GY-63_MS5611/libraries/MAX14661
2023-02-25 16:29:54 +01:00
..
.github 0.1.4 MAX14661 2023-02-25 16:29:54 +01:00
documents 0.1.0 MAX14661 multiplexer I2C 2021-06-03 09:31:17 +02:00
examples 0.1.2 MAX14661 2021-12-21 13:06:15 +01:00
test 0.1.4 MAX14661 2023-02-25 16:29:54 +01:00
.arduino-ci.yml 0.1.3 MAX14661 2022-11-16 15:18:12 +01:00
CHANGELOG.md 0.1.4 MAX14661 2023-02-25 16:29:54 +01:00
keywords.txt 0.1.2 MAX14661 2021-12-21 13:06:15 +01:00
library.json 0.1.4 MAX14661 2023-02-25 16:29:54 +01:00
library.properties 0.1.4 MAX14661 2023-02-25 16:29:54 +01:00
LICENSE 0.1.4 MAX14661 2023-02-25 16:29:54 +01:00
MAX14661.cpp 0.1.4 MAX14661 2023-02-25 16:29:54 +01:00
MAX14661.h 0.1.4 MAX14661 2023-02-25 16:29:54 +01:00
README.md 0.1.4 MAX14661 2023-02-25 16:29:54 +01:00

Arduino CI Arduino-lint JSON check License: MIT GitHub release

MAX14661

Arduino library for MAX14661 multiplexer with I2C interface.

Description

The MAX14661 multiplexer is a 16 x 2 channel multiplexer. It has 2 lines A and B which can be connected up to 16 A lines and 16 B lines.

The library provides 4 kinds of interfaces (see below)

  • PAIR switch A and B in pairs
  • SHADOW use a shadow register to set all simultaneously.
  • MUX open channels exclusively.
  • FULL control all as you like.

Mixing these interfaces is allowed but definitely not advised as especially the PAIR interface assumes that A and B selections are kept in sync. So depending on your application choose the interface you want to use.

The MAX14661 device can be controlled by SPI or I2C. This library implements the I2C interface.

I2C address

The I2C address can be adjusted by 2 address lines A0 and A1. Addresses go from 0x4C (76) .. 0x4F (79). See table 3 datasheet.

This implies you may have up to 4 MAX14661 multiplexers on one I2C bus. If you need more, consider a TCA9548.

According to the datasheet the I2C Serial-Clock Frequency is max 400 kHz. (SPI can do 10 MHz)

Interface

#include "MAX14661.h"

Constructor

  • MAX14661(deviceAddress, TwoWire *wire = &Wire) Constructor with device address, and optional the Wire interface as parameter.
  • bool begin() initializes the wire interface.
  • bool begin(sda, scl) idem, for the ESP32 where one can choose the I2C pins.
  • bool isConnected() checks if the device address is visible on the I2C bus.

PAIR interface

The functions in this interface part all work symmetrical on the A and B line. They are managed as a PAIR. So this is ideal e.g. to multiplex an I2C bus or a Serial TX/RX pair line.

The interface allows to have multiple lines A/B open in parallel.

// open ==> connect

  • bool openChannel(uint8_t channel) connects A/B to chosen channel.
  • bool closeChannel(uint8_t channel) disconnects channel from A/B.
  • bool isOpenChannel(uint8_t channel) returns true if connected to A/B.
  • void openAllChannels() connects all channels.
  • void closeAllChannels() disconnects all channels.
  • void setChannels(uint16_t mask) connect multiple channels with a bit mask.
  • uint16_t getChannels() returns a bit mask of the channels connected.

Note: setChannels(mask) is the only way to set channels at the very same moment in the PAIR interface.

SHADOW interface

Experimental - to be tested.

The SHADOW interface allows one to prepare which channels should be selected, and activate them all at once.

  • bool shadowClear() clears all shadow registers.
  • void activateShadow() write all shadow registers to the direction registers of A and B at once.

Prepare multiple channels at once. This is way faster than per channel.

  • bool setShadowChannelMaskA(uint16_t mask) write all channels at once.
  • uint16_t getShadowChannelMaskA() read shadow registers.
  • bool setShadowChannelMaskB(uint16_t mask) write all channels at once.
  • uint16_t getShadowChannelMaskB() read shadow registers.

Prepare per channel.

  • bool isOpenShadowChannelA(uint8_t channel) read status of specific channel in shadow registers.
  • void openShadowChannelA(uint8_t channel) prepare a specific channel to open.
  • void closeShadowChannelA(uint8_t channel) prepare a specific channel to close.
  • bool isOpenShadowChannelB(uint8_t channel) read status of specific channel in shadow registers.
  • void openShadowChannelB(uint8_t channel) prepare a specific channel to open.
  • void closeShadowChannelB(uint8_t channel) prepare a specific channel to close.

Note: there is no command that sets both A and B simultaneously.

MUX interface

The MUX interface allows one channel (0..15) to be open at a time.

  • void MUXA(uint8_t channel) if channel < 16 only that channel will be selected. All other values will select no channel.
  • uint8_t getMUXA() returns the selected channel. 255 means none selected.
  • void MUXB(uint8_t channel) if channel < 16 only that channel will be selected. All other values will select no channel.
  • uint8_t getMUXB() returns the selected channel. 255 means none selected.

FULL CONTROL interface

Full control per channel, any combination is possible. Use with care as these can interfere e.g. with the PAIR interface. All functions return false if channel > 15.

  • bool openA(uint8_t channel) idem
  • bool openB(uint8_t channel) idem
  • bool closeA(uint8_t channel) idem
  • bool closeB(uint8_t channel) idem

LOW LEVEL CONTROL interface

Check datasheet for the meaning of and the values in the registers.

  • uint8_t readRegister(uint8_t reg) read low level device register.
  • int writeRegister(uint8_t reg, uint8_t value) write value to device register.

Error handling

  • int lastError() returns the last error, limited to low level I2C for now.

to be elaborated / implemented(see future)

Define value notes
MAX14661_OK 0x00
MAX14661_ERR_I2C 0x80 not implemented yet
MAX14661_ERR_CHANNEL 0x81 not implemented yet

Operation

See examples

Future

Must

  • improve documentation

Should

  • test behaviour.
  • write unit tests.
  • implement error handling.
    • use an internal mode to see which of the three interfaces is used consequently or not?
    • MAX14661_ERR_ADDRESS ?

Could

  • optimize low level bit set/clr/get read/write 2 bytes at once.
  • test I2C communication speed.
    • 100- 400 kHz and up.
  • measure performance.
  • cache direct registers. (fast response).
  • ShutDown() SD pin. for low power datasheet p.15
    • document it.
    • implement.

Wont

  • SPI interface.
    • separate (derived ?) class
  • initial values parameter for begin()?
    • depends on interface (PAIR MUX SHADOW) used, ambiguous.
    • ==> user task.