Well. It’s been a while. Here’s what’s new:
I monitor my heating system (temperatures, zone activation) with an Arduino, and relay the values to my home monitoring system through an ESP-01 / ESP8266. The Arduino occasionally hangs up.
I have tried to fix this by checking the power supply for good clean power; by making it reboot itself every 24 hours; by enabling the ATmega328’s watchdog timer. It still hangs up.
When it is running, it flashes an LED connected to the standard pin 13 of the Arduino. I recalled seeing that a 555 timer could be used as a missing-pulse detector. This would trigger if the 1Hz flashing stops. Cool. The missing pulse detector takes its output low during pulse starvation, and takes it high during the happy times when the pulses continue. I needed to take that prolonged low value and turn it into a one-shot pulse to drop and resume the power to the Arduino, and a second 555 could be configured as a one-shot to create this pulse. I had to add a capacitor in between to prevent continuous retriggering of the second 555, which would keep the power off to the Arduino.
The circuit “1” in the schematic illustrates this setup.
I happened to have a 556 handy, which comprises the functionality of two 555 timers. The equivalent simpler circuit is “2” in the schematic.
But, duh. I’m really more of a programmer at heart. And I had some ATtiny85 chips around. So I created an Arduino program to embody all the above functionality in a much simpler circuit – “3” in the schematic.
Note: in the code and the schematic the name ATmega refers to the (processor on the) Arduino board.
Watchdog_watchdog_schAnd I put it all onto a very small solderless breadboard. Since I needed regulated 5V to feed all the components, I put standard voltage regulation onto the breadboard as well.
The Arduino program was very simple:
/* Watchdog_watchdog One of my Arduinos, the one that monitors temperatures and zone activations in my heating system, occasionally hangs up. This despite the fact that I'm using the ATmega watchdog to automatically reset it if it hangs. Dunno why. The power seems good and stable. I've tried replacing the ATmega chip. I've decided to kill a flea with a cannon. The ATmega blinks an LED at 1Hz to indicate that it's still alive - I call this a throbber. The ATtiny will monitor the throbber and if it stops, it will power-cycle the ATmega. Hah. The MOSFET in question will be a p-channel MOSFET configured on the high side of the power to the ATmega; when its gate is pulled low, it allows power to flow to the ATmega. The specific MOSFET I'm using is a 5LP01SP, which is a p-channel device whose pins are 1=source, 2=drain, 3=gate. */ #define pdThrobber_in 3 #define pdMOSFET 4 const unsigned long resetAfter_ms = 2000UL; unsigned long lastThrobAt_ms = 0UL; void setup() { pinMode ( pdThrobber_in, INPUT ); pinMode ( pdMOSFET, OUTPUT ); } void loop() { static int throbberStatePrevious = 0; int throbberState = digitalRead ( pdThrobber_in ); if ( throbberState != throbberStatePrevious ) { lastThrobAt_ms = millis(); throbberStatePrevious = throbberState; } if ( ( millis() - lastThrobAt_ms ) > resetAfter_ms ) { // BOOM. Cause a reset digitalWrite ( pdMOSFET, 1 ); // turns off ATmega delay ( 500 ); digitalWrite ( pdMOSFET, 0 ); delay ( 5000 ); // time enough to let the ATmega boot up lastThrobAt_ms = millis(); // reset the watchdog } }