_MODELED_RED, !digitalRead(PIN_MODELED_RED));
}
testcounter++;
//Print Motor values
Serial.print("cmd1");
Serial.print(", "); Serial.print("cmd2");
Serial.print(","); Serial.print("speedR");
Serial.print(","); Serial.print("speedL");
Serial.print(", "); Serial.print("speedR_meas");
Serial.print(","); Serial.print("speedL_meas");
Serial.print(", "); Serial.print("batVoltage");
Serial.print(", "); Serial.println("boardTemp");
Serial.println();
Serial.print("1: "); Serial.print(Feedback1.cmd1);
Serial.print(", "); Serial.print(Feedback1.cmd2);
Serial.print(","); Serial.print(Feedback1.speedR);
Serial.print(","); Serial.print(Feedback1.speedL);
Serial.print(", "); Serial.print(Feedback1.speedR_meas);
Serial.print(","); Serial.print(Feedback1.speedL_meas);
Serial.print(", "); Serial.print(Feedback1.batVoltage);
Serial.print(", "); Serial.println(Feedback1.boardTemp);
Serial.println();
Serial.print("2: "); Serial.print(Feedback2.cmd1);
Serial.print(", "); Serial.print(Feedback2.cmd2);
Serial.print(","); Serial.print(Feedback2.speedR);
Serial.print(","); Serial.print(Feedback2.speedL);
Serial.print(", "); Serial.print(Feedback2.speedR_meas);
Serial.print(","); Serial.print(Feedback2.speedL_meas);
Serial.print(", "); Serial.print(Feedback2.batVoltage);
Serial.print(", "); Serial.println(Feedback2.boardTemp);
}
if (millis()>30000 && STARTBUTTON_DOWN) {
poweroff();
}
}
// ########################## END ##########################
void poweroff() {
//TODO: trigger Relais for Board 1
// Wait for board to shut down
//TODO: trigger Relais for Board 2
// Wait for board to shut down
//Timeout error handling
digitalWrite(PIN_ENABLE, LOW); //poweroff own latch
delay(1000);
Serial.println("Still powered");
//still powered on: set error status "power latch error"
}
void poweronBoards() {
digitalWrite(PIN_RELAISFRONT,HIGH);
delay(200);digitalWrite(PIN_RELAISFRONT,LOW);
delay(50);
digitalWrite(PIN_RELAISREAR,HIGH);
delay(200);digitalWrite(PIN_RELAISREAR,LOW);
}
*/
void selfTest() {
digitalWrite(PIN_ENABLE,HIGH); //make shure latch is on
Serial.println("Entering selftest");
#define TESTDELAY 1000 //delay between test
#define TESTTIME 500 //time to keep tested pin on
delay(TESTDELAY); Serial.println("PIN_STARTLED");
digitalWrite(PIN_STARTLED,HIGH); delay(TESTTIME); digitalWrite(PIN_STARTLED,LOW);
delay(TESTDELAY); Serial.println("PIN_MODELED_GREEN");
digitalWrite(PIN_MODELED_GREEN,LOW); delay(TESTTIME); digitalWrite(PIN_MODELED_GREEN,HIGH);
delay(TESTDELAY); Serial.println("PIN_MODELED_RED");
digitalWrite(PIN_MODELED_RED,LOW); delay(TESTTIME); digitalWrite(PIN_MODELED_RED,HIGH);
delay(TESTDELAY); Serial.println("PIN_RELAISFRONT");
digitalWrite(PIN_RELAISFRONT,HIGH); delay(TESTTIME); digitalWrite(PIN_RELAISFRONT,LOW);
delay(TESTDELAY); Serial.println("PIN_RELAISREAR");
digitalWrite(PIN_RELAISREAR,HIGH); delay(TESTTIME); digitalWrite(PIN_RELAISREAR,LOW);
delay(TESTDELAY); Serial.println("ALL ON");
digitalWrite(PIN_STARTLED,HIGH);
digitalWrite(PIN_MODELED_GREEN,LOW);
digitalWrite(PIN_MODELED_RED,LOW);
digitalWrite(PIN_RELAISFRONT,HIGH);
digitalWrite(PIN_RELAISREAR,HIGH);
delay(TESTTIME*5);
digitalWrite(PIN_STARTLED,LOW);
digitalWrite(PIN_MODELED_GREEN,HIGH);
digitalWrite(PIN_MODELED_RED,HIGH);
digitalWrite(PIN_RELAISFRONT,LOW);
digitalWrite(PIN_RELAISREAR,LOW);
delay(TESTDELAY);
Serial.println("Powers off latch at millis>=60000");
Serial.println("Inputs:");
while(true) { //Keep printing input values forever
delay(100);
Serial.print("millis="); Serial.print(millis()); Serial.print(", throttle ADC="); Serial.println(analogRead(PIN_THROTTLE));
Serial.print("powerbutton down="); Serial.print(STARTBUTTON_DOWN); Serial.print(" modeswitch down="); Serial.println(MODESWITCH_DOWN);
while (millis()>=60000) {
digitalWrite(PIN_ENABLE, LOW); //poweroff own latch
Serial.println(millis());
}
}
}

