Table of Contents Introduction Symbol Circuit Fault Diagnosis

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3 Table of Contents.. Introduction Symbol Circuit Fault Diagnosis Diagnostic Procedure Diagnostic Tools Fault Testing Repair Tools Wiring Harness Terminal Repair Cooling System Fuel System Ignition System Starting System Charging System Electronic Control System (.0L) Power Supply and Data Line HOS/EVAP TPS/KS/IAC CKP/Evaporator Thermistor/ECT/IAT Electronic Control System (.L) Power Supply and Data Line HOS/EVAP TPS/KS/IAC CKP/Evaporator Thermistor/ECT/IAT Heating, Ventilation and Air Conditioning Compressor and Sensor Control Operation (.0L) Compressor and Sensor Control Operation (.L) Power Supply/Sensor/Actuator (.0L) Power Supply/Sensor/Actuator (.L) Instrument Cluster Power Supply and Signal (.0L) Signal Lamp (.0L) Lighting Signal Lamp (.0L) Power Supply and Signal (.L) Signal Lamp (.L) Lighting Signal Lamp (.L)

4 Table of Contents 4..3 Horn Cigarette Lighter Information and Entertainment System Power Supply Speaker Lighting System Headlamp Brake Lamp Turn Lamp Position Lamp and License Plate Lamp Fog Lamp Backup Lamp Interior Lamp Wiper Front Wiper Central Door Lock Power Window Body Control System On-board Network System DLC (Data Link Connector) Fuse and Relay Main Fuse Box I/P Fuse Box Power Supply Distribution Instrument Panel Power Supply Distribution Instrument Panel Power Supply Distribution Instrument Panel Power Supply Distribution Fuse Details Grounding Distribution Wiring Harness Connector Location View Grounding Location View Wiring Harness Connector Terminal View Abbreviation

5 .. Introduction..- Introduction..- Fuel System Main Fuse Box P0 +B 9 I/P Fuse Box P A 8.0 WH 8.0 WH EF0 8.0 WH 9 5A IF5 68 IR A 38 IF9 83 IR BN/WH 5 X05.0 RD/BU.0 RD/BU X YE/RD 5 X05.5 BU/WH 6 X04.5 BU/WH 3 X07.5 RD/BU.0 RD/BU E09 3 Fuel Injector.0 RD/BU E06 Fuel Injector.0 RD/BU E04 Fuel Injector 3.0 RD/BU E0 Fuel Injector 4.5 BU/WH 4 S0.5 RD/BU M S0 Fuel Pump 0.5 BN/WH Refer to 3.. Electronic Control System 4 E WH/BN E WH/YE 6 E WH/GN E0 0.5 WH/BK 0.5 YE/RD.0 BK.5 BK.5 BK 4 X07 3 E8 50 E8 63 E8 49 E8 64 E8 60 E8 ECM 8 G0 M000

6 ..- Introduction..-. System name.. Wiring harness connector numbering. Color Code Wiring Harness Color Legend In this manual, the wiring harness connector is numbered based on wiring harness. For example, connector of ECM wiring harness in engine wiring harnesses is numbered as E0. E is the wiring harness code, 0 is the connector serial number. BK BN BU GN Black Brown Blue Green The following table lists are wiring harness codes: Code EN E-- I/P P-- SO S-- DR D-- RF L-- X-- Wiring Harness Name Engine wiring harness Engine wiring harness connector I/P wiring harness I/P wiring harness connector Chassis wiring harness Chassis wiring harness connector Door wiring harness Door wiring harness connector Roof wiring harness Roof wiring harness Wiring harness to wiring harness connector Note:Door wiring harness consists of wiring harness of two front doors and back door. Note:For wiring harness connector numbering details, please refer to wiring harness connector layout view. GY LG LU OG PK RD SR VT WH YE Grey Light Green Light Blue Orange Pink Red Silver Purple White Yellow If a wiring harness has two colors, the first character shows the background color and the second shows the stripe color, divided by /. For example, YE/WH means yellow background color with white stripe. 7. Pin number. The pin number of mated connector pair are mirrored relationship, as shown below: 3. Component name. 4. System information related to the circuit. 5. For wiring harness to wiring harness connector, the black arrow represents positive pole and the box represents the negative pole. The character in the box is the connector code Wiring harness color and diameter. The following table shows the color code. M Grounding number. The grounding number starts with G. For grounding details, please refer to grounding layout view.

7 ..-3 Introduction Power supply type supplied to fuse. +B represents battery power supply. ACC represents power supply output when ignition switch is at ACC. IG represents terminal output when ignition switch is at ON. IG represents terminal 5 output when ignition switch is at ON. Note:The difference between IG and IG is that there is power supply output from IG, but no from IG when the ignition switch is at ST. M BK/WH 0.85 BK/WH 7 S0 3 S0a ECM(.0L) ECM(.3L) 0. Wiring harness splice point. 5. The 8-shaped symbol between wiring harnesses represents Unshielded Twisted Pair (UTP), which is used for sensor signal or data communication. Not Spliced Cross Circuit Spliced Cross Circuit 0.5 BU M0003. Fuse number consists of a fuse code and a sequential number. Code EF represents fuses in the main fuse and relay box; Code IF represents fuses in instrument panel fuse and relay box. For details, please refer to fuse table.. A relay is represented by two capital English letters. Code ER represents relays in the main fuse and relay box; Code IR represents relays in the instrument panel fuse and relay box. For details, please refer to the relay table. 3. Filling grey shade means the electronic component, P0 represents the wiring harness connector code. 4. Circuit differences in different models, engines or specifications are noted by dashed lines and texts beside the circuit. M VT 6. If a system wiring diagram requires more than one page, it starts with A and ends with A. If more than one circuit extends to the next page, use B, C and other letters to represent. M0006 A 0.5 RD/YE 0.5 RD/YE A

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9 .. Symbol..- Symbol..- G7 Grounding Normal Close Relay Battery Temperature Sensor Normal Open Relay Capacitor Solenoid Double Throw Relay Cigarette Lighter Solenoid Resistor Antenna Light Load Fuse Potentiometer Normal Open Switch Moderate Load Fuse Rheostat Normal Close Switch Heavy Load Fuse Ignition Coil Double Throw Switch Heater Knock Sensor M000

10 ..- Symbol..- Diode Bulb UTP (Unshielded Twisted Pair) Photodiode Horn M Starting Motor Light Emitting Diode Clock Spring Oxygen Sensor M Motor Airbag M Stopper Switch Not Spliced Cross Circuit Spliced Cross Circuit M000

