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Engine Control System (Diagnostic Codes (P0010 - P0415)): Overview Lexus LX J200 рестайлинг

Testing & Diagnostics 21 illustrations ~8062 words

DESCRIPTION

  1. This DTC is designed to detect opens or shorts in the camshaft oil control valve (OCV) circuit. If the OCV duty-cycle is excessively high or low while the engine is running, the ECM will illuminate the MIL and store the DTC.
  2. The VVT (variable valve timing) system adjusts the intake valve timing to improve the driveability. The engine oil pressure turns the camshaft actuator to adjust the valve timing. The OCV is a solenoid valve and switches the engine oil line. The valve moves when the ECM applies 12 V to the solenoid. The ECM changes the energizing time to the solenoid (duty-cycle) in accordance with the camshaft position, crankshaft position, throttle position, etc.

Scheme 76

Scheme 76
DTC No.DTC Detection ConditionTrouble Area
P0010An open or short in the Camshaft Oil Control Valve (OCV) for intake side (for Bank 1) circuit (1 trip detection logic).Open or short in Camshaft Oil Control Valve (OCV) (for intake side of Bank 1) circuit OCV (for intake side of Bank 1) ECM
P0020An open or short in the OCV for intake side (for Bank 2) circuit (1 trip detection logic).Open or short in OCV (for intake side of Bank 2) circuit OCV (for intake side of Bank 2) ECM

HINT

This DTC relates to the Camshaft Oil Control Valve (OCV).

MONITOR DESCRIPTION

This DTC is designed to detect opens or shorts in the camshaft oil control valve (OCV) circuit. If the OCV duty-cycle is excessively high or low while the engine is running, the ECM will illuminate the MIL and store the DTC.

The VVT system includes the ECM, Camshaft Oil Control Valve (OCV) and VVT controller. The ECM sends a target duty-cycle control signal to the OCV. This control signal regulates the oil pressure supplied to the VVT controller. Camshaft timing control is performed according to engine operating conditions such as the intake air volume, throttle valve position and engine coolant temperature. The ECM controls the OCV based on the signals transmitted by several sensors. The VVT controller regulates the intake camshaft angle using oil pressure through the OCV. As a result, the relative positions of the camshaft and crankshaft are optimized, the engine torque and fuel economy improve, and the exhaust emissions decrease under overall driving conditions. The ECM detects the actual intake valve timing using signals from the camshaft and crankshaft position sensors, and performs feedback control. This is how the target intake valve timing is verified by the ECM.

DTC No.DTC Detection ConditionTrouble Area
P0011 P0021The intake valve timing is not adjusted in the valve timing advance range (1 trip detection logic).Valve timing Camshaft oil control valve (OCV) (for intake side of Bank 1, 2) OCV filter Camshaft timing gear ECM
P0012 P0022The intake valve timing is not adjusted in the valve timing retard range (2 trip detection logic).Valve timing OCV (for intake side of Bank 1, 2) OCV filter Camshaft timing gear ECM
  1. The ECM optimizes the intake valve timing using the VVT (Variable Valve Timing) system to control the intake camshaft. The VVT system includes the ECM, Camshaft Oil Control Valve (OCV) and VVT controller. The ECM sends a target duty-cycle control signal to the OCV. This control signal regulates the oil pressure supplied to the VVT controller. The VVT controller can advance or retard the intake camshaft.
  2. If the difference between the target and actual intake valve timings is large, and changes in the actual intake valve timing are small, the ECM interprets this as the VVT controller stuck malfunction and stores DTC(s).
  1. DTC P0011 and P0021 (Advanced Cam Timing) are subject to 1 trip detection logic.
  2. DTC P0012 and P0022 (Retarded Cam Timing) are subject to 2 trip detection logic.
  3. These DTCs indicate that the VVT controller cannot operate properly due to OCV malfunctions or the presence of foreign objects in the OCV. Example: A DTC is stored when the following conditions 1 and 2 are met: 1. It takes 5 seconds or more to change the valve timing by 5°CA. 2. After the above condition 1 is met, the camshaft oil control valve is forcibly activated for 10 seconds.
  1. This DTC is designed to detect opens or shorts in the Camshaft Oil Control Valve (OCV) circuit. If the OCV duty-cycle is excessively high or low while the engine is running, the ECM will illuminate the MIL and store the DTC.
  2. The VVT (variable valve timing) system adjusts the intake valve timing to improve the driveability. The engine oil pressure turns the camshaft actuator to adjust the valve timing. The OCV is a solenoid valve and switches the engine oil line. The valve moves when the ECM applies 12 volts to the solenoid. The ECM changes the energizing time to the solenoid (duty-cycle) in accordance with the camshaft position, crankshaft position, throttle position, etc.

Scheme 77

Scheme 77
DTC No.DTC Detection ConditionTrouble Area
P0013An open or short in the Camshaft Oil Control Valve (OCV) for exhaust side (for Bank 1) circuit (1 trip detection logic).Open or short in Camshaft Oil Control Valve (OCV) (for exhaust side of Bank 1) circuit OCV (for exhaust side of Bank 1) ECM
P0023An open or short in the OCV for exhaust side (for Bank 2) circuit (1 trip detection logic).Open or short in OCV (for exhaust side of Bank 2) circuit OCV (for exhaust side of Bank 2) ECM

This DTC is designed to detect opens or shorts in the camshaft oil control valve (OCV) circuit. If the OCV duty-cycle is excessively high or low while the engine is running, the ECM will illuminate the MIL and store the DTC.

HINT

If DTC P0014, P0015, P0024 or P0025 is output, check the VVT (Variable Valve Timing) system.

The Variable Valve Timing (VVT) system includes the ECM, OCV and VVT controller. The ECM sends a target duty-cycle control signal to the OCV. This control signal regulates the oil pressure supplied to the VVT controller. Camshaft timing control is performed according to engine operating conditions such as the intake air volume, throttle valve position and engine coolant temperature. The ECM controls the OCV based on the signals transmitted by several sensors. The VVT controller regulates the exhaust camshaft angle using oil pressure through the OCV. As a result, the relative positions of the camshaft and crankshaft are optimized, the engine torque and fuel economy improve, and the exhaust emissions decrease under overall driving conditions. The ECM detects the actual exhaust valve timing using signals from the camshaft and crankshaft position sensors, and performs feedback control. This is how the target exhaust valve timing is verified by the ECM.

DTC No.DTC Detection ConditionTrouble Area
P0014 P0024The exhaust valve timing is not adjusted in the valve timing advance range (2 trip detection logic).Valve timing Camshaft oil control valve (OCV) (for exhaust side of Bank 1, 2) OCV filter Camshaft timing exhaust gear ECM
P0015 P0025The exhaust valve timing is not adjusted in the valve timing retard range (1 trip detection logic).Valve timing OCV (for exhaust side of Bank 1, 2) OCV filter Camshaft timing exhaust gear ECM
  1. The ECM optimizes the exhaust valve timing using the VVT (Variable Valve Timing) system to control the exhaust camshaft. The VVT system includes the ECM, Camshaft Oil Control Valve (OCV) and VVT controller. The ECM sends a target duty-cycle control signal to the OCV. This control signal regulates the oil pressure supplied to the VVT controller. The VVT controller can advance or retard the exhaust camshaft.
  2. If the difference between the target and actual exhaust valve timing is large, and changes in actual exhaust valve timing are small, the ECM interprets this as the VVT controller stuck malfunction and stores DTC(s).
  1. DTCs P0014 and P0024 (Advanced Cam Timing) are subject to 2 trip detection logic.
  2. DTCs P0015 and P0025 (Retarded Cam Timing) are subject to 1 trip detection logic. These DTCs indicate that the VVT controller cannot operate properly due to OCV malfunctions or the presence of foreign objects in the OCV. Example: A DTC is stored when the following conditions 1 and 2 are met: 1. It takes 5 seconds or more to change the valve timing by 5°CA. 2. After the above condition 1 is met, the camshaft oil control valve is forcibly activated for 10 seconds.

In the VVT (Variable Valve Timing) system, the appropriate intake and exhaust valve open and close timing is controlled by the ECM. The ECM performs intake and exhaust valve control by performing the following: 1) controlling the camshaft and camshaft oil control valve, and operating the camshaft timing gear; and 2) changing the relative positions of the camshaft and crankshaft.

