2-CH CAN HAT

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2-CH CAN HAT
2-CH CAN HAT

2-CH CAN HAT, SPI interfaces
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Overview

2-Channel Isolated CAN Bus Expansion HAT For Raspberry Pi, MCP2515 + SI65HVD230(or SN65HVD230) Dual Chips Solution, Multi Onboard Protection Circuits.

More

Introduction

This is a 2-Channel CAN bus expansion HAT designed for Raspberry Pi, supports CAN2.0, features multi-onboard protection circuits, high anti-interference capability, and stable operation. It suits fields such as automotive devices or industrial automation.

Features

  • Standard Raspberry Pi 40PIN GPIO extension header, supports Raspberry Pi series boards.
  • Adopts MCP2515 and SI65HVD230(or SN65HVD230) dual chips combined solution, allowing 2-channel CAN communication.
  • Integrated power isolation, providing stable isolated voltage, requires no extra power supply for the isolated terminal.
  • Onboard digital isolator, signal isolation makes communication safer, more stable, and better anti-interference.
  • Onboard TVS (Transient Voltage Suppressor) diode, provides ESD protection and transient peak voltage protection.
  • Onboard voltage translator, select 3.3V/5V operating voltage by jumper.
  • Onboard 120Ω terminal resistor, configured by jumper.
  • Breakout SPI control pins, for connecting with host control boards like STM32/Arduino.
  • Comes with online development resources and a manual.

Specifications

  • CAN controller: MCP2515
  • CAN transceiver: SI65HVD230 (or SN65HVD230)
  • Communication interface: SPI
  • Operating voltage: 5V
  • Logic level: 3.3V/5V
  • Dimensions: 65.0 x 56.5 mm
  • Mounting hole diameter: 3.0mm

Interfaces

CAN bus

PIN Raspberry Pi
(BCM)
Raspberry Pi
(WPI)
Description
5V 5V 5V 5V Power input
GND GND GND Ground
MISO 9 (MISO) 13 (MISO) SPI clock input
MOSI 10 (MOSI) 12 (MOSI) SPI data input
SCK 11 (SCLK) 14(SCLK) SPI data output
CS_0 8 (CE0) 10 (CE0) CAN_0 chip select
INT_0 23 (Default)/22 6 (Default)/5 CAN_0 interrupt output
CS_1 7 (CE1) 11 (CE1) CAN_1 chip select
INT_1 25 (Default)/24 4 (Default)/3 CAN_1 interrupt output


NOTE:

INT_0 is soldered by PIN23 by default, and INT_1 is soldered by PIN25 by default. 
If you need to modify the pins, you need to modify the soldering pad of the PCBA board, and also modify the setting of /boot/config.txt.
Take the modification of INT_0 as an example: if PIN23 is changed to PIN22, then the soldering pad of the red frame on the left board in the figure below needs to be modified to the soldering pad of the board on the right in the figure below:
2-CH-CAN-HAT-int-setting.png
Similarly, if you need to change INT_1 from the default PIN25 to PIN24, you need to solder the 0 ohm at the arrow of PIN25 to PIN24.

CAN bus

CAN module could process packets transmitted/received on the CAN bus. Packets transmit the first store packet to the related buffer and control register. Use the SPI interface to set the bits on the control register or enable the transmit pin for transmitting. Registers could be read to detect communication states and errors. It will first check if there are any errors of packets detected on the CAN bus, then verify it with a filter that is defined by the user. And store the packet in one of the buffers if it has no errors.
Raspberry Pi cannot support SPI bus, so this module uses an SPI interface and on board a receiver/transmitter for CAN communication.
Microchip Technology's MCP2515 is a stand-alone Controller Area Network (CAN) controller that implements the CAN specification, version 2.0B. It is capable of transmitting and receiving both standard and extended data and remote frames. The MCP2515 has two acceptance masks and six acceptance filters that are used to filter out unwanted messages, thereby reducing the host MCUs overhead. The MCP2515 interfaces with microcontrollers (MCUs) via an industry-standard Serial Peripheral Interface (SPI), that is Raspberry Pi can communicate with MCP2515 via SPI interface without an external driver. What we need to do is to enable the kernel driver on the devices tree. For more details, please refer to the datasheet.
MCP2515-PIN.png

Note: Since October 2021, due to the lack of stock of the SN65HVD230 chip and the price increase, the chip has been replaced with SI65HVD230, and the software and hardware functions are compatible.

