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Engine Control (Diagnostic Codes (P0010-P011B): Overview Lexus RX III

Testing & Diagnostics 7 illustrations ~9187 words

DESCRIPTION

The Variable Valve Timing (VVT) system includes the ECM, camshaft timing oil control valve assembly and VVT controller. The ECM sends a target duty-cycle control signal to the camshaft timing oil control valve assembly. This control signal regulates the oil pressure supplied to the VVT controller. Camshaft timing control is performed according to engine operating conditions such as intake air volume, throttle valve position and engine coolant temperature. The ECM controls the camshaft timing oil control valve assembly, based on the signals transmitted from several sensors. The VVT controller regulates the intake camshaft angle using oil pressure through the camshaft timing oil control valve assembly. 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.

Scheme 145

Scheme 145: DESCRIPTION
DTC No.DTC Detection ConditionTrouble Area
P0010Open or short in camshaft timing oil control valve assembly for intake camshaft (bank 1) circuit (1 trip detection logic)Open or short in camshaft timing oil control valve assembly for intake camshaft (bank 1) circuit Camshaft timing oil control valve assembly for intake camshaft (bank 1) ECM
P0020Open or short in camshaft timing oil control valve assembly for intake camshaft (bank 2) circuit (1 trip detection logic)Open or short in camshaft timing oil control valve assembly for intake camshaft (bank 2) circuit Camshaft timing oil control valve assembly for intake camshaft (bank 2) ECM

MONITOR DESCRIPTION

This DTC is designed to detect an open or short in the camshaft timing oil control valve assembly circuit. If the oil control valve duty-cycle is excessively high or low while the engine is running, the ECM will illuminate the MIL and set the DTC.

The Variable Valve Timing (VVT) system includes the ECM, camshaft timing oil control valve assembly and VVT controller. The ECM sends a target duty-cycle control signal to the camshaft timing oil control valve assembly. This control signal regulates the oil pressure supplied to the VVT controller. Camshaft timing control is performed according to engine operating conditions such as intake air volume, throttle valve position and engine coolant temperature. The ECM controls the camshaft timing oil control valve assembly, based on the signals transmitted from several sensors. The VVT controller regulates the intake camshaft angle using oil pressure through the camshaft timing oil control valve assembly. 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
P0010Open or short in camshaft timing oil control valve assembly for intake camshaft (bank 1) circuit (1 trip detection logic)Open or short in camshaft timing oil control valve assembly for intake camshaft (bank 1) circuit Camshaft timing oil control valve assembly for intake camshaft (bank 1) ECM
P0020Open or short in camshaft timing oil control valve assembly for intake camshaft (bank 2) circuit (1 trip detection logic)Open or short in camshaft timing oil control valve assembly for intake camshaft (bank 2) circuit Camshaft timing oil control valve assembly for intake camshaft (bank 2) ECM

This DTC is designed to detect an open or short in the camshaft timing oil control valve assembly circuit. If the oil control valve duty-cycle is excessively high or low while the engine is running, the ECM will illuminate the MIL and set the DTC.

Refer to DTC P0010. Refer to DESCRIPTION .

DTC No.DTC Detection ConditionTrouble Area
P0011 P0021Valve timing is not adjusted in valve timing advance range (1 trip detection logic)Valve timing Camshaft timing oil control valve assembly for intake camshaft (bank 1, 2) Oil control valve filter (bank 1, 2) Camshaft timing gear assembly ECM
P0012 P0022Valve timing is not adjusted in valve timing retard range (2 trip detection logic)Valve timing Camshaft timing oil control valve assembly for intake camshaft (bank 1, 2) Oil control valve filter (bank 1, 2) Camshaft timing gear assembly ECM
  1. The ECM optimizes the intake valve timing using the Variable Valve Timing (VVT) system to control the intake camshaft. The VVT system includes the ECM, the camshaft timing oil control valve assembly and the VVT controller.
  2. The ECM sends a target duty-cycle control signal to the camshaft timing oil control valve assembly. This control signal regulates the oil pressure supplied to the VVT controller. The VVT controller can advance or retard the intake camshaft. If the difference between the target and actual intake valve timing is large, and changes in the actual intake valve timing are small, the ECM interprets this as the VVT controller stuck malfunction and sets a DTC. Example: A DTC is set when the following conditions "A" and "B" are met: It takes 5 seconds or more to change the valve timing by 5°CA (Condition "A"). After the above condition is met, the camshaft timing oil control valve assembly is forcibly activated 10 seconds (Condition "B").
  3. DTCs P0011 and P0021 (advanced camshaft timing) are subject to 1 trip detection logic.
  4. DTCs P0012 and P0022 (retarded camshaft timing) are subject to 2 trip detection logic. These DTCs indicate that the VVT controller cannot operate properly due to camshaft timing oil control valve assembly malfunctions or the presence of foreign objects in the camshaft timing oil control valve assembly.
  5. The monitor will run if all of the following conditions are met: The engine is warm (the engine coolant temperature is 75°C [167°F] or more). The vehicle has been driven at more than 40 mph (64 km/h) for 3 minutes. The engine has idled for 3 minutes.

Refer to DTC P0010. Refer to DESCRIPTION .

DTC No.DTC Detection ConditionTrouble Area
P0011 P0021Valve timing is not adjusted in valve timing advance range (1 trip detection logic)Valve timing Camshaft timing oil control valve assembly for intake camshaft (bank 1, 2) Oil control valve filter (bank 1, 2) Camshaft timing gear assembly ECM
P0012 P0022Valve timing is not adjusted in valve timing retard range (2 trip detection logic)Valve timing Camshaft timing oil control valve assembly for intake camshaft (bank 1, 2) Oil control valve filter (bank 1, 2) Camshaft timing gear assembly ECM
  1. The ECM optimizes the intake valve timing using the Variable Valve Timing (VVT) system to control the intake camshaft. The VVT system includes the ECM, the camshaft timing oil control valve assembly and the VVT controller.
  2. The ECM sends a target duty-cycle control signal to the camshaft timing oil control valve assembly. This control signal regulates the oil pressure supplied to the VVT controller. The VVT controller can advance or retard the intake camshaft. If the difference between the target and actual intake valve timing is large, and changes in the actual intake valve timing are small, the ECM interprets this as the VVT controller stuck malfunction and sets a DTC. Example: A DTC is set when the following conditions "A" and "B" are met: It takes 5 seconds or more to change the valve timing by 5°CA (Condition "A"). After the above condition is met, the camshaft timing oil control valve assembly is forcibly activated 10 seconds (Condition "B").
  3. DTCs P0011 and P0021 (advanced camshaft timing) are subject to 1 trip detection logic.
  4. DTCs P0012 and P0022 (retarded camshaft timing) are subject to 2 trip detection logic. These DTCs indicate that the VVT controller cannot operate properly due to camshaft timing oil control valve assembly malfunctions or the presence of foreign objects in the camshaft timing oil control valve assembly.
  5. The monitor will run if all of the following conditions are met: The engine is warm (the engine coolant temperature is 75°C [167°F] or more). The vehicle has been driven at more than 40 mph (64 km/h) for 3 minutes. The engine has idled for 3 minutes.