DTC No.DTC Detection ConditionTrouble Area
P0016Deviation in the crankshaft position sensor signal and VVT sensor (for Intake side of Bank 1) signal (2 trip detection logic).Mechanical system (Timing chain has jumped tooth or chain stretched) Camshaft oil control valve (OCV) (for intake side of bank 1) Camshaft timing gear (bank 1) ECM
P0017Deviation in the crankshaft position sensor signal and VVT sensor (for Exhaust side of Bank 1) signal (2 trip detection logic).Mechanical system (Timing chain has jumped tooth or chain stretched) OCV (for exhaust side of bank 1) Camshaft timing exhaust gear (bank 1) ECM
P0018Deviation in the crankshaft position sensor signal and VVT sensor (for Intake side of Bank 2) signal (2 trip detection logic).Mechanical system (Timing chain has jumped tooth or chain stretched) OCV (for intake side of bank 2) Camshaft timing gear (bank 2) ECM
P0019Deviation in the crankshaft position sensor signal and VVT sensor (for Exhaust side of Bank 2) signal (2 trip detection logic).Mechanical system (Timing chain has jumped tooth or chain stretched) OCV (for exhaust side of bank 2) Camshaft timing exhaust gear (bank 2) ECM

To monitor the correlation of the intake camshaft position and crankshaft position, the ECM checks the VVT learning value while the engine is idling. The VVT learning value is calibrated based on the camshaft position and crankshaft position. The intake valve timing is set to the most retarded angle while the engine is idling. If the VVT learning value is out of the specified range in consecutive driving cycles, the ECM illuminates the MIL and stores DTC P0016 (Bank 1) or P0018 (Bank 2).

To monitor the correlation of the exhaust camshaft position and crankshaft position, the ECM checks the VVT learning value while the engine is idling. The VVT learning value is calibrated based on the camshaft position and crankshaft position. The exhaust valve timing is set to the most advanced angle while the engine is idling. If the VVT learning value is out of the specified range in consecutive driving cycles, the ECM illuminates the MIL and stores DTC P0017 (Bank 1) or P0019 (Bank 2).

Refer to DTC P2195. Refer to DESCRIPTION .

HINT

Scheme 78

Scheme 78: DESCRIPTION
  1. Although the DTC titles say oxygen sensor, these DTCs relate to the Air-Fuel Ratio (A/F) sensor.
  2. Sensor 1 refers to the sensor mounted in front of the Three-Way Catalytic Converter (TWC) and located near the engine assembly.
  3. When one of these DTCs is stored, the ECM enters fail-safe mode. The ECM turns off the A/F sensor heater in fail-safe mode. Fail-safe mode continues until the engine switch is turned off.
  4. The ECM provides a pulse width modulated control circuit to adjust the current through the heater. The A/F sensor heater circuit uses a relay on the +B side of the circuit.
DTC No.DTC Detection ConditionTrouble Area
P0031 P0051The Air-Fuel Ratio (A/F) sensor heater current is below 0.8 A (1 trip detection logic).Open in Air-Fuel Ratio (A/F) sensor heater circuit A/F sensor heater (for Sensor 1) Integration relay ECM
P0032 P0052An Air-Fuel Ratio (A/F) sensor heater current failure (1 trip detection logic).Short in A/F sensor heater circuit A/F sensor heater (for Sensor 1) Integration relay ECM
P101D P103DThe heater current is higher than the specified value while the heater is not operating. (1 trip detection logic)ECM

The ECM uses information from the Air-Fuel Ratio (A/F) sensor to regulate the air-fuel ratio and keep it close to the stoichiometric level. This maximizes the ability of the Three-Way Catalytic Converter (TWC) to purify the exhaust gases.

The A/F sensor detects oxygen levels in the exhaust gas and transmits the information to the ECM. The inner surface of the sensor element is exposed to the outside air. The outer surface of the sensor element is exposed to the exhaust gas. The sensor element is made of platinum coated zirconia and includes an integrated heating element.

The zirconia element generates a small voltage when there is a large difference in the oxygen concentrations between the exhaust gas and outside air. The platinum coating amplifies this voltage generation.

The A/F sensor is more efficient when heated. When the exhaust gas temperature is low, the sensor cannot generate useful voltage signals without supplementary heating. The ECM regulates the supplementary heating using a duty-cycle approach to adjust the average current in the sensor heater element. If the heater current is outside the normal range, the signal transmitted by the A/F sensor becomes inaccurate. As a result, the ECM is unable to regulate the air-fuel ratio properly.

When the current in the A/F sensor heater is outside the normal operating range, the ECM interprets this as a malfunction in the sensor heater and stores DTC(s).

  1. Refer to DTC P0136. Refer to «DESCRIPTION».

HINT

Scheme 79

Scheme 79
  1. When any of these DTCs is stored, the ECM enters fail-safe mode. The ECM turns off the Heated Oxygen (HO2) Sensor heater in fail-safe mode. Fail-safe mode continues until the engine switch is turned off.
  2. The ECM provides a pulse width modulated control circuit to adjust the current through the heater. The HO2 sensor heater circuit uses a relay on the +B side of the circuit.
DTC No.DTC Detection ConditionTrouble Area
P0037 P0057The Heated Oxygen (HO2) sensor heater current is below 0.3 A (1 trip detection logic).Open in Heated Oxygen (HO2) sensor heater circuit HO2 sensor heater (for Sensor 2) Integration relay ECM
P0038 P0058The Heated Oxygen (HO2) sensor heater current is exceeds the specified value (1 trip detection logic).Short in HO2 sensor heater circuit HO2 sensor heater (for Sensor 2) Integration relay ECM
P0141 P0161The Cumulative heater resistance correction value exceeds the threshold (2 trip detection logic).Open or short in HO2 sensor heater circuit HO2 sensor heater (for Sensor 2) Integration relay ECM
P102D P105DThe heater current is higher than the specified value while the heater is not operating. (1 trip detection logic)ECM

The sensing portion of the Heated Oxygen (HO2) sensor has a zirconia element which is used to detect the oxygen concentration in the exhaust gas. If the zirconia element is at the appropriate temperature, and the difference between the oxygen concentrations surrounding the inside and outside surfaces of the sensor is large, the zirconia element generates voltage signals. In order to increase the oxygen concentration detecting capacity of the zirconia element, the ECM supplements the heat from the exhaust with heat from a heating element inside the sensor.

Heated oxygen sensor heater range check (P0037, P0038, P0057, P0058, P102D and P105D)

The ECM monitors the current applied to the heated oxygen sensor heater to check the heater for malfunctions. If the heater current is outside the normal range, the signal transmitted by the heated oxygen sensor becomes inaccurate. When the current in the heated oxygen sensor heater is outside the normal operating range, the ECM interprets this as a malfunction in the sensor and stores a DTC.

Heated oxygen sensor heater performance (P0141 and P0161)

After the accumulated heater ON time exceeds 100 seconds, the ECM calculates the heater resistance using the battery voltage and the current applied to the heater.

If the resistance is higher than the threshold value, the ECM determines that there is a malfunction in the HO2 sensor heater and stores DTC P0141 or P0161.

Refer to DTC P0102. Refer to «DESCRIPTION».

DTC No.DTC Detection ConditionTrouble Area
P0101Conditions (a), (b), (c), (d) and (e) continue for more than 10 seconds (2 trip detection logic): (a) The engine is running. (b) The engine coolant temperature is 70°C (158°F) or higher. (c) The Throttle Position (TP) sensor voltage is 0.2 V or higher and 3.6 V or less. (d) The average engine load value ratio is less than 0.85, or more than 1.15 (varies with estimated engine load). Average engine load value ratio = Average engine load based on MAF meter output / Average engine load estimated from driving conditions (e) The average air-fuel ratio is less than -15%, or more than 15%.Mass Air Flow (MAF) meter Air induction system PCV hose connections

The MAF meter is a sensor that measures the amount of air flowing through the throttle valve. The ECM uses this information to determine the fuel injection time and to provide an appropriate air-fuel ratio. Inside the MAF meter, there is a heated platinum wire which is exposed to the flow of intake air. By applying a specific electrical current to the wire, the ECM heats it to a specific temperature. The flow of incoming air cools both the wire and an internal thermistor, affecting their resistance. To maintain a constant current value, the ECM varies the voltage applied to the wire and internal thermistor. The voltage level is proportional to the airflow through the sensor, and the ECM uses it to calculate the intake air volume.

The ECM monitors the average engine load value ratio to check the MAF meter for malfunctions. The average engine load value ratio is obtained by comparing the average engine load calculated from the MAF meter output to the average engine load estimated from the driving conditions, such as the engine speed and the throttle opening angle. If the average engine load value ratio is less than the threshold value, the ECM determines that the intake air volume is low, and if the average engine load value ratio is more than the threshold value, the ECM determines that the intake air volume is high.

