SFI SYSTEM DATA LIST / ACTIVE TEST

• Stored as Freeze Frame Data: Yes

• This is the current vehicle speed.

• The vehicle speed is detected using the wheel speed sensors.

• • Vehicle speed data is delayed when it is displayed. Therefore, even if the vehicle speed listed in the freeze frame data is 0 km/h (0 mph), this does not always mean that the malfunction occurred when the vehicle was stopped.

  • To accurately confirm whether the vehicle was stopped or not, use "SPD (NO)", which is the CVT output speed (for CVT Models).

• Stored as Freeze Frame Data: Yes

• When the crankshaft position sensor is malfunctioning, "Engine Speed" is approximately 0 rpm or varies greatly from the actual engine speed.

• Stored as Freeze Frame Data: Yes

• This is the engine load calculated based on the estimated intake manifold pressure.

• Calculate Load = Actual intake manifold pressure / maximum intake manifold pressure x 100 (%)

  (For example, when the actual intake manifold pressure is the same as atmospheric pressure, Calculate Load is 100%.)

• Stored as Freeze Frame Data: Yes

• This is the engine intake air charging efficiency.

• Vehicle Load = Current intake airflow (g/rev.) / maximum intake airflow x 100%

  Maximum intake airflow = Displacement (L) / 2 x 1.2 (g/rev.)

• Stored as Freeze Frame Data: Yes

• This is the intake air amount from the mass air flow meter sub-assembly.

• Stored as Freeze Frame Data: Yes

• Standard atmospheric pressure: 101 kPa(abs) [758 mmHg(abs)]

• For every 100 m (328 ft.) increase in altitude, pressure drops by 1 kPa (7.5 mmHg). This varies by weather.

• Stored as Freeze Frame Data: Yes

• This is the intake manifold pressure.

• Stored as Freeze Frame Data: Yes

• This is the engine oil temperature.

• Stored as Freeze Frame Data: Yes

• This is the engine coolant temperature.

• Stored as Freeze Frame Data: Yes

• After a long soak, the engine coolant temperature, intake air temperature and ambient air temperature are approximately equal.

• If the value is -40°C (-40°F), or 140°C (284°F), the sensor circuit is open or shorted.

• Stored as Freeze Frame Data: Yes

• This is the time elapsed since the engine started.

• Stored as Freeze Frame Data: Yes

• This is the coolant temperature stored when the ignition switch is turned to ON.

• Stored as Freeze Frame Data: Yes

• This is the intake air temperature stored when the ignition switch is turned to ON.

• Stored as Freeze Frame Data: Yes

• If 11 V or less, characteristics of some electrical components may change.

• Stored as Freeze Frame Data: No

• The accelerator pedal position sensor No. 1 output is converted using 5 V = 100%.

• Stored as Freeze Frame Data: Yes

• The accelerator pedal position sensor No. 1 output is converted using 5 V = 100%.

• Stored as Freeze Frame Data: Yes

• The accelerator pedal position sensor No. 2 output is converted using 5 V = 100%.

• Stored as Freeze Frame Data: No

• This is the raw voltage from the accelerator pedal position sensor No. 1.

• Stored as Freeze Frame Data: No

• This is the raw voltage from the accelerator pedal position sensor No. 2.

• Accelerator pedal position sensor No. 2 is used to monitor accelerator pedal position sensor No. 1. When there is a malfunction in sensor No. 1, the ECM uses sensor No. 2 to control the engine.

• Stored as Freeze Frame Data: No

• This is a parameter calculated by the ECM which indicates whether the accelerator pedal is in the learned idle position.

• Stored as Freeze Frame Data: No

• This is the value of accelerator pedal position sensor No. 1 learned when the accelerator pedal is released.

• Stored as Freeze Frame Data: No

• This is the value of accelerator pedal position sensor No. 2 learned when the accelerator pedal is released.

• Stored as Freeze Frame Data: Yes

• The throttle position sensor No. 1 output is converted using 5 V = 100%.

