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|
// By Ben V. Brown - V2.0 of the TS100 firmware
#include <MMA8652FC.hpp>
#include <main.hpp>
#include "OLED.hpp"
#include "Settings.h"
#include "Translation.h"
#include "cmsis_os.h"
#include "stdlib.h"
#include "stm32f1xx_hal.h"
#include "string.h"
#include "LIS2DH12.hpp"
#include <gui.hpp>
#define ACCELDEBUG 0
// C++ objects
OLED lcd(&hi2c1);
MMA8652FC accel(&hi2c1);
LIS2DH12 accel2(&hi2c1);
uint8_t PCBVersion = 0;
// File local variables
uint16_t currentlyActiveTemperatureTarget = 0;
uint32_t lastMovementTime = 0;
uint32_t lastButtonTime = 0;
// FreeRTOS variables
osThreadId GUITaskHandle;
osThreadId PIDTaskHandle;
osThreadId ROTTaskHandle;
osThreadId MOVTaskHandle;
SemaphoreHandle_t rotationChangedSemaphore = NULL;
SemaphoreHandle_t accelDataAvailableSemaphore = NULL;
void startGUITask(void const *argument);
void startPIDTask(void const *argument);
void startMOVTask(void const *argument);
void startRotationTask(void const *argument);
// End FreeRTOS
// Main sets up the hardware then hands over to the FreeRTOS kernel
int main(void) {
/* Reset of all peripherals, Initializes the Flash interface and the Systick.
*/
HAL_Init();
Setup_HAL(); // Setup all the HAL objects
setTipPWM(0);
lcd.initialize(); // start up the LCD
lcd.setFont(0); // default to bigger font
//Testing for new weird board version
uint8_t buffer[1];
if (HAL_I2C_Mem_Read(&hi2c1, 29 << 1, 0x0F, I2C_MEMADD_SIZE_8BIT, buffer, 1,
1000) == HAL_OK) {
PCBVersion = 1;
accel.initalize(); // this sets up the I2C registers and loads up the default
// settings
} else if (HAL_I2C_Mem_Read(&hi2c1, 25 << 1, 0x0F, I2C_MEMADD_SIZE_8BIT,
buffer, 1, 1000) == HAL_OK) {
PCBVersion = 2;
//Setup the ST Accelerometer
accel2.initalize(); //startup the accelerometer
}
{
PCBVersion = 3;
}
HAL_IWDG_Refresh(&hiwdg);
restoreSettings(); // load the settings from flash
setCalibrationOffset(systemSettings.CalibrationOffset);
HAL_IWDG_Refresh(&hiwdg);
/* Create the thread(s) */
/* definition and creation of GUITask */
osThreadDef(GUITask, startGUITask, osPriorityBelowNormal, 0, 512);
GUITaskHandle = osThreadCreate(osThread(GUITask), NULL);
/* definition and creation of PIDTask */
osThreadDef(PIDTask, startPIDTask, osPriorityRealtime, 0, 256);
PIDTaskHandle = osThreadCreate(osThread(PIDTask), NULL);
/* definition and creation of ROTTask */
osThreadDef(ROTTask, startRotationTask, osPriorityLow, 0, 256);
ROTTaskHandle = osThreadCreate(osThread(ROTTask), NULL);
/* definition and creation of MOVTask */
osThreadDef(MOVTask, startMOVTask, osPriorityNormal, 0, 256);
MOVTaskHandle = osThreadCreate(osThread(MOVTask), NULL);
/* Create the objects*/
rotationChangedSemaphore =
xSemaphoreCreateBinary(); // Used to unlock rotation thread
accelDataAvailableSemaphore =
xSemaphoreCreateBinary(); // Used to unlock the movement thread
/* Start scheduler */
osKernelStart();
/* We should never get here as control is now taken by the scheduler */
while (1) {
}
}
void GUIDelay() {
osDelay(50); // 20Hz
}
void gui_drawTipTemp() {
// Draw tip temp handling unit conversion & tolerance near setpoint
uint16_t Temp = getTipRawTemp(0);
if (systemSettings.temperatureInF)
Temp = tipMeasurementToF(Temp);
else
Temp = tipMeasurementToC(Temp);
//[Disabled 24/11/2017] Round if nearby
// if (abs(Temp - systemSettings.SolderingTemp) < 3)
// Temp = systemSettings.SolderingTemp;
lcd.printNumber(Temp, 3); // Draw the tip temp out finally
}
ButtonState getButtonState() {
/*
* Read in the buttons and then determine if a state change needs to occur
*/
/*
* If the previous state was 00 Then we want to latch the new state if
* different & update time
* If the previous state was !00 Then we want to search if we trigger long
* press (buttons still down), or if release we trigger press
* (downtime>filter)
*/
static uint8_t previousState = 0;
static uint32_t previousStateChange = 0;
const uint16_t timeout = 40;
uint8_t currentState;
currentState = (
HAL_GPIO_ReadPin(KEY_A_GPIO_Port, KEY_A_Pin) == GPIO_PIN_RESET ?