If this is detected in 2 consecutive driving cycles, the MIL is illuminated and a DTC is stored.

The Mass Air Flow (MAF) meter is a sensor that measures the amount of air flowing through the throttle valve.

The ECM uses this information to determine the fuel injection time and to provide the appropriate air-fuel ratio.

Inside the MAF meter, there is a heated platinum wire which is exposed to the flow of intake air.

By applying a specific electrical current to the wire, the ECM heats it to a given temperature. The flow of incoming air cools both the wire and an internal thermistor, affecting their resistance. To maintain a constant current value, the ECM varies the voltage applied to the wire and internal thermistor. The voltage level is proportional to the airflow through the sensor, and the ECM uses it to calculate the intake air volume.

The circuit is constructed so that the platinum hot wire and the cold film element create a bridge circuit, and the power transistor is controlled so that the potentials of A and B remain equal to maintain the predetermined temperature.

HINT

When any of these DTCs are stored, the ECM enters fail-safe mode. During fail-safe mode, the ignition timing is calculated by the ECM, according to the engine speed and throttle valve position. Fail-safe mode continues until a pass condition is detected.

Scheme 80

Scheme 80: DESCRIPTION
DTC No.DTC Detection ConditionTrouble Area
P0102The Mass Air Flow (MAF) meter voltage is below 0.2 V for 3 seconds (1 trip detection logic: Engine speed is less than 4000 rpm) (2 trip detection logic: Engine speed is 4000 rpm or more).Open or short in Mass Air Flow (MAF) meter circuit MAF meter ECM
P0103The MAF meter voltage is higher than 4.9 V for 3 seconds (1 trip detection logic: Engine speed is less than 4000 rpm) (2 trip detection logic: Engine speed is 4000 rpm or more).Open or short in MAF meter circuit MAF meter ECM

HINT

When any of these DTCs is output, check the air-flow rate by entering the following menus: Powertrain / Engine and ECT / Data List / All Data / MAF.

Mass Air Flow Rate (gm/s)Malfunction
Approximately 0.0Open in Mass Air Flow (MAF) meter power source circuit Open or short in VG circuit
271.0 or moreOpen in E2G circuit

If there is a defect in the MAF meter or an open or short circuit, the voltage level deviates from the normal operating range. The ECM interprets this deviation as a malfunction in the MAF meter and stores DTC(s).

Example

When the sensor output voltage remains at below 0.2 V, or higher than 4.9 V for more than 3 seconds, the ECM stores DTC(s).

If the malfunction is not repaired successfully, a DTC is stored 3 seconds after the engine is next started.

After warmed engine stop

The ECM monitors the intake air temperature variation in the period from when the engine was warmed up on the previous trip until the next engine start. If the change in engine coolant temperature sensor output is less than the threshold, it is determined that a malfunction has occurred in the intake air temperature sensor. When this is detected, the MIL is illuminated and the DTC is set.

After cold engine start

The monitor runs when the engine is started cold after 5 hours or more have elapsed since the engine stopped. If the intake air temperature sensor output variation until the engine has warmed up completely is less than the threshold, it is determined that a malfunction has occurred in the intake air temperature sensor. When this is detected in 2 consecutive driving cycles, the MIL is illuminated and the DTC is set.

The ECM monitors the sensor voltage and uses this value to calculate the IAT. When the sensor output voltage deviates from the normal operating range, the ECM interprets this as a malfunction in the IAT sensor and stores a DTC.

Example

If the sensor output voltage is higher than 4.91 V for 0.5 seconds or more, the ECM determines that there is an open in the IAT sensor circuit, and stores DTC P0113. Conversely, if the output voltage is below 0.18 V for 0.5 seconds or more, the ECM determines that there is a short in the sensor circuit, and stores DTC P0112.

If the malfunction is not repaired successfully, a DTC is stored 0.5 seconds after the engine is next started.

A thermistor, whose resistance value varies according to the ECT, is built into the Engine Coolant Temperature (ECT) sensor.

The structure of the sensor and its connection to the ECM are the same as those of the Intake Air Temperature (IAT) sensor.

HINT

When any of DTCs P0115, P0117 and P0118 is stored, the ECM enters fail-safe mode. During fail-safe mode, the ECT is estimated to be 80°C (176°F) by the ECM. Fail-safe mode continues until a pass condition is detected.

DTC No.DTC Detection ConditionTrouble Area
P0115An open or short in the Engine Coolant Temperature (ECT) sensor circuit for 0.5 seconds (1 trip detection logic).Open or short in Engine Coolant Temperature (ECT) sensor circuit ECT sensor ECM
P0117A short in the ECT sensor circuit for 0.5 seconds (1 trip detection logic).Short in ECT sensor ECT sensor ECM
P0118An open in the ECT sensor circuit for 0.5 seconds (1 trip detection logic).Open in ECT sensor circuit ECT sensor ECM

HINT

When any of these DTCs is output, check the ECT by entering the following menus: Powertrain / Engine and ECT / Data List / All Data / Coolant Temp.

Temperature DisplayedMalfunction
40°C (-40°F)Open circuit
140°C (284°F) or higherShort circuit

The Engine Coolant Temperature (ECT) sensor is used to monitor the ECT. The ECT sensor has a thermistor with a resistance that varies according to the temperature of the engine coolant. When the coolant temperature is low, the resistance in the thermistor increases. When the temperature is high, the resistance drops. These variations in resistance are reflected in the output voltage from the sensor. The ECM monitors the sensor voltage and uses this value to calculate the ECT. When the sensor output voltage deviates from the normal operating range, the ECM interprets this as a fault in the ECT sensor and stores DTC(s).

Example

If the sensor output voltage is higher than 4.91 V for 0.5 seconds or more, the ECM determines that there is an open in the ECT sensor circuit, and stores DTC P0118. Conversely, if the voltage output is below 0.14 V for 0.5 seconds or more, the ECM determines that there is a short in the sensor circuit, and stores DTC P0117.

If the malfunction is not repaired successfully, a DTC is stored 0.5 seconds after the engine is next started.

Refer to DTC P0115. Refer to «DESCRIPTION».

DTC No.DTC Detection ConditionTrouble Area
P0116When either of the following conditions is met (2 trip detection logic): When a cold engine is started and the engine is warmed up, the Engine Coolant Temperature (ECT) sensor value does not change. After the warmed up engine is stopped and then the next cold engine start is performed, the ECT sensor value does not change.Water inlet sub-assembly with thermostat ECT sensor
P0116For Mexico Models: Case 1: Engine Coolant Temperature (ECT) between 35 and 60°C (95 and 140°F) when engine started, and conditions (a) and (b) met (2 trip detection logic) (a) Vehicle driven at varying speeds (accelerated and decelerated) (b) ECT remains within 3°C (5.4°F) of initial ECT Case 2: ECT more than 60°C (140°F) when engine started, and conditions (a) and (b) met (6 trip detection logic) (a) Vehicle driven at varying speeds (accelerated and decelerated) (b) ECT measurements remain within 1°C (1.8°F) of initial ECT on 6 successive occasionsWater inlet sub-assembly with thermostat ECT sensor

Engine coolant temperature (ECT) sensor cold start monitor

When a cold engine start is performed and then the engine is warmed up, if the ECT sensor value does not change, it is determined that a malfunction has occurred. If this is detected in 2 consecutive driving cycles, the MIL is illuminated and a DTC is stored.

ECT sensor soak monitor

If the ECT sensor value does not change after the warmed up engine is stopped and then the next cold engine start is performed, it is determined that a malfunction has occurred. If this is detected in 2 consecutive driving cycles, the MIL is illuminated and a DTC is stored.

ECT sensor high side stuck monitor (only for Mexico models)

The ECM monitors the sensor voltage and uses this value to calculate the ECT. If the sensor voltage output deviates from the normal operating range, the ECM interprets this deviation as a malfunction in the ECT sensor and stores the DTC.

Examples

  1. Upon starting the engine, the ECT is between 35 and 60°C (95 and 140°F). If after driving for 250 seconds, the ECT remains within 3°C (5.4°F) of the starting temperature, the DTC is stored (2 trip detection logic).
  2. Upon starting the engine, the ECT is over 60°C (140°F).If after driving at varying speeds (accelerating and decelerating) for a specified period of time, the ECT remains within 1°C (1.8°F) of the starting temperature, the DTC is stored (6 trip detection logic).