• Stored as Freeze Frame Data: Yes

• The throttle position sensor No. 2 output is converted using 5 V = 100%.

• Stored as Freeze Frame Data: No

• This is the stop light switch assembly signal (ST1- terminal).

• Stored as Freeze Frame Data: No

• When there is a difference between the target and actual throttle valve opening angles, system guard turns off and stops the electronic throttle control system function.

• OFF: Electronic throttle control is stopped.

• Stored as Freeze Frame Data: No

• This parameter indicates a malfunction in the electronic throttle when the throttle valve is open.

• Stored as Freeze Frame Data: No

• This is a parameter calculated by the ECM.

• The value is ON when the throttle is at the idle position and OFF when the throttle is open.

• Stored as Freeze Frame Data: No

• This is a value calculated by the ECM showing the voltage for the target throttle valve position. It is almost an exact match of the Throttle Position No. 1 value except during very rapid throttle valve movement, such as that used during wheelspin control.

• Stored as Freeze Frame Data: Yes

• This is the throttle valve opening amount used for engine control.

  (100% signifies 125° of throttle valve rotation. This does not include the amount the throttle valve is opened to maintain the idle speed during idling.)

• This value has no meaning when the ignition switch is ON and the engine is stopped.

• The throttle valve opening amount during idling is indicated by 0%. When the throttle valve is fully open, the value is 68%.

• Stored as Freeze Frame Data: No

• This is the throttle position sensor No. 1 output voltage.

• Stored as Freeze Frame Data: No

• This is the throttle position sensor No. 2 output voltage.

• Stored as Freeze Frame Data: No

• Throttle Position Command is the same value as Throttle Require Position.

• Stored as Freeze Frame Data: No

• This is the throttle position sensor No. 1 output voltage when there is no current supplied to the electronic throttle actuator. The accelerator pedal is released but the throttle valve is kept open by the throttle valve opener with the ignition switch ON.

• Stored as Freeze Frame Data: No

• This is the throttle position sensor No. 2 output voltage when there is no current supplied to the electronic throttle actuator. The accelerator pedal is released but the throttle valve is kept open by the throttle valve opener with the ignition switch ON.

• Stored as Freeze Frame Data: No

• When this value is large but the actual opening angle (Throttle Position No. 1) does not reach the target opening angle (Throttle Require Position), there is an "unable to open" malfunction.

• This value normally fluctuates around 1 A.

• Stored as Freeze Frame Data: Yes

• This is the output duty ratio of the throttle actuator drive circuit.

• Stored as Freeze Frame Data: No

• This is the duty ratio used to drive the throttle actuator and open the throttle valve. It is an ECM command signal.

• When the throttle valve is being opened, Throttle Motor Duty (Open) is 10 to 50%.

• Stored as Freeze Frame Data: No

• This is the duty ratio used to drive the throttle actuator and close the throttle valve. It is an ECM command signal.

• Stored as Freeze Frame Data: No

• The ECM uses this learned value to determine the fully closed (and fully open) position of the throttle valve. This learned value is calculated by the ECM with the throttle valve opener angle (approximately 4 to 7°, the position when the ignition switch is ON, the accelerator pedal is released and the throttle actuator is off).

• Learning is performed immediately after the ignition switch is turned to ON.

• Stored as Freeze Frame Data: No

• This is the power supply for the electronic throttle actuator. When the power supply is interrupted for approximately 1 second, DTCs P2118 (open circuit) and P0657 (short circuit, ECU malfunction) are stored and the electronic throttle control system enters fail-safe mode (normal operation is not restored until the ignition switch is turned off).

• Stored as Freeze Frame Data: No

• If +BM power is lost, this item changes to OFF.

• Stored as Freeze Frame Data: Yes

• This value has no meaning when the ignition switch is ON and the engine is stopped.

• Stored as Freeze Frame Data: Yes

• This is the total ISC airflow amount (the amount of intake air necessary to maintain idling).

• Stored as Freeze Frame Data: Yes

• This is the throttle valve opening amount while the engine is idling (the throttle valve opening amount necessary to maintain ISC air flow).

