DESCRIPTION
The VVT (variable valve timing) system adjusts the intake valve timing to improve driveability. The engine oil pressure turns the VVT controller to adjust the valve timing.
The camshaft timing oil control valve assembly is a solenoid valve and switches the engine oil line. The valve moves when the ECM applies the 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 113
| DTC No. | DTC Detection Condition | Trouble Area |
|---|---|---|
| P0010 | Open or short in camshaft timing oil control valve assembly circuit (1 trip detection logic) | Open or short in camshaft timing oil control valve assembly circuit Camshaft timing oil control valve assembly ECM |
MONITOR DESCRIPTION
This DTC is designed to detect open or short circuits in the camshaft timing oil control valve assembly circuit. If the camshaft timing oil control valve duty-cycle is excessively high or low while the power switch is on (IG) or engine is running, the ECM will illuminate the MIL and store the DTC.
Refer to DTC P0010. Refer to DESCRIPTION.
| DTC No. | DTC Detection Condition | Trouble Area |
|---|---|---|
| P0011 | Intake valve timing is stuck at a certain value when in the advance range (1 trip detection logic). | Valve timing Camshaft timing oil control valve assembly Oil control valve filter Camshaft timing gear assembly ECM |
| P0012 | Intake valve timing is stuck at a certain value when in the retard range (2 trip detection logic). |
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, the camshaft timing oil control valve assembly and the VVT controller (camshaft timing gear assembly). 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 a VVT controller stuck malfunction and stores a DTC.
- Example
- A DTC is stored 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 is forcibly activated for 10 seconds (Condition "B").
- The monitor will run if all of the following conditions are met
- DTC P0011 (Advanced Cam Timing) is subject to 1 trip detection logic.
- DTC P0012 (Retarded Cam Timing) is 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.
In the VVT (Variable Valve Timing) system, the appropriate intake valve open and close timing is controlled by the ECM. The ECM performs intake valve control by performing the following: 1) controlling the camshaft and camshaft timing oil control valve assembly, and operating the camshaft timing gear assembly; and 2) changing the relative positions of the camshaft and crankshaft.
| DTC No. | Detection Condition | Trouble Area |
|---|---|---|
| P0016 | Deviation in crankshaft position sensor signal and camshaft position sensor signal (2 trip detection logic) | Valve timing Camshaft timing oil control valve assembly Oil control valve filter Camshaft timing gear assembly 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 specified range in consecutive driving cycles, the ECM illuminates the MIL and stores the DTC P0016.
Refer to DTC P2195. Refer to DESCRIPTION.
HINT
Scheme 114
- When any of these DTCs is stored, 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 power switch is turned off.
- Although the DTC titles say the oxygen sensor, these DTCs relate to the air fuel ratio sensor.
- The ECM has 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 Condition | Trouble Area |
|---|---|---|
| P0031 | The heater current is less than 0.8 A, even when the air fuel ratio sensor heater output duty cycle is 30% or more (1 trip detection logic). | Open in air fuel ratio sensor (sensor 1) heater circuit Air fuel ratio sensor (sensor 1) ECM |
| P0032 | An air fuel ratio sensor heater current reaches the high limit. (Hybrid IC high current limiter monitor input "Fail") (1 trip detection logic). | Short in air fuel ratio sensor (sensor 1) heater circuit Air fuel ratio sensor (sensor 1) ECM |
| P101D | The 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 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.
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.
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 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 becomes inaccurate, as a result, the ECM is unable to regulate air fuel ratio properly.
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 stores a DTC.
Refer to DTC P0136. Refer to DESCRIPTION.
HINT
When any of these DTCs is stored, 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 power switch is turned off.
Scheme 115
| DTC No. | DTC Detection Condition | Trouble Area |
|---|---|---|
| P0037 | The heater current the specified value or less while the heater is operating (1 trip detection logic). | Open in heated oxygen sensor (sensor 2) heater circuit Heated oxygen sensor (sensor 2) ECM |
| P0038 | The heater current reaches high limit. (Hybrid IC high current limiter monitor input "Fail") (1 trip detection logic). | Short in heated oxygen sensor (sensor 2) heater circuit Heated oxygen sensor (sensor 2) ECM |
| P0141 | The cumulative heater resistance correction value exceeds the threshold (2 trip detection logic). | Open or short in heated oxygen sensor (sensor 2) heater circuit Heated oxygen sensor (sensor 2) ECM |
| P102D | The 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 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 and P102D)
- 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 heater and stores a DTC.
Heated Oxygen Sensor Heater Performance (P0141)
- After the accumulated heater ON time exceeds 100 seconds, the ECM calculates the heater resistance using auxiliary battery voltage and the current applied to the heater. If the resistance is above the threshold value, the ECM determines that there is a malfunction in the heated oxygen sensor heater and stores DTC P0141.
Refer to DTC P0102. Refer to DESCRIPTION.
| DTC No. | DTC Detection Condition | Trouble Area |
|---|---|---|
| P0101 | All of the following conditions continue for more than 10 seconds (2 trip detection logic): (a) Engine running (b) Engine coolant temperature 70°C (158°F) or more (c) Throttle position sensor voltage is 0.2 V or more, and less than 2 V (d) Average engine load value ratio less than 0.85, or more than 1.15 (varies with estimated engine load) Average engine load value ratio = Average engine load based on mass air flow meter output / Average engine load estimated from driving conditions (e) Average air fuel ratio less than -20%, or more than 20% | Mass air flow meter sub-assembly Intake system PCV hose connections EGR valve assembly |
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 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 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 the DTC is stored.