The engine has two temperature sensors, an Engine Coolant Temperature (ECT) sensor and an Intake Air Temperature (IAT) sensor, to detect the temperature while the engine is in operation. A thermistor, whose resistance value varies according to the temperature, is built into each sensor. When the temperature is low, the resistance of the thermistor increases. When the temperature is high, the resistance drops. These variations in resistance are transmitted to the ECM as voltage changes. Based on these temperature signals output from the sensors, the ECM determines the fuel injection time and the ignition timing to control the engine.

DTC No.DTC Detection ConditionTrouble Area
P011BAll of the following conditions are met (2 trip detection logic): The battery voltage is 10.5 V or higher. 7 hours or more have elapsed from engine stop on the previous trip. 15 seconds after a cold engine start. The minimum Intake Air Temperature (IAT) after the engine starts is higher than -10°C (14°F). The average Engine Coolant Temperature (ECT) before the engine starts is higher than -10°C (14°F). The difference between the readings of ECT and IAT is greater than 20°C (36°F).IAT sensor ECT sensor ECM

Scheme 81

Scheme 81

HINT

  1. Waiting is required to prevent the temperature of the engine from affecting the readings. If the engine has been operated recently, it will not be possible to accurately compare the readings.
  1. For diagnosis, in order to duplicate the detection conditions of the DTC, it is necessary to park the vehicle for 7 hours. Parking the vehicle for 7 hours ensures that the actual temperature of the ECT and IAT are very similar. When the vehicle has been parked for less than 7 hours, differences in the readings may exist, but this does not necessarily indicate a fault.

The ECM monitors the difference between the Engine Coolant Temperature (ECT) and the Intake Air Temperature (IAT) when the engine is started cold to detect the engine temperature conditions accurately. The monitor runs when the engine started cold after 7 hours or more have elapsed since the engine was stopped (engine switch turned off) on the previous trip. If the difference between the ECT and the IAT on a cold start exceeds 20°C (36°F), the ECM interprets this as a malfunction in the ECT sensor circuit and IAT sensor circuit, and stores the DTC.

HINT

  1. These DTCs relate to the Throttle Position (TP) sensor.

The Throttle Position (TP) sensor is mounted on the throttle body, and detects the opening angle of the throttle valve. This sensor is a non-contact type sensor. It uses Hall-effect elements in order to yield accurate signals even in extreme driving conditions, such as at high speeds as well as very low speeds.

The TP sensor has 2 sensor circuits, each of which transmits a signal, VTA1 and VTA2. VTA1 is used to detect the throttle valve angle and VTA2 is used to detect malfunctions in VTA1. The sensor signal voltages vary between 0 V and 5 V in proportion to the throttle valve opening angle, and are transmitted to the VTA terminals of the ECM.

As the valve closes, the sensor output voltage decreases and as the valve opens, the sensor output voltage increases. The ECM calculates the throttle valve opening angle according to these signals and controls the throttle actuator in response to driver inputs. These signals are also used in calculations such as air-fuel ratio correction, power increase correction and fuel-cut control.

Scheme 82

Scheme 82
DTC No.DTC Detection ConditionTrouble Area
P0120The output voltage of VTA1 quickly fluctuates beyond lower and upper malfunction thresholds for 2 seconds or more (1 trip detection logic)Throttle Position (TP) sensor (built into throttle body) ECM
P0121The difference between VTA1 and VTA2 voltages is less than 0.8 V, or more than 1.6 V for 2 seconds or less (1 trip detection logic)TP sensor (built into throttle body) TP sensor circuit ECM
P0122The output voltage of VTA1 is 0.2 V or less for 2 seconds or more (1 trip detection logic)TP sensor (built into throttle body) Short in VTA1 circuit Open in VC circuit ECM
P0123The output voltage of VTA1 is 4.54 V or more for 2 seconds or more (1 trip detection logic)TP sensor (built into throttle body) Open in VTA1 circuit Open in E2 circuit Short between VC and VTA1 circuits ECM
P0220The output voltage of VTA2 quickly fluctuates beyond lower and upper malfunction thresholds for 2 seconds or more (1 trip detection logic)TP sensor (built into throttle body) ECM
P0222The output voltage of VTA2 is 1.75 V or less for 2 seconds or more (1 trip detection logic)TP sensor (built into throttle body) Short in VTA2 circuit Open in VC circuit ECM
P0223The output voltage of VTA2 is 4.8 V or more, and VTA1 is between 0.2 V and 2.02 V for 2 seconds or more (1 trip detection logic)TP sensor (built into throttle body) Open in VTA2 circuit Open in E2 circuit Short between VC and VTA2 circuits ECM
P2135Either condition (a) or (b) is met (1 trip detection logic): (a) The difference between output voltages of VTA1 and VTA2 is 0.02 V or less for 0.5 seconds or more (b) The output voltage of VTA1 is 0.2 V or less and VTA2 is 1.75 V or less for 0.4 seconds or moreShort between VTA1 and VTA2 circuits TP sensor (built into throttle body) ECM

HINT

  1. When any of these DTCs are set, check the throttle valve opening angle using the Techstream. Enter the following menus: Powertrain / Engine and ECT / Data List / Throttle Position No. 1 and Throttle Position No. 2.
  2. Throttle Position No. 1 is the VTA1 signal, and Throttle Position No. 2 is the VTA2 signal.
Tester DisplayAccelerator Pedal Fully ReleasedAccelerator Pedal Fully Depressed
Throttle Position No. 10.5 to 1.1 V3.2 to 4.8 V
Throttle Position No. 22.1 to 3.1 V4.6 to 4.98 V

REFERENCE (NORMAL CONDITION)

P0120, P0122, P0123, P0220, P0223, P2135

The ECM uses the Throttle Position (TP) sensor to monitor the throttle valve opening angle. There are several checks that the ECM performs to confirm the proper operation of the TP sensor.

  1. A specific voltage difference is expected between the sensor terminals, VTA1 and VTA2, for each throttle valve opening angle. If the difference between VTA1 and VTA2 is incorrect, the ECM interprets this as a malfunction in the sensor, and sets a DTC.
  2. VTA1 and VTA2 each have a specific voltage range. If VTA1 or VTA2 is outside the normal operating range, the ECM interprets this as a malfunction in the sensor, and sets a DTC.
  3. VTA1 and VTA2 should never be close to the same voltage level. If VTA1 is within 0.02 V of VTA2, the ECM determines that there is a short circuit in the sensor, and sets a DTC.

If the malfunction is not repaired successfully, a DTC is set 2 seconds after the engine is next started.

P0121

This sensor transmits two signals: VTA1 and VTA2. VTA1 is used to detect the throttle opening angle and VTA2 is used to detect malfunctions in VTA1. The ECM performs several checks to confirm the proper operation of the TP sensor and VTA1.

For each throttle opening angle, a specific voltage difference is expected between the outputs of VTA1 and VTA2. If the output voltage difference between the two signals deviates from the normal operating range, the ECM interprets this as a malfunction in the TP sensor. The ECM illuminates the MIL and stores the DTC.

If the malfunction is not repaired successfully, the DTC is stored 2 seconds after the engine is next started.

  1. Refer to DTC P0115. Refer to «DESCRIPTION». DTC No. DTC Detection Condition Trouble Area P0125 The Engine Coolant Temperature (ECT) does not reach the closed loop enabling temperature for 20 minutes (this period varies with the engine start ECT) (2 trip detection logic). Engine Coolant Temperature (ECT) sensor Cooling system Water inlet sub-assembly with thermostat

The resistance of the ECT sensor varies in proportion to the actual ECT. The ECT supplies a constant voltage to the sensor and monitors the signal output voltage of the sensor. The signal output voltage varies according to the changing resistance of the sensor. After the engine is started, the ECT is monitored through this signal. If the ECT sensor indicates that the engine is not yet warm enough for closed loop fuel control, despite a specified period of time having elapsed since the engine was started, the ECM interprets this as a malfunction in the sensor or cooling system and stores the DTC.

Example

The ECT is -5°C (23°F) at engine start. After about 1 minute of running time, the ECT sensor still indicates that the engine is not warm enough to begin closed loop fuel (air-fuel ratio feedback) control. The ECM interprets this as a malfunction in the sensor or cooling system and stores the DTC.

This DTC is stored when the Engine Coolant Temperature (ECT) does not reach 75°C (167°F) despite sufficient engine warm-up time having elapsed.