11 ..3 Circuit Fault Diagnosis..3- Circuit Fault Diagnosis..3- Diagnostic Procedure Refer to the following procedure for the circuit fault diagnosis:. Confirm Fault To do the proper repair, confirm the fault symptoms described by the customer firstly. Inspect the relevant component carefully to confirm the fault symptoms and make record. DO NOT disassemble the component before confirmation of the fault scope and causes.. Read Wiring Diagram and Analyze Causes Make a complete analysis and judgement on the fault components from power supply to grounding according to the sub-system wiring diagram and determine the repair solution. If it cannot be determined, please read the system description in the Description and Operation section in the repair manual to understand the working principle. And inspect other circuits that has common part with the fault circuit, for example, the fuse, grounding, switch, etc. Inspect the circuit not covered in step. If other components in the common circuit work properly, it means the fault exists in its own circuit. Otherwise, the fuse or grounding may have faults. 3. Inspect Circuits and Components Always use the wiring diagram together with repair manual and refer to the diagnostic procedure for the relevant circuits or components in the repair manual. For the circuit with a control module, fully use diagnostic tools to do the test. Effective diagnosis should be a logical and reasonable operation. Fully use the diagnostic procedures in the repair manual and start the inspection from the causes and the components with easiest inspection way. 4. Repair Fault Repair the fault. Refer to the wiring diagram and the description for fault treatment in repair manual. For example, the diagnostic procedure for poor grounding and the wiring harness connector treatment. 5. Confirm Circuit Working Condition After repair, all functions should be reinspected to confirm the fault repaired. For the fuse blown fault, Inspect all the relevant circuits using this fuse. Diagnostic Tools. Voltmeter and Test Lamp M0300 Use test lamp or voltmeter to inspect the circuit status. Test lamp comprises a pair of wiring harnesses and a V bulb. When inspecting, connect one wiring harness to the ground and the other one to the certain measurement point. If the bulb is lit, it means the measurement point has power supply. Warning: DO NOT use test lamp to inspect the control module voltage. Otherwise it could damage the interior circuit inside the control module. Please use a voltmeter with 0 MΩ or higher internal resistance (for example, to test the ECM voltage). Voltmeter has the same connection method as the test lamp, but voltmeter can display the voltage value of the circuit. Use a voltmeter with high resistance to test the voltage. If the circuit has poor connection, the voltmeter may show the normal value, but the voltage cannot drive the load successfully.

12 ..3- Circuit Fault Diagnosis..3-. Self-powered Test Lamp and Ohmmeter M0300 Use test lamp with own V power supply or ohmmeter to inspect the circuit for continuity. Test lamp comprises a bulb, battery and a pair of wiring harnesses. The bulb will be lit when the two wiring harnesses are connected. Before testing, disconnect the negative battery cable and pull out the fuse of the circuit. To test the circuit for continuity, connect two wiring harnesses to the two measurement points. If the bulb is lit, it means the circuit is normal. Warning: DO NOT use self-powered test lamp to inspect the control module. Otherwise, it could damage the interior circuit inside the control module. Please use a ohmmeter with 0 MΩ or higher internal resistance. Ohmmeter has the same usage method as voltmeter, but ohmmeter can show the resistance value. The lower resistance, the better continuity. 3. Jumper Wire with Fuse Use jumper wire to test a broken point for open loop circuit (circuit open). The jumper wire is a tool that should be in tandem with the circuit. Warning: To protect the circuit to be inspected, DO NOT use the fuse higher than the rated capacity of circuit to inspect relevant circuits. DO NOT use the jumper wire as the input or output signal when a control module such as ECM or TCM is in the circuit. Otherwise it could damage the circuit interior inside the control module. Fault Testing. Voltage Testing 5A 0.5RD +B E00 Switch E00 0.5G C00 Solenoid I/P Fuse and Relay Box Voltmeter Test Lamp 5A M03004 Voltage testing is to test the voltage at a certain point. When testing a certain connector terminal, insert the positive probe into the wiring harness from the connector back without assembling wiring harness connector. M03003

13 ..3-3 Circuit Fault Diagnosis..3-3 When testing the voltage with test lamp or voltmeter, connect the negative of testing tools to battery negative. Connect the other wiring harness of the test lamp or the positive probe of the voltmeter to the test position. 3 If a voltmeter is used and voltage display lower V above compared to the rated value, it means a circuit fault. It means a circuit fault if a test lamp is used and lamp is not lit.. Power Testing 3. Short Circuit Testing 5A 0.5RD +B E00 Switch I/P Fuse and Relay Box Voltmeter Test Lamp E00 0.5G Switch C00 Solenoid M03006 M03005 Disconnect the negative battery cable. Connect one wiring harness of the selfpowered test lamp or the probe of the ohmmeter to the test component. If using ohmmeter, please connect the two probes each other and use reset button to adjust the ohmmeter to zero. 3 Connect the other wiring harness of the test lamp or probe of the ohmmeter to the other side of the test load. 4 If the bulb is lit, it means the circuit is normal. If an ohmmeter is used and the resistance value is very low or close to 0 Ω, it means the component has good continuity. Disconnect negative battery cable. Connect one wiring harness of the selfpowered test lamp or one probe of the ohmmeter to the output terminal of the fuse. 3 Connect the other wiring harness of the test lamp or other probe of the ohmmeter to the grounding. 4 Disconnect all the electrical loads to the fuse. CAUTION: If not disconnecting all the electrical loads to the fuse, when testing the low resistance circuit like lights, the ohmmeter will always display the low value. This will cause wrong judgement. 5 Do the careful inspection from the place closest to the fuse. 6 If the bulb is lit or ohmmeter has value display less than 5 Ω, it means the short circuit to the ground.

14 Voltage Drop Testing Circuit Fault Diagnosis Repair Tools A +B I/P Fuse and Relay Box Voltmeter 0.5RD E00 Switch E00 0.5G M03008 C00 Solenoid. 5 KΩ Rheostat M03007 This is a test to inspect the voltage drop along the wiring harness, connector or switch. Connect the positive probe of the voltmeter to one end of the circuit close to the battery (connector or switch side). Connect the negative probe to the other end of the circuit (the other side of connector or switch). 3 Switch on or off to make the circuit work. 4 The voltmeter will display the voltage difference between the two test points. 5 If the voltage difference is more than 0. V (less than 50 mv for 5 V voltage circuit), it means a circuit fault. Inspect for loose, oxidized or corrosive circuit. M03009 It can simulate each ohm-type sensor signal, like coolant temperature sensor, air intake pressure and temperature sensor and the like. And help make quick judgement on the performance of the component.

