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UGR-Gen3-Torque-Controller
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started writing code but not finished yet :(

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bitscuit 2023-04-11 19:19:55 +02:00
parent 1a690a3722
commit b4eebea7de
1 changed files with 96 additions and 330 deletions
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src/main.cpp
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@ -1,339 +1,71 @@
#include <Arduino.h> #include <Arduino.h>
#include <FlexCAN_T4.h> #include <FlexCAN_T4.h>
/*CODE BY TIM VAN HAUWERMEIREN 2022*/
/*SLIGHT CHANGES BY NIELS DANZON 2023*/
#define FILTER_ID -1
/*
0: ERPM, Duty Cycle, Input Voltage
1: AC Current, DC Current
2: Controller temperature, Motor temperature, Fault code
3: Id, Iq
4: Throttle Signal, Brake Signal, DI1, DI2, DI3, DI4, DO1, DO2, DO3, DO4, Drive Enable, Capacitor Temp Limit, DC Current Limit,
Drive Enable Limit, IGBT Acceleration Temp Limit, IGBT Temp Limit, Input Voltage Limit, Motor Acceleration Temp Limit, Motor Temp Limit, RPM Min Limit, RPM Max Limit, Power Limit
*/
//Pin Declaration
#define AnalogIn 17
#define statusLED 13
#define AnalogAct 12
#define ManualAct 11
#define Stop 10
//Set Speed value used in Set Mode
#define setSpeed 500
//Function Declaration //Function Declaration
void printMessage(const CAN_message_t *); // function for writing to the terminal
void setupCan();
void sendEnable(); // function to turn the inverter on DON'T FORGET TO EDIT THE ID OF THE DRIVE void sendEnable(); // function to turn the inverter on DON'T FORGET TO EDIT THE ID OF THE DRIVE
void sendERPM(); // function to change the speed DON'T FORGET TO EDIT THE ID OF THE DRIVE void sendERPM(); // function to change the speed DON'T FORGET TO EDIT THE ID OF THE DRIVE
void calculateSpeed();
void blinkLED();
//Variable Declaration /* CAN variables */
uint64_t time_last_update; FlexCAN_T4<CAN1, RX_SIZE_256, TX_SIZE_16> can_lv; /* LV CAN bus is connected to controller 1 */
uint64_t time_last_update_can; FlexCAN_T4<CAN2, RX_SIZE_256, TX_SIZE_16> can_mc; /* Motorcontroller/Invertor CAN bus is connected to controller 2 */
FlexCAN_T4<CAN1, RX_SIZE_256, TX_SIZE_16> Can0; #define CAN_LV_BAUD 1000000 /* Data rate of the LV CAN = 1Mbps */
elapsedMillis sinceSpeedUpdate; // counter voor snelheidssignaal #define CAN_MC_BAUD 500000 /* Data rate of the MC CAN = 500kbps */
long speed; uint64_t time_last_can_mc_send = 0; /* Timestamp of last message that was sent to motorcontrollers (because they have timeout safety shit) */
bool analog = false; uint64_t time_last_apps = 0; /* Timestamp of last message for APPS values */
bool manual = false; uint64_t time_last_rtd_state = 0; /* Timestamp of last message for Boot Sequence State stuff */
bool stop = false;
/* CAN heartbeat stuff */
uint64_t time_last_heartbeat = 0; /* Timestamp of last heartbeat message that was sent */
#define HEARTBEAT_PERIOD 100 /* Send heartbeat message every 100ms */
#define CAN_ID_HEARTBEAT 0x080 /* CAN ID of heartbeat messages (see spreadsheet) */
#define CAN_MODULE_ID 0x05 /* Module ID of this system (see spreadsheet) */
/* CAN config continued */
#define CAN_ID_APPS 0x110 /* CAN ID of APPS values (not using Module ID of APPS) */
#define CAN_ID_BOOT_SEQ 0x090 /* CAN ID of Boot Sequence Status (for RTD) values (using Module ID of ECU for safety) */
/* Torque Controller variables */
uint8_t apps_value = 0; /* Value of the APPS sensor (0-255) */
char rtd_state = 0; /* Whether or not RTD is actived */
void setup() { void handle_can_lv_message(const CAN_message_t &msg) {
// put your setup code here, to run once: /* Callback for LV CAN messages */