The Variable Valve Timing (VVT) system includes the ECM, camshaft timing oil control valve assembly and VVT controller. The ECM sends a target duty-cycle control signal to the camshaft timing oil control valve assembly. 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 camshaft timing oil control valve assembly, based on the signals transmitted by several sensors. The VVT controller regulates the exhaust camshaft angle using oil pressure through the camshaft timing oil control valve assembly. 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 intake valve timing is verified by the ECM.

DTC No.DTC Detection ConditionTrouble Area
P0013Open or short in camshaft timing oil control valve assembly for exhaust camshaft (bank 1) circuit (1 trip detection logic)Open or short in camshaft timing oil control valve assembly for exhaust camshaft (bank 1) circuit Camshaft timing oil control valve assembly for exhaust camshaft (bank 1) ECM
P0023Open or short in camshaft timing oil control valve assembly for exhaust camshaft (bank 2) circuit (1 trip detection logic)Open or short in camshaft timing oil control valve assembly for exhaust camshaft (bank 2) circuit Camshaft timing oil control valve assembly for exhaust camshaft (bank 2) ECM

This DTC is designed to detect an open or short in the camshaft timing oil control valve assembly circuit. If the camshaft timing oil control valve assembly duty-cycle is excessively high or low while the engine is running, the ECM will illuminate the MIL and set the DTC.

The Variable Valve Timing (VVT) system includes the ECM, camshaft timing oil control valve assembly and VVT controller. The ECM sends a target duty-cycle control signal to the camshaft timing oil control valve assembly. 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 camshaft timing oil control valve assembly, based on the signals transmitted by several sensors. The VVT controller regulates the exhaust camshaft angle using oil pressure through the camshaft timing oil control valve assembly. 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 intake valve timing is verified by the ECM.

DTC No.DTC Detection ConditionTrouble Area
P0013Open or short in camshaft timing oil control valve assembly for exhaust camshaft (bank 1) circuit (1 trip detection logic)Open or short in camshaft timing oil control valve assembly for exhaust camshaft (bank 1) circuit Camshaft timing oil control valve assembly for exhaust camshaft (bank 1) ECM
P0023Open or short in camshaft timing oil control valve assembly for exhaust camshaft (bank 2) circuit (1 trip detection logic)Open or short in camshaft timing oil control valve assembly for exhaust camshaft (bank 2) circuit Camshaft timing oil control valve assembly for exhaust camshaft (bank 2) ECM

This DTC is designed to detect an open or short in the camshaft timing oil control valve assembly circuit. If the camshaft timing oil control valve assembly duty-cycle is excessively high or low while the engine is running, the ECM will illuminate the MIL and set the DTC.

Refer to DTC P0013. Refer to DESCRIPTION .

DTC No.DTC Detection ConditionTrouble Area
P0014 P0024Valve timing is not adjusted in valve timing advance range (2 trip detection logic)Valve timing Camshaft timing oil control valve assembly for exhaust camshaft (bank 1, 2) Oil control valve filter (bank 1, 2) Camshaft timing exhaust gear assembly ECM
P0015 P0025Valve timing is not adjusted in valve timing retard range (1 trip detection logic)Valve timing Camshaft timing oil control valve assembly for exhaust camshaft (bank 1, 2) Oil control valve filter (bank 1, 2) Camshaft timing exhaust gear assembly ECM
  1. The ECM optimizes the exhaust valve timing using the Variable Valve Timing (VVT) system to control the exhaust camshaft. The VVT system includes the ECM, camshaft timing oil control valve assembly and VVT controller.
  2. The ECM sends a target duty-cycle control signal to the camshaft timing oil control valve assembly. This control signal regulates the oil pressure supplied to the VVT controller. The VVT controller can advance or retard the exhaust camshaft. 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 sets a DTC. Example: A DTC is set when the following conditions "A" and "B" are met: It takes 5 seconds or more to change the valve timing by 5°CA (Condition "A"). After the above condition is met, the camshaft timing oil control valve assembly is forcibly activated 10 seconds (Condition "B").
  3. DTCs P0014 and P0024 (advanced camshaft timing) are subject to 2 trip detection logic.
  4. DTCs P0015 and P0025 (retarded camshaft timing) are subject to 1 trip detection logic. These DTCs indicate that the VVT controller cannot operate properly due to camshaft timing oil control valve assembly malfunctions or the presence of foreign objects in the camshaft timing oil control valve assembly.
  5. The monitor will not run unless the following conditions are met: The engine is warm (the engine coolant temperature is 75°C [167°F] or more). The vehicle has been driven at more than 40 mph (64 km/h) for 3 minutes. The engine has idled for 3 minutes.

Refer to DTC P0013. Refer to DESCRIPTION .