15 ..3-5 Circuit Fault Diagnosis LED Test Lamp 4. Probe M0300 Bidirectional two-color LED lamp can change its color when exchanging the positive and negative. This feature can be used to test the PWM control signals of Hall sensor. 3. Airbag Test Tool M030 When testing a system component, insert this tool into the connector from the back and it is unnecessary to break the wiring harness to reduce man-made fault. 5. Terminal Repair Tool M030 Before installing a new airbag after airbag system has faults or vehicle accident, install this tool to the airbag system, and use diagnostic tools to confirm the airbag system work properly. After that, install the new airbag. This process can guarantee a safe airbag operation. M0303 When maintaining and repairing certain terminal, use this tool to separate them from the connector.

16 ..3-6 Circuit Fault Diagnosis..3-6 Wiring Harness Terminal Repair. Remove the terminal pin. M0304. Separate the clip with wiring harness terminal repair tool. Wiring Harness Terminal Clip Wiring Harness Terminal Repair Tool M Pull out the wiring harness terminal from the rear of connector. M0306

17 ..3-7 Circuit Fault Diagnosis Adjust and clean the wiring harness terminal contact plate pulled out from connector. M0307

18 ..3-8 Circuit Fault Diagnosis..3-8 Poor Grounding Connection Repair Procedure. Remove the grounding bolt.. Clean the two surfaces (both bolt side and vehicle contact side) of the copper ring with abrasive cloth until the oxide completely cleared. M Clean the grounding surface on the vehicle with abrasive cloth until it is completely cleaned. M0309 M0300

19 ..3-9 Circuit Fault Diagnosis Reinstall the wiring harness and retaining bolt of grounding. Tighten it to specified torque. Torque for M6 bolt: 8 Nm Torque for M8 bolt: 0 Nm M030

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21 3..4 Cooling System Cooling System Cooling System (.0L) Main Fuse Box P0 I/P Fuse Box P40 +B 80A 8.0 WH 8.0 WH EF0 8.0 WH 9 5A IF5.0 RD/BU 68 IR A.0 RD/BU 5 IF03 6 0A 7 IF BN/WH 0.5 RD/BU RD/BU.0 BU/WH 6 63 IR03 IR X BK/WH.0 BU/RD 0.5 BK/RD.0 RD/BK 9 X05 P0 3 X05 P3 0.5 BN/WH 0.5 BK/WH M P0.0 BK.0 BK Radiator Fan 0.5 BK/RD M P3.0 BK.0 BK Condenser Fan 3 E07 G05 5 E07 6 E07 ECM G03 M30400

22 3..4- Cooling System (.L) Cooling System Main Fuse Box P0 I/P Fuse Box P40 +B 80A 8.0 WH 8.0 WH EF0 8.0 WH 9 5A IF5.0 RD/BU 68 IR A.0 RD/BU 5 IF03 6 0A 7 IF BN/WH 0.5 RD/BU RD/BU.0 BU/WH 6 63 IR03 IR X BK/WH.0 BU/RD 0.5 BK/RD.0 RD/BK 9 X05 P0 3 X05 P3 0.5 BN/WH 0.5 BK/WH M P0.0 BK.0 BK Radiator Fan 0.5 BK/RD M P3.0 BK.0 BK Condenser Fan 3 E07a G05 5 E07a 6 E07a ECM G03 M30400

23 Cooling System Operating circuit analysis of radiator fan is as follows: Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (radiator fan fuse IF03) Radiator fan relay-terminal 58 Radiator fan relay closing contact Radiator fan relayterminal 59 Radiator fan connector P0-terminal Radiator fan motor Radiator fan connector P0-terminal Grounding G05 Radiator fan motor is powered on and fan starts to work normally. Operating circuit analysis of condenser fan is as follows: Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (radiator fan fuse IF04) Condenser fan relay-terminal 63 Condenser fan relay closing contact Condenser fan relay-terminal 64 Condenser connector P3-terminal Condenser fan motor Condenser fan connector P3-terminal Grounding G03 Condenser fan motor is powered on and fan starts to work normally.

24 Cooling System Main Fuse Box EF0 P0 I/P Fuse Box 3 IF IF08 IF0 IF0 IF03 IF04 IF05 IF IF IF3 IF IF IF0 IF9 IF8 IF7 IF6 IF5 IF4 IF3 IF IF IF0 IF IR0 45 IR0 50 IR03 55 IR04 60 IR IF40 IF39 IF38 IF37 IF36 IF35 IF34 IF33 IF3 IF3 IF30 IF9 IF8 IF7 IF6 IF IR06 70 IR07 75 IR08 80 IR09 85 IR P40

25 Cooling System I/P Wiring Harness to Engine Wiring Harness Engine Wiring Harness to I/P Wiring Harness X05 Radiator Fan Condenser Fan P0 P3 ECM (.0L) E07

26 Cooling System ECM (.L) E07a

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28 3..7 Fuel System Fuel System (.0L) Fuel System Main Fuse Box P0 +B I/P Fuse Box P40 80A 8.0 WH 8.0 WH EF0 8.0 WH 9 5A IF5 68 IR A 38.5 RD/YE IF RD/BU 80 IR BN/WH.0 RD/BU.0 RD/BU 0.5 YE/RD.5 BU/WH 6 X04.5 BU/WH 5 X05 X05 5 X05 3 X07.0 BU/RD 0.85 RD/BU E09 Fuel Injector 0.85 RD/BU E06 Fuel Injector 0.85 RD/BU E04 Fuel Injector RD/BU E0 Fuel Injector 4.5 BU/WH 4 S BU/RD M S0 Fuel Pump 0.5 BN/WH 3 E07 Refer to 3.. Electronic Control System (.0L) E WH/BN E WH/YE E WH/GN E0 50 E07 63 E07 49 E07 64 E WH/BK 0.5 Lg/RD 60 E07.5 BK.5 BK.5 BK 4 X07 ECM G0 M30700