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 fuel injection duration 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 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 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 is 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 116
| DTC No. | DTC Detection Condition | Trouble Area |
|---|---|---|
| P0102 | Mass air flow meter sub-assembly 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 meter sub-assembly circuit Mass air flow meter sub-assembly ECM |
| P0103 | Mass air flow meter sub-assembly 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 mass air flow meter sub-assembly circuit Mass air flow meter sub-assembly ECM |
HINT
When any of these DTCs are output, check the air-flow rate by entering the following menus: Powertrain / Engine and ECT / Data List / Primary / MAF.
| Mass Air Flow Rate (gm/sec) | Malfunction |
|---|---|
| Approximately 0.0 | Open in mass air flow meter sub-assembly power source circuit Open or short in VG circuit |
| 271.0 or more | Open in E2G circuit |
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 circuit and stores a DTC.
Example
When the sensor output voltage remains below 0.2 V or higher than 4.9 V for more than 3 seconds, the ECM stores a DTC.
The manifold absolute pressure sensor detects the intake manifold pressure as a voltage using a built-in sensor. The ECM calculates intake manifold pressure based on this voltage and also calculates the EGR valve and purge VSV opening amount according to changes in the intake manifold pressure.
Scheme 117
| DTC No. | DTC Detection Condition | Trouble Area |
|---|---|---|
| P0106 | Intake manifold pressure measured after engine start drops by less than 3 kPa (22.5 mmHg) compared to the intake manifold pressure (atmospheric pressure) measured before engine start (2 trip detection logic). | Intake system Manifold absolute pressure sensor |
When the intake manifold pressure measured after engine start drops by less than 3 kPa (22.5 mmHg) compared to the intake manifold pressure (atmospheric pressure) measured before engine start, the ECM interprets this as a malfunction in the manifold absolute pressure sensor and stores the DTC.
Refer to DTC P0106. Refer to DESCRIPTION.
| DTC No. | DTC Detecting Condition | Trouble Area |
|---|---|---|
| P0107 | The output voltage from the manifold absolute pressure sensor less than 0.5 V for 0.5 seconds. (1 trip detection logic) | Open or short in manifold absolute pressure sensor circuit Manifold absolute pressure sensor ECM |
| P0108 | The output voltage from the manifold absolute pressure sensor more than 4.5 V for 0.5 seconds. (1 trip detection logic) | Open or short in manifold absolute pressure sensor circuit Manifold absolute pressure sensor ECM |
HINT
When DTC P0107 or P0108 is detected, check the manifold absolute pressure by selecting Powertrain / Engine and ECT / Data List / Primary / MAP on the Techstream.
| Pressure Displayed | Malfunction |
|---|---|
| Approximately 0 kPa(abs) [0 mmHg(abs)] | Short in PIM circuit to ground Short in PIM circuit to E2 circuit Open in VC circuit |
| 130 kPa(abs) [975 mmHg(abs)] or higher | Short in VC circuit to PIM circuit Open in PIM circuit Open in E2 circuit |
The ECM monitors the sensor voltage and uses this value to calculate the manifold absolute pressure. When the sensor output voltage deviates from the normal operating range, the ECM interprets this as a malfunction in the manifold absolute pressure sensor and stores a DTC.
Example
When the sensor output voltage remains less than 0.5 V, or more than 4.5 V for 0.5 seconds, the ECM stored a DTC.
After warm engine stopped
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 the intake air 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 stored.
After a cold engine in started
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 stored.
Refer to DTC P0111. Refer to DESCRIPTION.
HINT
When either DTC P0112 or P0113 is stored, 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 Condition | Trouble Area |
|---|---|---|
| P0112 | Short 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 |
| P0113 | Open 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 stored, check the intake air temperature by entering the following menus: Powertrain / Engine and ECT / Data List / Primary / Intake Air.
| Temperature Displayed | Malfunction |
|---|---|
| 40°C (-40°F) | Open circuit |
| More than 128°C (262°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 stores 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 stores 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 stored DTC P0112.
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 the same as those of the intake air temperature sensor.
HINT
When any of DTCs P0115, P0117 and P0118 are stored, 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 Condition | Trouble Area |
|---|---|---|
| P0115 | Open 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 |
| P0117 | Short 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 |
| P0118 | Open 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 stored, check the engine coolant temperature by entering the following menus: Powertrain / Engine and ECT / Data List / Primary / Coolant Temp.
| Temperature Displayed | Malfunction |
|---|---|
| 40°C (-40°F) | Open circuit |
| More than 135°C (275°F) | Short circuit |
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 fault in the engine coolant temperature sensor circuit and stores 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 stores 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 stored DTC P0117.
