CAN-Multiplex Worksheet

Colour of the wire Yellow Black
Time per division: 20us
Voltage per division: 1V

1.4 Record the waveform of the other wire in the twisted pair:

Colour of the wire:  Yellow brown
Time per division: 20us
Voltage per division: 1V

In the following graph there is a pattern for both Yellow Black and Yellow Brown CAN wires at same time on oscilloscope:

1.5
Q.  What is aliasing? describe it.
A.  It is the effect that create the distortion in the signals and causes different continuous signals to indistinguishable when taking on the oscilloscope. (www.wordiq.com)

1.6
Q. How do you know these waveforms are not aliasing?
A. From the first two oscilloscope graphs, we can see the see the distinguished waveform and there is not deformation in the wave pattern.

1.7
In the 1.3 waveform above, what is the main voltage on the line?
About 3.2 V
Q. What is the other voltage on the line, when the voltage is pulled up or down to talk?
A. About 2.2 V

1.8
In the 1.4 waveform above, what is the main voltage on the line?
1.3 V

Q. What is the voltage on the line, when the voltage in pulled up or down to talk?
A. 2.5V

1.9
Observe the signal in 1.3 and 1.4 above with a voltmeter.
1.3 one's is 2.37
1.4 one's is 2.65

2.3 List the different systems that are controlled by CAN?

3.0 Wiring Diagram Excercise:

3.2  Body computer no subsystem (2.4L)

3.3  High speed system are in ECU/ PCM. The pin no. E24 (Red colour) and E11(White) are high speed wires of the system.

3.4  Seat belt input, RR door switch, RF door switch, LR door switch, LF door switch and many more in underdash fuse/relay box 

3.5  The location of the gateway is "Gauge Control Module" in the diagram.

3.6  The system can be diagnose at "Multiplex Control Inspection Connector".

3.7 We connect the Scan tool at Multiplex Control Inspection Connector to diagnose the system. From here we can diagnose every where because the system is communicating   with each other by CAN high and CAN low. Any module having fault will be detected at Multiplex Control Inspection Connector.

3.8 Locate a system that goes to "sleep" after a short time. What is it?

      Alarm Bonnet Switch

3.9 

Q. What voltage do you see when it is "awake"?

A. 0.29 V (DC)

Q. What voltage do you see when it is "asleep"?

A. 0.21 V

Q. On what wire do you see this change?

A. yellow brown (non CAN)

3.10 Amp Drain:

Measure the amp drain at the battery when the system is asleep

0.92 A after 5 minutes

0.6 A after 10 minutes

Q. How long did it take the system to go to sleep?

A. 5 minutes

Q. What made the system "wake up"

A. Alarm Bonnet Switch. 

     

Controlled Area Network Board

There are two pattern in above graph. Channel one graph is pulling down by channel two and channel two is by channel one. They are pulling up and down by each other in different interval of time. Channel two is pulling up to higher value than channel one to lower value by channel two. The base voltage for channel  one is  3.1V and for channel two is 1 V. Both voltages switch on and off simultaneously.

Right Indicator Pattern:

The pattern starts changing at A and B. This is the point where two signals start talking each others. At D and C, there is a big pulling between two signals.

Left Indicator:

The pattern of both waves start change at A and F. This the point where two signals start talking with each others. At B and just after H, the pattern is some different from its original. May be they stop talking with each others. At C and G, the signals again start talking with each others. At D and I, they stop talking as it looks like as a original pattern.

At A and D, the patterns start changing, the signals start talking to each other at this point. They patterns came back to its original form (upper B) and again start talking at lower B till C and E. After C and G, the patterns again come back to its original form.

Stoplights:

The patterns start changing at A and H. It is the point where two signals starts talking to each others. The patterns come back to their original form at B and H for a moment and again start talking at C and F. At D and G the waveforms came back to their original form for a long time.

Fuel Pump:

The signals start changing pattern at A and F. They start talking at this point. Then the came  back to their original pattern at B and J. They changed their pattern at G and C. Their is a big stationary pattern at E and I

Reverse Lights:

There is a change in pattern at A and E and it come back to its original form at B and H. C and F are the indistinguishable patterns. There is a big stationary pattern D and G.