DTC No.DTC Detection ConditionTrouble Area
P0014 P0024Valve timing is not adjusted in valve timing advance range (2 trip detection logic)Valve timing Camshaft timing oil control valve assembly for exhaust camshaft (bank 1, 2) Oil control valve filter (bank 1, 2) Camshaft timing exhaust gear assembly ECM
P0015 P0025Valve timing is not adjusted in valve timing retard range (1 trip detection logic)Valve timing Camshaft timing oil control valve assembly for exhaust camshaft (bank 1, 2) Oil control valve filter (bank 1, 2) Camshaft timing exhaust gear assembly ECM
  1. The ECM optimizes the exhaust valve timing using the Variable Valve Timing (VVT) system to control the exhaust camshaft. The VVT system includes the ECM, camshaft timing oil control valve assembly and VVT controller.
  2. The ECM sends a target duty-cycle control signal to the camshaft timing oil control valve assembly. This control signal regulates the oil pressure supplied to the VVT controller. The VVT controller can advance or retard the exhaust camshaft. 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 sets a DTC. Example: A DTC is set when the following conditions "A" and "B" are met: It takes 5 seconds or more to change the valve timing by 5°CA (Condition "A"). After the above condition is met, the camshaft timing oil control valve assembly is forcibly activated 10 seconds (Condition "B").
  3. DTCs P0014 and P0024 (advanced camshaft timing) are subject to 2 trip detection logic.
  4. DTCs P0015 and P0025 (retarded camshaft timing) are subject to 1 trip detection logic. These DTCs indicate that the VVT controller cannot operate properly due to camshaft timing oil control valve assembly malfunctions or the presence of foreign objects in the camshaft timing oil control valve assembly.
  5. The monitor will not run unless the following conditions are met: The engine is warm (the engine coolant temperature is 75°C [167°F] or more). The vehicle has been driven at more than 40 mph (64 km/h) for 3 minutes. The engine has idled for 3 minutes.

Refer to DTC P0010. Refer to DESCRIPTION .

DTC No.DTC Detection ConditionTrouble Area
P0016Deviations in crankshaft and camshaft position sensor (for intake camshaft) signals (2 trip detection logic)Valve timing Camshaft timing oil control valve assembly for intake camshaft (bank 1, 2) Oil control valve filter (bank 1, 2) Camshaft timing gear assembly ECM
P0018Deviations in crankshaft and camshaft position sensor (for intake camshaft) signal (2 trip detection logic)

The ECM optimizes the valve timing by using the Variable Valve Timing (VVT) system to control the intake camshaft. The VVT system includes the ECM, the camshaft timing oil control valve assembly and the VVT controller.

The ECM sends a target duty-cycle control signal to the camshaft timing oil control valve assembly. This control signal regulates the oil pressure applied to the VVT controller. The VVT controller can advance or retard the intake camshaft. The ECM calibrates the intake valve timing by setting the intake camshaft to the most retarded angle while the engine is idling. The ECM closes the camshaft timing oil control valve assembly to retard the cam. The ECM stores this value as the VVT learning value. When the difference between the target and actual intake valve timing is 5°CA (crankshaft angle) or less, the ECM stores it.

If the VVT learning value matches the following conditions, the ECM determines the existence of a malfunction in the VVT system, and sets the DTC.

  1. The VVT learning value: Less than 18.5°CA, or more than 43.5°CA.
  2. The above condition continues for 18 seconds or more.

This DTC indicates that the intake camshaft has been installed toward the crankshaft at an incorrect angle, caused by factors such as the timing chain having jumped a tooth.

This monitor begins to run after the engine has idled for 5 minutes.

Refer to DTC P0010. Refer to DESCRIPTION .

DTC No.DTC Detection ConditionTrouble Area
P0016Deviations in crankshaft and camshaft position sensor (for intake camshaft) signals (2 trip detection logic)Valve timing Camshaft timing oil control valve assembly for intake camshaft (bank 1, 2) Oil control valve filter (bank 1, 2) Camshaft timing gear assembly ECM
P0018Deviations in crankshaft and camshaft position sensor (for intake camshaft) signal (2 trip detection logic)

The ECM optimizes the valve timing by using the Variable Valve Timing (VVT) system to control the intake camshaft. The VVT system includes the ECM, the camshaft timing oil control valve assembly and the VVT controller.

The ECM sends a target duty-cycle control signal to the camshaft timing oil control valve assembly. This control signal regulates the oil pressure applied to the VVT controller. The VVT controller can advance or retard the intake camshaft. The ECM calibrates the intake valve timing by setting the intake camshaft to the most retarded angle while the engine is idling. The ECM closes the camshaft timing oil control valve assembly to retard the cam. The ECM stores this value as the VVT learning value. When the difference between the target and actual intake valve timing is 5°CA (crankshaft angle) or less, the ECM stores it.

If the VVT learning value matches the following conditions, the ECM determines the existence of a malfunction in the VVT system, and sets the DTC.

  1. The VVT learning value: Less than 18.5°CA, or more than 43.5°CA.
  2. The above condition continues for 18 seconds or more.

This DTC indicates that the intake camshaft has been installed toward the crankshaft at an incorrect angle, caused by factors such as the timing chain having jumped a tooth.

This monitor begins to run after the engine has idled for 5 minutes.

Refer to DTC P0013. Refer to DESCRIPTION .

DTC No.DTC Detection ConditionTrouble Area
P0017Deviations in crankshaft and camshaft position sensor (for exhaust camshaft) signals (2 trip detection logic)Valve timing Camshaft timing oil control valve assembly for exhaust camshaft (bank 1, 2) Oil control valve filter (bank 1, 2) Camshaft timing exhaust gear assembly ECM
P0019Deviations in crankshaft and camshaft position sensor (for exhaust camshaft) signal (2 trip detection logic)

The ECM checks valve timing (VVT learning value) on the exhaust side while the engine is running at a low speed, in order to monitor the gap between the current and target valve timing on the exhaust side. The VVT learning value is calculated from the positions of the camshaft and crankshaft. The camshaft will come to the most retarded position when the engine is running at a low speed. If the camshaft position is normal, the VVT learning value should be within the specified range. If the VVT learning value is not within the specified range, the ECM determines this as a malfunction.

Refer to DTC P0013. Refer to DESCRIPTION .

DTC No.DTC Detection ConditionTrouble Area
P0017Deviations in crankshaft and camshaft position sensor (for exhaust camshaft) signals (2 trip detection logic)Valve timing Camshaft timing oil control valve assembly for exhaust camshaft (bank 1, 2) Oil control valve filter (bank 1, 2) Camshaft timing exhaust gear assembly ECM
P0019Deviations in crankshaft and camshaft position sensor (for exhaust camshaft) signal (2 trip detection logic)

The ECM checks valve timing (VVT learning value) on the exhaust side while the engine is running at a low speed, in order to monitor the gap between the current and target valve timing on the exhaust side. The VVT learning value is calculated from the positions of the camshaft and crankshaft. The camshaft will come to the most retarded position when the engine is running at a low speed. If the camshaft position is normal, the VVT learning value should be within the specified range. If the VVT learning value is not within the specified range, the ECM determines this as a malfunction.