Refer to DTC P0115. Refer to DESCRIPTION.
| DTC No. | DTC Detection Condition | Trouble Area |
|---|---|---|
| P0116 | When either of the following conditions is met (2 trip detection logic): During engine warm up after cold engine starts, change in engine coolant temperature sensor output is below threshold In duration between warmed engine stopped and next cold engine starts, change in engine coolant temperature sensor output below threshold | Water inlet with thermostat sub-assembly Engine coolant temperature sensor |
| For 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) met (2 trip detection logic) (a) Vehicle driven at varying speeds (accelerated and decelerated) (b) Engine coolant temperature remains within 3°C (5.4°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) met (1 trip detection logic) (a) Vehicle driven at varying speeds (accelerated and decelerated) (b) Engine coolant temperature measurements remain within 1°C (1.8°F) of initial engine coolant temperature on 6 successive occasions | Water inlet with thermostat sub-assembly Engine coolant temperature sensor |
Engine Coolant Temperature Sensor Cold Start Monitor
The monitor runs when the engine is started cold. If the change in engine coolant temperature sensor output until the engine is warmed up completely is less than the threshold, it is determined that a malfunction has occurred in the engine coolant temperature sensor. When this is detected in 2 consecutive driving cycles, the MIL is illuminated and the DTC is stored.
Engine Coolant Temperature Sensor Soak Monitor
The ECM compares the engine coolant temperature when the warmed engine is stopped and when the engine is started on the next trip when more than 5 hours has elapsed since the engine was stopped. If the change in engine coolant temperature sensor output is less than the threshold, it is determined that a malfunction has occurred in the engine coolant temperature sensor. When this is detected in 2 consecutive driving cycles, the MIL is illuminated and the DTC is stored.
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 stores the DTC.
Examples
- Upon starting the engine and 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 (5.4°F) of the starting temperature, the DTC is stored (2 trip detection logic).
- When starting the engine and the engine coolant temperature is more than 60°C (140°F): If after driving for 250 seconds, the ECM remains within 1°C (1.8°F) of the starting temperature, the DTC is stored (1 trip detection logic).
The engine has two temperature sensors, an engine coolant temperature sensor and an intake air temperature sensor, to detect temperature while the engine is operating. A thermistor, whose resistance value varies according to the temperature, is built into each sensor. When the 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. 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 Condition | Trouble Area |
|---|---|---|
| P011B | All of the following conditions are met (2 trip detection logic): The auxiliary battery voltage is 10.5 V or higher. 7 hours or more have elapsed since the engine stopped on the previous trip. 15 seconds or more after a cold engine start. Either of the following conditions is met: The minimum intake air temperature after the engine starts is -10°C (14°F) or higher. The engine coolant temperature before the engine starts is -10°C (14°F) or higher. The difference between the readings of the engine coolant temperature and intake air temperature is higher than 20°C (36°F). | Intake air temperature sensor (built into mass air flow meter sub-assembly) Engine coolant temperature sensor ECM |
Scheme 118
HINT
- 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.
- 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 (power switch turned 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 stores the DTC.
HINT
These DTCs relate to the throttle position sensor.
The throttle position sensor is mounted on the throttle body assembly, 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 throttle position sensor has 2 sensor circuits, VTA1 and VTA2 each of which transmits a signal. 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 VTA1 and VTA2 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 119
| DTC No. | DTC Detection Condition | Trouble Area |
|---|---|---|
| P0120 | Output voltage of VTA1 quickly fluctuates beyond lower and upper malfunction thresholds for 2 seconds or more (1 trip detection logic) | Throttle position sensor (built into throttle body assembly) ECM |
| P0121 | Difference between VTA1 and VTA2 voltages less than 0.8 V, or more than 1.6 V for 2 seconds (1 trip detection logic) | Throttle position sensor (built into throttle body assembly) Throttle position sensor circuit ECM |
| P0122 | Output voltage of VTA1 0.2 V or less for 2 seconds or more (1 trip detection logic) | Throttle position sensor (built into throttle body assembly) Short in VTA1 circuit Open in VCTA circuit ECM |
| P0123 | Output voltage of VTA1 4.54 V or more for 2 seconds or more (1 trip detection logic) | Throttle position sensor (built into throttle body assembly) Open in VTA1 circuit Open in ETA circuit Short between VCTA and VTA1 circuits ECM |
| P0220 | Output voltage of VTA2 quickly fluctuates beyond lower and upper malfunction thresholds for 2 seconds or more (1 trip detection logic) | Throttle position sensor (built into throttle body assembly) ECM |
| P0222 | Output voltage of VTA2 1.75 V or less for 2 seconds or more (1 trip detection logic) | Throttle position sensor (built into throttle body assembly) Short in VTA2 circuit Open in VCTA circuit ECM |
| P0223 | Output voltage of VTA2 4.8 V or more, and VTA1 between 0.2 V and 2.02 V for 2 seconds or more (1 trip detection logic) | Throttle position sensor (built into throttle body assembly) Open in VTA2 circuit Open in ETA circuit Short between VCTA and VTA2 circuits ECM |
| P2135 | Either condition (a) or (b) met (1 trip detection logic): (a) Difference between output voltages of VTA1 and VTA2 0.02 V or less for 0.5 seconds or more (b) Output voltage of VTA1 is 0.2 V or less, and VTA2 is 1.75 V or less for 0.4 seconds or more | Short between VTA1 and VTA2 circuits Throttle position sensor (built into throttle body assembly) ECM |
The ECM uses the throttle position sensor to monitor the throttle valve opening angle. There are several checks that the ECM performs to confirm the proper operation of the throttle position sensor.
P0120, P0122, P0123, P0220, P0222, P0223 and P2135
- 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 circuit, and stores a DTC.
- 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 circuit, and stores a DTC.