• Stored as Freeze Frame Data: Yes

• This is the feedback amount necessary to adjust the airflow amount to maintain the target idling speed.

• Stored as Freeze Frame Data: Yes

• This is the learned value of the airflow amount necessary for engine idling.

• Stored as Freeze Frame Data: Yes

• This is the ISC compensation amount determined according to the electrical load.

• Stored as Freeze Frame Data: Yes

• This is the ISC compensation amount determined according to the air conditioner load.

• Stored as Freeze Frame Data: Yes

• This parameter indicates whether the engine speed dropped immediately after starting due to poor combustion, etc. This parameter changes to ON when the engine speed drops to below the following speeds 1 to 7 seconds after the engine is started (when the A/C is on, the engine speed thresholds below increase by 100 to 200 rpm).

• • 900 rpm (when the engine coolant temperature is 10°C (50°F))

• • 850 rpm (when the engine coolant temperature is 30°C (86°F))

• • 750 rpm (when the engine coolant temperature is 60°C (140°F))

    Before 5 seconds elapse after starting the engine, this parameter indicates the status of the previous trip.

    After 5 seconds elapse after starting the engine, this parameter indicates the status of the current trip.

    Tip:

    The engine is considered to have started when the engine speed reaches 400 rpm. When the engine speed decreases immediately after starting the engine, this parameter changes to ON and remains ON for the rest of the trip.

    ON: The engine speed decreased immediately after starting the engine.

    OFF: The engine speed did not decrease immediately after starting the engine.

• For use when engine stall, starting problems or rough idle is present.

• Stored as Freeze Frame Data: Yes

• This item is displayed only for CVT models.

• Stored as Freeze Frame Data: Yes

• The intake air amount and ignition timing are adjusted when there is a large decrease in engine speed (for example, a decrease to 550 rpm or less) in order to prevent engine stall.

• For use when engine stall, starting problems or rough idle is present.

• Stored as Freeze Frame Data: Yes

• This is the injection period of the No. 1 cylinder (the command value from the ECM).

• Stored as Freeze Frame Data: Yes

• This is the fuel injection volume for 10 injections.

• Stored as Freeze Frame Data: Yes

• This is the command signal from the ECM.

• This is the purge VSV control duty ratio. When EVAP (Purge) VSV is any value except 0%, EVAP purge* is being performed.

  *: Gasoline vapor from the fuel tank is being introduced into the intake system via the purge VSV.

• When the engine is cold or immediately after the engine is started, EVAP (Purge) VSV is 0%.

• Stored as Freeze Frame Data: Yes

• This is the percentage of total engine airflow contributed by EVAP purge operation.

  (Evap Purge Flow = Purge flow / Engine airflow x 100 (%))

• It is based on MAF and a stored value for airflow and controlled by adjusting the duty cycle for the purge VSV.

• Stored as Freeze Frame Data: Yes

• Purge Density Learn Value is the proportion of the decrease in injection volume (based on the change in the air fuel ratio feedback compensation value) related to a 1% purge flow rate.

  When Purge Density Learn Value is a large negative value, the purge effect is large.

• The purge density is determined from the change in the air fuel ratio feedback compensation value when purge flow is introduced.

• Purge density learning is performed so that the feedback compensation value is 0 +/-2%.

• Stored as Freeze Frame Data: Yes

• This parameter displays ON when EVAP (Purge) VSV is 30% or more, and displays OFF when the VSV duty ratio is less than 30%.

• Stored as Freeze Frame Data: Yes

• This is the target air fuel ratio used by the ECM.

• 1.0 is the stoichiometric air fuel ratio. Values that are more than 1 indicate the system attempting to make the air fuel ratio leaner. Values that are less than 1 indicate the system attempting to make the air fuel ratio richer.

• Target Air-Fuel Ratio and AF Lambda B1S1 are related.

• Stored as Freeze Frame Data: Yes

• This is the actual air fuel ratio calculated based on the air fuel ratio sensor output.