1 : 0) << 0;
currentState |= (
HAL_GPIO_ReadPin(KEY_B_GPIO_Port, KEY_B_Pin) == GPIO_PIN_RESET ?
1 : 0) << 1;
if (currentState)
lastButtonTime = xTaskGetTickCount();
if (currentState == previousState) {
if (currentState == 0)
return BUTTON_NONE;
if ((xTaskGetTickCount() - previousStateChange) > timeout) {
// User has been holding the button down
// We want to send a buttong is held message
if (currentState == 0x01)
return BUTTON_F_LONG;
else if (currentState == 0x02)
return BUTTON_B_LONG;
else
return BUTTON_NONE; // Both being held case, we dont long hold this
} else
return BUTTON_NONE;
} else {
// A change in button state has occurred
ButtonState retVal = BUTTON_NONE;
if (currentState) {
// User has pressed a button down (nothing done on down)
} else {
// User has released buttons
// If they previously had the buttons down we want to check if they were <
// long hold and trigger a press
if ((xTaskGetTickCount() - previousStateChange) < timeout) {
// The user didn't hold the button for long
// So we send button press
if (previousState == 0x01)
retVal = BUTTON_F_SHORT;
else if (previousState == 0x02)
retVal = BUTTON_B_SHORT;
else
retVal = BUTTON_BOTH; // Both being held case
}
}
previousState = currentState;
previousStateChange = xTaskGetTickCount();
return retVal;
}
return BUTTON_NONE;
}
static void waitForButtonPress() {
// we are just lazy and sleep until user confirms button press
// This also eats the button press event!
ButtonState buttons = getButtonState();
while (buttons) {
buttons = getButtonState();
GUIDelay();
lcd.refresh();
}
while (!buttons) {
buttons = getButtonState();
GUIDelay();
lcd.refresh();
}
}
void waitForButtonPressOrTimeout(uint32_t timeout) {
timeout += xTaskGetTickCount();
// Make timeout our exit value
for (;;) {
ButtonState buttons = getButtonState();
if (buttons)
return;
if (xTaskGetTickCount() > timeout)
return;
GUIDelay();
}
}
// returns true if undervoltage has occured
static bool checkVoltageForExit() {
uint16_t v = getInputVoltageX10(systemSettings.voltageDiv);
if ((v < lookupVoltageLevel(systemSettings.cutoutSetting))) {
lcd.clearScreen();
lcd.setCursor(0, 0);
if (systemSettings.detailedSoldering) {
lcd.setFont(1);
lcd.print(UndervoltageString);
lcd.setCursor(0, 8);
lcd.print(InputVoltageString);
lcd.printNumber(getInputVoltageX10(systemSettings.voltageDiv) / 10,
2);
lcd.drawChar('.');
lcd.printNumber(getInputVoltageX10(systemSettings.voltageDiv) % 10,
1);
lcd.print("V");
} else {
lcd.setFont(0);
lcd.print(UVLOWarningString);
}
lcd.refresh();
currentlyActiveTemperatureTarget = 0;
waitForButtonPress();
return true;
}
return false;
}
static void gui_drawBatteryIcon() {
if (systemSettings.cutoutSetting) {
// User is on a lithium battery
// we need to calculate which of the 10 levels they are on
uint8_t cellCount = systemSettings.cutoutSetting + 2;
uint16_t cellV = getInputVoltageX10(systemSettings.voltageDiv)
/ cellCount;
// Should give us approx cell voltage X10
// Range is 42 -> 33 = 9 steps therefore we will use battery 1-10
if (cellV < 33)
cellV = 33;
cellV -= 33; // Should leave us a number of 0-9
if (cellV > 9)
cellV = 9;
lcd.drawBattery(cellV + 1);
} else
lcd.drawSymbol(16); // Draw the DC Logo
}
static void gui_solderingTempAdjust() {
uint32_t lastChange = xTaskGetTickCount();
currentlyActiveTemperatureTarget = 0;
for (;;) {
lcd.setCursor(0, 0);
lcd.clearScreen();
lcd.setFont(0);
ButtonState buttons = getButtonState();