SN65HVD230 from TEXAS INSTRUMENTS is a CAN transceiver, which is designed for high communication frequency, anti-jamming, and high-reliability CAN bus communication. SN65HVD230 provides three different modes of operation: high-speed, slope control, and low-power modes. The operation mode can be controlled by Rs pin. Connect the Tx of the CAN controller to SN65HVD230's data input pin D, which can transmit the data of the CAN node to the CAN network; And connect the RX of the CAN controller to SN65HVD230's data input pin R to receive data.
SN65HVD230-PIN.jpg

Working with Raspberry Pi

The working voltage level of Raspberry Pi is 3.3V, therefore we need to set the VIO of 2-CH CAN HAT to 3.3V as below:
2-CH-CAN-HAT-3V3.jpg
Note: When connecting to the Raspberry Pi 2b, 3b, and 4b boards, please connect the booster and nylon post to fix it to avoid the back of the CAN terminal touching the HDMI interface causing a short circuit, and avoid wrong connection or poor contact:
2-CH CAN HAT 010.png
When connecting to the Raspberry Pi, you must add a booster seat, and then pass the needle through the bottom plate, the effect is as follows:
2-CH CAN HAT 020.png

Enable SPI interface

  • Open the terminal, and use the command to enter the configuration page.
sudo raspi-config
Choose Interfacing Options -> SPI -> Yes to enable the SPI interface.

RPI open spi.png
Reboot Raspberry Pi:

sudo reboot

Please make sure that the SPI interface was not used by other devices, you can check in the /boot/config.txt.

Install libraries

  • bcm2835

Open the terminal and run the commands below to install the bcm2835 library:

wget http://www.airspayce.com/mikem/bcm2835/bcm2835-1.60.tar.gz
tar zxvf bcm2835-1.60.tar.gz 
cd bcm2835-1.60/
sudo ./configure
sudo make
sudo make check
sudo make install
# For More:http://www.airspayce.com/mikem/bcm2835/

wiringPi

For 32-bit Raspberry Pi system

#Open the Raspberry Pi terminal and run the following command
cd
sudo apt-get install wiringpi
#For Raspberry Pi systems after May 2019 (earlier than that can be executed without), an upgrade may be required:
wget https://project-downloads.drogon.net/wiringpi-latest.deb
sudo dpkg -i wiringpi-latest.deb
gpio -v
# Run gpio -v and version 2.52 will appear, if it doesn't it means there was an installation error

# Bullseye branch system using the following command:
git clone https://github.com/WiringPi/WiringPi
cd WiringPi
. /build
sudo gpio -v
# Run gpio -v and version 2.70 will appear, if it doesn't it means there was an installation error

For 64-bit Raspberry Pi System

Copy the resource package to the Raspberry Pi using the command:

wget https://files.waveshare.com/upload/8/8c/WiringPi-master.zip

(optional, you can skip this step if you have used the unzip command) Install the unzip environment:

sudo apt-get install unzip

Go to the file location and execute the unzip command:

unzip WiringPi-master.zip

Go to the file directory (go to the "WiringPi-master" folder):

cd WiringPi-master/

Run sudo . /build:

sudo . /build 

(optional, see point 4 for errors) If . /build does not work, execute "chmod +x . /build" and then "sudo . /build":

chmod +x . /build

Example:
TF-Luna LiDAR Range SensorRas 05.png
TF-Luna LiDAR Range SensorRas 07.png

  • Python

Install python library:

#python2
sudo apt-get update
sudo apt-get install python-pip
sudo apt-get install python-pil
sudo apt-get install python-numpy
sudo pip install RPi.GPIO
sudo pip install spidev
sudo pip2 install python-can
#python3
sudo apt-get update
sudo apt-get install python3-pip
sudo apt-get install python3-pil
sudo apt-get install python3-numpy
sudo pip3 install RPi.GPIO
sudo pip3 install spidev 
sudo pip3 install python-can


Preparation

Insert the module into Raspberry Pi, and then modify the config.txt file:

sudo nano /boot/config.txt
The above configuration is based on the Raspbian OS system. If it is used in the Ubuntu system, the config.txt path is generally "/boot/firmware/config.txt "

Append these statements to the file:

dtparam=spi=on
dtoverlay=mcp2515-can1,oscillator=16000000,interrupt=25
dtoverlay=mcp2515-can0,oscillator=16000000,interrupt=23
dtoverlay=spi-bcm2835-overlay
  • Save and exit, then restart your Pi:
sudo reboot
  • After restart, check if initialize successfully:
dmesg | grep spi

2-CH-CAN-HAT-SPI-Init.png

  • Set up CAN:
sudo ip link set can0 up type can bitrate 1000000
sudo ip link set can1 up type can bitrate 1000000
sudo ifconfig can0 txqueuelen 65536
sudo ifconfig can1 txqueuelen 65536
  • For more information about CAN kernel instructions, please check:
https://www.kernel.org/doc/Documentation/networking/can.txt
  • Run "ifconfig":
ifconfig

2-CH-CAN-HAT-ifconfig.jpg

  • Turn off CAN device:
sudo ifconfig can0 down
sudo ifconfig can1 down

Testing

If there is only one 2-CH CAN HAT on hand, you can connect CAN0_H and CAN1_H and CAN0_L and CAN1_L of the module as shown in the following figure:
2-CH-CAN-HAT-connect.jpg

  • install can-utils:
sudo apt-get install can-utils
  • Open two terminal windows:

One terminal input receives the CAN0 data command:

candump can0

Another terminal input sends the CAN1 data command:

cansend can1 000#11.22.33.44
  • The demonstration effect is as follows: (receiving on the left, sending on the right.)