- 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 circuit, and stores a DTC.
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 throttle position 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 throttle position sensor. The ECM illuminates the MIL and stores the DTC.
Refer to DTC P0115. Refer to DESCRIPTION.
| DTC No. | DTC Detection Condition | Trouble Area |
|---|---|---|
| P0125 | Engine coolant temperature does not reach closed-loop enabling temperature for 20 minutes (this period varies with engine start engine coolant temperature) (2 trip detection logic) | Cooling system Engine coolant temperature sensor Water inlet with thermostat sub-assembly |
The resistance of the engine coolant temperature sensor varies in proportion to the actual engine coolant temperature. The ECM 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 engine coolant temperature is monitored through this signal. If the engine coolant temperature 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
When the engine coolant temperature is 5°C (41°F) or higher at engine start: After approximately 85 seconds of running time, the engine coolant temperature 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.
HINT
This DTC relates to the water inlet with thermostat sub-assembly.
This DTC is stored when the engine coolant temperature does not reach 75°C (167°F) despite sufficient engine warm-up time having elapsed.
| DTC No. | DTC Detection Condition | Trouble Area |
|---|---|---|
| P0128 | Conditions (a), (b) and (c) are met for 5 seconds (2 trip detection logic): (a) Cold start (b) Engine warmed up (c) Engine coolant temperature less than 75°C (167°F) | Water inlet with thermostat sub-assembly Cooling system Engine coolant temperature sensor Front exhaust pipe assembly ECM |
Scheme 120
The ECM estimates the engine coolant temperature based on the starting temperature, engine loads, and engine speeds. The ECM then compares the estimated temperature with the actual engine coolant temperature. When the estimated engine coolant temperature reaches 75°C (167°F), the ECM checks the actual engine coolant temperature. If the actual engine coolant temperature is less than 75°C (167°F), the ECM interprets this as a malfunction in the water inlet with thermostat sub-assembly or the engine cooling system and stores the DTC.
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 TWC (Three-Way Catalytic Converter) is used. For the most efficient use of the TWC, the air fuel ratio must be precisely controlled so that it is always close to the stoichiometric air fuel level. 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 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 is high. The heated oxygen 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 is low. The heated oxygen sensor informs the ECM that the post-TWC 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 TWC is rich or lean, and adjusts the fuel injection duration 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 121
| DTC No. | DTC Detection Condition | Trouble Area |
|---|---|---|
| P0136 | Either condition is met: Abnormal voltage output: During active air fuel ratio control, heated oxygen sensor voltage does not increase to 0.59 V or higher for certain period of time (2 trip detection logic) Low impedance: Sensor impedance less than 5 ohms for 30 seconds or more when ECM presumes sensor to being warmed up and operating normally (2 trip detection logic) | Heated oxygen sensor (sensor 2) circuit Heated oxygen sensor (sensor 2) Air fuel ratio sensor (sensor 1) Gas leaks from exhaust system Fuel pressure Fuel injector assembly PCV valve and hose Intake system EGR valve assembly |
| P0137 | Either condition is met: Low voltage (open): During active air fuel ratio control, following conditions (a) and (b) met for certain period of time (2 trip detection logic) (a) Heated oxygen sensor voltage output less than 0.21 V (b) Target air fuel ratio rich High impedance: Sensor impedance 15 kohms or more for more than 90 seconds or more when ECM presumes sensor to be warmed up and operating normally (2 trip detection logic) | Heated oxygen sensor (sensor 2) circuit Heated oxygen sensor (sensor 2) Gas leak from exhaust system EGR valve assembly Air fuel ratio sensor (sensor 1) |
| P0138 | Extremely high voltage (short): Heated oxygen sensor voltage output exceeds 1.2 V for 10 seconds or more (2 trip detection logic) | Heated oxygen sensor (sensor 2) circuit Heated oxygen sensor (sensor 2) ECM |
| P0139 | Either condition is met: Heated oxygen sensor (sensor 2) voltage does not drop to below 0.2 V immediately after fuel cut starts (2 trip detection logic) Heated oxygen sensor voltage does not drop from 0.35 to 0.2 V immediately after air fuel cut starts (2 trip detection logic) | Heated oxygen sensor (sensor 2) circuit Heated oxygen sensor (sensor 2) Gas leaks from exhaust system EGR valve assembly |
| DTC No. | DTC Detection Conditions | Trouble Areas |
|---|---|---|
| P0136 | Not applicable | None |
| P0137 | Low voltage (open): During active air-fuel ratio control, both of the following conditions are met for a certain period of time (2 trip detection logic): (a) The Heated oxygen sensor voltage output is below 0.21 V. (b) The target air fuel ratio is rich. | Heated oxygen sensor (sensor 2) circuit Heated oxygen sensor (sensor 2) Gas leak from exhaust system EGR valve assembly Air fuel ratio sensor (sensro1) |
| P0138 | Not applicable | None |
| P0139 | Not applicable | None |
FOR MEXICO MODELS
Scheme 122
Scheme 123
Scheme 124
- Active Air fuel Ratio Control The ECM usually performs air fuel ratio feedback control so that the air fuel ratio 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 sensor malfunctions (refer to the diagram below). Active air fuel ratio control is performed for approximately 30 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 Heated Oxygen Sensor (DTC P0136) 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 heated oxygen sensor voltage does not increase to 0.59 V or higher during active air fuel ratio control, the ECM determines that the sensor voltage output is abnormal and stores DTCs P0136.