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@ -1,130 +0,0 @@
// ########################## SEND ##########################
void SendSerial1(int16_t uSpeedLeft, int16_t uSpeedRight)
{
// Create command
Command1.start = (uint16_t)START_FRAME;
Command1.speedLeft = (int16_t)uSpeedLeft;
Command1.speedRight = (int16_t)uSpeedRight;
Command1.checksum = (uint16_t)(Command1.start ^ Command1.speedLeft ^ Command1.speedRight);
Serial2.write((uint8_t *) &Command1, sizeof(Command1));
}
void SendSerial2(int16_t uSpeedLeft, int16_t uSpeedRight)
{
// Create command
Command2.start = (uint16_t)START_FRAME;
Command2.speedLeft = (int16_t)uSpeedLeft;
Command2.speedRight = (int16_t)uSpeedRight;
Command2.checksum = (uint16_t)(Command2.start ^ Command2.speedLeft ^ Command2.speedRight);
Serial3.write((uint8_t *) &Command2, sizeof(Command2));
}
// ########################## RECEIVE ##########################
void ReceiveSerial1()
{
// Check for new data availability in the Serial buffer
if ( Serial2.available() ) {
incomingByte1 = Serial2.read(); // Read the incoming byte
bufStartFrame1 = ((uint16_t)(incomingBytePrev1) << 8) + incomingByte1; // Construct the start frame
}
else {
return;
}
// If DEBUG_RX is defined print all incoming bytes
#ifdef DEBUG_RX
Serial.print(incomingByte1);
return;
#endif
// Copy received data
if (bufStartFrame1 == START_FRAME) { // Initialize if new data is detected
p1 = (byte *)&NewFeedback1;
*p1++ = incomingBytePrev1;
*p1++ = incomingByte1;
idx1 = 2;
} else if (idx1 >= 2 && idx1 < sizeof(SerialFeedback)) { // Save the new received data
*p1++ = incomingByte1;
idx1++;
}
// Check if we reached the end of the package
if (idx1 == sizeof(SerialFeedback)) {
uint16_t checksum;
checksum = (uint16_t)(NewFeedback1.start ^ NewFeedback1.cmd1 ^ NewFeedback1.cmd2 ^ NewFeedback1.speedR ^ NewFeedback1.speedL
^ NewFeedback1.speedR_meas ^ NewFeedback1.speedL_meas ^ NewFeedback1.batVoltage ^ NewFeedback1.boardTemp ^ NewFeedback1.curL_DC ^ NewFeedback1.curR_DC);
// Check validity of the new data
if (NewFeedback1.start == START_FRAME && checksum == NewFeedback1.checksum) {
// Copy the new data
memcpy(&Feedback1, &NewFeedback1, sizeof(SerialFeedback));
lastValidDataSerial1_time = millis();
}
idx1 = 0; // Reset the index (it prevents to enter in this if condition in the next cycle)
/*
// Print data to built-in Serial
Serial.print("1: "); Serial.print(Feedback.cmd1);
Serial.print(" 2: "); Serial.print(Feedback.cmd2);
Serial.print(" 3: "); Serial.print(Feedback.speedR);
Serial.print(" 4: "); Serial.print(Feedback.speedL);
Serial.print(" 5: "); Serial.print(Feedback.speedR_meas);
Serial.print(" 6: "); Serial.print(Feedback.speedL_meas);
Serial.print(" 7: "); Serial.print(Feedback.batVoltage);
Serial.print(" 8: "); Serial.println(Feedback.boardTemp);
} else {
Serial.println("Non-valid data skipped");
}*/
}
// Update previous states
incomingBytePrev1 = incomingByte1;
}
void ReceiveSerial2()
{
// Check for new data availability in the Serial buffer
if ( Serial3.available() ) {
incomingByte2 = Serial3.read(); // Read the incoming byte
bufStartFrame2 = ((uint16_t)(incomingBytePrev2) << 8) + incomingByte2; // Construct the start frame
}
else {
return;
}
// If DEBUG_RX is defined print all incoming bytes
#ifdef DEBUG_RX
Serial.print(incomingByte2);
return;
#endif
// Copy received data
if (bufStartFrame2 == START_FRAME) { // Initialize if new data is detected
p2 = (byte *)&NewFeedback2;
*p2++ = incomingBytePrev2;
*p2++ = incomingByte2;
idx2 = 2;
} else if (idx2 >= 2 && idx2 < sizeof(SerialFeedback)) { // Save the new received data
*p2++ = incomingByte2;
idx2++;
}
// Check if we reached the end of the package
if (idx2 == sizeof(SerialFeedback)) {
uint16_t checksum;
checksum = (uint16_t)(NewFeedback2.start ^ NewFeedback2.cmd1 ^ NewFeedback2.cmd2 ^ NewFeedback2.speedR ^ NewFeedback2.speedL
^ NewFeedback2.speedR_meas ^ NewFeedback2.speedL_meas ^ NewFeedback2.batVoltage ^ NewFeedback2.boardTemp ^ NewFeedback2.curL_DC ^ NewFeedback2.curR_DC);
// Check validity of the new data
if (NewFeedback2.start == START_FRAME && checksum == NewFeedback2.checksum) {
// Copy the new data
memcpy(&Feedback2, &NewFeedback2, sizeof(SerialFeedback));
lastValidDataSerial2_time = millis();
}
idx2 = 0; // Reset the index (it prevents to enter in this if condition in the next cycle)
}
// Update previous states
incomingBytePrev2 = incomingByte2;
}