29 3..7- Fuel System Operating circuit analysis of fuel injector is as follows: Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (main relay fuse IF5) Main relay-terminal 68 Main relay closing contact Main relay-terminal 69 Connector X05-terminal Fuel injector connector E09-terminal Fuel injector coil Fuel injector connector E09-terminal ECM connector E07-terminal 50 ECM Grounding Fuel injector coil is powered on to inject oil and ECM controls fuel-injection amount through pulse width of power supply to fuel injector coil. Operating circuit analysis of fuel injector is as follows: Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (main relay fuse IF5) Main relay-terminal 68 Main relay closing contact Main relay-terminal 69 Connector X05-terminal Fuel injector connector E06-terminal Fuel injector coil Fuel injector connector E06-terminal ECM connector E07-terminal 63 ECM Grounding Fuel injector coil is powered on to inject oil and ECM controls fuel-injection amount through pulse width of power supply to fuel injector coil. Operating circuit analysis of fuel injector 3 is as follows: Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (main relay fuse IF5) Main relay-terminal 68 Main relay closing contact Main relay-terminal 69 Connector X05-terminal Fuel injector 3 connector E04-terminal Fuel injector 3 coil Fuel injector 3 connector E04 terminal ECM connector E07-terminal 49 ECM Grounding Fuel injector coil is powered on to inject oil and ECM controls fuel-injection amount through pulse width of power supply to fuel injector coil. Operating circuit analysis of fuel injector 4 is as follows: Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (main relay fuse IF5) Main relay-terminal 68 Main relay closing contact Main relay-terminal 69 Connector X05-terminal Fuel injector 4 connector E0-terminal Fuel injector 4 coil Fuel injector 4 connector E0-terminal ECM connector E07-terminal 64 ECM Grounding Fuel injector coil is powered on to inject oil and ECM controls fuel-injection amount through pulse width of power supply to fuel injector coil. Operating circuit analysis of fuel pump is as follows: Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (fuel pump fuse IF9) Fuel pump relay-terminal 83 Fuel pump closing contact Fuel pump-terminal 84 Connector X04-terminal 6 Connector X07-terminal 3 Fuel pump connector S0-terminal 4 Fuel pump motor Fuel pump connector S0-terminal Connector X07-terminal 4 Grounding G0 Fuel pump motor is powered on to start work and ECM controls fuel pump running through fuel pump relay.

30 Fuel System (.L) Fuel System Main Fuse Box P0 +B I/P Fuse Box P40 80A 8.0 WH 8.0 WH EF0 8.0 WH 9 5A BN/WH IF5.0 RD/BU.0 RD/BU IR RD/BU YE/RD 37 5A IF BU/WH.5 RD/YE 6 X04.5 BU/WH 83 IR X05 X05 5 X05 3 X07.5 RD/BU 0.85 RD/BU E09a Fuel Injector 0.85 RD/BU E06a Fuel Injector 0.85 RD/BU E04a Fuel Injector RD/BU E0a Fuel Injector 4.5 BU/WH 4 S0.5 RD/BU M S0 Fuel Pump 0.5 BN/WH 3 E07a Refer to 3.. Electronic Control System (.L) E09a 0.5 WH/BN E06a 0.5 WH/YE E04a 0.5 WH/GN E0a 50 E07a 63 E07a 49 E07a 64 E07a 0.5 WH/BK 0.5 YE/RD 60 E07a.5 BK.5 BK.5 BK 4 X07 ECM G0 M30700

31 Fuel System Operating circuit analysis of fuel injector is as follows: Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (main relay fuse IF5) Main relay-terminal 68 Main relay closing contact Main relay-terminal 69 Connector X05-terminal Fuel injector connector E09a-terminal Fuel injector coil Fuel injector connector E09a-terminal ECM connector E07a-terminal 50 ECM Grounding Fuel injector coil is powered on to inject oil and ECM controls fuel-injection amount through pulse width of power supply to fuel injector coil. Operating circuit analysis of fuel injector is as follows: Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (main relay fuse IF5) Main relay-terminal 68 Main relay closing contact Main relay-terminal 69 Connector X05-terminal Fuel injector connector E06a-terminal Fuel injector coil Fuel injector connector E06a-terminal ECM connector E07a-terminal 63 ECM Grounding Fuel injector coil is powered on to inject oil and ECM controls fuel-injection amount through pulse width of power supply to fuel injector coil. Operating circuit analysis of fuel injector 3 is as follows: Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (main relay fuse IF5) Main relay-terminal 68 Main relay closing contact Main relay-terminal 69 Connector X05-terminal Fuel injector 3 connector E04a-terminal Fuel injector 3 coil Fuel injector 3 connector E04a-terminal ECM connector E07a-terminal 49 ECM Grounding Fuel injector coil is powered on to inject oil and ECM controls fuel-injection amount through pulse width of power supply to fuel injector coil. Operating circuit analysis of fuel injector 4 is as follows: Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (main relay fuse IF5) Main relay-terminal 68 Main relay closing contact Main relay-terminal 69 Connector X05-terminal Fuel injector 4 connector E0a-terminal Fuel injector 4 coil Fuel injector 4 connector E0a-terminal ECM connector E07a-terminal 64 ECM Grounding Fuel injector coil is powered on to inject oil and ECM controls fuel-injection amount through pulse width of power supply to fuel injector coil. Operating circuit analysis of fuel pump is as follows: Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (fuel pump fuse IF9) Fuel pump relay-terminal 83 Fuel pump closing contact Fuel pump-terminal 84 Connector X04-terminal 6 Connector X07-terminal 3 Fuel pump connector S0-terminal 4 Fuel pump motor Fuel pump connector S0-terminal Connector X07-terminal 4 Grounding G0 Fuel pump motor is powered on to start work and ECM controls fuel pump running or not through fuel pump relay.

