- MCP2515 SPI CAN Controller: Provides the missing CAN peripheral for the Feather SAMD21. Compatible with the MCP2515 Arduino Library initialising with
CS #6
andINT #5
. The track to#5
can be cut if the user does not require interrupts and wishes to use the pin for something else. 16 MHz crystal used for high-data rate capture. - SN65HVD230 CAN Transceiver: Front-end for the differential CAN signals; -2/7 V common mode range on bus, +/- 25 kV ESD protection and upto 1 Mbps datarate. Slope can be controlled with the Rs resistor
R2
, by default it is configured in 'high-speed' mode (RX and TX active). A 120R termination resistor is on-board but not connected by default (a solder link is provided to being in circuit). UPDATE: I've now routed the transeiver RX/TX to pins#9
and#10
so that the STM32 Feather can use the on-board CAN peripheral rather than MCP2515. - RX/TX LEDS: I've tied pull-up LEDs on the transmission lines between the MCP2515 and MCP2551 to provide indication of activity. They should not degrade the signal as they are low current (2 mA) but can be removed if edges are lost at high-speed.
- MCP1703T-5002E: 5 V LDO provides power to the Feather via VUSB given a source of 5-16 V. The board 3V3 is then powered by the Feather's on-board 3V3 regulator. NOTE VIN should not be supplied with VUSB to avoid back-powering the USB port.
- DS3231: Commonly used high-accuracy RTC module with on-board CR1220 back-up battery. Compatible with the DS3231 Arduino Library.
- Hand-drawn silk art! Something I did on the train, inspired by feather's and bikes! CAN is synonymous with the automotive industry so I wanted to put a bike spin on things...
- Make 0603 passives 0402.
- Use same CR1220 holder as Adafruit RTC Wing.
I have some bare boards in fabrication at the moment, which I plan to hand-assemble for my own use. If there is interest, I will get an assembly run done (unless it wins the competition of course!) after this validation.