DESCRIPTION
Refer to DTC P003012.
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Refer to DTC P030000.
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DTC No. | Detection Item | DTC Detection Condition | Trouble Area | MIL | Memory | Note |
---|---|---|---|---|---|---|
P11EA00 | Bank 1 Air-Fuel Ratio Imbalance (Port) | The difference in air fuel ratios between the cylinders exceeds the threshold (2 trip detection logic). |
| Comes on | DTC stored | SAE Code: P11EA |
P11EC00 | Cylinder #1 Air-Fuel Ratio Imbalance (Port) | The difference in air fuel ratios between the cylinders exceeds the threshold (2 trip detection logic). |
| Comes on | DTC stored | SAE Code: P11EC |
P11ED00 | Cylinder #2 Air-Fuel Ratio Imbalance (Port) | The difference in air fuel ratios between the cylinders exceeds the threshold (2 trip detection logic). |
| Comes on | DTC stored | SAE Code: P11ED |
P11EE00 | Cylinder #3 Air-Fuel Ratio Imbalance (Port) | The difference in air fuel ratios between the cylinders exceeds the threshold (2 trip detection logic). |
| Comes on | DTC stored | SAE Code: P11EE |
P11EF00 | Cylinder #4 Air-Fuel Ratio Imbalance (Port) | The difference in air fuel ratios between the cylinders exceeds the threshold (2 trip detection logic). |
| Comes on | DTC stored | SAE Code: P11EF |
P219A00 | Bank 1 Air-Fuel Ratio Imbalance | The difference in air fuel ratios between the cylinders exceeds the threshold (2 trip detection logic). |
| Comes on | DTC stored | SAE Code: P219A |
P219C00 | Cylinder 1 Air-Fuel Ratio Imbalance | The difference in air fuel ratios between the cylinders exceeds the threshold (2 trip detection logic). |
| Comes on | DTC stored | SAE Code: P219C |
P219D00 | Cylinder 2 Air-Fuel Ratio Imbalance | The difference in air fuel ratios between the cylinders exceeds the threshold (2 trip detection logic). |
| Comes on | DTC stored | SAE Code: P219D |
P219E00 | Cylinder 3 Air-Fuel Ratio Imbalance | The difference in air fuel ratios between the cylinders exceeds the threshold (2 trip detection logic). |
| Comes on | DTC stored | SAE Code: P219E |
P219F00 | Cylinder 4 Air-Fuel Ratio Imbalance | The difference in air fuel ratios between the cylinders exceeds the threshold (2 trip detection logic). |
| Comes on | DTC stored | SAE Code: P219F |
MONITOR DESCRIPTION
Fuel System Air Fuel Ratio Cylinder Imbalance MonitorThe ECM uses the air fuel ratio sensor (sensor 1) and crankshaft position sensor to monitor the difference in air fuel ratios between the cylinders caused by differences in injection volumes between the cylinders, leakage in the intake or exhaust system, etc.
When the air fuel ratios of the cylinders are lean or rich with respect to each other, the ECM determines that there is a malfunction, illuminates the MIL and stores a DTC.
Air Fuel Ratio Sensor (Sensor 1) Monitoring Method: P11EA00 (for port injection), or P219A00 (for direct injection) is stored primarily when a rich side imbalance is detected.When the system detects a difference in air fuel ratios between the cylinders due to fluctuation in the air fuel ratio sensor (sensor 1) output over 1 engine cycle (2 crankshaft revolutions), the system determines that there is a problem.
Crankshaft Position Sensor Monitoring Method: P11EC00, P11ED00, P11EE00 and/or P11EF00 (for port injection), or P219C00, P219D00, P219E00 and/or P219F00 (for direct injection) are stored primarily when a lean side imbalance is detected.The system monitors the engine speed variation and when the variation becomes large, the system determines that there is a difference in air fuel ratios between the cylinders, which it determines to be a problem.