HINT

  1. Although the DTC titles include oxygen sensor, these DTCs relate to the air fuel ratio sensor.
  2. Sensor 1 refers to the sensor mounted in front of the three way catalytic converter and located near the engine assembly.

The air fuel ratio sensor generates voltage* that corresponds to the actual air fuel ratio. This sensor voltage is used to provide the ECM with feedback so that it can control the air fuel ratio. The ECM determines the deviation from the stoichiometric air fuel ratio level, and regulates the fuel injection time. If the air fuel ratio sensor malfunctions, the ECM is unable to control the air fuel ratio accurately.

The air fuel ratio sensor is the planar type and is integrated with a heater, which heats the solid electrolyte (zirconia element). This heater is controlled by the ECM. When the intake air volume is low (the exhaust gas temperature is low), a current flows into the heater to heat the sensor, in order to facilitate accurate oxygen concentration detection. In addition, the sensor and heater portions are narrower than the conventional type. The heat generated by the heater is conducted to the solid electrolyte through the alumina, therefore the sensor activation is accelerated.

In order to obtain a high purification rate of the carbon monoxide (CO), hydrocarbon (HC) and nitrogen oxide (NOx) components in the exhaust gas, a three way catalytic converter is used. For the most efficient use of the three way catalytic converter, the air fuel ratio must be precisely controlled so that it is always close to the stoichiometric level.

*: Value changes inside the ECM. Since the air fuel ratio sensor is the current output element, the current is converted to a voltage inside the ECM. Any measurements taken at the air fuel ratio sensor or ECM connectors will show a constant voltage.

Scheme 146

Scheme 146

HINT

Scheme 147

Scheme 147
  1. When any of these DTCs are set, the ECM enters fail-safe mode. The ECM turns off the air fuel ratio 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 air fuel ratio sensor heater circuit uses a relay on the +B side of the circuit.
DTC No.DTC Detection ConditionTrouble Area
P0031 P0051Air fuel ratio sensor heater (bank 1, 2 sensor 1) current less than 0.8 A (1 trip detection logic)Open in air fuel ratio sensor heater (bank 1, 2 sensor 1) circuit Air fuel ratio sensor heater (bank 1, 2 sensor 1) A/F fuse Engine room junction block assembly (A/F relay) ECM
P0032 P0052Air fuel ratio sensor heater (bank 1, 2 sensor 1) current fail (1 trip detection logic)Short in air fuel ratio sensor heater (bank 1, 2 sensor 1) circuit Air fuel ratio sensor heater (bank 1, 2 sensor 1) A/F fuse Engine room junction block assembly (A/F relay) ECM

HINT

  1. Bank 1 refers to the bank that includes cylinder No. 1.
  2. Bank 2 refers to the bank that does not include cylinder No. 1.
  3. Sensor 1 refers to the sensor closest to the engine assembly.
  4. Sensor 2 refers to the sensor farthest away from the engine assembly.
  1. The ECM uses information from the air fuel ratio 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 to purify the exhaust gases.
  2. The air fuel ratio 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.
  3. 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.
  4. The air fuel ratio 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 air fuel ratio sensor will be inaccurate, as a result, the ECM will be unable to regulate air fuel ratio properly.
  5. When the current in the air fuel ratio sensor heater is outside the normal operating range, the ECM interprets this as a malfunction in the sensor heater and sets a DTC. Example: The ECM sets DTC P0032 or P0052 when the current in the air fuel ratio sensor heater is fail. Conversely, when the heater current is less than 0.8 A, DTC P0031 or P0051 is set.

HINT

  1. Although the DTC titles include oxygen sensor, these DTCs relate to the air fuel ratio sensor.
  2. Sensor 1 refers to the sensor mounted in front of the three way catalytic converter and located near the engine assembly.

The air fuel ratio sensor generates voltage* that corresponds to the actual air fuel ratio. This sensor voltage is used to provide the ECM with feedback so that it can control the air fuel ratio. The ECM determines the deviation from the stoichiometric air fuel ratio level, and regulates the fuel injection time. If the air fuel ratio sensor malfunctions, the ECM is unable to control the air fuel ratio accurately.

The air fuel ratio sensor is the planar type and is integrated with a heater, which heats the solid electrolyte (zirconia element). This heater is controlled by the ECM. When the intake air volume is low (the exhaust gas temperature is low), a current flows into the heater to heat the sensor, in order to facilitate accurate oxygen concentration detection. In addition, the sensor and heater portions are narrower than the conventional type. The heat generated by the heater is conducted to the solid electrolyte through the alumina, therefore the sensor activation is accelerated.

In order to obtain a high purification rate of the carbon monoxide (CO), hydrocarbon (HC) and nitrogen oxide (NOx) components in the exhaust gas, a three way catalytic converter is used. For the most efficient use of the three way catalytic converter, the air fuel ratio must be precisely controlled so that it is always close to the stoichiometric level.

*: Value changes inside the ECM. Since the air fuel ratio sensor is the current output element, the current is converted to a voltage inside the ECM. Any measurements taken at the air fuel ratio sensor or ECM connectors will show a constant voltage.

HINT

  1. When any of these DTCs are set, the ECM enters fail-safe mode. The ECM turns off the air fuel ratio 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 air fuel ratio sensor heater circuit uses a relay on the +B side of the circuit.
DTC No.DTC Detection ConditionTrouble Area
P0031 P0051Air fuel ratio sensor heater (bank 1, 2 sensor 1) current less than 0.8 A (1 trip detection logic)Open in air fuel ratio sensor heater (bank 1, 2 sensor 1) circuit Air fuel ratio sensor heater (bank 1, 2 sensor 1) A/F fuse Engine room junction block assembly (A/F relay) ECM
P0032 P0052Air fuel ratio sensor heater (bank 1, 2 sensor 1) current fail (1 trip detection logic)Short in air fuel ratio sensor heater (bank 1, 2 sensor 1) circuit Air fuel ratio sensor heater (bank 1, 2 sensor 1) A/F fuse Engine room junction block assembly (A/F relay) ECM

HINT

  1. Bank 1 refers to the bank that includes cylinder No. 1.
  2. Bank 2 refers to the bank that does not include cylinder No. 1.
  3. Sensor 1 refers to the sensor closest to the engine assembly.
  4. Sensor 2 refers to the sensor farthest away from the engine assembly.
  1. The ECM uses information from the air fuel ratio 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 to purify the exhaust gases.
  2. The air fuel ratio 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.
  3. 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.
  4. The air fuel ratio 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 air fuel ratio sensor will be inaccurate, as a result, the ECM will be unable to regulate air fuel ratio properly.
  5. When the current in the air fuel ratio sensor heater is outside the normal operating range, the ECM interprets this as a malfunction in the sensor heater and sets a DTC. Example: The ECM sets DTC P0032 or P0052 when the current in the air fuel ratio sensor heater is fail. Conversely, when the heater current is less than 0.8 A, DTC P0031 or P0051 is set.