Using the wiring diagram and CAN board identify the input/output pins, wire colours. Relay or transistor for the right hand indicator and rear wiper:
The pin number for right hand side indicator on board with respect to wiring diagram is 7 and for rear wiper is 9.
Transistor for right hand indicator is U7 but there is no relay for it.
There is no transistor for rear wiper. It has RL4s relay only.

Using the wiring diagram identify both voltage regulators that resemble the one that you built in TTEC4824. Note all the input pins and where the output are connected to

Input pins for regulator no.1 are 1 and 2. Output were connected to pin no. 14 of the IC (Intergreated chip)
Input pins for regulator no.2 are 1 and 2. Output were connected to pin no. 1 of the IC, resistor R17 and R20, diode D4 and D6.
  
Using the wiring diagram follow one circuit though from the input to the output. Note all the inputs/IC/ relay/transistors and describe how the circuit operates.


12 V input supply at pins 1 and 2 then it go to voltage regulator and then output goes to capacitor in parallel and to pin no.14. If pin 14 is connected to pin no.1 then it goes to resistance R29. After that it goes to another chip circuit and then connected to the resistor and transistor in parallel and the output goes to pin no. 1 which is for tail light.
The 12 V input is coming into voltage regulator, which regulate the voltage and cut it down to some lower value  it then charge the capacitor which is in parallel with IC. IC futher regulate the voltage and pass on the resistance R29. After that the current goes to the chip having light emitting diode which active the transistor in it to activate the another transistor U3 which is connected to a resistor R24 in parallel and this transistor takes the output voltage to the tail light.

On Vehicle Testing

 toyo

ABS wheel speed sensors:


Q. On the vehicle that you have been assigned does it use analogue or digital wheel sensors?
A. Digital

Q. how did you conclude that the wheel sensors were analogue or digital?
A. Checked with oscilloscope

Measure the air gap for each wheel sensor.
State the air gap and visual condition of each wheel sensor

Front Right: 0.022 in (inches)
Front Left: 0.024 in
Rear Right: 0.022 in
Rear Left: 0.024 in

Oscilloscope pattern:

Q. Is this pattern an analogue or digital pattern?
A. Analogue

Using a scan tool go to the ABS live data screen and note all the sensors, data and what it is telling you?

1, It has three stages solenoid: hold, up and down
Up: It builds the pressure
Down: Releases the pressure
Hold: Holds the pressure

2, Motor runs when we give the command through scan tool
3, When it is on, the relay clicks
4, On turning off,m it clicks again

Electronic Transmission and Scan Tools


Abbreviations
PCM= Powertrain Control Module
TCC= Torque Converter Clutch
TPS= Throttle Position Sensor
ECT= Engine Coolant Temperature Sensor
VSS= Vehicle Speed Sensor
RSA= Transmission Range Fluid Pressure Switch Assembly
TTS= Transmission Temperature Sensor

Block Diagram:

Wiring Diagram

                                               (Holden: Diagnostic Trouble Codes)

Shift Solenoids:


Q. Which solenoids are "on" when this vehicle is shifted into drive and starts out in first gear?
A. 1-2 and 2-3

Q. Which solenoids are "on" when this vehicle automatically shifts into second gear?
A. 2-3

Q. Which solenoids are "on" when this vehicle automatically shifts into third gear?
A. None

Q. Which solenoids are "on" when this vehicle automatically shifts into fourth gear?
A. 1-2

Shift Solenoid Malfunction: Describe what would happen if none of the solenoids came "on". Would the vehicle drive? What gear would it be in? How fast could the vehicle go? could it have the power to climb hill?

A. Yes, the vehicle would drive. It would drive in third gear. It can go fast as the vehicle normally run in third gear but it couldn't have that much power to climb the hill.

Codes: 
Code: 21
This code is for high Voltage of TPS. It shows that the signal voltage stays 4.9 V for about two seconds at engine idling. Loose connection at earth can cause this code
Code: 14
This code is for low voltage signal to PCM by ECT sensor. The short circuiting of the signal wire can cause this code.

