Go module for the MCP2221A USB to I²C/UART Protocol Converter with GPIO (datasheet)
- Fully-documented API
- Compliant Go module (see below: Installation)
- Supports multiple MCP2221A devices simultaneously
- Define custom USB device VID/PID
- GPIO input/output
- All dedicated and alternate functions (see below: GP operating modes)
- ADC read (10-bit, 3 channels/pins), configurable reference voltage
- DAC write (5-bit, 2 pins, shared output), configurable reference voltage and default output
- Dedicated UART/I²C activity LED modes with configurable polarity
- Rising/falling/both edge interrupt detection
- Clock output on 1 pin (up to 12 MHz)
- Save default/power-on configuration to flash memory (GPIO mode/value, DAC output, etc.)
- Password-protected flash support
- Configure minimum required operating current (510 mA max)
- I²C read/write (configurable bit rate, up to 400 kHz)
- I²C address scanner discovers all slaves on the bus
- Convenience routines for reading registers from devices with 8-bit and 16-bit subaddressing
Note that UART support is provided natively through the USB interface as a CDC device and is not handled by this module. It should show up in your OS as a regular TTY serial interface (/dev/tty* on Linux/macOS, COM on Windows).
- github.com/karalabe/hid - USB HID interface
If you are not using Go modules (or are unsure), just use the go built-in package manager:
go get -u -v github.com/ardnew/mcp2221aEither use the built-in package manager as above (and drop the -u):
go get -v github.com/ardnew/mcp2221aOr simply add the import statement to your Go package's source code:
import (
// ... other imports ...
mcp "github.com/ardnew/mcp2221a"
)The next time you run go build, the appropriate package will be downloaded automatically! Gee whiz!
See examples for some demo applications:
- GPIO - classic "Blink" demo, toggles an LED connected to GPIO pin GP0
- I²C - I²C address scanner, and also reads and prints the "Device ID" register contents from an INA260 power sensor
- ADC - continuously reads and prints an analog value on GPIO pin GP1
- DAC - continuously writes and prints an always-incrementing 5-bit value on GPIO pin GP2
- Flash - prints the USB product descriptors from flash memory, and toggles power-up GPIO output value on pin GP0
All of the available operating modes for the general-purpose (GP) pins:
GPIO: Operate as a digital input or a digital output pin.SSPND: Reflects the USB state (Suspend/Resume); active-low whenSuspendhas been issued by the USB host, and driven high onResume.- This lets the application react (e.g enter a low-power mode) when USB communication has been suspended or resumed.
- The pin value can be inverted (high on
Suspend, low onResume) using theFlashmodule.
USBCFG: Starts out low during power-up/reset and goes high after successfully enumerating on the USB host.- The pin will also go low when in
Suspendmode and high onResume. - The pin value can be inverted (start high, low after enumeration) using the
Flashmodule.
- The pin will also go low when in
LED_URX,LED_UTX: Indicates UART (Rx/Tx) data being received/transmitted by pulsing the pin high for a few milliseconds.- The pin value can be inverted (pulse low on receive/transmit) using the
Flashmodule.
- The pin value can be inverted (pulse low on receive/transmit) using the
LED_I2C: Indicates I²C (Rx and Tx) data being received and transmitted by pulsing the pin high for a few milliseconds.- The pin value can be inverted (pulse low on receive and transmit) using the
Flashmodule.
- The pin value can be inverted (pulse low on receive and transmit) using the
CLKR: Digital output, providing a clock signal derived from the device’s internal clock.- The clock’s nominal frequency is 12 MHz ± 0.25%.
- Other clock values and duty cycles can be configured using the
Flashmodule.
IOC: Digital input ("Interrupt-on-Change") that is sensitive to rising, falling, or both edges.- The desired edge can be configured using the
FlashandSRAMmodules.
- The desired edge can be configured using the
However, only certain pins support each of the operating modes listed above — per the following matrix yanked from the datasheet:
| GP0 | GP1 | GP2 | GP3 | |
|---|---|---|---|---|
| Default | GPIO | GPIO | GPIO | GPIO |
| Dedicated | SSPND | CLKR | USBCFG | LED_I2C |
| Alt 1 | LED_URX | ADC1 | ADC2 | ADC3 |
| Alt 2 | -- | LED_UTX | DAC1 | DAC2 |
| Alt 3 | -- | IOC | -- | -- |
No idea why the first row of alternate functions is named Dedicated, that's how they are identified in the datasheet...
Please refer to this before sending me a confusing question:
To get started reading this thing, and easier grokking, note that:
- The first half of the datasheet (.pdf) defines internal registers and inter-component behaviors which are all but completely transparent to us. This info can be ignored, but be sure to read the front-matter and any component descriptions.
- The second half of the datasheet (.pdf) defines the USB HID command and response formats. This is the good stuff that pertains to developers of or using this Go module.
Adafruit makes a crazy cheap, snazzy breakout with built-in 3.3V regulator (with VBUS/5V and 3.3V output pins), an I²C Qwiic/Stemma QT connector (as well as the regular SDA/SCL pins), and best of all a USB-C connector as its programming interface:
- https://www.adafruit.com/product/4471
- Only $6.50 USD (5 Feb 2020), wow!