if (buttons)
lastChange = xTaskGetTickCount();
switch (buttons) {
case BUTTON_NONE:
// stay
break;
case BUTTON_BOTH:
// exit
return;
break;
case BUTTON_B_LONG:
break;
case BUTTON_F_LONG:
break;
case BUTTON_F_SHORT:
if (lcd.getRotation()) {
systemSettings.SolderingTemp += 10; // add 10
} else {
systemSettings.SolderingTemp -= 10; // sub 10
}
break;
case BUTTON_B_SHORT:
if (!lcd.getRotation()) {
systemSettings.SolderingTemp += 10; // add 10
} else {
systemSettings.SolderingTemp -= 10; // sub 10
}
break;
default:
break;
}
// constrain between 50-450 C
if (systemSettings.temperatureInF) {
if (systemSettings.SolderingTemp > 850)
systemSettings.SolderingTemp = 850;
} else {
if (systemSettings.SolderingTemp > 450)
systemSettings.SolderingTemp = 450;
}
if (systemSettings.temperatureInF) {
if (systemSettings.SolderingTemp < 120)
systemSettings.SolderingTemp = 120;
} else {
if (systemSettings.SolderingTemp < 50)
systemSettings.SolderingTemp = 50;
}
if (xTaskGetTickCount() - lastChange > 200)
return; // exit if user just doesn't press anything for a bit
lcd.drawChar('-');
lcd.drawChar(' ');
lcd.printNumber(systemSettings.SolderingTemp, 3);
if (systemSettings.temperatureInF)
lcd.drawSymbol(0);
else
lcd.drawSymbol(1);
lcd.drawChar(' ');
lcd.drawChar('+');
lcd.refresh();
GUIDelay();
}
}
static int gui_showTipTempWarning() {
for (;;) {
uint16_t tipTemp = tipMeasurementToC(getTipRawTemp(0));
lcd.clearScreen();
lcd.setCursor(0, 0);
if (systemSettings.detailedSoldering) {
lcd.setFont(1);
lcd.print(WarningAdvancedString);
lcd.setCursor(0, 8);
lcd.print(WarningTipTempString);
if (systemSettings.temperatureInF) {
lcd.printNumber(tipMeasurementToF(getTipRawTemp(0)), 3);
lcd.print("F");
} else {
lcd.printNumber(tipMeasurementToC(getTipRawTemp(0)), 3);
lcd.print("C");
}
} else {
lcd.setFont(0);
lcd.drawArea(0, 0, 24, 16, WarningBlock24);
lcd.setCursor(24, 0);
// lcd.print(WarningSimpleString);
lcd.print(" ");
if (systemSettings.temperatureInF) {
lcd.printNumber(tipMeasurementToF(getTipRawTemp(0)), 3);
lcd.drawSymbol(0);
} else {
lcd.printNumber(tipMeasurementToC(getTipRawTemp(0)), 3);
lcd.drawSymbol(1);
}
}
if (systemSettings.coolingTempBlink && tipTemp > 70) {
if (xTaskGetTickCount() % 50 < 25)
lcd.clearScreen();
}
lcd.refresh();
ButtonState buttons = getButtonState();
if (buttons == BUTTON_F_SHORT)
return 1;
else if (buttons == BUTTON_B_SHORT || buttons == BUTTON_BOTH)
return 0;
if (tipTemp < 50)
return 0; //Exit the warning screen
GUIDelay();
}
return 0;
}
static uint16_t min(uint16_t a, uint16_t b) {
if (a > b)
return b;
else
return a;
}
static int gui_SolderingSleepingMode() {
// Drop to sleep temperature and display until movement or button press
for (;;) {
ButtonState buttons = getButtonState();
if (buttons)
return 0;
if ((xTaskGetTickCount() - lastMovementTime < 100)
|| (xTaskGetTickCount() - lastButtonTime < 100))
return 0; // user moved or pressed a button, go back to soldering
if (checkVoltageForExit())
return 1; // return non-zero on error
if (systemSettings.temperatureInF)
currentlyActiveTemperatureTarget = ftoTipMeasurement(
min(systemSettings.SleepTemp,
systemSettings.SolderingTemp));
else
currentlyActiveTemperatureTarget = ctoTipMeasurement(
min(systemSettings.SleepTemp,
systemSettings.SolderingTemp));
// draw the lcd
uint16_t tipTemp;
if (systemSettings.temperatureInF)
tipTemp = tipMeasurementToF(getTipRawTemp(0));
else