- Open in Heated Oxygen Sensor Circuit (DTC P0137) 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 heated oxygen sensor has an open circuit, or the voltage output of the sensor noticeably decreases, 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 heated oxygen sensor output does not change. While performing active air fuel ratio control, when the target air fuel ratio is rich and the heated oxygen 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. HINT: *: 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)»(ref-551527-S37227994502013051500000).
- High or Low Impedance of Heated Oxygen Sensor (DTCs P0136 or P0137) During normal air fuel ratio feedback control, there are small variations in the exhaust gas oxygen concentration. In order to continuously monitor the slight variation of the heated oxygen 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: The impedance cannot be measured using an ohmmeter. DTC P0136 indicates the deterioration of the heated oxygen sensor. The ECM stores the DTC by calculating the impedance of the sensor when the typical enabling conditions are satisfied (2 driving cycles). DTC P0137 indicates an open or short circuit in the heated oxygen sensor (2 driving cycles). The ECM stores the DTC when the impedance of the sensor exceeds the threshold 15 kohms.
- Extremely High Output Voltage of Heated Oxygen Sensor (DTC P0138) The ECM continuously monitors the heated oxygen sensor output voltage while the engine is running. DTC P0138 is stored if the heated oxygen sensor voltage output is 1.2 V or higher for 10 seconds or more.
- Abnormal Voltage Output of Heated Oxygen Sensor During Fuel-cut (DTC P0139) The sensor output voltage drops to less than 0.2 V (extremely lean status) immediately when the vehicle decelerates and fuel cut is operating. If the voltage does not drop to less than 0.2 V for 6 seconds or more, or voltage does not drop from 0.35 to 0.2 V for 1 second or more, the ECM determines that the sensor response has deteriorated, illuminates the MIL and stores a DTC.
HINT
Refer to DTC P2195. Refer to DESCRIPTION.
| DTC No. | DTC Detection Condition | Trouble Area |
|---|---|---|
| P014C | The "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 | The "Lean to Rich response rate deterioration level*" value is standard or more (2 trip detection logic) | |
| P015A | The "Rich to Lean delay level*" value is standard or more (2 trip detection logic) | |
| P015B | The "Lean to Rich delay level*" value is standard or more (2 trip detection logic) |
*: Calculated by ECM based on the air fuel ratio sensor output.
After the engine has been 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 quantity 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, DTC P014C and P014D are output.
If the air-fuel ratio sensor output timing is delayed, DTC P015A and P015B are output.
Scheme 125
The fuel trim is related to the feedback compensation value, not to the basic injection duration. The fuel trim consists of both the short-term and long-term fuel trim.
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 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 Condition | Trouble Area |
|---|---|---|
| P0171 | With warm engine and stable air fuel ratio feedback, fuel trim considerably in error to lean side (2 trip detection logic) | Intake system Fuel injector assembly Mass air flow meter sub-assembly Engine coolant temperature sensor Fuel pressure Gas leaks from exhaust system Open or short in air fuel ratio sensor (sensor 1) circuit Air fuel ratio sensor (sensor 1) PCV valve and hose PCV hose connections EGR valve assembly Wire harness or connector ECM |
| P0172 | With warm engine and stable air fuel ratio feedback, fuel trim considerably in error to rich side (2 trip detection logic) | Fuel injector assembly Mass air flow meter sub-assembly Engine coolant temperature sensor Ignition system Fuel pressure Gas leak from exhaust system Open or short in air fuel ratio sensor (sensor 1) circuit Air fuel ratio sensor (sensor 1) EGR valve assembly Wire harness or connector ECM |
HINT
- When DTC P0171 is stored, the actual air fuel ratio is on the lean side. When DTC P0172 is stored, the actual air fuel ratio is on the rich side.
- If the vehicle runs out of fuel, the air fuel ratio is lean and DTC P0171 may be stored. The MIL then illuminates.
- When the total of the short-term and long-term fuel trim values is within the malfunction threshold (and the engine coolant temperature is more than 75°C (167°F)), the system is functioning normally.
Under closed-loop fuel control, a fuel injection volume that deviates from that estimated by the ECM causes 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 value. Deviations from the ECM's estimated fuel injection volume 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 a malfunction threshold, the ECM interprets this a fault in the fuel system and stores a DTC.
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 126
When the engine misfires, high concentrations of hydrocarbons (HC) enter the exhaust gas. Extremely high hydrocarbon concentration levels can cause an increase in exhaust emission levels. Extremely high concentrations of hydrocarbons can also cause increases in the three-way catalytic converter temperature, which may cause damage to the three-way catalytic converter. To prevent this increase in emissions and to limit the possibility of thermal damage, the ECM monitors the misfire count. When the temperature of the three-way catalytic converter reaches the point of thermal degradation, the ECM blinks the MIL. To monitor misfires, the ECM uses both the camshaft position sensor and the crankshaft position sensor. The camshaft position sensor is used to identify any misfiring cylinders and the crankshaft position sensor is used to measure variations in the crankshaft rotation speed. Misfires are counted when the crankshaft rotation speed variations exceed predetermined thresholds. If the misfire count exceeds the threshold levels, and could cause emission control system performance deterioration, the ECM illuminates the MIL and stores a DTC.