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

The heated oxygen sensor is located behind the three-way catalytic converter, 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 heated oxygen sensor informs the ECM that the post-three-way catalytic converter 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 heated oxygen sensor informs the ECM that the post-three-way catalytic converter air fuel ratio is rich (high voltage, i.e. more than 0.45 V). The heated oxygen 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 heated oxygen sensor to determine whether the air fuel ratio after the three-way catalytic converter is rich or lean, and adjusts the fuel injection time accordingly. Thus, if the heated oxygen sensor is working improperly due to internal malfunctions, the ECM is unable to compensate for deviations in the primary air fuel ratio control.

Scheme 148

Scheme 148: DESCRIPTION

HINT

Scheme 149

Scheme 149
  1. Sensor 2 refers to the sensor mounted behind the three-way catalytic converter and located far from the engine assembly.
  2. When any of these DTCs are set, the ECM enters fail-safe mode. The ECM turns off the heated oxygen sensor heater in fail-safe mode. Fail-safe mode continues until the engine switch is turned off.
  3. The ECM provides a pulse width modulated control circuit to adjust the current through the heater. The heated oxygen sensor heater circuit uses a relay on the +B side of the circuit.
DTC No.DTC Detection ConditionTrouble Area
P0037 P0057Heated oxygen sensor heater (bank 1, 2 sensor 2) current is less than 0.3 A (1 trip detection logic)Open in heated oxygen sensor heater (bank 1, 2 sensor 2) circuit Heated oxygen sensor heater (bank 1, 2 sensor 2) ECM
P0038 P0058Heated oxygen sensor heater (bank 1, 2 sensor 2) current fail (1 trip detection logic)Short in heated oxygen sensor heater (bank 1, 2 sensor 2) circuit Heated oxygen sensor heater (bank 1, 2 sensor 2) ECM
P0141 P0161Cumulative heater resistance correction value exceeds the acceptable threshold (2 trip detection logic)Open or short in heated oxygen sensor heater (bank 1, 2 sensor 2) Heated oxygen sensor heater (bank 1, 2 sensor 2) ECM

HINT

  1. Bank 1 refers to the bank that includes cylinder No. 1.
  2. Bank 2 refers to the bank that does not include cylinder No. 1.
  3. Sensor 1 refers to the sensor closest to the engine assembly.
  4. Sensor 2 refers to the sensor farthest away from the engine assembly.

The sensing portion of the heated oxygen 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 and P0058)

  1. 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)

  1. 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 above the threshold value, the ECM will determine that there is a malfunction in the heated oxygen sensor heater and set DTCs P0141 and P0161.

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

The heated oxygen sensor is located behind the three-way catalytic converter, 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 heated oxygen sensor informs the ECM that the post-three-way catalytic converter 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 heated oxygen sensor informs the ECM that the post-three-way catalytic converter air fuel ratio is rich (high voltage, i.e. more than 0.45 V). The heated oxygen 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 heated oxygen sensor to determine whether the air fuel ratio after the three-way catalytic converter is rich or lean, and adjusts the fuel injection time accordingly. Thus, if the heated oxygen sensor is working improperly due to internal malfunctions, the ECM is unable to compensate for deviations in the primary air fuel ratio control.

HINT

  1. Sensor 2 refers to the sensor mounted behind the three-way catalytic converter and located far from the engine assembly.
  2. When any of these DTCs are set, the ECM enters fail-safe mode. The ECM turns off the heated oxygen sensor heater in fail-safe mode. Fail-safe mode continues until the engine switch is turned off.
  3. The ECM provides a pulse width modulated control circuit to adjust the current through the heater. The heated oxygen sensor heater circuit uses a relay on the +B side of the circuit.
DTC No.DTC Detection ConditionTrouble Area
P0037 P0057Heated oxygen sensor heater (bank 1, 2 sensor 2) current is less than 0.3 A (1 trip detection logic)Open in heated oxygen sensor heater (bank 1, 2 sensor 2) circuit Heated oxygen sensor heater (bank 1, 2 sensor 2) ECM
P0038 P0058Heated oxygen sensor heater (bank 1, 2 sensor 2) current fail (1 trip detection logic)Short in heated oxygen sensor heater (bank 1, 2 sensor 2) circuit Heated oxygen sensor heater (bank 1, 2 sensor 2) ECM
P0141 P0161Cumulative heater resistance correction value exceeds the acceptable threshold (2 trip detection logic)Open or short in heated oxygen sensor heater (bank 1, 2 sensor 2) Heated oxygen sensor heater (bank 1, 2 sensor 2) ECM

HINT

  1. Bank 1 refers to the bank that includes cylinder No. 1.
  2. Bank 2 refers to the bank that does not include cylinder No. 1.
  3. Sensor 1 refers to the sensor closest to the engine assembly.
  4. Sensor 2 refers to the sensor farthest away from the engine assembly.

The sensing portion of the heated oxygen 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 and P0058)

  1. 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)

  1. 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 above the threshold value, the ECM will determine that there is a malfunction in the heated oxygen sensor heater and set DTCs P0141 and P0161.

Refer to DTC P0102. Refer to DESCRIPTION .

DTC No.DTC Detection ConditionTrouble Area
P0101Conditions (a), (b), (c) and (d) are met (2 trip detection logic): (a) Engine running (b) Engine coolant temperature 70°C (158°F) or more (c) Throttle position sensor voltage 0.24 to 2 V (d) Average engine load value ratio less than 0.8%, or more than 1.15% (varies with estimated engine load) Average engine load value ratio = Average engine load based on mass air flow meter sub-assembly output / Average engine load estimated from driving conditionsMass air flow meter sub-assembly Intake system PCV hose connections

The mass air flow meter sub-assembly 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 mass air flow meter sub-assembly, 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 these components of the mass air flow meter sub-assembly. 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 mass air flow meter sub-assembly for malfunctions. The average engine load value ratio is obtained by comparing the average engine load calculated from the mass air flow meter sub-assembly 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 below the threshold value, the ECM determines that the intake air volume is low, and if the average engine load value ratio is above 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 set.