tipTemp = tipMeasurementToC(getTipRawTemp(0));
lcd.clearScreen();
lcd.setCursor(0, 0);
if (systemSettings.detailedSoldering) {
lcd.setFont(1);
lcd.print(SleepingAdvancedString);
lcd.setCursor(0, 8);
lcd.print(SleepingTipAdvancedString);
lcd.printNumber(tipTemp, 3);
if (systemSettings.temperatureInF)
lcd.print("F");
else
lcd.print("C");
lcd.print(" ");
lcd.printNumber(getInputVoltageX10(systemSettings.voltageDiv) / 10,
2);
lcd.drawChar('.');
lcd.printNumber(getInputVoltageX10(systemSettings.voltageDiv) % 10,
1);
lcd.drawChar('V');
} else {
lcd.setFont(0);
lcd.print(SleepingSimpleString);
lcd.printNumber(tipTemp, 3);
if (systemSettings.temperatureInF)
lcd.drawSymbol(0);
else
lcd.drawSymbol(1);
}
if (systemSettings.ShutdownTime) // only allow shutdown exit if time > 0
if (lastMovementTime)
if (((uint32_t) (xTaskGetTickCount() - lastMovementTime))
> (uint32_t) (systemSettings.ShutdownTime * 60 * 100)) {
// shutdown
currentlyActiveTemperatureTarget = 0;
return 1; // we want to exit soldering mode
}
lcd.refresh();
GUIDelay();
}
return 0;
}
static void gui_solderingMode() {
/*
* * Soldering (gui_solderingMode)
* -> Main loop where we draw temp, and animations
* --> User presses buttons and they goto the temperature adjust screen
* ---> Display the current setpoint temperature
* ---> Use buttons to change forward and back on temperature
* ---> Both buttons or timeout for exiting
* --> Long hold front button to enter boost mode
* ---> Just temporarily sets the system into the alternate temperature for
* PID control
* --> Long hold back button to exit
* --> Double button to exit
*/
bool boostModeOn = false;
uint32_t sleepThres = 0;
if (systemSettings.SleepTime < 6)
sleepThres = systemSettings.SleepTime * 10 * 100;
else
sleepThres = (systemSettings.SleepTime - 5) * 60 * 100;
for (;;) {
uint16_t tipTemp = getTipRawTemp(0);
ButtonState buttons = getButtonState();
switch (buttons) {
case BUTTON_NONE:
// stay
boostModeOn = false;
break;
case BUTTON_BOTH:
// exit
return;
break;
case BUTTON_B_LONG:
return; // exit on back long hold
break;
case BUTTON_F_LONG:
// if boost mode is enabled turn it on
if (systemSettings.boostModeEnabled)
boostModeOn = true;
break;
case BUTTON_F_SHORT:
case BUTTON_B_SHORT: {
uint16_t oldTemp = systemSettings.SolderingTemp;
gui_solderingTempAdjust(); // goto adjust temp mode
if (oldTemp != systemSettings.SolderingTemp) {
saveSettings(); // only save on change
}
}
break;
default:
break;
}
// else we update the screen information
lcd.setCursor(0, 0);
lcd.clearScreen();
lcd.setFont(0);
if (tipTemp > 16300) {
lcd.print(BadTipString);
lcd.refresh();
currentlyActiveTemperatureTarget = 0;
waitForButtonPress();
return;
} else {
if (systemSettings.detailedSoldering) {
lcd.setFont(1);
lcd.print(SolderingAdvancedPowerPrompt); //Power:
lcd.printNumber(getTipPWM(), 3);
lcd.print("%");
lcd.setCursor(0, 8);
lcd.print(SleepingTipAdvancedString);
uint16_t Temp = getTipRawTemp(0);
if (systemSettings.temperatureInF)
Temp = tipMeasurementToF(Temp);
else
Temp = tipMeasurementToC(Temp);
lcd.printNumber(Temp, 3);
if (systemSettings.temperatureInF)
lcd.print("F");
else
lcd.print("C");
lcd.print(" ");
lcd.printNumber(
getInputVoltageX10(systemSettings.voltageDiv) / 10, 2);
lcd.drawChar('.');
lcd.printNumber(
getInputVoltageX10(systemSettings.voltageDiv) % 10, 1);
lcd.drawChar('V');
} else {
// We switch the layout direction depending on the orientation of the lcd.