| DTC No. | DTC Detection Condition | Trouble Area |
|---|---|---|
| P0300 | Simultaneous misfiring of several cylinders occurs and one of the following conditions is met (2 trip detection logic). A misfire occurs that may damage the three-way catalytic converter (MIL blinks when detect immediately). An emission deterioration misfire occurs (MIL illuminates). | Open or short in engine wire harness Connector connection Vacuum hose connections Ignition system Fuel injector assembly Fuel pressure Mass air flow meter sub-assembly Engine coolant temperature sensor Compression pressure Valve timing PCV valve and hose PCV hose connections Intake system EGR valve assembly ECM |
| P0301 P0302 P0303 P0304 | Misfiring of a specific cylinder occurs and one of the following conditions is met (2 trip detection logic). A misfire occurs that may damage the three-way catalytic converter (MIL blinks when detect immediately). An emission deterioration misfire occurs (MIL illuminates). |
When DTCs for misfiring cylinders are randomly stored, but DTC P0300 is not stored, it indicates that misfires have been detected in different cylinders at different times. DTC P0300 is only stored when several misfiring cylinders are detected at the same time.
The ECM illuminates the MIL and stores a DTC when either one of the following conditions, which could cause emission control system performance deterioration, is detected (2 trip detection logic).
- Within the first 1000 crankshaft revolutions after the engine starts, an excessive number of misfires (approximately 20 to 50 misfires per 1000 crankshaft revolutions) occurs once.
- An excessive number of misfires (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 damage, is detected.
- At a high engine speed, a sufficient amount of misfires to damage the catalyst occurring within 200 crankshaft revolutions is detected once.
- At a normal engine speed, a sufficient amount of misfires to damage the catalyst occurring within 200 crankshaft revolutions is detected 3 times.
Misfire Monitor for Mexico Models
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).
- Within the first 1000 crankshaft revolutions after the engine starts, an excessive number of misfires (approximately 500 misfires per 1000 crankshaft revolutions) occurs once.
- An excessive number of misfires (approximately 250 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 the following condition, which could cause the three-way catalytic converter damage, is detected.
- A catalyst damage misfire, which is monitored every 200 crankshaft revolutions, occurs 3 times.
A flat-type knock control sensor (non-resonant type) has a structure that can detect vibrations between approximately 5 and 15 kHz.
The knock control sensor is fitted onto the engine block to detect engine knocking.
The knock control 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 Condition | Trouble Area |
|---|---|---|
| P0327 | Output voltage of knock control sensor less than 0.5 V for 1 second or more (1 trip detection logic) | Short in knock control sensor circuit Knock control sensor ECM |
| P0328 | Output voltage of knock control sensor more than 4.5 V for 1 second or more (1 trip detection logic) | Open in knock control sensor circuit Knock control sensor ECM |
HINT
When DTC P0327 or P0328 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 power switch is turned off.
Reference: Inspection using an oscilloscope
Scheme 127
The correct waveform is as shown.
| ECM Terminal Name | Between KNK1 and EKNK |
|---|---|
| Tester Range | 1 V/DIV., 1 ms./DIV. |
| Condition | Engine speed maintained at 2500 RPM after warming up engine |
If the output voltage transmitted by the knock control sensor remains low or high for more than 1 second, the ECM interprets this as a malfunction in the sensor circuit, and stores a DTC.
The monitor for DTCs P0327 and P0328 begins to run when 5 seconds have elapsed since the engine was started.
The crankshaft position sensor system consists of a No. 1 crankshaft position sensor plate and a pickup coil.
The sensor plate has 34 teeth and is installed on the crankshaft. The pickup coil is made of wound copper wire, an iron core and magnet. The No. 1 crankshaft position sensor plate rotates and, as each tooth passes by the pickup coil, a pulse signal is created. The pickup coil generates 34 signals per engine revolution. Based on these signals, the ECM calculates the crankshaft position and engine speed. Using these calculations, the fuel injection time and ignition timing are controlled.
| DTC No. | DTC Detection Condition | Trouble Area |
|---|---|---|
| P0335 | When either of following conditions are met: (1 trip detection logic) Missing crankshaft position sensor signal despite camshaft position sensor signal inputs normal after engine cranked No crankshaft position sensor signal to ECM while engine running | Open or short in crankshaft position sensor circuit Crankshaft position sensor No. 1 crankshaft position sensor plate ECM |
Scheme 128
- Reference: Inspection using an oscilloscope. HINT: The correct waveform is as shown. A failure of the ground for the shielding of the wiring may result in noisy waveforms. ECM Terminal Name Between NE+ and NE- Tester Range 5 V/DIV., 20 ms./DIV. Condition Idling with warm engine
If there is no signal from the crankshaft position sensor despite the engine rotating, the ECM interprets this as a malfunction of the sensor.
The camshaft position sensor for intake camshaft (G2 signal) consists of a magnet and MRE (Magneto Resistance Element).