2-CH-CAN-HAT-cansend.png
If you have two 2-CH CAN HAT on hand, you can directly connect CAN_H and CAN_L two by two. The effect is the same as the above, pay attention to match the communication rate, identify the ID, and output the interface serial number.

Python example

  • Enter the directory of the Python example:
  • Run the receiver.py script in the receiver terminal:
sudo python reveive.py
  • Run the send.py script in the sender terminal:
sudo python send.py

【Note】 The CAN1 is used as sender, and CAN0 is used as receiver.

Codes analysis

【Python example】

The demo codes provided are based on Python, please check that you installed the python-can library.
Before you send data, you should create a CAN device first,

os.system('sudo ip link set can0 type can bitrate 100000')
os.system('sudo ifconfig can0 up')

This code is used to initialize CAN0 as the receiver/sender. If you want to change it to CNA1, you can use this one:

os.system('sudo ip link set can1 type can bitrate 100000')
os.system('sudo ifconfig can1 up')
  • Connect to CAN BUS
can0 = can.interface.Bus(channel = 'can0', bustyp = 'socketcan_ctypes')
As the python-can version is upgraded to 4.0.0, the corresponding code changes are as follows, otherwise an error will be reported.
can1 = can.interface.Bus(channel = 'can0', bustype = 'socketcan')
  • or
can0 = can.interface.Bus(channel = 'can1', bustyp = 'socketcan_ctypes')
  • Create message


msg = can.Message(arbitration_id=0x123, data=[0, 1, 2, 3, 4, 5, 6, 7], extended_id=False)
As the python-can version is upgraded to 4.0.0, the corresponding code changes are as follows, otherwise an error will be reported.
msg = can.Message(is_extended_id=False, arbitration_id=0x123, data=[0, 1, 2, 3, 4, 5, 6, 7])
  • Send message
can0.send(msg)
  • or:
can1.send(msg)
  • Finally, close the CAN device:
os.system('sudo ifconfig can0 down')
  • or:
os.system('sudo ifconfig can1 down')
  • Receive message:
msg = can0.recv(10.0)

The variable of recv() function is the timeout of receiving.
For more information, please refer to:https://python-can.readthedocs.io/en/stable/interfaces/socketcan.html

【WringPi example】

  • Blocking the reception, the Raspberry Pi opens the terminal and runs:
cd 2-CH_CAN_HAT_Code/wiringPi/receive/
make clean
sudo make
sudo ./can_receive
  • Raspberry Pi opens the terminal and runs:
cd 2-CH_CAN_HAT_Code/ wiringPi/receive/
make clean
sudo make
sudo ./can_send

Resources

Documentation

Datasheet

3D Drawing

FAQ

 Answer:
Stacking multiple 2-CH CAN HAT expansion boards is not supported, the interfaces and drivers will conflict; if other HAT expansion boards are stacked, if the interfaces and drivers do not conflict, theoretically they can be stacked, for example, 2-CH RS485 HAT can be stacked with 2-CH CAN HAT.

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 Answer:
CAN bus can be connected to multiple CAN slaves in parallel, but the addresses should not conflict, and the actual data communication volume and interference should be considered, subject to the actual measurement.

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 Answer:
Ground pin, common ground can ensure the stability and reliability of the signal, to avoid signal interference and noise. The CAN itself is a differential signal line, if the customer's CAN device does not have a GND pin, it can also be left unconnected.

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 Answer:
You can try to update the kernel version:
sudo apt update
sudo apt upgrade
uname -a


 Answer:
If the initialization fails, you can restart the Raspberry Pi or other main control platform development boards to ensure that the connection is correct, refer to the wiki to carefully check whether there is any leakage in the configuration and whether the logic voltage jumper pin is selected correctly.


 Answer:
The chip is affected by many factors such as the surrounding environment, communication distance, wires, software and so on. During high-speed communication, the data baud rate may not reach the nominal maximum rate. Users need to ensure stability and select a suitable communication speed according to actual measurements.


 Answer:
G is the signal ground, also called isolated ground. In the industrial environment, CAN is subject to changeable surroundings and to ensure stability, the G of the two communication modules need to be connected.

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 Answer:
If the initialization is successful and the speed is set properly, it still cannot communicate normally. Please check whether the CAN_H of the next two 2-CH CAN HATs is connected to another CAN_H, and whether CAN_L is connected to another CAN_L. It should be noted that these two lines cannot be reversed. H corresponds to H, and L corresponds to L. If there is no problem, please check whether the CAN port configured by the program is correct. For example, CAN0 is required, but the program code configures CAN1. At the same time, it is also necessary to check whether the hardware is connected correctly and whether there is a short circuit in the CAN interface. As shown in the figure below, the CAN interface and the HDMI interface of the Raspberry Pi are accidentally connected to cause a short circuit, which makes the CAN unable to communicate normally. At this time, it is necessary to purchase a 2-CH The 2×20PIN long row seat of accessories delivered during CAN HAT will be heightened.

2-CH CAN HAT01.png


 Answer:

Check whether the hardware connections are in poor contact. Check the software configuration to see if SPI is turned on, etc.


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