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AGirs (formerly ArduinoGirs)

This project implements a Girs server for the Arduino. That is, it is an interactive server that can send and receive IR signals, with some bells and whistles. The interactive server is mainly meant for interact with other programs. communicating over a serial line (likely in USB disguise), or TCP-sockets.

It is build on top of the low-level library called Infrared4Arduino.

The main content of the project is an applications, Girs (including the "light" version GirsLite), which constitutes the server. There is also another application, Listener, which is a uni-directional program that just emits decodes on the serial interface. (It can for example to be used in conjunction with my Java program dispatcher). Finally, there is a IR-to-serial demonstration program; an IR to serial converter (Opponator). These application are found as subdirectories of the directory examples. The subdirectory src contains a fairly small amount of supporting functionality, forming a library in the traditional Arduino sense.

This slighty unlogical organization is due to the wish to be compatible with the current Arduino library specification, required/desired for inclusion in the Arduino library manager. (There is presently no "Arduino application manager".)

For compilation with the Arduino IDE, the library Infrared4Arduino should be installed with the Arduino library manager.

Configuration files

It is a modular program that is heavily based on CPP symbols, defined in the configuration file examples/Girs/config.h. This determines the capacities of the compiled program, and adapts the configuration to the underlying hardware. The options are (somewhat) documented in examples/Girs/GirsFat.config.h. Not all combination are sensible or implemented. Some, but not all, of the non-sensible combinations will be detected and will generate a compilation error.

If the preprocessor symbol LCD is defined in src/GirsLib/LedLcdManager.cpp (which is the default, except for the Arduino Micro), the library is configured with support for the LCD display, regardless of the settings in config.h.

Modules and interactive commands

General

The program takes commands from its input stream, and write responses on its output stream. The general concept is presented here. A command input consists of one single line, terminated with a carrage return (binary 0x0d). Output is also presented as a single line, terminated with a carrage return. Needless to say, these lines can be long. On a successful execution, typically "OK" is returned.

The communication can take place with another program or with a human using a version of a serial terminal. The command names can, in this implementation, be shortened as long as they are unique. Generally speaking, error handling and plausibility checking are presently basically non-existent...

The program runs in a single thread, with no multitasking whatsoever. Also, even in the Ethernet version, only one concurrent session is supported.

Base commands

These commands are always present in a Girs server. They correspond to the Base module.

version

Input: version

Output: The program name followed by the version string. Example: AGirs 1.0.0.

modules

Input: modules

Output: Returns list of implemented modules, separated by whitespace. Example: Base Transmit Capture Renderer Receive Decoder Led Lcd Parameters.

Comment: A communicating peer evaluates this, in order to find out the capabilities of the Girs implementation. Both IrScrutinizer and the Lirc Girs driver do this, and adjust their behavior accordingly.

NamedRemotes

Presently not implemented, but is planned.

Transmit

Supported if the CPP symbol TRANSMIT is defined in the configuration.

transmit

Input: send <no_sends> <frequency> <length_intro> <length_repeat> <durations...>

Output: OK

Semantics:

The intro sequence is always sent exactly one. If it is empty, the repeat sequence is sent <no_sends> times, otherwise <no_sends> - 1 times. Finally, the (normally empty) ending sequence is sent once.

Capture

Available if configured with the CAPTURE option.

Input: analyze or capture

Output (Normal): f=<frequency> <durations with signs...>

Output (Timeout): .

Semantics:

Receive

Available if configured with the RECEIVE option.

Input: receive

Output (Normal): `<durations with signs...>

Output (Timeout): .

Semantics:

Render

Available if configured with the RENDER option.

Input: transmit <no_sends> <protocol> <protocol_parameters>

Output (normal): OK

Output (Syntax error): <error message>

Semantics:

Example: transmit 1 rc5 0 12. This turns on or off most Philips TVs.

Decoder

Available if configured with the DECODER option. No additional interactive commands, instead the receive-d commands are attempted to be decoded, and optionally display on an LCD display.

LED

Available if configured with the LED option.

Input: led <logical_led_nr> on|off|blink

Output: OK.

Turns on/off/blinks the LED with the given logical number.

LCD

Available if configured with the LCD option.

Input: lcd <message>

Output: OK

Shows the message <message> on a connected LCD display for a certain time.

Parameters

Available if configured with the PARAMETERS option. The allows to inspect and to change some parameters.

Input: parameter <parameter_name> [<parameter_value>]

Output: <parameter_name>=<parameter_value>

Semantics: If <parameter_value> is given, the value is assigned to the named parameter, if possible. If not given, the present value is reported.

Named of available adjustable parameters:

The adjustable parameters depend on the configuration options. A few of these are listed next.

Pronto

Available if configured with the PRONTO option.

Input: hex <no_sends> <pronto_hex_signal>

Output: OK.

Semantics:

Sends the given signal the requested number of times.

Info

Available if configured with the option INFO.

Input: info

Output: Information on current platform; for example Board: Arduino Mega2560, CPU frequency: 16000000L

Memory

Available if configured with the option FREEMEM.

Input: memory

Output: number of free bytes.

Ethernet support

If using an Ethernet shield with W5500 or W5200 chip, be sure that the Ethernet library version 2.0.0 or later is used, since it supports all W5*00 chips, auto-detecting during runtime.