setupCan();
pinMode(statusLED, OUTPUT);
pinMode(AnalogIn, INPUT);
pinMode(AnalogAct, INPUT_PULLUP);
pinMode(ManualAct, INPUT_PULLUP);
pinMode(Stop, INPUT_PULLUP);
Serial.print("Over 5 sec: test starten");
delay(5000); // 5 seconden wachten
// onderstaande code geschreven door Niels Danzon (nog niet getest dus als het niet werkt aanpassen of die van Tim gebruiken)
speed = 1000; // Set ERPM=RPM*number of poles --> RPM = ERPM/10 (for emrax 208)
sendERPM();
sinceSpeedUpdate = 0;
while (speed <= 50000)
{
sendERPM();
if (sinceSpeedUpdate >= 2000)
{
sinceSpeedUpdate = 0;
speed += 1000;
}
}
/* OLD CODE BY TIM VAN HAUWERMEIREN:
problem with code is that it constantly accelerates and deaccelerates the motor because of the delay between the commands
delay(10000); if ((msg.id & 0xff0) == CAN_ID_APPS) {
speed = 1000; /* APPS value */
sendERPM(); apps_value = msg.buf[0];
delay(2000); time_last_apps = millis();
speed = 2000; }
sendERPM(); else if ((msg.id & 0xfff) == CAN_ID_BOOT_SEQ) {
delay(2000); /* Boot Sequence Status */
speed = 3000; char bs = msg.buf[0];
sendERPM(); rtd_state = (bs == 5) ? 0b1 : 0b0;
speed = 4000; time_last_rtd_state = millis();
sendERPM(); }
delay(2000);
speed = 5000;
sendERPM();
delay(2000);
speed = 6000;
sendERPM();
delay(2000);
speed = 7000;
sendERPM();
delay(2000);
speed = 8000;
sendERPM();
delay(2000);
speed = 9000;
sendERPM();
delay(2000);
speed = 10000;
sendERPM();
delay(2000);
speed = 11000;
sendERPM();
delay(2000);
speed = 12000;
sendERPM();
delay(2000);
speed = 13000;
sendERPM();
delay(2000);
speed = 14000;
sendERPM();
delay(2000);
speed = 15000;
sendERPM();
speed = 16000;
sendERPM();
delay(2000);
speed = 17000;
sendERPM();
delay(2000);
speed = 18000;
sendERPM();
delay(2000);
speed = 19000;
sendERPM();
delay(2000);
speed = 20000;
sendERPM();
delay(2000);
speed = 21000;
sendERPM();
delay(2000);
speed = 22000;
sendERPM();
delay(2000);
speed = 23000;
sendERPM();
delay(2000);
speed = 24000;
sendERPM();
delay(2000);
speed = 25000;
sendERPM();
speed = 26000;
sendERPM();
delay(2000);
speed = 27000;
sendERPM();
delay(2000);
speed = 28000;
sendERPM();
delay(2000);
speed = 29000;
sendERPM();
delay(2000);
speed = 30000;
sendERPM();
delay(2000);
speed = 31000;
sendERPM();
delay(2000);
speed = 32000;
sendERPM();
delay(2000);
speed = 33000;
sendERPM();
speed = 34000;
sendERPM();
delay(2000);
speed = 35000;
sendERPM();
delay(2000);
speed = 36000;
sendERPM();
delay(2000);
speed = 37000;
sendERPM();
delay(2000);
speed = 38000;
sendERPM();
delay(2000);
speed = 39000;
sendERPM();
delay(2000);
speed = 40000;
sendERPM();
delay(2000);
speed = 41000;
sendERPM();
delay(2000);
speed = 41500;
sendERPM();
delay(2000);
speed = 42000;
sendERPM();
delay(2000);
speed = 42500;
sendERPM();
delay(2000);
speed = 43000;
sendERPM();
delay(2000);
speed = 43500;
sendERPM();
delay(2000);
speed = 44000;
sendERPM();
delay(2000);
speed = 44500;
sendERPM();
delay(2000);
speed = 45000;
sendERPM();
delay(2000);
speed = 46000;
sendERPM();
delay(2000);
speed = 47000;
sendERPM();
delay(2000);
speed = 48000;
sendERPM();
delay(2000);
speed = 49000;
sendERPM();
delay(2000);
speed = 50000;
sendERPM();
delay(2000);*/
} }
void loop() { // no idea if this is still needed with the new code (I don't know C++) void handle_can_mc_message(const CAN_message_t &msg) {
// Wait Loop /* Callback for MC CAN messages */
while(!(analog || manual)){
stop = false;
//calculateSpeed();
speed = 50000;
sendERPM();
//delay(500);
//blinkLED();
if(digitalRead(AnalogAct)){
analog = false;
}
else{
analog = true;
Serial.print("Analog Mode\n");
}
if(digitalRead(ManualAct)){
manual = false;
}
else{
manual = true;