DTC No.DTC Detection ConditionTrouble Area
P0128Conditions (a), (b) and (c) are met for 5 seconds (2 trip detection logic): (a) Cold start. (b) The engine is warmed up. (c) The ECT is below 75°C (167°F).Water inlet sub-assembly with thermostat Cooling system ECT sensor ECM

Scheme 83

Scheme 83: MONITOR DESCRIPTION

The ECM estimates the ECT based on the starting temperature, engine loads, and engine speeds. The ECM then compares the estimated temperature with the actual ECT. When the estimated ECT reaches 75°C (167°F), the ECM checks the actual ECT. If the actual ECT is below 75°C (167°F), the ECM interprets this as a malfunction in the thermostat or the engine cooling system and stores the DTC.

A three-way catalytic converter (TWC) is used in order to convert the carbon monoxide (CO), hydrocarbon (HC), and nitrogen oxides (NOx) into less harmful substances. To allow the TWC to function effectively, it is necessary to keep the air-fuel ratio of the engine near the stoichiometric air-fuel ratio. For helping the ECM to deliver accurate air-fuel ratio control, a Heated Oxygen (HO2) sensor becomes used.

The HO2 sensor is located behind the TWC, and detects the oxygen concentration in the exhaust gas. Since the sensor is integrated with the heater that heats the sensing portion, it is possible to detect the oxygen concentration even when the intake air volume is low (the exhaust gas temperature is low).

When the air-fuel ratio becomes lean, the oxygen concentration in the exhaust gas becomes rich. The HO2 sensor informs the ECM that the post-TWC air-fuel ratio is lean (low voltage, i.e. less than 0.45 V).

Conversely, when the air-fuel ratio is richer than the stoichiometric air-fuel level, the oxygen concentration in the exhaust gas becomes lean. The HO2 sensor informs the ECM that the post-TWC air-fuel ratio is rich (high voltage, i.e. more than 0.45 V). The HO2 sensor has the property of changing its output voltage drastically when the air-fuel ratio is close to the stoichiometric level.

The ECM uses the supplementary information from the HO2 sensor to determine whether the air-fuel ratio after the TWC is rich or lean, and adjusts the fuel injection time accordingly. Thus, if the HO2 sensor is working improperly due to internal malfunctions, the ECM is unable to compensate for deviations in the primary air-fuel ratio control.

Scheme 84

Scheme 84: DESCRIPTION
DTC No.DTC Detection ConditionTrouble Area
P0136 P0156Abnormal voltage is output: During active air-fuel ratio control, the following conditions (a) and (b) are met for a certain period of time (2 trip detection logic): (a) The Heated Oxygen (HO2) sensor voltage does not decrease to below 0.59 V. (b) The HO2 sensor voltage does not increase to higher than 0.21 V. Low impedance: The sensor impedance is below 5 ohms for more than 30 seconds when the ECM presumes the sensor to be warmed up and operating normally (2 trip detection logic).Open or short in Heated Oxygen (HO2) sensor (for Bank 1, 2) circuit HO2 sensor (for Bank 1, 2) HO2 sensor heater (for Bank 1, 2) Air-fuel Ratio (A/F) sensor (for Bank 1, 2) Integration relay Gas leak from exhaust system
P0137 P0157Low voltage (open): During active air-fuel ratio control, the following conditions (a) and (b) are met for a certain period of time (2 trip detection logic): (a) The HO2 sensor voltage output is below 0.21 V. (b) The target air-fuel ratio is rich. High impedance: The sensor impedance is 15 kohms or higher for more than 90 seconds when the ECM presumes the sensor to be warmed up and operating normally (2 trip detection logic).Open in HO2 sensor (for Bank 1, 2) circuit HO2 sensor (for Bank 1, 2) HO2 sensor heater (for Bank 1, 2) Integration relay Gas leak from exhaust system Air fuel ratio sensor
P0138 P0158High voltage (short): During active air-fuel ratio control, the following conditions (a) and (b) are met for a certain period of time (2 trip detection logic): (a) The HO2 sensor voltage output is higher than 0.59 V. (b) The target air-fuel ratio is lean. Extremely high voltage (short): The HO2 sensor voltage output exceeds 1.2 V for more than 10 seconds (2 trip detection logic).Short in HO2 sensor (for Bank 1, 2) circuit HO2 sensor (for Bank 1, 2) Air-Fuel ratio (A/F) sensor (for Bank 1, 2) ECM
P0139 P0159HO2 sensor voltage does not drop below 0.2 V immediately after fuel cut starts (2 trip detection logic). HO2 sensor voltage does not drop from 0.35 V to 0.2 V immediately after fuel cut starts (2 trip detection logic).Short in HO2 sensor (for Bank 1, 2 Sensor 2) circuit HO2 sensor (for Bank 1, 2 Sensor 2) ECM
DTC No.DTC Detection ConditionTrouble Area
P0136 P0156Not applicableNone
P0137 P0157Low voltage (open): During active air-fuel ratio control, following conditions (a) and (b) are met for a certain period of time (2 trip detection logic) (a) HO2 sensor voltage output less than 0.21 V (b) Target air-fuel ratio richOpen in HO2 sensor (bank 1, 2 sensor 2) circuit HO2 sensor (bank 1, 2 sensor 2) HO2 sensor heater (bank 1, 2 sensor 2) Integration relay Gas leak from exhaust system
P0138 P0158Not applicableNone
P0139 P0159Not applicableNone

FOR MEXICO MODELS

Active Air-Fuel Ratio Control

The ECM usually performs air-fuel ratio feedback control so that the Air-Fuel Ratio (A/F) sensor output indicates a near stoichiometric air-fuel level. This vehicle includes active air-fuel ratio control in addition to regular air-fuel ratio control. The ECM performs active air-fuel ratio control to detect any deterioration in the Three-Way Catalytic Converter (TWC) and Heated Oxygen (HO2) sensor malfunctions (refer to the diagram below).

Active air-fuel ratio control is performed for approximately 15 to 20 seconds while driving with a warm engine. During active air-fuel ratio control, the air-fuel ratio is forcibly regulated to become lean or rich by the ECM. If the ECM detects a malfunction, a DTC is stored.

Abnormal Voltage Output of HO2 Sensor (DTC P0136 and P0156)

While the ECM is performing active air-fuel ratio control, the air-fuel ratio is forcibly regulated to become rich or lean. If the sensor is not functioning properly, the voltage output variation is small. For example, when the HO2 sensor voltage does not decrease to below 0.21 V and does not increase to higher than 0.59 V during active air-fuel ratio control, the ECM determines that the sensor voltage output is abnormal and stores DTC P0136 or P0156.

Scheme 85

Scheme 85: MONITOR DESCRIPTION

Open or Short in Heated Oxygen (HO2) Sensor Circuit (DTC P0137 and P0157 or P0138 and P0158)

During active air-fuel ratio control, the ECM calculates the Oxygen Storage Capacity (OSC)* of the Three-Way Catalytic Converter (TWC) by forcibly regulating the air-fuel ratio to become rich or lean. If the HO2 sensor has an open or short, or the voltage output of the sensor decreases significantly, the OSC indicates an extraordinarily high value. Even if the ECM attempts to continue regulating the air-fuel ratio to become rich or lean, the HO2 sensor output does not change.

While performing active air-fuel ratio control, when the target air-fuel ratio is rich and the HO2 sensor voltage output is less than 0.21 V (lean), the ECM interprets this as an abnormally low sensor output voltage and stores DTC P0137 or P0157. When the target air-fuel ratio is lean and the voltage output is more than 0.59 V (rich) during active air-fuel ratio control, the ECM determines that the sensor voltage output is abnormally high, and stores DTC P0138 or P0158.

HINT

DTC P0138 or P0158 is also stored if the HO2 sensor voltage output is 1.2 V or more for 10 seconds or more.

*: The TWC has the capability to store oxygen. The OSC and the emission purification capacity of the TWC are mutually related. The ECM determines whether the catalyst has deteriorated based on the calculated OSC value. Refer to «DTC P0420: Catalyst System Efficiency Below Threshold (Bank 1); DTC P0430: Catalyst System Efficiency Below Threshold (Bank 2)».

Scheme 86

Scheme 86

High or Low Impedance of Heated Oxygen (HO2) Sensor (DTC P0136 and P0156 or P0137 and P157)

Scheme 87

Scheme 87

During normal air-fuel ratio feedback control, there are small variations in the exhaust gas oxygen concentration. In order to continuously monitor the slight variations in the HO2 sensor signal while the engine is running, the impedance* of the sensor is measured by the ECM. The ECM determines that there is a malfunction in the sensor when the measured impedance deviates from the standard range.

