C.5.2 finding the start bit – Campbell Hausfeld SDM-CAN User Manual

Appendix C. Using SDM-CAN on J1939 Networks

Table C-6 Mapping of J1939 Identifier Field Values into a 29-Bit Identifier

Bit

28

27

26

25 24

23

22

21

20 19 18 17 16 15 14 13 12 11 10

9 8 7 6 5 4 3 2 1 0

SOF P

3

P
2

P
1

R
1

D
P

P
F
8

P
F
7

P
F
6

P
F
5

P
F
4

P
F
3

P
F
2

P
F
1

P
S
8

P
S
7

P
S
6

P
S
5

P
S
4

P
S
3

P
S
2

P
S
1

S
A
8

S
A
7

S
A
6

S
A
5

S
A
4

S
A
3

S
A
2

S
A
1

Value 0 1 1 0 0 1 1 1 1 0 0 0 0 0 0 0 0 0 0 1 1 0 0 0 0 0 0 0 0

This gives a binary value of 01100111100000000001100000000 that can then be
split into three values for use as the ID parameter.

The first value is made up of bits 0..10 which is 01100000000

2

this is converted to

768

10

and used as the first ID parameter.

The second value is made up of bits 11..23 which is 1111000000000

2

this is

converted to 7680

10

and used as the second ID parameter.

The third value is made up of bits 24..28 which is 01100

2

this is converted to 12

10

and used as the third ID parameter.

C.5.2 Finding the Start Bit

The byte number of the Accelerator pedal position value is 2

Table C-7 Accelerator Pedal Position Value Byte Number

1

2 3 4 5 6 7 8

87654321

87654321 87654321 87654321 87654321 87654321 87654321 87654321

The start bit for this value is 49, as it is the least significant bit of the data value
within the data frame that this parameter refers to.

An example for Accelerator pedal position is shown below.

;{CR23X}

;

*Table 1 Program

01: 1.0 Execution Interval (seconds)

;Retrieve Accelerator pedal position Data from CAN network

8: SDM-CAN (P118)

1: 0 SDM Address

2: 4 Time Quanta

3: 5 Tseg1

4: 2 Tseg2

5: 768 ID Bits 0..10 (-- for 11-bit CAN ID)

6: 7680 ID Bits 11..23

7: 12 ID Bits 24..28

8: 2 Rx, unsigned int, LSB 1st

9: 49 Start Bit No.

10: 8 No. of Bits

11: 1 No. of Values

12: 7 Loc [ Throttle ]

C-5