Diagnosis:


First problem testing: We can do the voltage drop test for that with help of a multi-meter. we can check the wiring manually if there is any loose connection in the circuit. we can check the resistance of the circuit to earth with help of a muti-meter. Oscilloscope is the another tool for checking TPS activity by examining the waveform on the screen.

Second problem testing: Checking the resistance of the circuit and voltage drop test with multi-meter can help in finding the problem in the circuit.

Antilock Braking Systems (off car)

Possible causes for damaging an ECU

Spiked by careless welding, i.e MIG welding without disconnecting the battery
True

Enclosure seal damaged and with obvious sign of water ingress.
True

Faults are much more likely to be with connections or sensors.
True

Discuss how these ECU issues should be incorporated into diagnostic practices to test an ABS system.
While testing the ABS sytem, one should be careful about testing the component of ABS. ECU components are so closely welded up so it must be careful while testing between different components. During welding the components in ECU, the welding spikes of different components can touch each other and during operation or voltage supply it may short circcuit the components or can give worng signal or voltage output. Same is for water in vapours in ECU.

1 = Wheel                                       5 = master cylinder
2 = sensor                                       6 = caliper
3 = reluctor wheel                           7 = booster
4 = modulator

Wiring Diagram Practice


Using the wiring diagram in the workshop manuals identify the wheel speed sensors and list their wire colours for each sensor.
Front right:      A 10, Black and White
Front left:       A 9, Green and Red
Rear left:        A 22, Blue  and pink
Rear right:     A 23, yellow and brown

In the ABS wheel sensor what is the reason for the braded wire?

To cancel out the effect induced emf in two wires. When the current pass through two wire, running parallel to each other, the induced emf produces in both wires which interfere the signal to ECU.

Identify and list all the fuses that are used by the ABS circuit

Fuse box, Gauge fuse, Dome fuse, Stop fuse and ECU fuse.

Identify the earth for the ABS control unit and ABS motor their wire colours what pins numbers.

ABS control  unit: 1 White and Black

ABS motor: 1 White and Black

On the wiring diagram for the ABS actuator, identify which solenoids control which wheel cylinder. Then note the wire colours and numbers

Front Right Wheel:   

                                 Pin number:   2,6

                                 Wire colour:  Red White, Red Green

                                                     

Front Left Wheel:   

                                Pin number:  3,7

                                Wire colour:  Blue Red, Blue White

Rear Left Wheel:

                               Pin number:  1,5

                              Wire colour:  Brown White, Brown Red

Rear Right Wheel: 

                             Pin number:  4,8

                            Wire colour:  Green Brown, Green Yellow

                                                  

Q. In the four cases above, state when the ABS motor will  be working

A. When there is increase and decrease in pressure in hydrolyic   break lines.

Conversion of frequency into time:

T=1/F

= 1/0.5=2s

ABS Demonstrators: 

Left front             ECU Pin # 2O   and     2P

Left rear             ECU Pin# 2R     and      2Q

Right front          ECU Pin# 2N    and     2M

Right rear          ECU Pin# 2S     and     2T

Q. By looking at the wiring diagram, what type of speed sensor is this?

A. Inductive.

Q. Describe how it works.

A. Sensor consist of a winding and a magnet. The wire is winding over a permanent magnet. There is a toothed wheel rotating along vehicle wheel close to sensor. During the rotation of the wheel, the teeth of the sensor rotor pass close to the sensor pole piece. When the tooth of the sensor rotor comes near the sensor pole piece, it enhances the strength of the permanent magnet. This increases magnetic flux induces the current in the windings in one direction. When the sensor rotor teeth moves away from the sensor pole, the strength of the magnet diminishes. This causes the collapsing of the magnetic flux across the windings, which induces the current in the windings in opposite direction and hence this sensor generates the AC current in its windings.

Q. Locate an oscilloscope. Turn it on and set it up to be fully operational. What oscilloscope are you using?

A. Tektronix TDS 1002.

Wave form for left front wheel senor

Wave form for Right front wheel sensor

Wave form for left rear wheel sensor

Wave form for right rear wheel sensor

Q. Are all waveform exactly the same?

A. No.

Discuss what are the differences and what can cause these differences between the waveforms.

