1. MotoHawk Training
CAN
Controller Area Network

2. OUTLINE CAN Introduction CAN Physical Network CAN Message Format
MotoHawk Block Walk Through
MotoHawk “Post Office”
MotoHawk Advanced CAN Blocks
CAN Protocol Overview

3. INTRODUCTION CAN = Controller Area Network
Communication specification implemented for automotive applications in the 1980s
Often, the term “CAN” is misused
CAN is a hardware definition for interoperability between modules
CAN specification does not state the data content of a given message
Protocols built on top of CAN state the data content (ex. J1939, GMLAN)
MotoHawk doesn’t define a protocol, but allows access to the CAN hardware to implement a protocol
By itself, CAN is not difficult (I mean it)

4. OUTLINE CAN Introduction CAN Physical Network CAN Message Format
MotoHawk Block Walk Through
MotoHawk “Post Office”
MotoHawk Advanced CAN Blocks
CAN Protocol Overview

5. PHYSICAL NETWORK Two wire robust serial communication
Up to 1Mbps data rate which is limited by wire length
Kbps
30 1Mbps
Termination resistance required
Maximum bandwidth
2000 messages per
4000 messages per
8000 messages per
Designed bandwidth should not exceed 70% of the maximum bandwidth
CAN +
CAN -
Wire
Length
120 Ω

6. PHYSICAL NETWORK Bus arbitration is handled with a simple strategy
All modules on the bus attempt to transmit a message at the same time
The message with the lowest address wins
This strategy is handled at the hardware level
Dominant Bits (0) vs. Recessive Bits (1)
Multiple modules on the same bus cannot transmit the same address at the same time
Module 0 continues
to transmit while Module 1
waits for next opportunity to
transmit
Module 0
Module 1 T0 T1 T2 T3

7. OUTLINE CAN Introduction CAN Physical Network CAN Message Format
MotoHawk Block Walk Through
MotoHawk “Post Office”
MotoHawk Advanced CAN Blocks
CAN Protocol Overview

8. MESSAGE FORMAT A CAN 2.0B Message can contain up to 131 bits
As application developers, 3 fields are important:
4 bits determine the length of the data (aka payload) (Range : 0-8)
Up to 64 bits of data depending on data length
ID Format
Extended IDs are 29 bits
Standard IDs are 11 bits
Extended and Standard IDs can exist on the same bus at the same time
Standard IDs have less message overhead (higher percentage of data per message)

9. OUTLINE CAN Physical Network CAN Message Format
MotoHawk Block Walk Through
MotoHawk “Post Office”
MotoHawk Advanced CAN Blocks
CAN Protocol Overview

10. CAN DEFINITION BLOCK First, the CAN hardware needs to be initialized
Baud rate and transmit queue size configured
If the baud rate and/or MotoTune protocol settings are not configured properly, then MotoTune can’t talk to the module via CAN (and therefore programming cannot be performed via CAN)
Boot key sets CAN baud rate to 250kbps

11. Send CAN Raw Block

12. CAN Exercise #1 CAN Bus Test
Construct a calibratable CAN message transmitter
Use CANKing to monitor bus traffic
System Diagram

13. CAN Exercise #1
Transmit a message using the Send CAN Raw Block on address 0x1F4.
CAN 1
ID Type : Standard (0)
Data Length : 8
Transmission Rate : 50 ms
Use calibrations for visibility from MotoTune
Change the Tx ID and note that the CAN bus traffic changes
Change the Data and Data length and note that the traffic changes
Use CANKing to debug any failed communication or monitor the bus traffic

14. OUTLINE CAN Introduction CAN Physical Network CAN Message Format
MotoHawk Block Walk Through
MotoHawk “Post Office”
MotoHawk Advanced CAN Blocks
CAN Protocol Overview

15. POST OFFICE
CAN is the hardware layer, so how are transmitted messages sorted and filtered in MotoHawk?
A Post Office is the simplest analogy
Mailboxes
Letters
Addresses
Zip Codes

16. POST OFFICE
Many messages are transmitted on a bus at a given time, but a module may only be interested in a small subset
Similar to a post office where the messages are letters and the software dispatcher is the postman
A “mail box” in MotoHawk is called a “slot”

17. POST OFFICE
A “slot” has an address known as a CAN ID similar to the address on a mailbox
The MotoHawk post office needs to deliver messages to these slots
How does it happen?