Serial.print("Manual Mode\n");
}
Serial.print("Waiting\n");
delay(1000);
}
//Analog Mode
while(analog){
calculateSpeed();
sendERPM();
if(digitalRead(Stop)){
analog = true;
}
else{
analog = false;
}
}
//Set Mode
while(manual){
speed = 500;
sendERPM();
if(digitalRead(Stop)){
manual = true;
}
else{
manual = false;
}
}
} }
void printMessage(const CAN_message_t &msg) { void can_setup() {
/*This function is called when a CAN message is received via the CAN bus. The message will be printed to the Serial for debugging purposes. /* Init LV CAN */
:param msg: Received Can message can_lv.begin();
:type msg: CAN_message_t can_lv.setBaudRate(CAN_LV_BAUD);
:return: void can_lv.setMaxMB(16);
:rtype: void can_lv.enableFIFO();
*/ can_lv.enableFIFOInterrupt();
Serial.println("test"); can_lv.onReceive(handle_can_lv_message);
if(msg.id == FILTER_ID || FILTER_ID == -1){
Serial.print("MB "); Serial.print(msg.mb);
Serial.print(" LEN: "); Serial.print(msg.len);
Serial.print(" TS: "); Serial.print(msg.timestamp);
Serial.print(" ID: "); Serial.print(msg.id, HEX);
Serial.print(" Buffer: ");
for ( uint8_t i = 0; i < msg.len; i++ ) {
Serial.print(msg.buf[i]); Serial.print(" ");
}
Serial.println();
}
}
/* Init MC CAN */
void setupCan() { can_mc.begin();
/*Initialize all CAN elements can_mc.setBaudRate(CAN_MC_BAUD);
:return: void can_mc.setMaxMB(16);
:rtype: void can_mc.enableFIFO();
*/ can_mc.enableFIFOInterrupt();
Serial.begin(115200); can_mc.onReceive(handle_can_mc_message);
delay(400);
//Set up the clock and controller
Can0.begin();
//Set the symbol datarate to 1.000.000, TODO check max value
Can0.setBaudRate(500000);
//Set the maximal amount of MailBox'es (MB), an MB is a single buffer for a specific message type
//For transmitting frames on the CAN bus you can put them into a mailbox and they'll be scheduled to be sent when possible.
//Each mailbox is set either as a transmission or reception box.
Can0.setMaxMB(16);
// Enable FIFO, allows more than one instance of the same message to be stored before the CPU is interrupted
// therefore preventing any information loss for high frequency messages
Can0.enableFIFO();
// This allows frames to be interrupt driven rather than polling them in the loop.
Can0.enableFIFOInterrupt();
Can0.onReceive(printMessage);
} }
@ -376,18 +108,52 @@ void sendERPM() {
} }
} }
/* Subroutine to check if new heartbeat message needs to be sent and transmits it if needed */
void check_heartbeat() {
/* Return if not needed yet */
if (millis() < time_last_heartbeat + HEARTBEAT_PERIOD) return;
void calculateSpeed(){ /* Send heartbeat */
uint64_t analogSpeed = analogRead(AnalogIn); CAN_message_t m;
m.id = CAN_ID_HEARTBEAT | CAN_MODULE_ID;
speed = map(analogSpeed, 0, 1023, 0, 45000); m.buf[0] = HEARTBEAT_STATUS_OK;
can_lv.write(m);
/* Update stats */
time_last_heartbeat = millis();
} }
/* Subroutine to update invertors */
void update_drives() {
/* TODO: Return if not needed yet */
//if (millis() < time_last_heartbeat + HEARTBEAT_PERIOD) return;
void blinkLED(){ /* Update speed */
digitalWrite(statusLED, HIGH); uint8_t speed = apps_value;
delay(500);
digitalWrite(statusLED, LOW); /* Check if data is recent enough */
delay(500); //if (millis() > time_last_apps
/* Send heartbeat */
CAN_message_t m;
m.id = CAN_ID_HEARTBEAT | CAN_MODULE_ID;
m.buf[0] = HEARTBEAT_STATUS_OK;
can_lv.write(m);
/* Update stats */
time_last_heartbeat = millis();
} }
void setup() {
/* Init CAN */
can_setup();
}
void loop() {
/* Main event loop */
can_lv.events(); /* Handle CAN LV events */
can_mc.events(); /* Handle CAN MC events */
check_heartbeat(); /* Do heartbeat stuffz */
update_drives(); /* Do motorcontroller shit */
}