• Performing the "Control the Injection Volume" or "Control the Injection Volume for A/F Sensor" function of the Active Test enables the technician to check the voltage output of the sensor.

• Results of real-vehicle check when performing the Active Test:

• • Injection Volume: +/-0%

    AF Lambda B1S1: 0.99

    AFS Voltage B1S1: 3.29 V

    AFS Current B1S1: 0.00 mA

    O2S B1S2: 0.8 V

  • Injection Volume: -12.5%

    AF Lambda B1S1: 1.14

    AFS Voltage B1S1: 3.84 V

    AFS Current B1S1: 0.22 mA

    O2S B1S2: 0.05 V

  • Injection Volume: 12.5%

    AF Lambda B1S1: 0.93

    AFS Voltage B1S1: 2.83 V

    AFS Current B1S1: -0.16 mA

    O2S B1S2: 0.95 V

• Stored as Freeze Frame Data: Yes

• This is the voltage output of the air fuel ratio sensor (the voltage cannot be measured at the terminals of the sensor). This value is calculated by the ECM based on the current output of the air fuel ratio sensor (refer to AFS Current B1S1 below for the actual sensor output).

• Performing the Control the Injection Volume or Control the Injection Volume for A/F Sensor function of the Active Test enables the technician to check the voltage output of the sensor.

• Stored as Freeze Frame Data: Yes

• With a stoichiometric air fuel ratio (for example, during idling after the engine is warmed up), the air fuel ratio sensor current output is approximately -0.5 to 0.5 mA.

• When the value is outside the range of 0.7 to 2.2 mA when the fuel-cut is being performed, there is a malfunction in the air fuel ratio sensor or sensor circuit.

• Stored as Freeze Frame Data: Yes

• When the value is any value except 0%, current is being supplied to the heater.

• Stored as Freeze Frame Data: Yes

• This is the output voltage of the heated oxygen sensor.

• Values close to 0 V indicate an air fuel ratio leaner than the stoichiometric ratio.

• Values close to 1 V indicate an air fuel ratio richer than the stoichiometric ratio.

• During air fuel ratio feedback control, the value moves back and forth in the range of 0 to 1 V.

• Performing the "Control the Injection Volume" or "Control the Injection Volume for A/F Sensor" function of the Active Test enables the technician to check voltage output of the sensor.

• Results of real-vehicle check when performing the Active Test:

• • Injection Volume: -12.5%

    AF Lambda B1S1: 1.14

    AFS Voltage B1S1: 3.84 V

    AFS Current B1S1: 0.22 mA

    O2S B1S2: 0.05 V

  • Injection Volume: 12.5%

    AF Lambda B1S1: 0.93

    AFS Voltage B1S1: 2.83 V

    AFS Current B1S1: -0.16 mA

    O2S B1S2: 0.95 V

• Stored as Freeze Frame Data: Yes

• After driving approximately 10 min. in an urban area: 5 to 15000 ohm

• Stored as Freeze Frame Data: Yes

• When the value is any value except 0 A, current is being supplied to the heater.

• Stored as Freeze Frame Data: Yes

• This item is the "short-term fuel injection volume compensation ratio" used to maintain the air fuel ratio at the stoichiometric ratio using the air fuel ratio sensor for feedback.

• Stored as Freeze Frame Data: Yes

• The ECM will learn the Long FT #1 values based on Short FT #1. The goal is to keep Short FT #1 at 0% to keep the air fuel ratio mixture at the stoichiometric ratio.

• This value is used to determine whether the system related to air fuel ratio control is malfunctioning.

• The condition of the system is determined based on the sum of Short FT #1 and Long FT #1 (excluding times when the system is in transition).

• • 20% or more: There may be a lean air fuel ratio.

  • -20 to 20%: The air fuel ratio can be determined to be normal.

  • -20% or less: There may be a rich air fuel ratio.

  • Air fuel ratio feedback learning is divided up according to the engine operating range (engine speed x load), and a separate value is stored for each operating range. "Long FT #1" indicates the learned value for the current operating range.