This applies both to the Girs application as well as to the Listener.

Hardware configuration

I have written a fairly detailed description of using an Arduino Nano (clone) by soldering suitable components to the PCB. This is a small handy gadget at the size of a (large) stamp and the price of a (small) pizza, perfect for using with IrScrutinizer and Lirc.

The hardware configuration is determined by including a suitable header file. It describes the attach sensor(s) and the pins they are connected to. To allow soldering sensors directly to the holes in some boards, the program supports defining e.g. SENSOR_GND and SENSOR_VCC, which will make the program define these pins as digital outputs, being fed by constant 0 and 5 volts (3.3 Volts on a 3.3 Volt board) respectively.

Note that the sending pin and the capture pin (as opposed to the receive pin) are not configurable, but has to follow the following table:

<pre> Sender Pin Capture Pin Uno/Nano (ATmega328P) 3 8 Leonardo/Micro (ATmega32U4) 9 4 Mega2560 (ATmega2560) 9 49 </pre>

Sending non-modulated signals.

RF signals (433 MHz and other carrier frequencies) do not use the IR typical modulation. Also there are a few IR protocols (like Revox, Barco, Archer) not using modulation. These signals can be sent by defining the symbol NON_MOD, and connecting some hardware capable of sending non-modulated signals (IR- or RF-) to the GPIO pin defined as NON_MOD_PIN. Then transmitted signals having frequency 0 will be directed to that device. (Later versions may use different syntax and semantic.)

Testing

The flashed unit can be tested with a standard terminal program, like the serial monitor of the Arduino IDE. For this, set the baud rate to 115200, and the line ending to carriage return. It is now possible to communicate with the unit using the commands of Girs. Just type the command to the program, and the unit will respond. Exactly which commands are available depends on the configuration. In all cases, the version and the modules commands are available. If receive is implemented, just type "r" (without the quotes), followed by return, and fire a suitable IR signal at the receiver. The raw capture will be output to the terminal program. Using the clipboard, it can be pasted to IrScrutinizer, and analyzed. Of course, also the other commands can be tested in this way.

API

Up-to-date API, generated by Doxygen.

Dependencies

In previous versions, the library LiquidCrystal_I2C was explicitly needed to be included. Currently, it has been integrated in the project (and slightly modified); see src/GirsLib/LiquidCrystal_I2C_bm.[h|cpp].

Questions and answers

Use the girs driver contained in the recent official upstream Lirc distribution. This is described here. also contained in the (recent) distro as girs.html. Configuration options: use TRANSMIT if sending is desired, and RECEIVE if receiving is desired. CAPTURE is not meaningful for Lirc. Turn on PARAMETERS -- Lircd adjust the ending timeout. If using DECODE and an LCD display (which is cool, but useless), be sure to define DONT_REPORT_DECODES. Use of Ethernet connections are supported. Due to the inner workings of Lirc, it is advantageous not define both TRANSMIT and RECEIVE unless you really need it.

To build the project for the Arduino, use the Arduino IDE from arduino.cc, as in most Arduino projects. The Makefile is used for maintainer work, like generating API documentation with Doxygen, as well as generating keywords.txt. It also generates scripts for Linux and Windows, that can be used for flashing the firmware to an Arduino Nano without deploying the Arduino IDE.

Please follow the links given. Differently put, "receive" uses a demodulating receiver, "capture" a non-demodulating decoder. Note that this is not universally accepted terminology (yet!).

Only cards based on the W5100, W5200, and W5500 chip (and compatible), like the official shield. There are both cheap clones of the original available, as well as smallish W5100-based cards.

Also the next generation of W5500 based shields, like the official Arduino Ethernet Shield 2 work. For this, use the Ethernet library version 2.0.0 (or later).

As indicated by the name, it is a minimalist Girs server for the Arduino, that implements only the capture and the transmit modules, without all options. It is meant to be used with IrScrutinizer versions 1.1.0 or later, as well as with Lirc, using the Lirc girs driver by yours truly. Documentation is found with the Lirc driver, in the Lirc sources the file girs.html.

It is not an independent program, it is just AGirs with certain options enabled, namely the CPP symbols TRANSMIT, CAPTURE, LED, and (optionally) NON_MOD defined. Alternatively, if RECEIVE is defined, but not CAPTURE, the program mimics the capture command with a demodulating sensor, for usage with IrScrutinizer without a non-demodulating sensor.

It has been merged with examples/Girs. To build GirsLite, make sure that examples/config.h is configured as you desire.

Now discontinued, replaced by GirsLite. Just as GirsLite, this was just a certain configuration of AGirs, "optimized" for Lirc, supporting TRANSMIT, NON_MOD (optionally), RECEIVE, LED, LCD, DECODE (only to the LCD), TRANSMITTERS (only a dummy implementation).

No, the present Arduino IDE does not support this. I an not aware of a clean solution. Sorry. Fiddling with the library's config.h for project specific configurations defeats the very idea of a library.

It is pronounced like in "girl". The "language" Girs is written capitalized, the name of an implementation is usually written in lower case.

License

The entire work is licensed under the GPL2 "or later" license, just as Infrared4Arduino. Michael's code (that is contained in Infrared4Arduino) carries the GPL2-license, although he is willing to agree to "or later versions".