if (lcd.getRotation()) {
// battery
gui_drawBatteryIcon();
lcd.drawChar(' '); // Space out gap between battery <-> temp
if (systemSettings.temperatureInF) {
gui_drawTipTemp(); // Draw current tip temp
lcd.drawSymbol(0); // deg F
} else {
gui_drawTipTemp(); // Draw current tip temp
lcd.drawSymbol(1); // deg C
}
// We draw boost arrow if boosting, or else gap temp <-> heat indicator
if (boostModeOn)
lcd.drawSymbol(2);
else
lcd.drawChar(' ');
// Draw heating/cooling symbols
// If tip PWM > 10% then we are 'heating'
if (getTipPWM() > 10)
lcd.drawSymbol(14);
else
lcd.drawSymbol(15);
} else {
// Draw heating/cooling symbols
// If tip PWM > 10% then we are 'heating'
if (getTipPWM() > 10)
lcd.drawSymbol(14);
else
lcd.drawSymbol(15);
// We draw boost arrow if boosting, or else gap temp <-> heat indicator
if (boostModeOn)
lcd.drawSymbol(2);
else
lcd.drawChar(' ');
if (systemSettings.temperatureInF) {
gui_drawTipTemp(); // Draw current tip temp
lcd.drawSymbol(0); // deg F
} else {
gui_drawTipTemp(); // Draw current tip temp
lcd.drawSymbol(1); // deg C
}
lcd.drawChar(' '); // Space out gap between battery <-> temp
gui_drawBatteryIcon();
}
}
}
// Update the setpoints for the temperature
if (boostModeOn) {
if (systemSettings.temperatureInF)
currentlyActiveTemperatureTarget = ftoTipMeasurement(
systemSettings.BoostTemp);
else
currentlyActiveTemperatureTarget = ctoTipMeasurement(
systemSettings.BoostTemp);
} else {
if (systemSettings.temperatureInF)
currentlyActiveTemperatureTarget = ftoTipMeasurement(
systemSettings.SolderingTemp);
else
currentlyActiveTemperatureTarget = ctoTipMeasurement(
systemSettings.SolderingTemp);
}
// Undervoltage test
if (checkVoltageForExit()) {
return;
}
lcd.refresh();
if (systemSettings.sensitivity)
if (xTaskGetTickCount() - lastMovementTime > sleepThres
&& xTaskGetTickCount() - lastButtonTime > sleepThres) {
if (gui_SolderingSleepingMode()) {
return; // If the function returns non-0 then exit
}
}
GUIDelay();
}
}
/* StartGUITask function */
void startGUITask(void const *argument) {
/*
* Main program states:
*
* * Soldering (gui_solderingMode)
* -> Main loop where we draw temp, and animations
* --> User presses buttons and they goto the temperature adjust screen
* ---> Display the current setpoint temperature
* ---> Use buttons to change forward and back on temperature
* ---> Both buttons or timeout for exiting
* --> Long hold front button to enter boost mode
* ---> Just temporarily sets the system into the alternate temperature for
* PID control
* --> Long hold back button to exit
* --> Double button to exit
* * Settings Menu (gui_settingsMenu)
* -> Show setting name
* --> If no button press for > 3 Seconds, scroll description
* -> If user presses back button, adjust the setting
* -> Currently the same as 1.x (future to make more depth based)
*/
uint8_t animationStep = 0;
uint8_t tempWarningState = 0;
bool buttonLockout = false;
HAL_IWDG_Refresh(&hiwdg);
switch (systemSettings.OrientationMode) {
case 0:
lcd.setRotation(false);
break;
case 1:
lcd.setRotation(true);
break;
case 2:
lcd.setRotation(false);
break;
default:
break;
}