Refer to DTC P0102. Refer to DESCRIPTION .

DTC No.DTC Detection ConditionTrouble Area
P0101Conditions (a), (b), (c) and (d) are met (2 trip detection logic): (a) Engine running (b) Engine coolant temperature 70°C (158°F) or more (c) Throttle position sensor voltage 0.24 to 2 V (d) Average engine load value ratio less than 0.8%, or more than 1.15% (varies with estimated engine load) Average engine load value ratio = Average engine load based on mass air flow meter sub-assembly output / Average engine load estimated from driving conditionsMass air flow meter sub-assembly Intake system PCV hose connections

The mass air flow meter sub-assembly 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 mass air flow meter sub-assembly, 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 these components of the mass air flow meter sub-assembly. 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 mass air flow meter sub-assembly for malfunctions. The average engine load value ratio is obtained by comparing the average engine load calculated from the mass air flow meter sub-assembly 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 below the threshold value, the ECM determines that the intake air volume is low, and if the average engine load value ratio is above 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 set.

The mass air flow meter sub-assembly 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 mass air flow meter sub-assembly, 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 these components in the mass air flow meter sub-assembly. The voltage level is proportional to the air flow 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 temperature sensor 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 set, 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 150

Scheme 150: DESCRIPTION
DTC No.DTC Detection ConditionTrouble Area
P0102Mass air flow meter sub-assembly voltage is less than 0.2 V for 3 secondsOpen or short in mass air flow meter sub-assembly circuit Mass air flow meter sub-assembly ECM
P0103Mass air flow meter sub-assembly voltage is more than 4.9 V for 3 secondsOpen or short in mass air flow meter sub-assembly circuit Mass air flow meter sub-assembly ECM

HINT

When any of these DTCs are set, check the air flow rate by entering the following menus on the Techstream: Powertrain / Engine / Data List / MAF.

Mass Air Flow Rate (gm/sec)ConditionMalfunction
Approximately 0.0Engine not running 30 seconds after engine switch on (IG)Open in mass air flow meter sub-assembly power source circuit Open or short in VG circuit
More than 0.53Engine not running 30 seconds after engine switch on (IG)Open in E2G circuit

Note. Perform the inspection with the vehicle indoors and on a level surface. Perform the inspection of the mass air flow meter sub-assembly while it is installed to the air cleaner case (installed to the vehicle). During the test, do not use an exhaust air duct on the tail exhaust pipe assembly.

If there is a defect in the mass air flow meter sub-assembly 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 mass air flow meter sub-assembly and sets a DTC.

Example

When the sensor output voltage remains less than 0.2 V, or more than 4.9 V, for more than 3 seconds, the ECM sets a DTC.

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

The mass air flow meter sub-assembly 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 mass air flow meter sub-assembly, 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 these components in the mass air flow meter sub-assembly. The voltage level is proportional to the air flow 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 temperature sensor 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 set, 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.

DTC No.DTC Detection ConditionTrouble Area
P0102Mass air flow meter sub-assembly voltage is less than 0.2 V for 3 secondsOpen or short in mass air flow meter sub-assembly circuit Mass air flow meter sub-assembly ECM
P0103Mass air flow meter sub-assembly voltage is more than 4.9 V for 3 secondsOpen or short in mass air flow meter sub-assembly circuit Mass air flow meter sub-assembly ECM

HINT

When any of these DTCs are set, check the air flow rate by entering the following menus on the Techstream: Powertrain / Engine / Data List / MAF.

Mass Air Flow Rate (gm/sec)ConditionMalfunction
Approximately 0.0Engine not running 30 seconds after engine switch on (IG)Open in mass air flow meter sub-assembly power source circuit Open or short in VG circuit
More than 0.53Engine not running 30 seconds after engine switch on (IG)Open in E2G circuit

Note. Perform the inspection with the vehicle indoors and on a level surface. Perform the inspection of the mass air flow meter sub-assembly while it is installed to the air cleaner case (installed to the vehicle). During the test, do not use an exhaust air duct on the tail exhaust pipe assembly.

If there is a defect in the mass air flow meter sub-assembly 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 mass air flow meter sub-assembly and sets a DTC.

Example

When the sensor output voltage remains less than 0.2 V, or more than 4.9 V, for more than 3 seconds, the ECM sets a DTC.

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

The ECM performs OBD II monitoring based on the values from the intake air temperature sensor. If there is no change of the sensor value within the normal range, the ECM will not be able to perform OBD II monitoring or will misdiagnose that there is a malfunction in the sensor. The ECM detects that the intake air temperature sensor value is stuck by monitoring the sensor after the engine switch is turned off or after the engine is started.

  1. The intake air temperature sensor, in the mass air flow meter sub-assembly, monitors the intake air temperature. The intake air temperature sensor has a built-in thermistor with a resistance that varies according to the temperature of the intake air. When the intake air temperature becomes low, the resistance of the thermistor increases. When the temperature becomes high, the resistance drops. These variations in resistance are transmitted to the ECM as voltage changes ( (Scheme 145)(Scheme 145) ).
  2. The intake air temperature sensor is powered by a 5 V supply from the THA terminal of the ECM, via resistor R which is located inside the ECM.
  3. Resistor R and the intake air temperature sensor are connected in series. When the resistance value of the intake air temperature sensor changes, according to changes in the intake air temperature, the voltage at terminal THA also varies. Based on this signal, the ECM increases the fuel injection volume when the engine is cold to improve driveability.
DTC No.DTC Detection ConditionTrouble Area
P0111When either of the following conditions is met (2 trip detection logic): The intake air temperature rise is small, from the previous trip warm-up to the following trip When the change in the intake air temperature after engine start is less than the threshold valueMass air flow meter sub-assembly

The ECM performs OBD II monitoring based on the values from the intake air temperature sensor. If there is no change of the sensor value within the normal range, the ECM will not be able to perform OBD II monitoring or will misdiagnose that there is a malfunction in the sensor. The ECM detects that the intake air temperature sensor value is stuck by monitoring the sensor after the engine switch is turned off or after the engine is started.