MONITOR STRATEGY
Related DTCs | P11EA: Air fuel ratio cylinder imbalance monitor (for port injection of bank 1) P11EC: Air fuel ratio cylinder imbalance monitor (for port injection of cylinder 1) P11ED: Air fuel ratio cylinder imbalance monitor (for port injection of cylinder 2) P11EE: Air fuel ratio cylinder imbalance monitor (for port injection of cylinder 3) P11EF: Air fuel ratio cylinder imbalance monitor (for port injection of cylinder 4) P219A: Air fuel ratio cylinder imbalance monitor (for direct injection of bank 1) P219C: Air fuel ratio cylinder imbalance monitor (for direct injection of cylinder 1) P219D: Air fuel ratio cylinder imbalance monitor (for direct injection of cylinder 2) P219E: Air fuel ratio cylinder imbalance monitor (for direct injection of cylinder 3) P219F: Air fuel ratio cylinder imbalance monitor (for direct injection of cylinder 4) |
Required Sensors/Components (Main) | Air fuel ratio sensor (sensor 1) Crankshaft position sensor |
Required Sensors/Components (Related) | Mass air flow meter sub-assembly Engine coolant temperature sensor Vehicle speed sensor |
Frequency of Operation | Once per driving cycle |
Duration | 20 seconds: Air fuel ratio sensor (sensor 1) monitoring method 10 to 15 seconds: Crankshaft position sensor monitoring method |
MIL Operation | 2 driving cycles |
Sequence of Operation | None |
TYPICAL ENABLING CONDITIONS
P11EA and P219A: Air Fuel Ratio Sensor (Sensor 1) Monitoring Method Monitor runs whenever the following DTCs are not stored | P0010, P1360, P1362, P1364, P1366, P2614 (Motor drive VVT system control module) P0011 (VVT system - advance) P0012 (VVT system - retard) P0013 (Exhaust VVT oil control solenoid) P0014 (Exhaust VVT system - advance) P0015 (Exhaust VVT system - retard) P0016 (VVT system - misalignment) P0017 (Exhaust VVT system - misalignment) P0031, P0032, P101D (Air fuel ratio sensor (sensor 1) heater) P0087, P0088, P0191, P0192, P0193 (Fuel pressure sensor (for high pressure side)) P0101, P0102, P0103 (Mass air flow meter) P0107, P0108 (Manifold absolute pressure) P0117, P0118 (Engine coolant temperature sensor) P0121, P0122, P0123, P0222, P0223, P2135 (Throttle position sensor) P0125 (Insufficient coolant temperature for closed loop fuel control) P014C, P014D, P015A, P015B, P2195, P2196, P2237, P2238, P2239, P2252, P2253 (Air fuel ratio sensor (sensor 1)) P0201, P0202, P0203, P0204, P062D, P21CF, P21D0, P21D1, P21D2 (Fuel injector) P0335, P0337, P0338 (Crankshaft position sensor) P0340, P0342, P0343 (Camshaft position sensor) P0365, P0367, P0368 (Exhaust camshaft position sensor) P0401 (EGR system (closed)) P0657, P0658, P2102, P2103 (Throttle actuator) P107B, P107C, P107D (Fuel pressure sensor (for low pressure side)) P1235 (High pressure fuel pump circuit) |
Monitor runs whenever the following DTCs are not stored | P0010, P1360, P1362, P1364, P1366, P2614 (Motor drive VVT system control module) P0011 (VVT system - advance) P0012 (VVT system - retard) P0013 (Exhaust VVT oil control solenoid) P0014 (Exhaust VVT system - advance) P0015 (Exhaust VVT system - retard) P0016 (VVT system - misalignment) P0017 (Exhaust VVT system - misalignment) P0087, P0088, P0191, P0192, P0193 (Fuel pressure sensor (for high pressure side)) P0101, P0102, P0103 (Mass air flow meter) P0107, P0108 (Manifold absolute pressure) P0112, P0113 (Intake air temperature sensor) P0117, P0118 (Engine coolant temperature sensor) P0121, P0122, P0123, P0222, P0223, P2135 (Throttle position sensor) P0125 (Insufficient coolant temperature for closed loop fuel control) P0201, P0202, P0203, P0204, P062D, P21CF, P21D0, P21D1, P21D2 (Fuel injector) P0327, P0328 (Knock control sensor) P0335, P0337, P0338 (Crankshaft position sensor) P0340, P0342, P0343 (Camshaft position sensor) P0365, P0367, P0368 (Exhaust camshaft position sensor) P0401 (EGR system (closed)) P0657, P0658, P2102, P2103 (Throttle actuator) P107B, P107C, P107D (Fuel pressure sensor (for low pressure side)) P1235 (High pressure fuel pump circuit) |
Air fuel ratio sensor (sensor 1) status | Activated |
Engine speed | 1400 rpm or higher, and less than 2600 rpm |
Engine coolant temperature | 75°C (167°F) or higher |
Atmospheric pressure | 76 kPa(abs) [11 psi(abs)] or higher |
Fuel system status | Closed loop |
Engine load | 40% or higher, and less than 70% |