    [A/F Learn Value Idle #1], [A/F Learn Value Low #1], [A/F Learn Value Mid1 #1], [A/F Learn Value Mid2 #1] and [A/F Learn Value High #1] indicate the learned values for the different operating ranges. The learned value that is the same as "Long FT #1" indicates the current engine operating range.

• Stored as Freeze Frame Data: Yes

• Total FT #1 = Short FT #1 + Long FT #1

• Stored as Freeze Frame Data: Yes

• OL (Open Loop): Has not yet satisfied conditions to go to closed loop.

• CL (Closed Loop): Uses feedback to perform fuel control.

• OLDrive: Open loop due to driving conditions (fuel enrichment).

• OLFault: Open loop due to a detected system fault.

• CLFault: Closed loop but the air fuel ratio sensor, which is used for fuel control, is malfunctioning.

• Stored as Freeze Frame Data: Yes

• Learning is performed when idling with the engine warmed up (engine coolant temperature is 80°C [176°F] or higher).

• Stored as Freeze Frame Data: Yes

• Learning is performed when driving with the engine warmed up (engine coolant temperature is 80°C [176°F] or higher) and operating in the low load range (when the range of engine loads is divided into four parts).

• Stored as Freeze Frame Data: Yes

• Learning is performed when driving with the engine warmed up (engine coolant temperature is 80°C [176°F] or higher) and operating in the mid-size load range closer to the low load range (when the range of engine loads is divided into four parts).

• Stored as Freeze Frame Data: Yes

• Learning is performed when driving with the engine warmed up (engine coolant temperature is 80°C [176°F] or higher) and operating in the mid-size load range closer to the high load range (when the range of engine loads is divided into four parts).

• Stored as Freeze Frame Data: Yes

• Learning is performed when driving with the engine warmed up (engine coolant temperature is 80°C [176°F] or higher) and operating in the high load range (when the range of engine loads is divided into four parts).

• Stored as Freeze Frame Data: Yes

• This is the ignition timing retard compensation amount determined by the presence or absence of knocking.

  Ignition timing = Most retarded timing value*1 + Knock Correct Learn Value*2 + Knock Feedback Value*3 + each compensation amount

  Example: 21 deg(CA) = 10 deg(CA) + 14 deg(CA) - 3 deg(CA)

  *1: The most retarded timing value is a constant determined by the engine speed and engine load.

  *2: The knock correction learned value is calculated as shown below in order to keep Knock Feedback Value as close to -3 deg(CA) as possible.

  When Knock Feedback Value is less than -4 deg(CA), Knock Correct Learn Value is slowly decreased.

  When Knock Feedback Value is more than -2 deg(CA), Knock Correct Learn Value is slowly increased.

  *3: The base value is -3 deg(CA) and is adjusted based on the presence or absence of knocking. When there is no knocking, the value is increased, and when knocking is present, the value is decreased.

  -1 deg(CA): There is no knocking and ignition timing is advanced.

  -6 deg(CA): Knocking is present and the ignition timing is being retarded.

• Stored as Freeze Frame Data: Yes

• Refer to "Knock Feedback Value".

• When there is knocking or a lack of power, compare the following values to another vehicle of the same model.

• • Engine Speed

  • Calculate Load

  • IGN Advance

  • Knock Feedback Value

  • Knock Correct Learn Value

• Knock Correct Learn Value is large: There is no knocking and the ignition timing is advanced.

• Knock Correct Learn Value is small: Knocking is present and the ignition timing is being retarded.

• Stored as Freeze Frame Data: Yes

• This is the ignition timing advance compensation amount used to stabilize idling (each cylinder has a separate value). When the speed for a certain cylinder drops, the system advances the timing for that particular cylinder in an attempt to restore the speed and stabilize idling.

• It may be possible to use this item to help determine specific cylinders which are not operating normally.

• Stored as Freeze Frame Data: Yes

• This is the ignition timing advance compensation amount used to stabilize idling (each cylinder has a separate value). When the speed for a certain cylinder drops, the system advances the timing for that particular cylinder in an attempt to restore the speed and stabilize idling.