  1. The intake air temperature sensor, in the mass air flow meter sub-assembly, monitors the intake air temperature. The intake air temperature sensor has a built-in thermistor with a resistance that varies according to the temperature of the intake air. When the intake air temperature becomes low, the resistance of the thermistor increases. When the temperature becomes high, the resistance drops. These variations in resistance are transmitted to the ECM as voltage changes ( (Scheme 145)(Scheme 145) ).
  2. The intake air temperature sensor is powered by a 5 V supply from the THA terminal of the ECM, via resistor R which is located inside the ECM.
  3. Resistor R and the intake air temperature sensor are connected in series. When the resistance value of the intake air temperature sensor changes, the voltage at terminal THA varies accordingly. Based on this signal, the ECM increases the fuel injection volume when the engine is cold to improve driveability. HINT: When any of DTCs P0112 and P0113 are set, the ECM enters fail-safe mode. During fail-safe mode, the intake air temperature is estimated to be 20°C (68°F) by the ECM. Fail-safe mode continues until a pass condition is detected.
DTC No.DTC Detection ConditionTrouble Area
P0112Short in intake air temperature sensor circuit for 0.5 seconds (1 trip detection logic)Short in intake air temperature sensor circuit Intake air temperature sensor (built into mass air flow meter sub-assembly) ECM
P0113Open in intake air temperature sensor circuit for 0.5 seconds (1 trip detection logic)Open in intake air temperature sensor circuit Intake air temperature sensor (built into mass air flow meter sub-assembly) ECM

HINT

When any of these DTCs are set, check the intake air temperature by entering the following menus on the Techstream: Powertrain / Engine / Data List / Intake Air.

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

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

Example

If the sensor output voltage is more than 4.91 V for 0.5 seconds or more, the ECM determines that there is an open in the intake air temperature sensor circuit, and sets DTC P0113. Conversely, if the output voltage is less than 0.18 V for 0.5 seconds or more, the ECM determines that there is a short in the sensor circuit, and sets DTC P0112.

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

  1. The intake air temperature sensor, in the mass air flow meter sub-assembly, monitors the intake air temperature. The intake air temperature sensor has a built-in thermistor with a resistance that varies according to the temperature of the intake air. When the intake air temperature becomes low, the resistance of the thermistor increases. When the temperature becomes high, the resistance drops. These variations in resistance are transmitted to the ECM as voltage changes ( (Scheme 145)(Scheme 145) ).
  2. The intake air temperature sensor is powered by a 5 V supply from the THA terminal of the ECM, via resistor R which is located inside the ECM.
  3. Resistor R and the intake air temperature sensor are connected in series. When the resistance value of the intake air temperature sensor changes, the voltage at terminal THA varies accordingly. Based on this signal, the ECM increases the fuel injection volume when the engine is cold to improve driveability. HINT: When any of DTCs P0112 and P0113 are set, the ECM enters fail-safe mode. During fail-safe mode, the intake air temperature is estimated to be 20°C (68°F) by the ECM. Fail-safe mode continues until a pass condition is detected.
DTC No.DTC Detection ConditionTrouble Area
P0112Short in intake air temperature sensor circuit for 0.5 seconds (1 trip detection logic)Short in intake air temperature sensor circuit Intake air temperature sensor (built into mass air flow meter sub-assembly) ECM
P0113Open in intake air temperature sensor circuit for 0.5 seconds (1 trip detection logic)Open in intake air temperature sensor circuit Intake air temperature sensor (built into mass air flow meter sub-assembly) ECM

HINT

When any of these DTCs are set, check the intake air temperature by entering the following menus on the Techstream: Powertrain / Engine / Data List / Intake Air.

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

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

Example

If the sensor output voltage is more than 4.91 V for 0.5 seconds or more, the ECM determines that there is an open in the intake air temperature sensor circuit, and sets DTC P0113. Conversely, if the output voltage is less than 0.18 V for 0.5 seconds or more, the ECM determines that there is a short in the sensor circuit, and sets DTC P0112.

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

A thermistor, whose resistance value varies according to the engine coolant temperature, is built into the engine coolant temperature sensor.

The structure of the sensor and its connection to the ECM are similar to those of the intake air temperature sensor.

HINT

When any of DTCs P0115, P0117 or P0118 are set, the ECM enters fail-safe mode. During fail-safe mode, the engine coolant temperature 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
P0115Open or short in engine coolant temperature sensor circuit for 0.5 seconds (1 trip detection logic)Open or short in engine coolant temperature sensor circuit Engine coolant temperature sensor ECM
P0117Short in engine coolant temperature sensor circuit for 0.5 seconds (1 trip detection logic)Short in engine coolant temperature sensor circuit Engine coolant temperature sensor ECM
P0118Open in engine coolant temperature sensor circuit for 0.5 seconds (1 trip detection logic)Open in engine coolant temperature sensor circuit Engine coolant temperature sensor ECM

HINT

When any of these DTCs are set, check the engine coolant temperature by entering the following menus on the Techstream: Powertrain / Engine / Data List / Coolant Temp.

Temperature DisplayedMalfunction
40°C (-40°F)Open circuit
140°C (284°F) or moreShort circuit
  1. The engine coolant temperature sensor is used to monitor the engine coolant temperature. The engine coolant temperature sensor has a thermistor with a resistance that varies according to the temperature of the engine coolant. When the coolant temperature becomes low, the resistance in the thermistor increases. When the temperature becomes 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 engine coolant temperature. When the sensor output voltage deviates from the normal operating range, the ECM interprets this as a malfunction in the engine coolant temperature sensor and sets a DTC. Example: If the sensor output voltage is more than 4.91 V for 0.5 seconds or more, the ECM determines that there is an open in the engine coolant temperature sensor circuit, and sets DTC P0118. Conversely, if the voltage output is less than 0.14 V for 0.5 seconds or more, the ECM determines that there is a short in the sensor circuit, and sets DTC P0117. If the malfunction is not repaired successfully, a DTC is set 0.5 seconds after the engine is next started.

A thermistor, whose resistance value varies according to the engine coolant temperature, is built into the engine coolant temperature sensor.

The structure of the sensor and its connection to the ECM are similar to those of the intake air temperature sensor.