uint32_t ticks = xTaskGetTickCount();
ticks += 400; //4 seconds from now
while (xTaskGetTickCount() < ticks) {
if (showBootLogoIfavailable() == false)
ticks = xTaskGetTickCount();
ButtonState buttons = getButtonState();
if (buttons)
ticks = xTaskGetTickCount(); //make timeout now so we will exit
GUIDelay();
}
HAL_IWDG_Refresh(&hiwdg);
if (systemSettings.autoStartMode) {
// jump directly to the autostart mode
if (systemSettings.autoStartMode == 1)
gui_solderingMode();
}
#if ACCELDEBUG
for (;;) {
HAL_IWDG_Refresh(&hiwdg);
osDelay(100);
}
//^ Kept here for a way to block this thread
#endif
for (;;) {
ButtonState buttons = getButtonState();
if (tempWarningState == 2)
buttons = BUTTON_F_SHORT;
if (buttons != BUTTON_NONE && buttonLockout)
buttons = BUTTON_NONE;
else
buttonLockout = false;
switch (buttons) {
case BUTTON_NONE:
// Do nothing
break;
case BUTTON_BOTH:
// Not used yet
//In multi-language this might be used to reset language on a long hold or some such
break;
case BUTTON_B_LONG:
// Show the version information
{
lcd.clearScreen(); // Ensure the buffer starts clean
lcd.setCursor(0, 0); // Position the cursor at the 0,0 (top left)
lcd.setFont(1); // small font
lcd.print((char *) "V2.03 PCB"); // Print version number
lcd.printNumber(PCBVersion, 1);
lcd.setCursor(0, 8); // second line
lcd.print(__DATE__); // print the compile date
lcd.refresh();
waitForButtonPress();
lcd.setFont(0); // reset font
}
break;
case BUTTON_F_LONG:
gui_solderingTempAdjust();
saveSettings();
break;
case BUTTON_F_SHORT:
lcd.setFont(0);
lcd.displayOnOff(true); // turn lcd on
gui_solderingMode(); // enter soldering mode
tempWarningState = 0; // make sure warning can show
break;
case BUTTON_B_SHORT:
lcd.setFont(0);
lcd.displayOnOff(true); // turn lcd on
enterSettingsMenu(); // enter the settings menu
saveSettings();
buttonLockout = true;
setCalibrationOffset(systemSettings.CalibrationOffset); // ensure cal offset is applied
break;
default:
break;
}
currentlyActiveTemperatureTarget = 0; // ensure tip is off
uint16_t tipTemp = tipMeasurementToC(getTipRawTemp(0));
if (tipTemp < 50) {
if (systemSettings.sensitivity) {
if ((xTaskGetTickCount() - lastMovementTime) > 6000
&& (xTaskGetTickCount() - lastButtonTime) > 6000)
lcd.displayOnOff(false); // turn lcd off when no movement
else
lcd.displayOnOff(true); // turn lcd on
} else
lcd.displayOnOff(true); // turn lcd on
} else
lcd.displayOnOff(true); // turn lcd on
if (tipTemp > 600)
tipTemp = 0;
if (tipTemp > 50) {
if (tempWarningState == 0) {
currentlyActiveTemperatureTarget = 0; // ensure tip is off
lcd.displayOnOff(true); // force LCD on
if (gui_showTipTempWarning() == 1) {
tempWarningState = 2; // we can re-enter the warning
} else
tempWarningState = 1;
}
} else
tempWarningState = 0;
// Clear the lcd buffer
lcd.clearScreen();
lcd.setCursor(0, 0);
if (systemSettings.detailedIDLE) {
lcd.setFont(1);
if (tipTemp > 470) {
lcd.print(TipDisconnectedString);
} else {
lcd.print(IdleTipString);
if (systemSettings.temperatureInF)
lcd.printNumber(tipMeasurementToF(getTipRawTemp(0)), 3);
else
lcd.printNumber(tipMeasurementToC(getTipRawTemp(0)), 3);
lcd.print(IdleSetString);