*: The effective resistance in an alternating current electrical circuit.

HINT

  1. The impedance cannot be measured using an ohmmeter.
  2. DTC P0136 and P0156 indicate the deterioration of the HO2 sensor. The ECM stores this DTC by calculating the impedance of the sensor when the typical enabling conditions are satisfied (2 driving cycles).
  3. DTC P0137 and P0157 indicate an open or short circuit in the HO2 sensor (2 driving cycles). The ECM stores this DTC when the impedance of the sensor exceeds the threshold 15 kohms.

HO2 sensor output voltage during fuel cut (P0139 or P0159)

The sensor output voltage drops to below 0.2 V (extremely lean status) immediately when the vehicle decelerates and fuel cut is operating. If the voltage does not drop to below 0.2 V when accumulated intake air mass is more than 16.6 g, or does not drop from 0.35 V to 0.2 V within 1 second, the ECM determines that the sensor response has deteriorated, illuminates the MIL and stores a DTC.

HINT

  1. Refer to DTC P2195. Refer to «DESCRIPTION»(/lexus/lx/j200-2012-2015/remont/testing-diagnostics/#engine-control-system-diagnostic-codes-p1604-p2610-circuit-tests) .
  2. Sensor 1 refers to the sensor mounted in front of the three-way catalytic converter and located near the engine assembly.
DTC No.DTC Detection ConditionTrouble Area
P014C P014EThe "Rich to Lean response rate deterioration level*" value is standard or less (2 trip detection logic).Air fuel ratio sensor (sensor 1) Air fuel ratio sensor (sensor 1) heater ECM
P014D P014FThe "Lean to Rich response rate deterioration level*" value is standard or more (2 trip detection logic).
P015A P015CThe "Rich to Lean delay level*" value is standard or more (2 trip detection logic).
P015B P015DThe "Lean to Rich delay level*" value is standard or more (2 trip detection logic).
  1. *: Calculated by ECM based on the air fuel ratio sensor output.

After the engine is warmed up, the ECM carries out air-fuel ratio feedback control, and maintains the air-fuel ratio at the theoretical level. In addition, after all the preconditions have been met, active air-fuel ratio control is carried out for approximately 10 seconds, and during active air-fuel ratio control, the ECM measures the response of the air fuel ratio sensor by increasing or decreasing a specific injection volume based on the theoretical air-fuel ratio learned during normal air-fuel control. The ECM determines whether there is an air fuel ratio sensor malfunction at the mid-point of active air-fuel ratio control.

If the air fuel ratio sensor's response ability is reduced, DTCs P014C P014D, P014E and P014F are stored.

If the time it takes the air fuel ratio sensor output to change is delayed, DTCs P015A, P015B, P015C and P015D are stored.

Scheme 88

Scheme 88: MONITOR DESCRIPTION

The fuel trim is related to the feedback compensation value, not to the basic injection time. The fuel trim consists of both the short-term and the long-term fuel trims.

The short-term fuel trim is fuel compensation that is used to constantly maintain the air-fuel ratio at stoichiometric levels. The signal from the Air-Fuel Ratio (A/F) sensor indicates whether the air-fuel ratio is rich or lean compared to the stoichiometric ratio. This triggers a reduction in the fuel injection volume if the air-fuel ratio is rich and an increase in the fuel injection volume if it is lean.

Factors such as individual engine differences, wear over time and changes in operating environment cause short-term fuel trim to vary from the central value. The long-term fuel trim, which controls overall fuel compensation, compensates for long-term deviations in the fuel trim from the central value caused by the short-term fuel trim compensation.

DTC No.DTC Detection ConditionTrouble Area
P0171 P0174With a warm engine and stable air-fuel ratio feedback, the fuel trim is considerably in error to the lean side (2 trip detection logic).Air induction system Injector blockage Mass Air Flow (MAF) meter Engine Coolant Temperature (ECT) sensor Fuel pressure Gas leak from exhaust system Open or short in Air-Fuel Ratio (A/F) sensor (for Sensor 1) circuit A/F sensor (for Sensor 1) A/F sensor heater (for Sensor 1) Integration relay A/F sensor heater and integration relay circuits PCV valve and hose PCV hose connections ECM Wire harness or connector
P0172 P0175With a warm engine and stable air-fuel ratio feedback, the fuel trim is considerably in error to the rich side (2 trip detection logic).Injector leakage or blockage MAF meter ECT sensor Ignition system Fuel pressure Gas leak from exhaust system Open or short in A/F sensor (for Sensor 1) circuit A/F sensor (for Sensor 1) A/F sensor heater (for Sensor 1) Integration relay A/F sensor heater and integration relay circuits ECM Wire harness or connector

HINT

  1. When DTC P0171 or P0174 is stored, the actual air-fuel ratio is on the lean side. When DTC P0172 or P0175 is stored, the actual air-fuel ratio is on the rich side.
  2. If the vehicle runs out of fuel, the air-fuel ratio is lean and DTC P0171 or P0174 may be stored. The MIL is then illuminated.
  3. When the total of the short-term and long-term fuel trim values is within the malfunction threshold (and the engine coolant temperature is higher than 75°C [167°F]), the system is functioning normally.

Under closed loop fuel control, fuel injection volumes that deviate from those estimated by the ECM cause changes in the long-term fuel trim compensation value. The long-term fuel trim is adjusted when there are persistent deviations in the short-term fuel trim values. Deviations from the ECM estimated fuel injection volumes also affect the average fuel trim learning value, which is a combination of the average short-term fuel trim (fuel feedback compensation value) and the average long-term fuel trim (learning value of the air-fuel ratio). If the average fuel trim learning value exceeds the malfunction threshold, the ECM interprets this as a fault in the fuel system and stores DTC(s).

Example

The average fuel trim learning value is +35% or more or -35% or less, the ECM interprets this as a fuel system malfunction.

Scheme 89

Scheme 89: MONITOR DESCRIPTION

The ECM illuminates the MIL and stores a DTC when either one of the following conditions, which could cause emission deterioration, is detected (2 trip detection logic).

  1. Within the first 1000 crankshaft revolutions of the engine starting, an excessive misfiring rate (approximately 20 to 50 misfires per 1000 crankshaft revolutions) occurs once.
  2. An excessive misfiring rate (approximately 20 to 50 misfires per 1000 crankshaft revolutions) occurs a total of 4 times.

The ECM flashes the MIL (immediate detection logic) and stores a DTC (2 trip detection logic) when either one of the following conditions, which could cause the Three-Way Catalytic Converter (TWC) damage, is detected.

  1. At a high engine speed, a catalyst damage misfire, which is monitored every 200 crankshaft revolutions, occurs once.
  2. At a normal engine speed, a catalyst damage misfire, which is monitored every 200 crankshaft revolutions, occurs 3 times.

HINT

If a catalyst damage misfire occurs, the ECM informs the driver by flashing the MIL.

Misfire Monitor for Mexico Models

The ECM illuminates the MIL and sets a DTC when either one of the following conditions, which could cause emission deterioration, is detected (2 trip detection logic).

  1. Within the first 1000 crankshaft revolutions of the engine starting, an excessive misfiring rate (approximately 250 misfires per 1000 crankshaft revolutions) occurs once.
  2. An excessive misfiring rate (approximately 125 misfires per 1000 crankshaft revolutions) occurs a total of 4 times.

The ECM flashes the MIL and sets a DTC when the following condition, which could cause the Three-Way Catalytic Converter (TWC) damage, is detected (2 trip detection logic).

  1. A catalyst damage misfire, which is monitored every 200 crankshaft revolutions, occurs 3 times.

A flat type knock sensor (non-resonant type) has a structure that can detect vibrations between approximately 5 kHz and 15 kHz.

Knock sensors are fitted onto the engine block to detect engine knocking.

The knock sensor contains a piezoelectric element which generates a voltage when it becomes deformed.

The voltage is generated when the engine block vibrates due to knocking. Any occurrence of engine knocking can be suppressed by delaying the ignition timing.