The camshaft has a timing rotor for the camshaft position sensor. When the camshaft rotates, changes occur in the air gaps between the timing rotor and MRE, which affects the magnet. As a result, the resistance of the MRE material fluctuates. The camshaft position sensor converts the camshaft rotation data to pulse signals, and uses the pulse signals to determine the camshaft angle, which it sends to the ECM. Then the ECM uses this data to control fuel injection time and injection timing.
| DTC No. | DTC Detection Condition | Trouble Area |
|---|---|---|
| P0340 | When either of following conditions is met: (1 trip detection logic) No camshaft position sensor signal to ECM at engine speed 600 RPM or more Missing camshaft position sensor signal despite crankshaft position sensor inputs normal at engine speed of 600 RPM or more | Open or short in camshaft position sensor circuit Camshaft position sensor Intake camshaft Valve timing ECM |
| P0342 | Output voltage of camshaft position sensor less than 0.3 V for 4 seconds (1 trip detection logic) | Open or short in camshaft position sensor circuit Camshaft position sensor ECM |
| P0343 | Output voltage of camshaft position sensor more than 4.7 V for 4 seconds (1 trip detection logic) | Open or short in camshaft position sensor circuit Camshaft position sensor ECM |
Reference: Inspection using an oscilloscope.
Scheme 129
The correct waveform is as shown.
| ECM Terminal Name | Between G2+ and G2 |
|---|---|
| Tester Range | 5 V/DIV., 20 ms./DIV. |
| Condition | Idling with warm engine |
If no signal is transmitted by the camshaft position sensor despite the engine revolving, or the rotation of the camshaft and the crankshaft is not synchronized, the ECM interprets this as a malfunction of the sensor.
HINT
- These DTCs indicate malfunctions relating to the primary circuit.
- If DTC P0351 is output, check the No. 1 ignition coil assembly circuit.
- If DTC P0352 is output, check the No. 2 ignition coil assembly circuit.
- If DTC P0353 is output, check the No. 3 ignition coil assembly circuit.
- If DTC P0354 is output, check the No. 4 ignition coil assembly circuit.
A Direct Ignition System (DIS) is used on this vehicle.
The DIS is an ignition system in which each cylinder is ignited by it's own ignition coil assembly and spark plug. The secondary wiring of each ignition coil generates a powerful voltage which is applied directly to each spark plug. The spark passes from the center electrode of the spark plug to the ground electrode.
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 130
| DTC No. | DTC Detection Conditions | Trouble Areas |
|---|---|---|
| P0351 P0352 P0353 P0354 | No IGF signal to ECM while engine running (1 trip detection logic) | Ignition system Open or short in IGF or IGT circuit (1 to 4) between ignition coil assembly and ECM No. 1 to No. 4 ignition coil assemblies ECM |
Reference: Inspection using an oscilloscope.
Scheme 131
HINT
While idling the engine, check the waveform between terminals IGT (1 to 4) and E1, and IGF and E1 of the ECM connector.
| ECM Terminal Name | CH1: Between IGT (1 to 4) and E1 CH2: Between IGF and E1 |
|---|---|
| Tester Range | 2 V/DIV., 20 ms./DIV. |
| Condition | Idling |
Scheme 132
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 a DTC.
Based on the driving conditions, the ECM regulates the volume of exhaust gas that is recirculated to the engine's combustion chambers and thus lowers the combustion temperature to reduce NOx emissions. The ECM monitors signals such as engine speed, coolant temperature, electric load, and vehicle speed. When the EGR permission conditions are fulfilled, the ECM controls the opening of the EGR valve linearly through signals to the EGR step motor.
| DTC No. | DTC Detection Condition | Trouble Area |
|---|---|---|
| P0401 | Change in intake manifold pressure is small when the EGR valve is opened and closed during idle fuel cut operation. (2 trip detection logic) | EGR valve assembly EGR passage EGR pipe with cooler sub-assembly Manifold absolute pressure sensor ECM |
The ECM monitors the pressure inside the intake manifold while opening and closing the EGR valve during fuel cut operation. If there is no change in the manifold absolute pressure sensor value, the ECM interprets this as a malfunction in the EGR valve assembly, illuminates the MIL and stores the DTC (2 trip detection logic).
Refer to DTC P0401. Refer to DESCRIPTION.
| DTC No. | DTC Detection Condition | Trouble Area |
|---|---|---|
| P0403 | Open or short in EGR valve assembly circuit (1 trip detection logic) | Open or short in EGR valve assembly circuit EGR valve assembly ECM |
This DTC is designed to detect an open or short in the EGR valve assembly circuit.
Example
- If the EGR1, EGR2, EGR3 or EGR4 terminal output voltage is excessively low, but the step motor is still operating, the ECM determines that there is a short in the EGR valve assembly circuit, and stores the DTC.
- If the EGR1, EGR2, EGR3 or EGR4 terminal output voltage is excessively low, and the step motor is not operating, the ECM determines that there is an open in the EGR valve assembly circuit, and stores the DTC.
The ECM uses sensors mounted in front of and behind the Three-Way Catalytic Converter (TWC) to monitor its efficiency.
The first sensor, the air fuel ratio sensor, sends pre-catalyst information to the ECM. The second sensor, the heated oxygen sensor, sends post-catalyst information to the ECM.
In order to detect any deterioration in the three-way catalytic converter, the ECM calculates the oxygen storage capacity of the three-way catalytic converter. This calculation is based on the voltage output of the heated oxygen sensor while performing active air fuel ratio control.