HINT

When any of DTCs P0115, P0117 or P0118 are set, the ECM enters fail-safe mode. During fail-safe mode, the engine coolant temperature 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
P0115Open or short in engine coolant temperature sensor circuit for 0.5 seconds (1 trip detection logic)Open or short in engine coolant temperature sensor circuit Engine coolant temperature sensor ECM
P0117Short in engine coolant temperature sensor circuit for 0.5 seconds (1 trip detection logic)Short in engine coolant temperature sensor circuit Engine coolant temperature sensor ECM
P0118Open in engine coolant temperature sensor circuit for 0.5 seconds (1 trip detection logic)Open in engine coolant temperature sensor circuit Engine coolant temperature sensor ECM

HINT

When any of these DTCs are set, check the engine coolant temperature by entering the following menus on the Techstream: Powertrain / Engine / Data List / Coolant Temp.

Temperature DisplayedMalfunction
40°C (-40°F)Open circuit
140°C (284°F) or moreShort circuit
  1. The engine coolant temperature sensor is used to monitor the engine coolant temperature. The engine coolant temperature sensor has a thermistor with a resistance that varies according to the temperature of the engine coolant. When the coolant temperature becomes low, the resistance in the thermistor increases. When the temperature becomes 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 engine coolant temperature. When the sensor output voltage deviates from the normal operating range, the ECM interprets this as a malfunction in the engine coolant temperature sensor and sets a DTC. Example: If the sensor output voltage is more than 4.91 V for 0.5 seconds or more, the ECM determines that there is an open in the engine coolant temperature sensor circuit, and sets DTC P0118. Conversely, if the voltage output is less than 0.14 V for 0.5 seconds or more, the ECM determines that there is a short in the sensor circuit, and sets DTC P0117. If the malfunction is not repaired successfully, a DTC is set 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 cold engine started and engine warmed up, engine coolant temperature sensor value does not change After warmed up engine stopped and then next cold engine start performed, engine coolant temperature sensor value does not changeThermostat Engine coolant temperature sensor
P0116For Mexico Models: Case 1: Engine coolant temperature between 35°C and 60°C (95°F and 140°F) when engine started, and conditions (a) and (b) are met (2 trip detection logic) (a) Vehicle driven at varying speeds (accelerated and decelerated) (b) Engine coolant temperature remains within 3°C (37.4°F) of initial engine coolant temperature Case 2: Engine coolant temperature more than 60°C (140°F) when engine started, and conditions (a) and (b) are met (6 trip detection logic) (a) Vehicle driven at varying speeds (accelerated and decelerated) (b) Engine coolant temperature measurements remain within 1°C (33.8°F) of initial engine coolant temperature on 6 successive occasionsThermostat Engine coolant temperature sensor

Engine coolant temperature sensor cold start monitor

When a cold engine start is performed and then the engine is warmed up, if the engine coolant temperature 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 set.

Engine coolant temperature sensor soak monitor

If the engine coolant temperature 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 set.

Engine coolant temperature sensor high side stuck monitor (only for Mexico models)

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

Examples

  1. Upon starting the engine, the engine coolant temperature is between 35°C and 60°C (95°F and 140°F). If after driving for 250 seconds, the engine coolant temperature remains within 3°C (37.4°F) of the starting temperature, the DTC is set (2 trip detection logic).
  2. Upon starting the engine, the engine coolant temperature is over 60°C (140°F). If after driving for 250 seconds, the ECM remains within 1°C (33.8°F) of the starting temperature, the DTC is set (6 trip detection logic).

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 cold engine started and engine warmed up, engine coolant temperature sensor value does not change After warmed up engine stopped and then next cold engine start performed, engine coolant temperature sensor value does not changeThermostat Engine coolant temperature sensor
P0116For Mexico Models: Case 1: Engine coolant temperature between 35°C and 60°C (95°F and 140°F) when engine started, and conditions (a) and (b) are met (2 trip detection logic) (a) Vehicle driven at varying speeds (accelerated and decelerated) (b) Engine coolant temperature remains within 3°C (37.4°F) of initial engine coolant temperature Case 2: Engine coolant temperature more than 60°C (140°F) when engine started, and conditions (a) and (b) are met (6 trip detection logic) (a) Vehicle driven at varying speeds (accelerated and decelerated) (b) Engine coolant temperature measurements remain within 1°C (33.8°F) of initial engine coolant temperature on 6 successive occasionsThermostat Engine coolant temperature sensor

Engine coolant temperature sensor cold start monitor

When a cold engine start is performed and then the engine is warmed up, if the engine coolant temperature 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 set.

Engine coolant temperature sensor soak monitor

If the engine coolant temperature 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 set.

Engine coolant temperature sensor high side stuck monitor (only for Mexico models)

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

Examples

  1. Upon starting the engine, the engine coolant temperature is between 35°C and 60°C (95°F and 140°F). If after driving for 250 seconds, the engine coolant temperature remains within 3°C (37.4°F) of the starting temperature, the DTC is set (2 trip detection logic).
  2. Upon starting the engine, the engine coolant temperature is over 60°C (140°F). If after driving for 250 seconds, the ECM remains within 1°C (33.8°F) of the starting temperature, the DTC is set (6 trip detection logic).

The engine has 2 temperature sensors, an engine coolant temperature sensor and an intake air temperature sensor, to detect the temperature while the engine is operating. 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 duration 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) Battery voltage 10.5 V or more 7 hours or more elapsed from engine stops on previous trip 15 seconds after cold engine starts Minimum intake air temperature after engine starts more than -10°C (14°F) Average engine coolant temperature before engine starts more than -10°C (14°F) Difference between readings of engine coolant temperature and intake air temperature greater than 20°C (36°F)Intake air temperature sensor Engine coolant temperature sensor ECM

Scheme 151

Scheme 151

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 engine coolant temperature and intake air temperature are very similar. When the vehicle has been parked for less than 7 hours, differences in the readings may exist. This does not necessarily indicate a fault.

The ECM monitors the difference between the engine coolant temperature and the intake air temperature 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 has elapsed since the engine was stopped (engine switch turned to off) on the previous trip. If the difference between the engine coolant temperature and the intake air temperature on a cold start exceeds 20°C (36°F), the ECM interprets this as a malfunction in the engine coolant temperature sensor circuit and intake air temperature sensor circuit, and sets the DTC.