32 Fuel System Main Fuse Box EF0 P0 I/P Fuse Box 3 IF IF08 IF0 IF0 IF03 IF04 IF05 IF IF IF3 IF IF IF0 IF9 IF8 IF7 IF6 IF5 IF4 IF3 IF IF IF0 IF IR0 45 IR0 50 IR03 55 IR04 60 IR IF40 IF39 IF38 IF37 IF36 IF35 IF34 IF33 IF3 IF3 IF30 IF9 IF8 IF7 IF6 IF IR06 70 IR07 75 IR08 80 IR09 85 IR P40

33 Fuel System I/P Wiring Harness to Chassis Wiring Harness Chassis Wiring Harness to I/P Wiring Harness X04 I/P Wiring Harness to Engine Wiring Harness Engine Wiring Harness to I/P Wiring Harness X05

34 Fuel System Chassis Wiring Harness to Fuel Pump Wiring Harness Fuel Pump Wiring Harness to Chassis Wiring Harness X07 Fuel Injector Fuel Injector E09 E09a Fuel Injector Fuel Injector E06 E06a

35 Fuel System Fuel Injector 3 Fuel Injector 3 E04 E04a Fuel Injector 4 Fuel Injector 4 E0 ECM (.0L) E0a E07

36 Fuel System ECM (.L) E07a Fuel Pump 3 4 S0

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38 3..8 Ignition System Ignition System (.0L) Ignition System Main Fuse Box P0 +B I/P Fuse Box P40 80A 8.0 WH 8.0 WH EF0 8.0 WH 5A 8.0 WH 9 30 IF IR05 69 Crankshaft Position Sensor Ignition Coil BU 0.5 VT.0 BK.5 BK/YE 0.5 BK 0.5 BN/WH 0.5 BN/WH.5 RD/BU.0 RD/BU 4 X05.0 BK/WH 5 X05.5 BK/WH.5 BK/WH E6 E7 Ignition Coil 3 3 E05 E05 E05 E6 E7.5 BK/BU G30 47 E07 46 E07 3 E07 3 E07 7 E07 ECM M30800

39 3..8- Ignition System Operating circuit analysis of ignition coil, 4 is as follows: Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (main relay fuse IF5) Main relay-terminal 68 Main relay closing contact Main relay-terminal 69 Connector X05-terminal 4 Ignition coil, 4 connector E6-terminal Ignition coil Ignition coil, 4 connector E6-terminal ECM connector E07-terminal 3 ECM Ignition time of ignition coil is controlled by ECM according to the engine operating condition. Operating circuit analysis of ignition coil, 3 is as follows: Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (main relay fuse IF5) Main relay-terminal 68 Main relay closing contact Main relay-terminal 69 Connector X05-terminal 4 Ignition coil, 3 connector E7-terminal Ignition coil Ignition coil, 3 connector E7-terminal ECM connector E07-terminal 7 ECM Ignition time of ignition coil is controlled by ECM according to the engine operating condition.

40 Ignition System (.L) Ignition System Main Fuse Box P0 +B I/P Fuse Box P40 80A 8.0 WH 8.0 WH EF0 8.0 WH 5A 8.0 WH 9 30 IF IR05 69 Crankshaft Position Sensor Ignition Coil Ignition Coil Ignition Coil 3 Ignition Coil BU/RD 0.5 BU/WH 0.5 YE/BK 0.5 BU/RD 0.5 YE/BK 0.5 BN/WH.5 BK/YE 0.5 BN/WH.5 RD/BU.0 RD/BU X05.0 RD/BU 5 X05.5 RD/BU.5 RD/BU.5 RD/BU.5 RD/BU E9a E8a E7a E6a 3 E05a E05a E05a 3 E9a E9a 3 E8a E8a 3 E7a E7a 3 E6a E6a.5 BK.0 BK.5 BK/VT.5 BK.0 BK.5 BK/BU.5 BK.0 BK.5 BK/RD.5 BK.0 BK G303 G303 G303 G E07a 47 E07a 9 E07a 3 E07a 3 E07a 6 E07a 7 E07a E07a ECM M30800

41 Ignition System Operating circuit analysis of ignition coil is as follows: Ignition coil is controlled by ECM through Connector E07a-terminal 3 Ignition coil connector E9a-terminal 3 Ignition coil. Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (main relay fuse IF5) Main relay-terminal 68 Main relay closing contact Main relay-terminal 69 Connector X05-terminal Ignition coil connector E9a-terminal Ignition coil Ignition coil connector E9a-terminal Grounding G303 Ignition time of ignition coil is controlled by ECM according to the engine operating condition. Operating circuit analysis of ignition coil is as follows: Ignition coil is controlled by ECM through Connector E07a-terminal 6 Ignition coil connector E8a-terminal 3 Ignition coil. Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (main relay fuse IF5) Main relay-terminal 68 Main relay closing contact Main relay-terminal 69 Connector X05-terminal Ignition coil connector E8a-terminal Ignition coil Ignition coil connector E8a-terminal Grounding G303 Ignition time of ignition coil is controlled by ECM according to the engine operating condition. Operating circuit analysis of ignition coil 3 is as follows: Ignition coil 3 is controlled by ECM through Connector E07a-terminal 7 Ignition coil 3 connector E7a-terminal 3 Ignition coil. Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (main relay fuse IF5) Main relay-terminal 68 Main relay closing contact Main relay-terminal 69 Connector X05-terminal Ignition coil 3 connector E7a-terminal Ignition coil Ignition coil 3 connector E7a-terminal Grounding G303 Ignition time of ignition coil is controlled by ECM according to the engine operating condition. Operating circuit analysis of ignition coil 4 is as follows: Ignition coil 4 is controlled by ECM through Connector E07a-terminal Ignition coil 4 connector E6a-terminal 3 Ignition coil. Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (main relay fuse IF5) Main relay-terminal 68 Main relay closing contact Main relay-terminal 69 Connector X05-terminal Ignition coil 4 connector E6a-terminal Ignition coil Ignition coil 4 connector E6a-terminal Grounding G303 Ignition time of ignition coil is controlled by ECM according to the engine operating condition.

42 Ignition System Main Fuse Box EF0 P0 I/P Fuse Box 3 IF IF08 IF0 IF0 IF03 IF04 IF05 IF IF IF3 IF IF IF0 IF9 IF8 IF7 IF6 IF5 IF4 IF3 IF IF IF0 IF IR0 45 IR0 50 IR03 55 IR04 60 IR IF40 IF39 IF38 IF37 IF36 IF35 IF34 IF33 IF3 IF3 IF30 IF9 IF8 IF7 IF6 IF IR06 70 IR07 75 IR08 80 IR09 85 IR P40

43 Ignition System I/P Wiring Harness to Engine Wiring Harness Engine Wiring Harness to I/P Wiring Harness X05 Crankshaft Position Sensor Crankshaft Position Sensor 3 3 E05 ECM E05a E07

44 Ignition System ECM E07a Ignition Coil (, 4) Ignition Coil 3 E6 E9a Ignition Coil (, 3) Ignition Coil 3 E7 E8a

45 Ignition System Ignition Coil 3 Ignition Coil E7a E6a

46 3..9 Starting System Starting System Starting System I/P Fuse Box P40 40A IF0 Main Fuse Box P0 80A 8.0 WH 8.0 WH 8.0 WH EF0 ST IG 5.0 RD ACC LOCK OFF 6 P3.0 BK/YE X04.0 BK/YE 3.0 WH/GN 4 P3 ST IG ACC LOCK OFF Ignition Switch L L S5 Battery S S3 Starting Motor M S6 M30900

47 3..9- Starting System Operating circuit analysis of starting motor is is as follows: Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (ignition switch fuse IF0) Ignition switch connector P3-terminal 4 Ignition switch ST contact Ignition switch connector P3-terminal 6 Connector X04-terminal Starting motor connector S3-terminal Starting motor solenoid switch Starting motor grounding Starting motor solenoid switch is powered on to close two contacts of solenoid switch. Current from the battery positive Connector S-terminal Solenoid switch closing contact Starting motor coil Starting motor grounding Controlled by starting switch, starting motor starts to work.