DTC No.DTC Detection ConditionTrouble Area
P0327The output voltage of the knock sensor (for Bank 1 Sensor 1) is less than 0.5 V (1 trip detection logic).Short in knock sensor (for Bank 1 Sensor 1) circuit Knock sensor (for Bank 1 Sensor 1) ECM
P0328The output voltage of the knock sensor (for Bank 1 Sensor 1) is more than 4.5 V (1 trip detection logic).Open in knock sensor (for Bank 1 Sensor 1) circuit Knock sensor (for Bank 1 Sensor 1) ECM
P0332The output voltage of the knock sensor (for Bank 2 Sensor 1) is less than 0.5 V (1 trip detection logic).Short in knock sensor (for Bank 2 Sensor 1) circuit Knock sensor (for Bank 2 Sensor 1) ECM
P0333The output voltage of the knock sensor (for Bank 2 Sensor 1) is more than 4.5 (1 trip detection logic).Open in knock sensor (for Bank 2 Sensor 1) circuit Knock sensor (for Bank 2 Sensor 1) ECM
P032CThe output voltage of the knock sensor (for Bank 1 Sensor 2) is less than 0.5 V (1 trip detection logic).Short in knock sensor (for Bank 1 Sensor 2) circuit Knock sensor (for Bank 1 Sensor 2) ECM
P032DThe output voltage of the knock sensor (for Bank 1 Sensor 2) is more than 4.5 (1 trip detection logic).Open in knock sensor (for Bank 1 Sensor 2) circuit Knock sensor (for Bank 1 Sensor 2) ECM
P033CThe output voltage of the knock sensor (for Bank 2 Sensor 2) is less than 0.5 V (1 trip detection logic).Short in knock sensor (for Bank 2 Sensor 2) circuit Knock sensor (for Bank 2 Sensor 2) ECM
P033DThe output voltage of the knock sensor (for Bank 2 Sensor 2) is more than 4.5 (1 trip detection logic).Open in knock sensor (for Bank 2 Sensor 2) circuit Knock sensor (for Bank 2 Sensor 2) ECM

HINT

When any of DTCs P0327, P0328, P0332, P0333, P032C, P032D, P033C and P033D is stored, the ECM enters fail-safe mode. During fail-safe mode, the ignition timing is delayed to its maximum retardation. Fail-safe mode continues until the engine switch is turned off.

Reference: Inspection using an oscilloscope

Scheme 90

Scheme 90

Standard

Tester ConnectionTool SettingConditionSpecified Condition
C53-94 (KNK1) - C53-93 (EKNK)0.01 to 10 V/DIV. 0.01 to 10 msec./DIV.Keep engine speed at 4000 rpm with warm engineThe correct waveform is as shown
C53-117 (KNK2) - C53-116 (EKN2)0.01 to 10 V/DIV. 0.01 to 10 msec./DIV.Keep engine speed at 4000 rpm with warm engineThe correct waveform is as shown
C53-96 (KNK3) - C53-95 (EKN3)0.01 to 10 V/DIV. 0.01 to 10 msec./DIV.Keep engine speed at 4000 rpm with warm engineThe correct waveform is as shown
C53-119 (KNK4) - C53-118 (EKN4)0.01 to 10 V/DIV. 0.01 to 10 msec./DIV.Keep engine speed at 4000 rpm with warm engineThe correct waveform is as shown

The knock sensor, located on the cylinder block, detects spark knock. When spark knock occurs, the piezoelectric element of the sensor vibrates. When the ECM detects a voltage in this frequency range, it retards the ignition timing to suppress the spark knock.

The ECM also senses background engine noise with the knock sensor and uses this noise to check for faults in the sensor. If the knock sensor signal level is too low for more than 10 seconds, or if the knock sensor output voltage is outside the normal range, the ECM interprets this as a fault in the knock sensor and stores DTC(s).

The crankshaft position (CKP) sensor system consists of a crankshaft position sensor plate and Magnetic Resistance Element (MRE) type sensor. The crankshaft position sensor plate has 34 teeth at 10° intervals (2 teeth are missing for detecting top dead center), and is installed to the rear end of the crankshaft. The crankshaft position sensor outputs 34 rotation signals per crankshaft revolution. The ECM uses the G2 signal to distinguish between the cylinders, and uses the NE signal to detect the crankshaft position and engine speed.

DTC No.DTC Detection ConditionTrouble Area
P0335No Crankshaft Position (CKP) sensor signal is sent to the ECM while cranking (1 trip detection logic). No CKP sensor signal is sent to the ECM at an engine speed of 450 rpm or more (1 trip detection logic).Open or short in Crankshaft Position (CKP) sensor circuit CKP sensor CKP sensor plate ECM
P0337The output voltage of the CKP sensor is less than 0.3 V for 4 seconds (1 trip detection logic).Open or short in CKP sensor circuit CKP sensor CKP sensor plate ECM
P0338The output voltage of the CKP sensor is more than 4.7 V for 4 seconds (1 trip detection logic).Open or short in CKP sensor circuit CKP sensor CKP sensor plate ECM
P0339Under conditions (a), (b) and (c), no CKP sensor signal is sent to the ECM for 0.05 seconds or more (1 trip detection logic): (a) The engine speed is 1000 rpm or more. (b) The starter signal is OFF. (c) 3 seconds or more have elapsed since the starter signal was switched from ON to OFF.Open or short in CKP sensor circuit CKP sensor CKP sensor plate ECM

Scheme 91

Scheme 91
  1. Reference: Inspection using an oscilloscope. Standard Tester Connection Tool Setting Condition Specified Condition C53-110 (NE+) - C53-111 (NE-) 5 V/DIV., 20 msec./DIV. Cranking or idling The correct waveform is as shown C53-90 (G2) - C53-89 (G2-) 5 V/DIV., 20 msec./DIV. Cranking or idling The correct waveform is as shown HINT: G2 stands for the camshaft position sensor signal, and NE stands for the crankshaft position sensor signal.

If there is no signal from the crankshaft position sensor despite the crankshaft revolving, the ECM interprets this as a malfunction of the sensor.

When the sensor output voltage remains at less than 0.3 V, or more than 4.7 V for more than 4 seconds, the ECM stores DTC(s).

The intake camshaft Variable Valve Timing (VVT) sensor (VV1, 2 signal) consists of a magnet and MRE (Magnetic Resistance Element).

The intake camshaft has 3 teeth on its outer circumference. When the intake camshaft rotates, changes occur in the air gaps between teeth and MRE, which affect the magnetic field. As a result, the resistance of the MRE material fluctuates. The VVT sensor converts the intake camshaft rotation data into pulse signals, uses the pulse signals to determine the camshaft angle, and sends it to the ECM.

The crankshaft position sensor plate has 34 teeth. The crankshaft position sensor generates 34 signals for each crankshaft revolution. Based on a combination of the VVT signal and NE signal, the ECM detects the crankshaft angle. Then the ECM uses this data to control fuel injection time and injection timing. Also, based on the NE signal, the ECM detects the engine speed.

DTC No.DTC Detection ConditionTrouble Area
P0340 P0345No VVT sensor signal to ECM at engine speed of 600 rpm or more (1 trip detection logic).Open or short in VVT sensor (for intake side) circuit VVT sensor (for intake side) Intake camshaft (for Bank 1, 2) Jumped tooth of timing chain ECM
P0342 P0347The output voltage of the VVT sensor (for intake side of Bank 1, 2) is below 0.3 V for 4 seconds (1 trip detection logic).Open or short in VVT sensor (for intake side) circuit VVT sensor (for intake side) Intake camshaft (for Bank 1, 2) Jumped tooth of timing chain ECM
P0343 P0348The output voltage of the VVT sensor (for intake side of Bank 1, 2) is higher than 4.7 V for 4 seconds (1 trip detection logic).Open or short in VVT sensor (for intake side) circuit VVT sensor (for intake side) Intake camshaft (for Bank 1, 2) Jumped tooth of timing chain ECM

Scheme 92

Scheme 92
  1. Reference: Inspection using an oscilloscope Standard Tester Connection Tool Setting Condition Specified Condition C53-110 (NE+) - C53-111 (NE-) 5 V/DIV. 20 msec./DIV. Cranking or idling The correct waveform is as shown C53-92 (VV1+) - C53-91 (VV1-) 5 V/DIV. 20 msec./DIV. Cranking or idling The correct waveform is as shown C53-87 (VV2+) - C53-88 (VV2-) 5 V/DIV. 20 msec./DIV. Cranking or idling The correct waveform is as shown HINT: VV1+ and VV2+ stand for the VVT sensor (for intake side) signal, and NE+ stands for the CKP sensor signal.

If no signal is transmitted by the VVT sensor despite the camshaft revolving, or the rotations of the camshaft and the crankshaft are not synchronized, the ECM interprets this as a malfunction of the sensor.