18. POST OFFICE Filtering is done with 2 masks
ID Mask : Filters a message by the address or the ID
Payload Mask : Filters a message by the data content
A mask is similar to assigning a “Don’t Care” or a “Do Care” to a particular number in the mask

19. Filtering Filtering is done with 2 masks
ID Mask : Filters a message by the address or the ID
Payload Mask : Filters a message by the data content
A ‘1’ in the mask means that the data and the value must match exactly
For example,
if ID mask = 0x7F0 ( )
and ID = 0x7E4 ( )
If incoming ID = 0x7E0, ( )
message goes to mailbox
If incoming ID = 0x7F4, ( )
x message is rejected by mailbox
If incoming ID = 0x7E1, ( )

20. READ CAN RAW BLOCK

21. POST OFFICE
The “Slot Name” is the name of the mailbox at the post office
The slot has default settings for the ID, ID Mask, Payload Value, and Payload Mask
This is the design time mailbox configuration

22. POST OFFICE The properties of the mailboxes can be changed at run time
The filters determined at design time can be strengthened (more restrictive), but cannot be weakened
In MotoHawk, the CAN Receive Slot Properties Block allows the user to change the filters at run time

23. POST OFFICE
What happens if the postal worker rings your doorbell to deliver a message?
This is an asynchronous reception of a message
The advantage is that processing time can be saved by not periodically polling this message
How does MotoHawk handle this situation?
Asynchronous reception processed with CAN Receive Slot Trigger Block
Slot name in this block must match the slot name specified in Read CAN Raw block or Read CAN Message block

24. OUTLINE CAN Introduction CAN Physical Network CAN Message Format
MotoHawk Basic Transmit Block
Exercise
MotoHawk “Post Office”
MotoHawk Advanced CAN Blocks
CAN Protocol Overview

25. MOTOHAWK ADVANCED CAN
The Read and Send CAN blocks are nice, but sometimes more advanced data parsing is necessary. Common questions:
I have 12 bit scaled data that spans across multiple bytes. How do I convert it into engineering units?
I have more data that can fit into 64 bits. How do I create multi-page messages?
I’m using a protocol that has a variable ID. How do I dynamically create the ID easily?
These are valid questions and there is an answer…

26. MOTOHAWK ADVANCED CAN
MotoHawk has 2 blocks – Read CAN Message and Send CAN Message (below)
These are very powerful blocks that allow users to set up multi-page documents and parse and scale both variables and IDs

27. MOTOHAWK ADVANCED CAN >> edit motohawk_can_example.m
Type this command in your MATLAB command prompt. I will do the same.

28. LITTLE ENDIAN vs BIG ENDIAN
Terminology originates from “Gulliver’s Travels”
“Endianness” refers to the order in which bytes are stored in memory
This table shows the 4 byte storage for 1025 (0x41)
Address
Big Endian Representation
Little Endian
Representation 00 01 02 03
By default, the MotoHawk CAN scripts use Big Endian byte ordering…which can lead to confusion

29. LITTLE ENDIAN vs BIG ENDIAN
Given this CAN definition byte ordering for a 4 byte variable:
Big Endian
MSB
Little Endian
LSB
63...….56
55...….48
47...….40
MSB
39...….32
LSB
Now, go let’s back to the script definition…

30. OUTLINE CAN Introduction CAN Physical Network CAN Message Format
MotoHawk Basic Transmit Block
Exercise
MotoHawk “Post Office”
MotoHawk Advanced CAN Blocks
CAN Protocol Overview

31. PID ECU 2 ECU 1 CLASS EXERCISE
Create a distributed control system to control the ETC over CAN
Pedal
Duty Cycle
PID
Analog signal from potentiometer
CAN message send
TPS %
City ID 0x81
ECU 2
CAN message receive
TPS %
TPS %
Analog signal from ECT
CAN message send
City ID 0x0B
Duty Cycle
Duty Cycle
ECU 1
CAN message receive
PWM output

32. CLASS EXERCISE Duty Cycle message definition
CAN 1
ID Type : Standard (0)
ID : 0x1F4
Data Length : 2 Bytes
Transmission Rate : 10 ms
Data Field
Duty Cycle (SIGNED)
Scale : 200/65,535
Offset : 0
Start bit: 48
Size: 2 bytes
TPS Percent message definition
ID : 0x2F4
Data Length : 1 Byte
Transmission Rate : 15 ms
TPS Percent (UNSIGNED)
Scale : 100/255
Start bit: 56
Size: 1 byte

33. PROTOCOL OVERVIEW CAN gets complicated when protocols are considered
J1939, SmartCraft, CCP, GMLAN, etc. are all examples of protocols that adhere to strict rules
These protocols can be implemented using Simulink and/or Stateflow
Some message formats (J1939) have already been implemented for other projects

34. MotoTron Control Solutions Production Controls in a Flash
MotoTron Control Solutions Production Controls in a Flash