View File

@ -1 +0,0 @@
.pio

View File

@ -1,67 +0,0 @@
# Continuous Integration (CI) is the practice, in software
# engineering, of merging all developer working copies with a shared mainline
# several times a day < https://docs.platformio.org/page/ci/index.html >
#
# Documentation:
#
# * Travis CI Embedded Builds with PlatformIO
# < https://docs.travis-ci.com/user/integration/platformio/ >
#
# * PlatformIO integration with Travis CI
# < https://docs.platformio.org/page/ci/travis.html >
#
# * User Guide for `platformio ci` command
# < https://docs.platformio.org/page/userguide/cmd_ci.html >
#
#
# Please choose one of the following templates (proposed below) and uncomment
# it (remove "# " before each line) or use own configuration according to the
# Travis CI documentation (see above).
#
#
# Template #1: General project. Test it using existing `platformio.ini`.
#
# language: python
# python:
# - "2.7"
#
# sudo: false
# cache:
# directories:
# - "~/.platformio"
#
# install:
# - pip install -U platformio
# - platformio update
#
# script:
# - platformio run
#
# Template #2: The project is intended to be used as a library with examples.
#
# language: python
# python:
# - "2.7"
#
# sudo: false
# cache:
# directories:
# - "~/.platformio"
#
# env:
# - PLATFORMIO_CI_SRC=path/to/test/file.c
# - PLATFORMIO_CI_SRC=examples/file.ino
# - PLATFORMIO_CI_SRC=path/to/test/directory
#
# install:
# - pip install -U platformio
# - platformio update
#
# script:
# - platformio ci --lib="." --board=ID_1 --board=ID_2 --board=ID_N

View File

@ -1,142 +0,0 @@
{
"configurations": [
{
"name": "!!! WARNING !!! AUTO-GENERATED FILE, PLEASE DO NOT MODIFY IT AND USE https://docs.platformio.org/page/projectconf/section_env_build.html#build-flags"
},
{
"name": "Linux",
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""
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""
]
},
"defines": [
"PLATFORMIO=40304",
"STM32F103xB",
"STM32F1",
"ARDUINO=10808",
"ARDUINO_ARCH_STM32",
"ARDUINO_ARCH_STM32F1",
"ARDUINO_GENERIC_STM32F103C",
"MCU_STM32F103C8",
"__STM32F1__",
"BOARD_generic_stm32f103c",
"F_CPU=72000000L",
"VECT_TAB_ADDR=0x8000000",
"ERROR_LED_PORT=GPIOC",
"ERROR_LED_PIN=13",
"CONFIG_MAPLE_MINI_NO_DISABLE_DEBUG=1",
""
],
"intelliSenseMode": "clang-x64",
"cStandard": "c11",
"cppStandard": "c++11",
"compilerPath": "/home/fisch/.platformio/packages/toolchain-gccarmnoneeabi@1.70201.0/bin/arm-none-eabi-gcc",
"compilerArgs": [
"-mcpu=cortex-m3",
"-mthumb",
"-march=armv7-m",
""
]
}
],
"version": 4
}

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@ -1,7 +0,0 @@
{
// See http://go.microsoft.com/fwlink/?LinkId=827846
// for the documentation about the extensions.json format
"recommendations": [
"platformio.platformio-ide"
]
}

