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A hardware watchdog timer for devices featuring a serial port

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generic-watchdog-timer

Overview

A hardware watchdog timer for devices featuring a serial port

This project introduces a standalone watchdog timer for use with any device featuring one availabe serial port (RS-232), and having the capability of periodically sending a specific string of data during its normal operation.

This project is an improvement over my previous project, the hardware-watchdog-timer, given that it allows for a more complex input to cause the watchdog to reset. More specifically, it requires a particular string of characters to be received, to cause the timer to reset, and as such prevent the target device from being restarted.

This watchdog timer (WDT) is also capable of sending commands back to the target system. In the current implementation, the WDT is sending a shutdown command to the target device, in order to allow it to shutdown properly, prior to being turned off.

Combined with a relay, this device is then capable of cycling the power of the target device in order to (hard) restart it in case of failure.

This source code is accompanied with an application schematic diagram to help in the construction of a complete unit using the PIC16F628A microcontroller and this firmware.

Technical description

In this implementation we are using the TIMER1 of this PIC microcontroller. From the three regular timers available in this device, this is the only 16 bit one. For our application it is ideal that the timer has this level of resolution, as it allows for a more accurate definition of the duration of the timer. Depending on the application it may also be better when compared to the 8 bit timers, in respect to the reduction of instruction loops, when longer timer durations are required.

Whenever the timer overflows, an interrupt is generated, and our interrupt service routine (isr) takes care of incrementing a counter variable or producing the WDT action (sending a command to the target device and briefly turning off and on the relay) when this variable overflows. Then TIMER1 is restarted and the cycle repeats.

On the other hand, while the timer is running, a software loop continuously reads from the serial port, comparing the stream of bytes with the expected string ("kiosk_wdtToken"). Everytime a match is found, the counter variable of the timer is reset to 0, preventing the triggering of the WDT.

I have selected this particular microcontroller due to the fact that I was already familiar with the architecture, and this model in particular while being cheap, has a useful feature set. One such example is the integrated USART which besides other modes of operation, it can be configured to behave as a regular RS-232 serial port.

In the simpler approach that is provided, the circuit can achieve the 9600 bps serial port speed, and several other bit rates (see the PIC16F628A datasheet for more details).

If the user needs 115200 bps for his application, then it is only feasible to run the device with an external clock to achieve that speed. In that case you must comment the line:

#define LOW_SPEED

that is in the main.h file.

The code will default to assuming an external (HS) clock and a serial port bitrate of 115200 bps. Timer settings will have its values set accordingly.

One aspect to note is that if the external 20 MHz crystal is chosen, it is no longer possible to power the device at 3.3 Volts. This has for example the implication that the serial port will need level shifting in order to interface with the 3.3 Volt serial port from the target device.

Prerequisites

The following software is needed for building this project:

  • MPLAB X IDE v5.45 or better;
  • XC8 toolchain (can be installed during the IDE installation process);
  • PICkit2 v2.61 in case you have an older PIC programmer. The newer versions of MPLAB X no longer support PICkit2 and older devices;

Building and flashing

This project can be built on the MPLAB X IDE. It requires the XC8 toolchain for compiling the firmware image.

Clone the repository to a location

Fist clone this repo to a folder in your computer, for example using TortoiseGIT, or just downloading the files.

Create a new project in the IDE

Create a new project in the IDE by going to "File" > "New Project" > "Microchip Embedded" > "Standalone Project". In the device section, enter the device name: PIC16F628A. If your tool is compatible, select it in the dropdown box below the device selection.

Hit "Next". In the compiler selection, select the XC8 compiler.

Finally give a project name and a location.

Now you need to add the source files from the this git project into your new project. On the left side of the IDE (Projects tab), right click on your project and select "Add Existing Item...". Select all the .c and .h files. Organize the header and c source files by dragging these to the corresponding folders.

Build the project

If everything is correct you should be able to build the project successfully. Click on the "Clean and Build Main Project" icon in the top menu. The result should appear in the bottom "Output" tab.

Flash the device

If your PIC programmer is directly supported, you can program the device by clicking on the "Make and program device" button in the icon menu.

If you have a pickit2, after building the project, you need to connect your programmer, open the pickit2 application, place a device in the programmer, click Erase (to make sure you are starting from a clean device), click "File" > "Import Hex", and then select the location where the Hex file generated by MPLAB X is located. You may find it in the project folder, under:

generic-watchdog-timer.X\dist\default\production

there should be a file named such as: generic-watchdog-timer.X.production.hex

After importing the file, click Write, and the PIC should be programmed in a few seconds. Click verify to make sure that the programmed data corresponds to the build image.