48 Starting System Main Fuse Box EF0 P0 I/P Fuse Box 3 IF IF08 IF0 IF0 IF03 IF04 IF05 IF IF IF3 IF IF IF0 IF9 IF8 IF7 IF6 IF5 IF4 IF3 IF IF IF0 IF IR0 45 IR0 50 IR03 55 IR04 60 IR IF40 IF39 IF38 IF37 IF36 IF35 IF34 IF33 IF3 IF3 IF30 IF9 IF8 IF7 IF6 IF IR06 70 IR07 75 IR08 80 IR09 85 IR P40

49 Starting System I/P Wiring Harness to Chassis Wiring Harness Chassis Wiring Harness to I/P Wiring Harness X04 Ignition switch Starting motor Switch P3 S Starting motor Battery Positive S3 S5

50 Starting System Battery Negative S6

51

52 3..0 Charging System Charging System Charging System I/P Fuse Box P40 IG YE/BK 65 Instrument Cluster 5A IF36 0A IF P Main Fuse Box P0 0.3 WH/RD 80A 8.0 WH EF0 8.0 WH.5 BK/BU S5 Battery P04 P03 3 P03 Alternator S6 M3000

53 3..0- Charging System Operating circuit analysis of alternator is as follows: When alternator is not working: Current from battery positive Main fuse box (main fuse EF0) I/P fuse box (ignition switch fuse IF0) Ignition switch connector P3-terminal 3 Ignition switch IG contact Ignition switch connector P3-terminal I/P fuse box (alternator fuse IF36) Alternator connector P03-terminal Alternator regulator and rotor coil Alternator grounding Current from instrument cluster (charging indicator) Instrument cluster connector P-terminal 4 Alternator connector P03-terminal 3 Alternator regulator Alternator grounding Charging indicator is turned on. When the alternator is working: Current from alternator stator coil Alternator commutator Connector P04-terminal Main fuse box (main fuse EF0) Connector S5-terminal Battery When the alternator is working, alternator regulator and rotor coil supply power to all electrical devices in vehicle on one hand and charge battery on the other hand.

54 Charging System Main Fuse Box EF0 P0 I/P Fuse Box 3 IF IF08 IF0 IF0 IF03 IF04 IF05 IF IF IF3 IF IF IF0 IF9 IF8 IF7 IF6 IF5 IF4 IF3 IF IF IF0 IF IR0 45 IR0 50 IR03 55 IR04 60 IR IF40 IF39 IF38 IF37 IF36 IF35 IF34 IF33 IF3 IF3 IF30 IF9 IF8 IF7 IF6 IF IR06 70 IR07 75 IR08 80 IR09 85 IR P40

55 Charging System Alternator Connector Alternator Positive 3 P03 P04 Instrument Cluster P Battery Positive Battery Negative S5 S6

56 Electronic Control System (.0L) Electronic Control System (.0L) 3..- Electronic Control System B+ IF IF5 IR Stepper Motor IF30 Carbon Canister Solenoid Air Intake Pressure/ Temperature Sensor 3 4 Front Oxygen Sensor Coolant Temperature Sensor 4 3 Rear Oxygen Sensor Evaporator Thermistor IG Diode Terminal IF37 7 ECM G30 3 Crankshaft Position Sensor Tristate Pressure Switch Instrument Cluster Throttle Position Sensor Diode A Terminal Diode B Terminal DLC Terminal 5 Knock Sensor G30 G30 G30 M3005

57 3..- Electronic Control System (.0L) 3..- Power Supply and Data Line Main Fuse Box P0 +B I/P Fuse Box P40 IG 80A 8.0 WH 8.0 WH EF0 8.0 WH 0A 8.0 WH IF 5A 8.0 WH 9 30 IF IR05 0A IF37 0A 3.0 YE/BK 66 IF33 Refer to 4.. On-board Network System DLC 0.5 PK/BU 0.5 PK/BU 0.5 PK/BU 0.5 PK/BU X BN/WH 5 X BN/WH.0 RD/BU.0 RD/BU X05 6 E07 5 E07 43 E07 48 E BK/YE.0 BK 0.5 BK 0.5 BK.0 BU/RD.5 RD/BU.0 RD/BU Refer to 3..7 Fuel System (.0L) 3..8 Ignition System (.0L) 3..0 Charging System E07 44 E07 0 E LG 0.5 PK/BK 0.5 BU/BK 0.5 RD/BU 0.5 BU X BU 6 E07 3 E07 8 E07 5 E07 7 E07 ECM Refer to 4.. Heating, Ventilation and Air Conditioning Power Supply/ Sensor/Actuator (.0L) Refer to 4.. Heating, Ventilation and Air Conditioning Power Supply/ Sensor/Actuator (.0L) Refer to 4.. Heating, Ventilation and Air Conditioning Power Supply/ Sensor/Actuator (.0L) Refer to 4.. Heating, Ventilation and Air Conditioning Power Supply/ Sensor/Actuator (.0L) G30 G30 M300

58 3..-3 HOS/EVAP Electronic Control System (.0L) Main Fuse Box P0 +B I/P Fuse Box P40 80A 8.0 WH 8.0 WH EF0 8.0 WH 9 5A 30 IF IR A 60 IF YE.0 RD/BU.5 RD/BU 0.5 BN/WH.5 RD/GN.0 RD/BU X05.5 RD/GN 6 X05 Refer to 3.. Electronic Control System (.0L) TPS/KS/IAC 0.5 YE/GN.5 RD/GN 6 X04 5 X05.0 RD/BU 0.85 RD/BU 0.85 RD/GN 0.5 YE/GN.5 RD/GN X YE/GN 9 X YE/GN 0.5 BN/WH E3 E3 E0 3 E0 Carbon Canister Solenoid E0 4 E0 Front Oxygen Sensor 0.5 YE/GN 3 S0 4 S0 S0 S0 0.5 WH/RD 0.5 YE Rear Oxygen Sensor 7 X YE 7 X RD/WH 0.85 YE/WH 0.5 BK/OG 0.5 WH/RD 0 X05 6 X WH 3 E07 37 E07 E07 45 E07 39 E07 4 E07 9 E07 ECM M300