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// AUTOMATICALLY GENERATED FILE. PLEASE DO NOT MODIFY IT MANUALLY
// PIO Unified Debugger
//
// Documentation: https://docs.platformio.org/page/plus/debugging.html
// Configuration: https://docs.platformio.org/page/projectconf/section_env_debug.html
{
"version": "0.2.0",
"configurations": [
{
"type": "platformio-debug",
"request": "launch",
"name": "PIO Debug",
"executable": "/media/fisch/HDD/Projects/bobbycar/bobbycar_repo/controller_pio/.pio/build/genericSTM32F103C8/firmware.elf",
"toolchainBinDir": "/home/fisch/.platformio/packages/toolchain-gccarmnoneeabi@1.70201.0/bin",
"svdPath": "/home/fisch/.platformio/platforms/ststm32/misc/svd/STM32F103xx.svd",
"preLaunchTask": {
"type": "PlatformIO",
"task": "Pre-Debug"
},
"internalConsoleOptions": "openOnSessionStart"
},
{
"type": "platformio-debug",
"request": "launch",
"name": "PIO Debug (skip Pre-Debug)",
"executable": "/media/fisch/HDD/Projects/bobbycar/bobbycar_repo/controller_pio/.pio/build/genericSTM32F103C8/firmware.elf",
"toolchainBinDir": "/home/fisch/.platformio/packages/toolchain-gccarmnoneeabi@1.70201.0/bin",
"svdPath": "/home/fisch/.platformio/platforms/ststm32/misc/svd/STM32F103xx.svd",
"internalConsoleOptions": "openOnSessionStart"
}
]
}

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@ -1,39 +0,0 @@
This directory is intended for project header files.
A header file is a file containing C declarations and macro definitions
to be shared between several project source files. You request the use of a
header file in your project source file (C, C++, etc) located in `src` folder
by including it, with the C preprocessing directive `#include'.
```src/main.c
#include "header.h"
int main (void)
{
...
}
```
Including a header file produces the same results as copying the header file
into each source file that needs it. Such copying would be time-consuming
and error-prone. With a header file, the related declarations appear
in only one place. If they need to be changed, they can be changed in one
place, and programs that include the header file will automatically use the
new version when next recompiled. The header file eliminates the labor of
finding and changing all the copies as well as the risk that a failure to
find one copy will result in inconsistencies within a program.
In C, the usual convention is to give header files names that end with `.h'.
It is most portable to use only letters, digits, dashes, and underscores in
header file names, and at most one dot.
Read more about using header files in official GCC documentation:
* Include Syntax
* Include Operation
* Once-Only Headers
* Computed Includes
https://gcc.gnu.org/onlinedocs/cpp/Header-Files.html

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@ -1,46 +0,0 @@
This directory is intended for project specific (private) libraries.
PlatformIO will compile them to static libraries and link into executable file.
The source code of each library should be placed in a an own separate directory
("lib/your_library_name/[here are source files]").
For example, see a structure of the following two libraries `Foo` and `Bar`:
|--lib
| |
| |--Bar
| | |--docs
| | |--examples
| | |--src
| | |- Bar.c
| | |- Bar.h
| | |- library.json (optional, custom build options, etc) https://docs.platformio.org/page/librarymanager/config.html
| |
| |--Foo
| | |- Foo.c
| | |- Foo.h
| |
| |- README --> THIS FILE
|
|- platformio.ini
|--src
|- main.c
and a contents of `src/main.c`:
```
#include <Foo.h>
#include <Bar.h>
int main (void)
{
...
}
```
PlatformIO Library Dependency Finder will find automatically dependent
libraries scanning project source files.
More information about PlatformIO Library Dependency Finder
- https://docs.platformio.org/page/librarymanager/ldf.html

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; PlatformIO Project Configuration File
;
; Build options: build flags, source filter
; Upload options: custom upload port, speed and extra flags
; Library options: dependencies, extra library storages
; Advanced options: extra scripting
;
; Please visit documentation for the other options and examples
; https://docs.platformio.org/page/projectconf.html
[env:genericSTM32F103C8]
platform = ststm32
board = genericSTM32F103C8
framework = arduino
upload_protocol = serial
monitor_speed = 115200

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This directory is intended for PIO Unit Testing and project tests.
Unit Testing is a software testing method by which individual units of
source code, sets of one or more MCU program modules together with associated
control data, usage procedures, and operating procedures, are tested to
determine whether they are fit for use. Unit testing finds problems early
in the development cycle.
More information about PIO Unit Testing:
- https://docs.platformio.org/page/plus/unit-testing.html