HINT

  1. These DTCs indicate malfunctions relating to the primary circuit.
  2. If DTC P0351 is output, check the No. 1 ignition coil circuit.
  3. If DTC P0352 is output, check the No. 2 ignition coil circuit.
  4. If DTC P0353 is output, check the No. 3 ignition coil circuit.
  5. If DTC P0354 is output, check the No. 4 ignition coil circuit.
  6. If DTC P0355 is output, check the No. 5 ignition coil circuit.
  7. If DTC P0356 is output, check the No. 6 ignition coil circuit.
  8. If DTC P0357 is output, check the No. 7 ignition coil circuit.
  9. If DTC P0358 is output, check the No. 8 ignition coil circuit.

A Direct Ignition System (DIS) is used on this vehicle.

The DIS is a 1-cylinder ignition system in which each cylinder is ignited by one ignition coil and one spark plug is connected to the end of each secondary wiring. A powerful voltage, generated in the secondary wiring, is applied directly to each spark plug. The sparks of the spark plugs pass from the center electrode to the ground electrodes.

The ECM determines the ignition timing and transmits the ignition (IGT) signals to each cylinder. Using the IGT signal, the ECM turns the power transistor inside the igniter on and off. The power transistor, in turn, switches on and off the current to the primary coil. When the current to the primary coil is cut off, a powerful voltage is generated in the secondary coil. This voltage is applied to the spark plugs, causing them to spark inside the cylinders. As the ECM cuts the current to the primary coil, the igniter sends back an ignition confirmation (IGF) signal to the ECM for each cylinder ignition.

Scheme 93

Scheme 93
DTC No.DTC Detection ConditionTrouble Area
P0351 P0352 P0353 P0354 P0355 P0356 P0357 P0358No IGF signal is sent to the ECM while the engine is running (1 trip detection logic).Ignition system Open or short in IGF (1 or 2) or IGT circuit (1 to 8) between ignition coil and ECM No. 1 to No. 8 ignition coils ECM
  1. Reference: Inspection using an oscilloscope.
  2. Standard Tester Connection Tool Setting Condition Specified Condition C53-40 (IGT1) - C53-81 (E1) 2 V/DIV., 20 msec./DIV. Idling The correct waveform is as shown C53-33 (IGT2) - C53-81 (E1) 2 V/DIV., 20 msec./DIV. Idling The correct waveform is as shown C53-37 (IGT3) - C53-81 (E1) 2 V/DIV., 20 msec./DIV. Idling The correct waveform is as shown C53-34 (IGT4) - C53-81 (E1) 2 V/DIV., 20 msec./DIV. Idling The correct waveform is as shown C53-35 (IGT5) - C53-81 (E1) 2 V/DIV., 20 msec./DIV. Idling The correct waveform is as shown C53-36 (IGT6) - C53-81 (E1) 2 V/DIV., 20 msec./DIV. Idling The correct waveform is as shown C53-38 (IGT7) - C53-81 (E1) 2 V/DIV., 20 msec./DIV. Idling The correct waveform is as shown C53-39 (IGT8) - C53-81 (E1) 2 V/DIV., 20 msec./DIV. Idling The correct waveform is as shown C53-104 (IGF1) - C53-81 (E1) 2 V/DIV., 20 msec./DIV. Idling The correct waveform is as shown C53-105 (IGF2) - C53-81 (E1) 2 V/DIV., 20 msec./DIV. Idling The correct waveform is as shown HINT: While cranking or idling the engine, check the waveform between terminals IGT (1 to 8) and E1, and IGF1 or IGF2 and E1 of the ECM connector.

Scheme 94

Scheme 94: MONITOR DESCRIPTION

If the ECM does not receive any IGF signals despite transmitting the IGT signal, it interprets this as a fault in the igniter and stores DTC(s).

If the malfunction is not repaired successfully, a DTC is stored 1 second after the engine is next started.

The exhaust camshaft Variable Valve Timing (VVT) sensor (EV1, 2 signal) consists of a magnet and MRE (Magnetic Resistance Element).

The exhaust camshaft has 3 teeth on its outer circumference. When the exhaust camshaft rotates, changes occur in the air gaps between the teeth and MRE, which affect the magnet. As a result, the resistance of the MRE material fluctuates. The VVT sensor converts the exhaust camshaft rotation data into pulse signals, uses the pulse signals to determine the camshaft angle, and sends it to the ECM.

DTC No.DTC Detection ConditionTrouble Area
P0365 P0390No VVT sensor signal to ECM at engine speed of 600 rpm or more (1 trip detection logic)Open or short in VVT sensor (for exhaust side) circuit VVT sensor (for exhaust side) Exhaust camshaft Jumped tooth of timing chain ECM
P0367 P0392The output voltage of the VVT sensor is below 0.3 V for 4 seconds (1 trip detection logic).Open or short in VVT sensor (for exhaust side) circuit VVT sensor (for exhaust side) Exhaust camshaft Jumped tooth of timing chain ECM
P0368 P0393The output voltage of the VVT sensor is higher than 4.7 V for 4 seconds (1 trip detection logic).Open or short in VVT sensor (for exhaust side) circuit VVT sensor (for exhaust side) Exhaust camshaft Jumped tooth of timing chain ECM

Scheme 95

Scheme 95
  1. Reference: Inspection using an oscilloscope Standard Tester Connection Tool Setting Condition Specified Condition C53-110 (NE+) - C53-111 (NE-) 5 V/DIV. 20 msec./DIV. Cranking or idling The correct waveform is as shown C53-69 (EV1+) - C53-68 (EV1-) 5 V/DIV. 20 msec./DIV. Cranking or idling The correct waveform is as shown C53-64 (EV2+) - C53-65 (EV2-) 5 V/DIV. 20 msec./DIV. Cranking or idling The correct waveform is as shown HINT: EV1+ and EV2+ stand for the VVT sensor (for exhaust side) signal, and NE+ stands for the CKP sensor signal.

If no signal is transmitted by the VVT sensor despite the camshaft revolving, or the rotations of the camshaft and the crankshaft are not synchronized, the ECM interprets this as a malfunction of the sensor.

The Secondary Air Injection (AIR) system consists of an air pump, the Air Switching Valve (ASV), a pressure sensor, the Air Injection Control Driver (AID) and the ECM. For a short time after a cold engine start, the AIR system pumps secondary air to the exhaust port of the cylinder head to purify the exhaust emissions. The secondary air is supplied by the air pump and is pumped to the exhaust port through the ASV.

The AID drives the ASV and the air pump according to command signals transmitted by the ECM. The pressure sensor detects the pressure in the secondary air passage when the AIR system is ON and OFF, and transmits a pressure signal to the ECM.

The AID is not only equipped to drive the pump and valve, but also with a diagnosis function to detect malfunctions in the AIR system circuit.

HINT

As a large current is required to drive the air pump and ASV, an AID is installed to this system.

Scheme 96

Scheme 96: DESCRIPTION
DTC No.DTC Detection ConditionTrouble Area
P0412 P0415After a cold engine start, all of the following conditions are met (1 trip detection logic): The Secondary Air Injection (AIR) system is not operating (air pump OFF, Air Switching Valve [ASV] OFF). The diagnostic signal from the Air Injection Control Driver (AID) is 40%. The battery voltage is 8 V or higher.Open in Air Switching Valve (ASV) drive circuit Air Injection Control Driver (AID) Air Switching Valve (ASV) ECM
P0412 P0415After a cold engine start, all of the following conditions are met (1 trip detection logic): The Secondary Air Injection (AIR) system is operating (air pump ON, Air Switching Valve [ASV] ON). The diagnostic signal from the Air Injection Control Driver (AID) is 40%. The battery voltage is 8 V or higher.Short between ASV drive circuit and body ground AID ASV ECM

The Air Injection Control Driver (AID) detects open and short circuits according to the voltages of the air pump terminal (VP) and the Air Switching Valve (ASV) terminal (VV), and transmits diagnostic information as a signal to the ECM.

For a short time after a cold engine start, the ECM transmits command signals to the AID to drive the air pump and ASV.

The AID transmits an ASV malfunction signal to the ECM if either of the following conditions is met

  1. The voltage at the AID terminal relating to the ASV is low despite the AID receiving command signals from the ECM to drive the ASV.
  2. The voltage at the AID terminal relating to the ASV is high despite the AID receiving no command signals from the ECM to drive the ASV.

The ECM stores the DTC based on diagnostic signals from the AID.