Remove the PIC from the programmer, and it is ready to be tested in your circuit.

Pin mappings of the PIC16F628A microcontroller

The diagram below shows the pin mappings of the PIC16F628A microntroller used for this particular application:

                    +---------------+
  N/A         -   --|(RA2)|   |(RA1)|--   > RELAY
                    |     \---/     |
  N/A         -   --|(RA3)     (RA0)|--   - N/A
                    |               |
  N/A         -   --|(RA4)     (RA7)|--   - XTAL
                    |               |
  N/A         -   --|(RA5)     (RA6)|--   - XTAL
                    |               |
  GND         -   --|(VSS)     (VDD)|--   - +5V
                    |               |
  N/A         -   --|(RB0)     (RB7)|--   - N/A
                    |               |
  RX          >   --|(RB1)     (RB6)|--   - N/A
                    |               |
  TX          <   --|(RB2)     (RB5)|--   - N/A
                    |               |
  N/A         -   --|(RB3)     (RB4)|--   - N/A
                    +---------------+

Sample Schematic and application

In the schematic below we are setting this watchdog timer to work with a SPST relay. The load is therefore switched this way. This version of the code will keep the relay energized during the normal operation of the target device. The user may however prefer to invert the output of the microcontroller, and use a SPDT relay, and as such use the normally closed pole of the relay instead. This way the relay does not have to be energized during normal operation, and will only need to be turned on when the watchdog timer needs to reboot the target device.

Alt

Below is a protoboard built from this circuit, and is currently being used to watch a Raspberry Pi 2 computer. The later has to be kept available because of hosting a home Assistant instance. When an reboot is necessary, it not only restarts the Raspberry Pi, but also the SSD drive that is connected to it.

Alt

Usage

The commands that the WDT accepts are comprised of a prefix and a suffix:

  • [prefix][suffix]

Because this watchdog timer was initially designed to be used together with a Hassio instance (the Home Assistant operating system), and given that the Raspberry Pi is by default configured to output debug/system/kernel logs to the available serial port, there is going to be more data going to the serial port, than just commands to control the WDT.

As such, in order to avoid the WDT from confusing commands with other output from the Raspberry Pi (or other device connected to the WDT), I defined the prefix as a sufficiently long string of random characters that be very unlikely to occur for different reasons than as commands to control the WDT.

As such the WDT currently supports the following commands:

  • WDT_BhAyycbmEi_1 - resets the WDT. The system needs to call this command periodically in order to prevent the WDT from restarting the device (the constant WT_TIMEOUT controls this timeout);
  • WDT_BhAyycbmEi_2 - disables the WDT. This command suspends the normal operation of the WDT. It is useful for example when a system reconfiguration needs to be done, and it is not possible to keep sending the reset commands;
  • WDT_BhAyycbmEi_3 - enables the WDT. This command enables the WDT, after having been kept disabled with the previous command.

After one of these commands is recognized by the WDT, the latter outputs a response, confirming the command that was sent. For example to interact via a Home Assistant terminal:

[core-ssh watchdog]$ /bin/stty -F /dev/ttyAMA0 9600
[core-ssh watchdog]$ cat /dev/ttyAMA0 &
[1] 625
[core-ssh watchdog]$ echo WDT_BhAyycbmEi_3 > /dev/ttyAMA0 
[core-ssh watchdog]$ #enable_wdt

In this case we can see that the WDT reacted to "WDT_BhAyycbmEi_3" command (enable WDT) by outputting the string "#enable_wdt" to the serial port.

There are the following possible responses:

  • #reset_wdt - the WDT have been reset successfully;
  • #enable_wdt - the WDT have been successfully enabled;
  • #disable_wdt - the WDT have been successfully disabled.

The choice to use the '#' character in the beginning of the strings, is for that fact that this way the messages are not interpreted by the bash interpreter of the host system as commands (it is assumed that we may be sharing the same port where a serial console is configured in the linux host).

Relevant links

License

Author: Luis Teixeira (https://creationfactory.co)

Licence and copyright notice:

Copyright 2022 Luis Teixeira

Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at

http://www.apache.org/licenses/LICENSE-2.0

Unless required by applicable law or agreed to in writing, softwar distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License.

You probably can have success with one of the Arduino based programmers that are around, but I haven't personally tested.

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