• It may be possible to use this item to help determine specific cylinders which are not operating normally.

• Stored as Freeze Frame Data: Yes

• This is the ignition timing advance compensation amount used to stabilize idling (each cylinder has a separate value). When the speed for a certain cylinder drops, the system advances the timing for that particular cylinder in an attempt to restore the speed and stabilize idling.

• It may be possible to use this item to help determine specific cylinders which are not operating normally.

• Stored as Freeze Frame Data: Yes

• This is the ignition timing advance compensation amount used to stabilize idling (each cylinder has a separate value). When the speed for a certain cylinder drops, the system advances the timing for that particular cylinder in an attempt to restore the speed and stabilize idling.

• It may be possible to use this item to help determine specific cylinders which are not operating normally.

• Stored as Freeze Frame Data: Yes

• This is the ECM control command.

• Stored as Freeze Frame Data: Yes

• ON: The ECM is sending commands to change the timing (even when the timing is advanced, when the timing is being maintained and not being retarded or advanced any further, the value changes to OFF).

• OFF: The system is commanding the timing to change to the most retarded timing.

• Stored as Freeze Frame Data: Yes

• ON: There is an intake VVT timing advance malfunction.

• Stored as Freeze Frame Data: No

• This value represents the duty ratio necessary to operate the camshaft timing oil control valve assembly in order to block the camshaft timing oil control valve assembly path and maintain the advanced state of the VVT controller.

• Refer to "VVT OCV Duty #1".

• Stored as Freeze Frame Data: No

• This is the VVT displacement angle during forced operation.

• By checking VVT Change Angle during the Active Test, it is also possible to determine whether or not the camshaft position sensor signal is being output.

• Refer to "VVT OCV Duty #1".

• Stored as Freeze Frame Data: No

• This is the requested duty value for forced operation.

• Stored as Freeze Frame Data: No

• This value represents the duty ratio necessary to operate the camshaft timing oil control valve assembly in order to block the camshaft timing oil control valve assembly path and maintain the advanced state of the VVT controller.

• Refer to "VVT Ex OCV Duty #1".

• Stored as Freeze Frame Data: No

• This is the displacement angle during forced operation.

• Refer to "VVT Ex OCV Duty #1".

• Stored as Freeze Frame Data: No

• This is the requested duty value for forced operation.

• Stored as Freeze Frame Data: Yes

• Minimum duration: 106 deg(CA)

• Maximum duration: 280 deg(CA)

• Stored as Freeze Frame Data: Yes

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• Stored as Freeze Frame Data: Yes

• This is the temperature of the front catalyst estimated by the ECM.

• This value is included in the conditions used to detect catalyst deterioration (DTC P0420), etc., and should therefore be used as a reference when recreating malfunction conditions.

• Stored as Freeze Frame Data: Yes

• This is the temperature of the rear catalyst estimated by the ECM.

• Stored as Freeze Frame Data: Yes

• This item is displayed only for CVT models.

• Stored as Freeze Frame Data: Yes

• This item is displayed only for manual transaxle models.

• Stored as Freeze Frame Data: Yes

• This item is displayed only for manual transaxle models.

• Stored as Freeze Frame Data: No

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• This is the number of DTCs stored.

• Stored as Freeze Frame Data: No

• This is the distance driven after a DTC is stored.

• Stored as Freeze Frame Data: Yes

• This is the time elapsed after DTCs were cleared (or after the vehicle left the factory). Time elapsed after the ignition switch is turned off is not counted.

• Stored as Freeze Frame Data: Yes

• This is the distance driven after DTCs were cleared (or after the vehicle left the factory).

• Stored as Freeze Frame Data: Yes

• This is the number of warmup cycles after the DTCs were cleared.

• This is the number of times the engine was warmed up* after DTCs were cleared (or after the vehicle left the factory).

  *: An engine warmup is defined as the engine coolant temperature rising 20°C (36°F) or more and reaching a temperature of 70°C (158°F) or higher after the engine is started.