Engine speed | 1400 rpm or higher, and less than 2400 rpm |
Engine coolant temperature | 75°C (167°F) or higher |
Air fuel ratio sensor (sensor 1) status | Activated |
Fuel system status | Closed loop |
Auxiliary battery voltage | 11 V or higher |
Vehicle speed | Less than 3 km/h (1.875 mph) |
Engine speed | 1050 rpm or higher, and less than 1350 rpm |
Engine coolant temperature | 75°C (167°F) or higher |
Air fuel ratio sensor (sensor 1) status | Activated |
Fuel system status | Closed loop |
Auxiliary battery voltage | 11 V or higher |
Air fuel ratio sensor (sensor 1) status | Activated |
Engine speed | 1400 rpm or higher, and less than 2400 rpm |
Engine coolant temperature | 75°C (167°F) or higher |
Atmospheric pressure | 76 kPa(abs) [11 psi(abs)] or higher |
Fuel system status | Closed loop |
Engine load | 40% or higher, and less than 70% |
TYPICAL MALFUNCTION THRESHOLDS
P11EA: Air Fuel Ratio Sensor (Sensor 1) Monitoring Method Air fuel ratio sensor (sensor 1) monitoring method criteria (rich side imbalance for port injection) | 1 or more |
Crankshaft position sensor monitoring method criteria (lean side imbalance for port injection) (first Judgment) | 1.5 or more |
Crankshaft position sensor monitoring method criteria (lean side imbalance for port injection) (second judgment) | 1 or more |
Air fuel ratio sensor (sensor 1) monitoring method criteria (rich side imbalance for direct injection) | 1 or more |
Crankshaft position sensor monitoring method criteria (lean side imbalance for direct injection) (first Judgment) | 1.5 or more |
Crankshaft position sensor monitoring method criteria (lean side imbalance for direct injection) (second judgment) | 1 or more |
MONITOR RESULT
Refer to detailed information in Checking Monitor Status.
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P11EA: Fuel System / A/F SENSOR DETERMINATION (Port) B1 Monitor ID | Test ID | Scaling | Unit | Description |
---|---|---|---|---|
$81 | $96 | Multiply by 0.001 | No dimension | Monitoring method using air fuel ratio sensor (sensor 1) (Port) |
Monitor ID | Test ID | Scaling | Unit | Description |
---|---|---|---|---|
$81 | $8D | Multiply by 0.001 | No dimension | Monitoring method using crank angle sensor (Port) |
Monitor ID | Test ID | Scaling | Unit | Description |
---|---|---|---|---|
$81 | $8E | Multiply by 0.001 | No dimension | Monitoring method using crank angle sensor (Port) |
Monitor ID | Test ID | Scaling | Unit | Description |
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$81 | $8F | Multiply by 0.001 | No dimension | Monitoring method using crank angle sensor (Port) |
Monitor ID | Test ID | Scaling | Unit | Description |
---|---|---|---|---|
$81 | $90 | Multiply by 0.001 | No dimension | Monitoring method using crank angle sensor (Port) |
Monitor ID | Test ID | Scaling | Unit | Description |
---|---|---|---|---|
$81 | $95 | Multiply by 0.001 | No dimension | Monitoring method using air fuel ratio sensor (sensor 1) (Direct) |
Monitor ID | Test ID | Scaling | Unit | Description |
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$81 | $85 | Multiply by 0.001 | No dimension | Monitoring method using crank angle sensor (Direct) |
Monitor ID | Test ID | Scaling | Unit | Description |
---|---|---|---|---|
$81 | $86 | Multiply by 0.001 | No dimension | Monitoring method using crank angle sensor (Direct) |
Monitor ID | Test ID | Scaling | Unit | Description |
---|---|---|---|---|
$81 | $87 | Multiply by 0.001 | No dimension | Monitoring method using crank angle sensor (Direct) |
Monitor ID | Test ID | Scaling | Unit | Description |
---|---|---|---|---|
$81 | $88 | Multiply by 0.001 | No dimension | Monitoring method using crank angle sensor (Direct) |
CONFIRMATION DRIVING PATTERN
HINT:
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CAUTION:
When performing the confirmation driving pattern, obey all speed limits and traffic laws.
HINT:
If the engine stops, further depress the accelerator pedal to restart the engine.
CAUTION:
When performing the confirmation driving pattern, obey all speed limits and traffic laws.
HINT:
CAUTION:
When performing the confirmation driving pattern, obey all speed limits and traffic laws.
HINT:
HINT:
Perform this step with the shift lever in D.
HINT:
The normal judgment procedure is used to complete DTC judgment and also used when clearing permanent DTCs.