59 3..-4 Electronic Control System (.0L) Operating circuit analysis of carbon canister solenoid is as follows: Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (main relay fuse IF5) Main relay-terminal 68 Main relay closing contact Main relay-terminal 69 Connector X05-terminal Carbon canister solenoid connector E3-terminal Carbon canister solenoid coil Carbon canister solenoid connector E3-terminal ECM connector E07-terminal 37 ECM Grounding Carbon canister solenoid coil is powered on to start work. Operating circuit analysis of front oxygen sensor is as follows: Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (main relay fuse IF5) Main relay-terminal 68 Main relay closing contact Main relay-terminal 69 I/P fuse box (oxygen sensor fuse IF30) Connector X05-terminal 6 Front oxygen sensor connector E0- terminal Front oxygen sensor (heating resistor) Front oxygen sensor connector E0-terminal ECM connector E07-terminal ECM Grounding Controlled by ECM directly, front oxygen sensor (heating resistor) is powered on to start work. Signal from front oxygen sensor Front oxygen sensor connector E0-terminal 3 ECM connector E07-terminal 39 ECM and front oxygen sensor Front oxygen sensor connector E0-terminal 4 ECM connector E07-terminal 45 ECM Operating circuit analysis of rear oxygen sensor is as follows: Current from the battery positive Main fuse box (main fuse EF0) I/P fuse box (main relay fuse IF5) Main relay-terminal 68 Main relay closing contact Main relay-terminal 69 I/P fuse box (oxygen sensor fuse IF30) Connector X04-terminal 6 Rear oxygen sensor connector S0- terminal 3 Rear oxygen sensor (heating resistor) Rear oxygen sensor connector S0-terminal Connector X04-terminal 7 Connector X05-terminal 0 ECM connector E07-terminal 4 ECM Grounding Controlled by ECM directly, rear oxygen sensor (heating resistor) is powered on to start work. Signal from rear oxygen sensor Rear oxygen sensor connector S0-terminal Connector X04- terminal 7 Connector X05-terminal 6 ECM connector E07-terminal 9 ECM and rear oxygen sensor Rear oxygen sensor connector S0-terminal 4 Connector X04-terminal 9 Connector X05-terminal ECM connector E07-terminal 39 ECM

60 3..-5 TPS/KS/IAC Electronic Control System (.0L) Throttle Position Sensor Knock Sensor 3 E03 E03 E03 E E 3 E Refer to 3.. Electronic Control System (.0L) HOS/EVAP 0.5 YE/GN 0.5 BU/WH 6 E07 ECM E07 36 E07 35 E07 E GY/GN 0.5 GY/BK 0.5 GY 0.5 GY/YE 0.5 YE/GN 0.5 YE/GN 0.5 BU/BN 0.5 RD 0.5 GN.0 BK 0.5 BK 39 E07 8 E07 30 E07 3 E07 G30 E4 4 E4 3 E4 E4 Stepper Motor M3003

61 3..-6 Electronic Control System (.0L) Operating circuit analysis of throttle position sensor is as follows: Current from ECM ECM connector E07-terminal 8 Throttle position sensor connector E03- terminal Throttle position sensor Throttle position sensor connector E03-terminal ECM connector E07-terminal 39 ECM Grounding Position signal from throttle position sensor Throttle position sensor connector E03-terminal 3 ECM connector E07-terminal 6 ECM Operating circuit analysis of knock sensor is as follows: Signal from knock sensor Knock sensor connector E-terminal ECM connector E07-terminal 3 ECM and knock sensor Knock sensor connector E-terminal ECM connector E07- terminal 30 ECM Operating circuit analysis of stepper motor is as follows: Stepper motor is powered on by four phases alternately, and rotating direction is determined by the power supplying order of four phases. When A phase is working, current from ECM ECM connector E07-terminal Stepper motor connector E4-terminal Stepper motor Stepper motor connector E4-terminal 4 ECM connector E07-terminal 36 ECM Grounding When B phase is working, current from ECM ECM connector E07-terminal Stepper motor connector E4-terminal Stepper motor Stepper motor connector E4-terminal 3 ECM connector E07-terminal 35 ECM Grounding When C phase is working, current from ECM ECM connector E07-terminal 35 Stepper motor connector E4-terminal 3 Stepper motor Stepper motor connector E4-terminal ECM connector E07-terminal ECM Grounding When D phase is working, current from ECM ECM connector E07-terminal 36 Stepper motor connector E4-terminal 4 Stepper motor Stepper motor connector E4-terminal ECM connector E07-terminal ECM Grounding

62 3..-7 Electronic Control System (.0L) CKP/Evaporator Thermistor/ECT/IAT Crankshaft Position Sensor Evaporator Thermistor Coolant Temperature Sensor Air Intake Pressure/Temperature Sensor E05 3 E05 E05 P39 P39 E 3 E 3 E5 4 E5 E5 E5 0.5 BK 0.5 BU/RD 0.5 LG/BK X05 4 X05.0 BK 0.5 BU 0.5 BU/GN 0.5 BU/RD 0.5 VT 0.5 YE/BK 0.5 BU/RD 0.5 BU/RD G LG/BK 0.5 BN/YE 0.5 YE/BK 0.5 YE/BU 0.5 BU/RD 47 E07 46 E07 3 E07 4 E07 9 E07 59 E07 40 E07 5 E07 ECM 57 E07 5 E07 9 E07 56 E07 0 E07 4 E GN 0.5 YE/RD 0.5 WH/BU 0.5 YE/WH 0.5 VT/YE 0.5 RD/YE Refer to 4.. Instrument Cluster Signal Lamp (.0L) Refer to 4.. On-board Network System DLC Refer to 4.. Instrument Cluster Signal Lamp (.0L) Refer to 4.. Refer to 4.. Instrument Cluster Instrument Cluster Signal Lamp (.0L) Power Supply and Signal Refer to 4..6 Lighting System Headlamp M3004