The oxygen storage capacity value is an indication of the oxygen storage capacity of the three-way catalytic converter. When the vehicle is being driven with a warm engine, active air fuel ratio control is performed for approximately 30 seconds. When it is performed, the ECM deliberately sets the air fuel ratio to lean or rich levels. If the cycle of the waveform for the heated oxygen sensor is long, the oxygen storage capacity is great. There is a direct correlation between the heated oxygen sensor and the oxygen storage capacity of the three-way catalytic converter.
The ECM uses the oxygen storage capacity value to determine the state of the three-way catalytic converter. If any deterioration has occurred, the ECM illuminates the MIL and stored the DTC.
This system determines the deterioration of the entire catalyst system (including the front and rear catalysts), by using the oxygen storage capacity value of the front catalyst, that is more sensitive than the rear catalyst, as the representative value. Therefore, be sure to replace the front and rear catalysts together when catalyst replacement is necessary.
| DTC No. | DTC Detection Condition | Trouble Area |
|---|---|---|
| P0420 | Oxygen storage capacity value smaller than standard value under active air fuel ratio control (2 trip detection logic) | Gas leaks from exhaust system Air fuel ratio sensor (sensor 1) Heated oxygen sensor (sensor 2) Front exhaust pipe assembly (TWC: Front and rear catalyst) EGR valve assembly |
Scheme 133
| *A | W/ Exhaust Heat Recirculation System | *B | W/o Exhaust Heat Recirculation System |
|---|---|---|---|
| *1 | Air Fuel Ratio Sensor (Sensor 1) | *2 | Exhaust Manifold Sub-assembly |
| *3 | Front Exhaust Pipe Assembly | *4 | Heated Oxygen Sensor (Sensor 2) |
| *5 | Tail Exhaust Pipe Assembly | *6 | TWC: Front Catalyst |
| *7 | TWC: Rear Catalyst |
TEXT IN ILLUSTRATION
Note. When replacing the front exhaust pipe assembly in order to replace the three-way catalytic converter, it is not necessary to replace the heated oxygen sensor.
The description can be found in the EVAP (Evaporative Emission) System. Refer to DESCRIPTION.
5 hours* after the power switch is turned off, the leak detection pump creates negative pressure (vacuum) in the EVAP system. The ECM monitors for leaks and actuator malfunctions based on the EVAP pressure.
HINT
*: If the engine coolant temperature is not less than 35°C (95°F) 5 hours after the power switch is turned off, the monitor check starts 2 hours later. If it is still not less than 35°C (95°F) 7 hours after the power switch is turned off, the monitor check starts 2.5 hours later.
| Sequence | Operation | Description | Duration |
|---|---|---|---|
| ECM activation | Activated by soak timer, 5, 7 or 9.5 hours after power switch turned off. | ||
| A | Atmospheric pressure measurement | Vent valve is turned off (vent) and EVAP system pressure is measured by ECM in order to register atmospheric pressure. If pressure in EVAP system is not between 70 kPa(abs) and 111 kPa(abs) [525 mmHg(abs) and 833 mmHg(abs)], ECM cancels EVAP system monitor. | 60 seconds |
| B | First reference pressure measurement | In order to determine reference pressure, leak detection pump creates negative pressure (vacuum) through reference orifice and then ECM checks if leak detection pump and vent valve operate normally. | 360 seconds |
| C | EVAP system pressure measurement | Vent valve is turned on (closed) to shut EVAP system. Negative pressure (vacuum) is created in EVAP system, and EVAP system pressure is then measured. Write down measured value as it will be used in leak check If EVAP pressure does not stabilize within 15 minutes, ECM cancels EVAP system monitor. | 15 minutes* |
| D | Purge VSV monitor | Purge VSV is opened and then EVAP system pressure is measured by ECM. Large increase indicates normal. | 10 seconds |
| E | Second reference pressure measurement | After second reference pressure measurement, leak check is performed by comparing first and second reference pressure measurements. If stabilized system pressure is higher than second reference pressure, ECM determines that EVAP system is leaking. | 60 seconds |
| Final check | Atmospheric pressure is measured and then monitoring result is recorded by ECM. |
*: If only a small amount of fuel is in the fuel tank, it takes longer for the EVAP pressure to stabilize.
Scheme 134
| *1 | Purge VSV: Off (Closed) | *2 | Purge VSV: On (Open) |
|---|---|---|---|
| *3 | Vent Valve: Off (Vent) | *4 | Vent Valve: On (Closed) |
| *5 | Leak Detection Pump: Off | *6 | Leak Detection Pump: On |
| *7 | Reference Orifice (0.02 inch) | *8 | Canister Pressure Sensor |
| *9 | Canister | *10 | No. 1 Canister |
| *11 | No. 2 Canister | *12 | Canister Pump Module |
| *13 | Canister Air Filter | *14 | Fuel Tank |
| *a | Operation A: Atmospheric Pressure Measurement | *b | Operation B, E: Reference Pressure Measurement |
| *c | Operation C: EVAP System Pressure Measurement | *d | Operation D: Purge VSV Monitor |
| *e | Atmospheric Pressure | *f | Negative Pressure |
TEXT IN ILLUSTRATION
The leak detection pump creates negative pressure through the reference orifice (in operation B and E). When the system is normal, the EVAP pressure is between 97 to 100 kPa(abs) [728 to 750 mmHg(abs)]* and saturated within a minute. If not, the ECM interprets this as a malfunction. The ECM illuminates the MIL and stores a DTC if this malfunction is detected in consecutive drive cycles.
*: Typical value.