Merge branch 'master' of https://github.com/Ralim/ts100

workspace/TS100/src/main.cpp

@@ -803,7 +803,8 @@ void startGUITask(void const *argument __unused) {
 #ifdef MODEL_TS80
 			//Here we re-check for tip presence
 			if (idealQCVoltage < 90)
-				idealQCVoltage = calculateMaxVoltage(systemSettings.cutoutSetting);
+				idealQCVoltage = calculateMaxVoltage(
+						systemSettings.cutoutSetting);
 			seekQC(idealQCVoltage, systemSettings.voltageDiv);
 #endif
 			gui_solderingMode(0);  // enter soldering mode
@@ -943,7 +944,8 @@ void startPIDTask(void const *argument __unused) {
 				//  to be unstable. Use a rolling average to dampen it.
 				// We overshoot by roughly 1/2 of 1 degree Fahrenheit.
 				//  This helps stabilize the display.
-				int32_t tError = currentlyActiveTemperatureTarget - rawTemp + rawC/4;
+				int32_t tError = currentlyActiveTemperatureTarget - rawTemp
+						+ rawC / 4;
 				tError = tError > INT16_MAX ? INT16_MAX : tError;
 				tError = tError < INT16_MIN ? INT16_MIN : tError;
 				tempError.update(tError);
@@ -954,17 +956,21 @@ void startPIDTask(void const *argument __unused) {
 				// P term - total power needed to hit target temp next cycle.
 				// thermal mass = 1690 milliJ/*C for my tip.
 				//  = Watts*Seconds to raise Temp from room temp to +100*C, divided by 100*C.
-				// divided by 20 to let I term dominate near set point.
-				// I should retune this, but don't want to do it until
-				//  the feed-forward temp adjustment is in place.
+				// we divide milliWattsNeeded by 20 to let the I term dominate near the set point.
+				//  This is necessary because of the temp noise and thermal lag in the system.
+				// Once we have feed-forward temp estimation we should be able to better tune this.
+
 #ifdef MODEL_TS100
-				const uint16_t mass = 1690 / 20;
+				const uint16_t mass = 1690 / 20; // divide here so division is compile-time.
 #endif
 #ifdef MODEL_TS80
 				const uint16_t mass = 1690 / 50;
 #endif
 
-				int32_t milliWattsNeeded = tempToMilliWatts(tempError.average(), mass, rawC);
+				int32_t milliWattsNeeded = tempToMilliWatts(tempError.average(),
+						mass, rawC);
+				// note that milliWattsNeeded is sometimes negative, this counters overshoot
+				//  from I term's inertia.
 				milliWattsOut += milliWattsNeeded;
 
 				// I term - energy needed to compensate for heat loss.

workspace/TS100/src/power.cpp

@@ -17,6 +17,8 @@ history<uint16_t, oscillationPeriod> milliWattHistory = {{0}, 0, 0};
 
 int32_t tempToMilliWatts(int32_t rawTemp, uint16_t mass, uint8_t rawC) {
 	// mass is in milliJ/*C, rawC is raw per degree C
+	// returns milliWatts needed to raise/lower a mass by rawTemp
+	//  degrees in one cycle.
 	int32_t milliJoules = mass * rawTemp / rawC;
 	return milliJoules * hz;
 }