lcd.printNumber(systemSettings.SolderingTemp, 3);
}
lcd.setCursor(0, 8);
lcd.print(InputVoltageString);
lcd.printNumber(getInputVoltageX10(systemSettings.voltageDiv) / 10,
2);
lcd.drawChar('.');
lcd.printNumber(getInputVoltageX10(systemSettings.voltageDiv) % 10,
1);
lcd.print("V");
} else {
lcd.setFont(0);
if (lcd.getRotation()) {
lcd.drawArea(12, 0, 84, 16, idleScreenBG);
lcd.setCursor(0, 0);
gui_drawBatteryIcon();
} else {
lcd.drawArea(0, 0, 84, 16, idleScreenBGF); // Needs to be flipped
lcd.setCursor(84, 0);
gui_drawBatteryIcon();
}
}
lcd.refresh();
animationStep++;
GUIDelay();
}
}
/* StartPIDTask function */
void startPIDTask(void const *argument) {
/*
* We take the current tip temperature & evaluate the next step for the tip
* control PWM
* Tip temperature is measured by getTipTemperature(1) so we get instant
* result
* This comes in Cx10 format
* We then control the tip temperature to aim for the setpoint in the settings
* struct
*
*/
int32_t integralCount = 0;
int32_t derivativeLastValue = 0;
int32_t kp, ki, kd;
kp = 80;
ki = 120;
kd = 60;
// REMEBER ^^^^ These constants are backwards
// They act as dividers, so to 'increase' a P term, you make the number
// smaller.
const int32_t itermMax = 60;
for (;;) {
uint16_t rawTemp = getTipRawTemp(1); // get instantaneous reading
if (currentlyActiveTemperatureTarget) {
// Compute the PID loop in here
// Because our values here are quite large for all measurements (0-16k ~=
// 33 counts per C)
// P I & D are divisors, so inverse logic applies (beware)
int32_t rawTempError = currentlyActiveTemperatureTarget - rawTemp;
int32_t ierror = (rawTempError / ki);
integralCount += ierror;
if (integralCount > (itermMax / 2))
integralCount = itermMax / 2; // prevent too much lead
else if (integralCount < -itermMax)
integralCount = itermMax;
int32_t dInput = (rawTemp - derivativeLastValue);
/*Compute PID Output*/
int32_t output = (rawTempError / kp);
if (ki)
output += integralCount;
if (kd)
output -= (dInput / kd);
if (output > 100) {
output = 100; // saturate
} else if (output < 0) {
output = 0;
}
/*if (currentlyActiveTemperatureTarget < rawTemp) {
output = 0;
}*/
setTipPWM(output);
derivativeLastValue = rawTemp; // store for next loop
} else {
setTipPWM(0); // disable the output driver if the output is set to be off
integralCount = 0;
derivativeLastValue = 0;
}
HAL_IWDG_Refresh(&hiwdg);
osDelay(10); // 100 Hz temp loop
}
}
#define MOVFilter 8
void startMOVTask(void const *argument) {
osDelay(4000); // wait for accel to stabilize
int16_t datax[MOVFilter];
int16_t datay[MOVFilter];
int16_t dataz[MOVFilter];
uint8_t currentPointer = 0;
memset(datax, 0, MOVFilter * sizeof(int16_t));
memset(datay, 0, MOVFilter * sizeof(int16_t));
memset(dataz, 0, MOVFilter * sizeof(int16_t));
int16_t tx, ty, tz;
int32_t avgx, avgy, avgz;
if (systemSettings.sensitivity > 9)
systemSettings.sensitivity = 9;
#if ACCELDEBUG
uint32_t max = 0;
#endif
if (PCBVersion == 3) {
for (;;)
osDelay(5000);
}
for (;;) {
int32_t threshold = 1200 + (9 * 200);
threshold -= systemSettings.sensitivity * 200; // 200 is the step size
if (PCBVersion == 2)
