# micropython_ir **Repository Path**: zypae/micropython_ir ## Basic Information - **Project Name**: micropython_ir - **Description**: Nonblocking device drivers to receive from IR remotes and for IR "blaster" apps. - **Primary Language**: Unknown - **License**: MIT - **Default Branch**: master - **Homepage**: None - **GVP Project**: No ## Statistics - **Stars**: 0 - **Forks**: 0 - **Created**: 2021-08-27 - **Last Updated**: 2021-08-27 ## Categories & Tags **Categories**: Uncategorized **Tags**: None ## README # Device drivers for IR (infra red) remote controls This repo provides a driver to receive from IR (infra red) remote controls and a driver for IR "blaster" apps. The device drivers are nonblocking. They do not require `uasyncio` but are compatible with it, and are designed for standard firmware builds. The receiver is cross platform and has been tested on Pyboard, ESP8266, ESP32 and Raspberry Pi Pico. In a typical use case the receiver is employed at the REPL to sniff the address and data values associated with buttons on a remote control. The transmitter is then used in an application to send those codes, emulating the remote control. Other use cases involve running the receiver in an application. This enables an IR remote to control a device such as a robot. ## Raspberry Pi Pico note Early firmware has [this issue](https://github.com/micropython/micropython/issues/6866) affecting USB communication with some PC's. This is now fixed. Please ensure you are using up to date firmware. #### [Receiver docs](./RECEIVER.md) The transmitter driver is compatible with Pyboard (1.x and D series) and ESP32. ESP8266 is unsupported; it seems incapable of generating the required signals. #### [Transmitter docs](./TRANSMITTER.md) # 1. IR communication IR communication uses a carrier frequency to pulse the IR source. Modulation takes the form of OOK (on-off keying). There are multiple protocols and at least three options for carrier frequency: 36, 38 and 40KHz. In the case of the transmitter the carrier frequency is a runtime parameter: any value may be specified. The receiver uses a hardware demodulator which should be purchased for the correct frequency. The receiver device driver sees the demodulated signal and is hence carrier frequency agnostic. Remotes transmit an address and a data byte, plus in some cases an extra value. The address denotes the physical device being controlled. The data defines the button on the remote. Provision usually exists for differentiating between a button repeatedly pressed and one which is held down; the mechanism is protocol dependent. # 2. Supported protocols The drivers support NEC and Sony protocols plus two Philips protocols, namely RC-5 and RC-6 mode 0. There is also support for the OrtekMCE protocol used on VRC-1100 remotes. These originally supported Microsoft Media Center but can be used to control Kodi and (with a suitable receiver) to emulate a PC keyboard. Examining waveforms from various remote controls it is evident that numerous protocols exist. Some are doubtless proprietary and undocumented. The supported protocols are those for which I managed to locate documentation. My preference is for the NEC version. It has conservative timing and good provision for error detection. RC-5 has limited error detection, and RC-6 mode 0 has rather fast timing. A remote using the NEC protocol is [this one](https://www.adafruit.com/products/389). # 3. Hardware Requirements These are discussed in detail in the relevant docs; the following provides an overview. The receiver is cross-platform. It requires an IR receiver chip to demodulate the carrier. The chip must be selected for the frequency in use by the remote. For 38KHz devices a receiver chip such as the Vishay TSOP4838 or the [adafruit one](https://www.adafruit.com/products/157) is required. This demodulates the 38KHz IR pulses and passes the demodulated pulse train to the microcontroller. In my testing a 38KHz demodulator worked with 36KHz and 40KHz remotes, but this is obviously neither guaranteed nor optimal. The transmitter requires a Pyboard 1.x (not Lite), a Pyboard D or an ESP32. Output is via an IR LED which will need a transistor to provide sufficient current. The ESP32 requires an extra transistor to work as a transmitter. ## 3.1 Carrier frequencies These are as follows. The Samsung and Panasonic remotes appear to use proprietary protocols and are not supported by these drivers. | Protocol | F KHz | How found | Support | |:---------:|:-----:|:-------------:|:-------:| | NEC | 38 | Measured | Y | | RC-5 RC-6 | 36 | Spec/measured | Y | | Sony | 40 | Spec/measured | Y | | MCE | 38 | Measured | Y | | Samsung | 38 | Measured | N | | Panasonic | 36.3 | Measured | N | # 4. References Sources of information about IR protocols. The `sbprojects.net` site is an excellent resource. [General information about IR](https://www.sbprojects.net/knowledge/ir/) The NEC protocol: [altium](http://techdocs.altium.com/display/FPGA/NEC+Infrared+Transmission+Protocol) [circuitvalley](http://www.circuitvalley.com/2013/09/nec-protocol-ir-infrared-remote-control.html) [sbprojects.net](https://www.sbprojects.net/knowledge/ir/nec.php) Philips protocols: [RC5 Wikipedia](https://en.wikipedia.org/wiki/RC-5) [RC5 sbprojects.net](https://www.sbprojects.net/knowledge/ir/rc5.php) [RC6 sbprojects.net](https://www.sbprojects.net/knowledge/ir/rc6.php) Sony protocol: [SIRC sbprojects.net](https://www.sbprojects.net/knowledge/ir/sirc.php) MCE protocol: [OrtekMCE](http://www.hifi-remote.com/johnsfine/DecodeIR.html#OrtekMCE) IR decoders (C sourcecode): [in the Linux kernel](https://github.com/torvalds/linux/tree/master/drivers/media/rc)