• Stored as Freeze Frame Data: No

• This is the number of emissions-related DTCs.

• Stored as Freeze Frame Data: Yes

• This is the cumulative number of ignitions.

• This counter is incremented by one for each ignition (this stops when misfire monitoring stops). This value is cleared every 200 revolutions.

• The misfire rate for each cylinder is calculated by dividing the misfire count for each cylinder by Ignition Trig. Count.

• The misfire rate for each cylinder = Cylinder 1 to 4 Misfire Count / Ignition Trig. Count

• Stored as Freeze Frame Data: Yes

• This is the misfire count for each individual cylinder.

• This counter is increased by one for each misfire and is cleared every 200 revolutions.

• Check this item to help determine the malfunctioning cylinder.

• Stored as Freeze Frame Data: Yes

• This is the misfire count for each individual cylinder.

• This counter is increased by one for each misfire and is cleared every 200 revolutions.

• Check this item to help determine the malfunctioning cylinder.

• Stored as Freeze Frame Data: Yes

• This is the misfire count for each individual cylinder.

• This counter is increased by one for each misfire and is cleared every 200 revolutions.

• Check this item to help determine the malfunctioning cylinder.

• Stored as Freeze Frame Data: Yes

• This is the misfire count for each individual cylinder.

• This counter is increased by one for each misfire and is cleared every 200 revolutions.

• Check this item to help determine the malfunctioning cylinder.

• Stored as Freeze Frame Data: Yes

• This is the total misfire count of all cylinders.

• This counter is increased by one for each misfire, has a maximum value of 255 and is cleared every 1000 revolutions.

• Stored as Freeze Frame Data: Yes

• This is the average engine speed recorded when misfiring occurs.

• This value is closer to the actual conditions of the vehicle at the time misfire occurred than the values of engine speed and engine load stored in the freeze frame data. When reproducing malfunction conditions, use this value as a reference.

• Stored as Freeze Frame Data: Yes

• This is the average engine load recorded when misfiring occurs.

• This value is closer to the actual conditions of the vehicle at the time misfire occurred than the values of engine speed and engine load stored in the freeze frame data. When reproducing malfunction conditions, use this value as a reference.

• Stored as Freeze Frame Data: Yes

• This is the misfire detection margin.

• Misfire Margin = (Misfire detection threshold - maximum engine speed variation) / misfire detection threshold x 100%

• When the variation in the engine speed is large and exceeds the misfire detection threshold, the misfire count starts. Misfire margin is a measure of how much the engine speed variation can increase with respect to the threshold before the engine is determined to be misfiring.

• A large value means there is a large margin for the engine speed to vary before the engine is determined to be misfiring.

• Stored as Freeze Frame Data: Yes

• This is the engine speed immediately after starting the engine.

• Stored as Freeze Frame Data: Yes

• Indicates the number of times starter turned ON in the current driving cycle. (However, the number of times the starter turned ON due to stop and start control is not counted.)

• Number of times starter turned ON before engine started displayed in the 1 position.

• Number of times starter turned ON after engine started displayed in the 10 position.

Example:

If "21" is displayed on the GTS, the starter was turned ON 1 time before engine start and turned ON 2 times after engine start. (The maximum value for each counter is 9 times before engine start and 11 times after engine start)

• Stored as Freeze Frame Data: Yes

• Before 5 seconds elapse after starting the engine, which is DTC P1604 (Startability Malfunction) detection duration, this parameter indicates the distance driven during the previous trip.

• After 5 seconds elapse after starting the engine, this parameter indicates the distance driven during the current trip calculated from the vehicle speed signal.

• Stored as Freeze Frame Data: Yes

• When the counter displays 1 or higher during an engine stall, startability malfunction or rough idle, it may be the result of pressure loss caused by deposits jamming the valve, etc.

• Stored as Freeze Frame Data: Yes

• The following list of statuses indicates the degree and frequency of rough idling from highest to lowest.

  Use this as a reference when trying to reproduce the rough idling.