63 3..-8 Electronic Control System (.0L) Operating circuit analysis of crankshaft position sensor is as follows: Current from ECM ECM connector E07-terminal 46 Crankshaft position sensor connector E05- terminal Crankshaft position sensor Crankshaft position sensor connector E05-terminal Grounding G30 Position signal from crankshaft position sensor Crankshaft position sensor connector E05-terminal 3 ECM connector E07-terminal 47 ECM Operating circuit analysis of air intake pressure/temperature sensor is as follows: Current from ECM ECM connector E07-terminal 9 Air intake pressure/temperature sensor connector E5-terminal 3 Air intake pressure/temperature sensor Connector E5-terminal ECM connector E07-terminal 40 ECM Grounding Air intake temperature signal from air intake pressure/temperature sensor Air intake pressure/ temperature sensor connector E5-terminal ECM connector E07-terminal 5 ECM Air intake pressure signal from air intake pressure/temperature sensor Air intake pressure/ temperature sensor connector E5-terminal 4 ECM connector E07-terminal 59 ECM Operating circuit analysis of evaporator thermistor is as follows: Current from ECM ECM connector E07-terminal 3 Connector X05-terminal 4 Evaporator thermistor connector P39-terminal Evaporator thermistor Evaporator thermistor connector P39- terminal Connector X05-terminal ECM connector E07-terminal 40 ECM Grounding Operating circuit analysis of coolant temperature sensor is as follows: Current from ECM ECM connector E07-terminal 4 Coolant temperature sensor connector E- terminal Coolant temperature sensor Coolant temperature sensor connector E-terminal ECM connector E07-terminal 40 ECM Grounding

64 3..-9 Electronic Control System (.0L) Main Fuse Box EF0 P0 I/P Fuse Box 3 IF IF08 IF0 IF0 IF03 IF04 IF05 IF IF IF3 IF IF IF0 IF9 IF8 IF7 IF6 IF5 IF4 IF3 IF IF IF0 IF IR0 45 IR0 50 IR03 55 IR04 60 IR IF40 IF39 IF38 IF37 IF36 IF35 IF34 IF33 IF3 IF3 IF30 IF9 IF8 IF7 IF6 IF IR06 70 IR07 75 IR08 80 IR09 85 IR P40

65 3..-0 Electronic Control System (.0L) I/P Wiring Harness to Chassis Wiring Harness Chassis Wiring Harness to I/P Wiring Harness X04 I/P Wiring Harness to Engine Wiring Harness Engine Wiring Harness to I/P Wiring Harness X05

66 3..- Electronic Control System (.0L) 3..- Front Oxygen Sensor Throttle Position Sensor E0 Crankshaft Position Sensor E03 Coolant Temperature Sensor 3 3 E05 ECM E E07

67 3..- Electronic Control System (.0L) 3..- Knock Sensor Carbon Canister Solenoid 3 E E3 Stepper Motor Air Intake Pressure/Temperature Sensor E4 E5 Rear Oxygen Sensor Evaporator Thermistor 4 3 S0 P39

68 Electronic Control System (.L) Electronic Control System (.L) 3..- Electronic Control System B+ IF IF5 IR Stepper Motor IF30 Carbon Canister Solenoid Air Intake Pressure/ Temperature Sensor 3 4 Front Oxygen Sensor 45 4 Coolant Temperature Sensor 4 3 Rear Oxygen Sensor Evaporator Thermistor IG Diode Terminal IF37 7 ECM 47 3 Crankshaft Position Sensor 9 Tristate Pressure Switch Instrument Cluster Throttle Position Sensor Diode A Terminal Diode B Terminal DLC Terminal 5 Knock Sensor G30 G30 G30 M3005

69 3..- Electronic Control System (.L) 3..- Power Supply and Data Line Main Fuse Box P0 +B I/P Fuse Box P40 IG 80A 8.0 WH 8.0 WH EF0 8.0 WH 0A 8.0 WH IF 5A 8.0 WH 9 30 IF IR05 0A IF37 0A 3.0 YE/BK 66 IF33 Refer to 4..8 On-board Network System DLC 0.5 PK/BU 0.5 PK/BU 0.5 PK/BU 0.5 PK/BU X BN/WH 5 X BN/WH.0 RD/BU.0 RD/BU X05 6 E07a 5 E07a 43 E07a 48 E07a 0.5 BK/YE.0 BK 0.5 BK 0.5 BK.0 RD/BU.5 RD/BU.0 RD/BU Refer to 3..7 Fuel System (.L) 3..8 Ignition System (.L) 3..0 Charging System ECM E07a 44 E07a 0 E07a 0.5 LG/RD 0.5 PK/BK 0.5 BU/BK 0.5 RD/BU 0.5 BU X BU 6 E07a 3 E07a 8 E07a 5 E07a 7 E07a Refer to 4.. Heating, Ventilation and Air Conditioning Power Supply/ Sensor/Actuator (.L) Refer to 4.. Heating, Ventilation and Air Conditioning Power Supply/ Sensor/Actuator (.L) Refer to 4.. Heating, Ventilation and Air Conditioning Power Supply/ Sensor/Actuator (.L) Refer to 4.. Heating, Ventilation and Air Conditioning Power Supply/ Sensor/Actuator (.L) G30 G30 M300

70 3..-3 HOS/EVAP Electronic Control System (.L) Main Fuse Box P0 +B I/P Fuse Box P40 80A 8.0 WH 8.0 WH EF0 8.0 WH 8.0 WH 9 5A 30 IF IR A 60 IF30 Refer to 3.. Electronic Control System (.L) TPS/KS/IAC 0.5 WH/RD 0.5 YE 7 X YE 6 X YE.0 RD/BU 0.5 BN/WH.0 RD/BU.5 RD/BU.5 RD/GN X05.5 RD/GN 6 X YE/GN.5 RD/GN 6 X04 5 X05.0 RD/BU X YE/GN 0.85 RD/BU 0.85 RD/GN 0.5 YE/GN.5 RD/GN 9 X YE/GN E3a 4 E0a E0a Carbon Canister Solenoid Front Oxygen Sensor 3 S0 4 S0 Rear Oxygen sensor 0.5 BN/WH E3a 3 E0a E0a S0 S0 7 X RD/WH 0.85 YE/WH 0.5 BK/OG 0.5 YE/GN 0.5 WH/RD 0 X WH 3 E07a 37 E07a E07a 45 E07a 39 E07a 4 E07a 9 E07a ECM M300