accel2.getAxisReadings(&tx, &ty, &tz);
else if (PCBVersion == 1)
accel.getAxisReadings(&tx, &ty, &tz);
datax[currentPointer] = (int32_t) tx;
datay[currentPointer] = (int32_t) ty;
dataz[currentPointer] = (int32_t) tz;
currentPointer = (currentPointer + 1) % MOVFilter;
#if ACCELDEBUG
// Debug for Accel
avgx = avgy = avgz = 0;
for (uint8_t i = 0; i < MOVFilter; i++) {
avgx += datax[i];
avgy += datay[i];
avgz += dataz[i];
}
avgx /= MOVFilter;
avgy /= MOVFilter;
avgz /= MOVFilter;
lcd.setFont(1);
lcd.setCursor(0, 0);
lcd.printNumber(abs(avgx - (int32_t) tx), 5);
lcd.print(" ");
lcd.printNumber(abs(avgy - (int32_t) ty), 5);
if ((abs(avgx - tx) + abs(avgy - ty) + abs(avgz - tz)) > max)
max = (abs(avgx - tx) + abs(avgy - ty) + abs(avgz - tz));
lcd.setCursor(0, 8);
lcd.printNumber(max, 5);
lcd.print(" ");
lcd.printNumber((abs(avgx - tx) + abs(avgy - ty) + abs(avgz - tz)), 5);
lcd.refresh();
if (HAL_GPIO_ReadPin(KEY_A_GPIO_Port, KEY_A_Pin) == GPIO_PIN_RESET)
max = 0;
#endif
// Only run the actual processing if the sensitivity is set (aka we are
// enabled)
if (systemSettings.sensitivity) {
// calculate averages
avgx = avgy = avgz = 0;
for (uint8_t i = 0; i < MOVFilter; i++) {
avgx += datax[i];
avgy += datay[i];
avgz += dataz[i];
}
avgx /= MOVFilter;
avgy /= MOVFilter;
avgz /= MOVFilter;
// So now we have averages, we want to look if these are different by more
// than the threshold
int32_t error = (abs(avgx - tx) + abs(avgy - ty) + abs(avgz - tz));
// If error has occured then we update the tick timer
if (error > threshold) {
lastMovementTime = xTaskGetTickCount();
}
}
osDelay(100); // Slow down update rate
}
}
/* StartRotationTask function */
void startRotationTask(void const *argument) {
/*
* This task is used to manage rotation of the LCD screen & button re-mapping
*
*/
if (PCBVersion == 3) {
for (;;)
osDelay(5000);
}
switch (systemSettings.OrientationMode) {
case 0:
lcd.setRotation(false);
break;
case 1:
lcd.setRotation(true);
break;
case 2:
lcd.setRotation(false);
break;
default:
break;
}
osDelay(500); // wait for accel to stabilize
for (;;) {
// a rotation event has occurred
uint8_t rotation = 0;
if (PCBVersion == 2) {
rotation = accel2.getOrientation();
} else if (PCBVersion == 1) {
rotation = accel.getOrientation();
}
if (systemSettings.OrientationMode == 2) {
if (rotation != 0) {
lcd.setRotation(rotation == 2); // link the data through
}
}
osDelay(500);
}
}
#define FLASH_LOGOADDR \
(0x8000000 | 0xF800) /*second last page of flash set aside for logo image*/
bool showBootLogoIfavailable() {
// check if the header is there (0xAA,0x55,0xF0,0x0D)
// If so display logo
uint16_t temp[98];
for (uint8_t i = 0; i < (98); i++) {
temp[i] = *(uint16_t *) (FLASH_LOGOADDR + (i * 2));
}
uint8_t temp8[98 * 2];
for (uint8_t i = 0; i < 98; i++) {
temp8[i * 2] = temp[i] >> 8;
temp8[i * 2 + 1] = temp[i] & 0xFF;
}
if (temp8[0] != 0xAA)
return false;
if (temp8[1] != 0x55)
return false;
if (temp8[2] != 0xF0)
return false;
if (temp8[3] != 0x0D)
return false;
lcd.drawArea(0, 0, 96, 16, (uint8_t *) (temp8 + 4));
lcd.refresh();
return true;
}
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