• 1. Misfire

  2. Continuous poor combustion

  3. Intermittent poor combustion

  4. Low frequency poor combustion

• Stored as Freeze Frame Data: Yes

• Indicates multiple cylinders are the cause of rough idling when ON.

• Stored as Freeze Frame Data: Yes

• Indicates speed has dropped compared to other cylinders and idling is rough for the indicated cylinder when ON.

• This item indicates cylinders which are likely to be the cause of rough idle.

• Stored as Freeze Frame Data: Yes

• This is the time elapsed after the starter turns on until the engine speed reaches 400 rpm.

• This value is cleared 5 seconds after the engine is started and the value is displayed as 0 ms.

• Stored as Freeze Frame Data: Yes

• Before 120 seconds elapse after starting the engine, this parameter indicates the engine coolant temperature at the end of the previous trip.

• After 120 seconds elapse after starting the engine, this parameter indicates the engine coolant temperature during the current trip.

• Stored as Freeze Frame Data: Yes

• Before 120 seconds elapse after starting the engine, this parameter indicates the intake air temperature at the end of the previous trip.

• After 120 seconds elapse after starting the engine, this parameter indicates the intake air temperature during the current trip.

• Stored as Freeze Frame Data: Yes

• This value changes to ON when the engine speed does not reach 500 rpm during cranking.

• Stored as Freeze Frame Data: Yes

• This item changes to ON when the engine speed drops to 200 rpm or less within approximately 2 seconds of starting the engine.

• Stored as Freeze Frame Data: Yes

• This is the lowest engine speed detected throughout the trip after the engine is started and ISC learning is completed.

• For use when engine stall, starting problems or rough idle is present.

• Stored as Freeze Frame Data: Yes

• The time elapsed after a fuel cut after high engine speed has occurred (more than the engine speed at which fuel cut occurs + 500 rpm).

• Stored as Freeze Frame Data: Yes

• Idle Fuel Cut = "ON" when the throttle valve is fully closed and the engine speed is high.

• Stored as Freeze Frame Data: Yes

• This is the fuel cut performed under a very light load to prevent the engine combustion from becoming incomplete.

• Stored as Freeze Frame Data: Yes

• When DTC P1604 is output and Immobiliser Fuel Cut History indicates ON, the engine could not start due to engine immobiliser operation.

• Stored as Freeze Frame Data: No

• Used for identifying the model code: ZSA4#

• Stored as Freeze Frame Data: No

• Used for identifying the engine type: 3ZRFAE

• Stored as Freeze Frame Data: No

• Used for identifying the number of cylinders: 4

• Stored as Freeze Frame Data: No

• Used for identifying the transmission (transaxle) type: CVT or MT

• Stored as Freeze Frame Data: No

• Used for identifying the destination: W

• Stored as Freeze Frame Data: No

• Used for identifying the model year: 201#

• Stored as Freeze Frame Data: No

• Used for identifying the engine system: Gasoline (gasoline engine)

• Stored as Freeze Frame Data: No

• This is output only when Check the Cylinder Compression is performed using the Active Test.

• This is the engine speed for each cylinder measured during the fuel-cut with the engine cranking.

• When there is compression loss, the engine speed for that cylinder increases.

• Stored as Freeze Frame Data: No

• This is output only when Check the Cylinder Compression is performed using the Active Test.

• This is the engine speed for each cylinder measured during the fuel-cut with the engine cranking.

• When there is compression loss, the engine speed for that cylinder increases.

• Stored as Freeze Frame Data: No

• This is output only when Check the Cylinder Compression is performed using the Active Test.

• This is the engine speed for each cylinder measured during the fuel-cut with the engine cranking.

• When there is compression loss, the engine speed for that cylinder increases.

• Stored as Freeze Frame Data: No

• This is output only when Check the Cylinder Compression is performed using the Active Test.

• This is the engine speed for each cylinder measured during the fuel-cut with the engine cranking.

• When there is compression loss, the engine speed for that cylinder increases.

• Stored as Freeze Frame Data: No

• This is output only when Check the Cylinder Compression is performed using the Active Test.