CAUTION:
When performing the confirmation driving pattern, obey all speed limits and traffic laws.
HINT:
If the engine stops, further depress the accelerator pedal to restart the engine.
CAUTION:
When performing the confirmation driving pattern, obey all speed limits and traffic laws.
HINT:
CAUTION:
When performing the confirmation driving pattern, obey all speed limits and traffic laws.
HINT:
HINT:
Perform this step with the shift lever in D.
HINT:
Techstream Display | Description |
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NORMAL |
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ABNORMAL |
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INCOMPLETE |
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HINT:
The normal judgment procedure is used to complete DTC judgment and also used when clearing permanent DTCs.
CAUTION / NOTICE / HINT
NOTICE:
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(Select Powertrain in Health Check and then check the time stamp data.)
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HINT:
PROCEDURE
1. | CHECK ANY OTHER DTCS OUTPUT |
(a) Connect the Techstream to the DLC3.
(b) Turn the power switch on (IG).
(c) Turn the Techstream on.
(d) Enter the following menus: Powertrain / Engine / Trouble Codes.
(e) Read the DTCs.
Powertrain > Engine > Trouble Codes Result | Proceed to |
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DTC P11EA00, P11EC00, P11ED00, P11EE00, P11EF00, P219A00, P219C00, P219D00, P219E00 and/or P219F00 is output | A |
DTC P11EA00, P11EC00, P11ED00, P11EE00, P11EF00, P219A00, P219C00, P219D00, P219E00 and/or P219F00 and other DTCs are output | B |
HINT:
If any DTCs other than DTC P11EA00, P11EC00, P11ED00, P11EE00, P11EF00, P219A00, P219C00, P219D00, P219E00 and/or P219F00 are output, troubleshoot those DTCs first.
B | GO TO DTC CHART |
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2. | READ VALUE USING TECHSTREAM (FREEZE FRAME DATA) |
(a) Connect the Techstream to the DLC3.
(b) Turn the power switch on (IG).
(c) Turn the Techstream on.
(d) Using the Techstream, confirm the vehicle conditions recorded in the Freeze Frame Data which were present when the DTC was stored.
Click here
HINT:
When the sum of Short FT B1S1 and Long FT B1S1 is positive, the engine is running lean, and when the sum is negative, the engine is running rich.
Air Fuel Ratio Sensor (Sensor 1) Monitoring Method (P11EA00 and P219A00) | Crankshaft Position Sensor Monitoring Method (P11EC00, P11ED00, P11EE00, P11EF00, P219C00, P219D00, P219E00 and P219F00) | Note |
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DTCs are output | DTC is output (Only one DTC relating to a single cylinder is output) | Malfunctioning of cylinders detected by the Crankshaft Position Sensor Monitoring Method is primarily suspected |
DTCs are output | DTCs are output (Multiple DTCs relating to multiple cylinders are output) | Malfunctioning of cylinders except ones detected by the Crankshaft Position Sensor Monitoring Method is primarily suspected.* |
DTCs are not output | DTCs are output | Malfunctioning of cylinders detected by the Crankshaft Position Sensor Monitoring Method is primarily suspected. |
DTCs are output | DTCs are not output | Malfunctioning of the bank detected by the Air Fuel Ratio Sensor (Sensor 1) Monitoring Method is primarily suspected. |
*: When any air-fuel ratio imbalance is detected, the ECM will perform air-fuel ratio feedback control to make the air-fuel ratio close to the stoichiometric level. This may result in an air-fuel ratio imbalance of normal cylinders and DTCs may be stored.
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3. | READ DTC OUTPUT |
(a) Connect the Techstream to the DLC3.
(b) Turn the power switch on (IG).
(c) Turn the Techstream on.
(d) Drive the vehicle in accordance with the driving pattern described in Confirmation Driving Pattern.
HINT:
(e) Enter the following menus: Powertrain / Engine / Trouble Codes.
(f) Read the DTCs.
Powertrain > Engine > Trouble Codes Result | Proceed to |
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DTC P11EA00 or P219A00 is output | A |
DTC P219A00 and P219C00, P219D00, P219E00 or P219F00 is output | B |
DTC P11EA00 and P11EC00, P11ED00, P11EE00 or P11EF00 is output | |
DTC P11EC00, P11ED00, P11EE00, P11EF00, P219C00, P219D00, P219E00 and/or P219F00 is output |
B | GO TO STEP 6 |
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4. | PERFORM ACTIVE TEST USING TECHSTREAM (CONTROL THE INJECTION VOLUME) |
(a) Connect the Techstream to the DLC3.