Both left and right front wheel sensors have lower amplitude than the rear wheel sensors but they have the same frequency. This means that there might be some wear and tear in the teeth of  front wheel sensors which cause the low amplitude of voltage in their waveforms.

With the wheel sensors spinning, measure AC volts with a multi-meter and record here:

Left front 3.2V

Left rear 2.7V

Right front 4.1V

Right rear 2.9 V

Q. Can a multimeter be as accurate in finding problems with the wheel speed sensor as an oscilloscope?

A. No

Discuss what the oscilloscope could find that the multimeter can not find and why?

Oscilloscope can find the variation in AC voltage from its lowest value to the highest value in the sign wave but multimeter will show us the average voltage only. For example if the AC signal varies between 0 to +5 and -5, the voltmeter will display 2.5 volts on its screen. 

Relay waveform

Explain with arrows what is happening in the waveform above.

A is the point where the voltage in the circuit was zero just before the closing of the switch to the relay. when  the switch turned the relay on, the potential difference starts building up but as the windings are not grounded to earth on other side of the relay (85), the oscilloscope shows 12 V as shown at B  in above graph.  The switch side in the relay is still at 87a because the windings are not grounded and there is not  the current flowing through the windings and hence there is no magnetic field around them to pull the switch down to 87 and the voltage on oscilloscope shows zero ( till F). Once the relay winding grounded by the transistor, the current starts flowing through the windings hence makes the oscilloscope to read zero voltage at 85 (C). The magnetic field starts building up around the windings. Because of the magnetic fields, the switch pulled down to 87 and now the oscilloscope reads 12 V at 30. When the windings disconnected from the ground, the oscilloscope reads 12 V at 85 as shown in above graph at D and at the same time the switch in the relay goes back to its original position at 87a, and the oscilloscope reads zero volts as shown in above graph at G. Again the windings are grounded by transistor and oscilloscope shows zero voltage, this time the windings remained grounded for a long time as shown in the above graph at E which pull the switch to 87 and hence the oscilloscope reads 12 V again at 30 as shown in above graph at H. there are some vibration in the relay switch as shown in above graph at I.

ABS Pump Relay waveform:

Explain with arrows what is happening in the wave form above.

The voltage at A in above graph is the voltage just before the relay turned on by the outside switch. When the switch turned on, the current will not flow through the windings as the 85 is not grounded yet by the transistor. The oscilloscope graph will read 12 volts (supply voltage) as shown in the above graph at B till C. Once the 85 is grounded to earth by the transistor, the oscilloscope graph went down to zero volt as shown at D in the above graph, the current starts flow through the windings and the magnetic field starts building up. The magnetic field  quickly pulls up the relay switch to 87 which turns the pump motor on by giving the power supply to the motor as shown above in the graph at I. When the relay disconnected at 85 by the transistor, the switch turned the pump motor off  as there is no current flowing through the windings and hence no magnetic field to keep the switch connected to 87. The oscilloscope read 12 V at 85  as shown above graph at F but as the pump motor was turning off, the graph voltage did not drop at once to zero as shown in above graph at J, K and L because there was back emf developing inside the motor winding which opposed the current to become zero. 

Happening during ABS Self Test:

When we first turned the key on, the oscilloscope showed the above graph along with the warning light. As we have seen in the last graph (the graph above this graph), the pump relay switch stayed on even after the stoppage of current flowing through the coil. This is that time at which ABS does self test and the waring light stays on. 

Create a fault in the system by slowing down a wheel speed sensor:

When we slow downed the right wheel manually while applying the break along with it, we heard the noise in ABS. In this process the ABS pump and outlet valve solenoid  turned on while the inlet valve solenoid turned off. During this operation the hydraulic pressure gauge for this wheel went down, showing that the pressure in this circuit has decreased. 

Catch an oscilloscope pattern when an ABS solenoid has actuated. What is the pin and name of the solenoid?

A. 2, B19

Q. How did you do it?

A. We connected the positive oscilloscope wire to the solenoid wire in the control module by using the circuit diagram and negative wire to the earth. Manually we slow downed the wheel related to this solenoid while applying the break at the same time. This operation gave us the following wave pattern on the oscilloscope.  

Oscilloscope pattern.

Time division: 25ms

Voltage division: 5 V.