(b) Turn the power switch on (IG).
(c) Turn the Techstream on.
(d) Put the engine in Inspection Mode (Maintenance Mode).
Powertrain > Hybrid Control > Utility Tester Display |
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Inspection Mode |
(e) Start the engine and warm it up until the engine coolant temperature reaches 75°C (167°F) or higher.
HINT:
The A/C switch and all accessory switches should be off and the shift lever should be in P or N.
(f) Enter the following menus: Powertrain / Engine / Active Test / Control the Injection Volume / Data List / Coolant Temperature and Misfire Count Cylinder #1 to #4.
Powertrain > Engine > Active Test Active Test Display |
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Control the Injection Volume |
Data List Display |
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Coolant Temperature |
Misfire Count Cylinder #1 |
Misfire Count Cylinder #2 |
Misfire Count Cylinder #3 |
Misfire Count Cylinder #4 |
HINT:
When the "Control the Injection Volume" Active Test is selected (injection volume is 0%), if a misfire count increases, proceed to step 6 (CHECK INTAKE SYSTEM).
(g) Perform the Control the Injection Volume operation with the engine idling.
(h) Check the misfire counts (Misfire Count Cylinder #1 to #4) while decreasing the injection volume in 5% increments.
The cylinder whose misfire count has not increased can be assumed to be running rich. Therefore, perform inspections while focusing on that cylinder.
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5. | CHECK FOR EXHAUST GAS LEAK |
(a) Check for exhaust gas leak.
OK:
No gas leaks in exhaust system.
HINT:
Perform "Inspection After Repair" after repairing or replacing the exhaust system.
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NG | REPAIR OR REPLACE EXHAUST SYSTEM |
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6. | CHECK INTAKE SYSTEM |
(a) Check the intake system for vacuum leaks.
Click here
OK:
No leaks in the intake system.
HINT:
Perform "Inspection After Repair" after repairing or replacing the intake system.
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NG | REPAIR OR REPLACE INTAKE SYSTEM |
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7. | INSPECT SPARK PLUG |
(a) Inspect the spark plug of the cylinder causing the imbalance.
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HINT:
Perform "Inspection After Repair" after replacing the spark plug.
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NG | REPLACE SPARK PLUG |
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8. | CHECK FOR SPARK (SPARK TEST) |
(a) Perform a spark test.
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HINT:
Click here
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9. | CHECK CYLINDER COMPRESSION PRESSURE |
(a) Measure the cylinder compression pressure of the misfiring cylinder.
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HINT:
Perform "Inspection After Repair" after repairing or replacing the engine assembly.
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NG | CHECK ENGINE TO DETERMINE CAUSE OF LOW COMPRESSION |
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10. | CHECK PORT FUEL INJECTOR ASSEMBLY OF CYLINDER CAUSING IMBALANCE |
(a) Check the port fuel injector assembly injection [whether fuel volume is high or low, and whether injection pattern is poor].
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HINT:
Perform "Inspection After Repair" after replacing the port fuel injector assembly.
Click here
NG | REPLACE PORT FUEL INJECTOR ASSEMBLY |
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11. | CHECK DIRECT FUEL INJECTOR ASSEMBLY OF CYLINDER CAUSING IMBALANCE |
(a) Check the direct fuel injector assembly.
Click here
HINT:
Perform "Inspection After Repair" after replacing the direct fuel injector assembly.
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NG | REPLACE DIRECT FUEL INJECTOR ASSEMBLY |
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12. | CHECK FOR CAUSE OF FAILURE |
(a) If the cause of the problem has not been found even after performing the troubleshooting procedure, perform the inspection below.
(b) Check the intake valve for deposits.
HINT:
As the DTC may have been stored due to deposits on the intake valve, remove the cylinder head sub-assembly and check the intake valve.
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13. | CLEAR DTC |
(a) Connect the Techstream to the DLC3.
(b) Turn the power switch on (IG).
(c) Turn the Techstream on.
(d) Clear the DTCs.
Powertrain > Engine > Clear DTCs(e) Turn the power switch off and wait for at least 30 seconds.
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14. | CONFIRM WHETHER MALFUNCTION HAS BEEN SUCCESSFULLY REPAIRED |
(a) Drive the vehicle in accordance with the driving pattern described in Confirmation Driving Pattern.
(b) Enter the following menus: Powertrain / Engine / Trouble Codes.
(c) Check for DTCs.
Powertrain > Engine > Trouble CodesDTCs are not output.
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