911 Targa (996) F6-3.6L (2004)
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Ignition Failure Sensor: Description and Operation
Misfire Monitoring
General Description
This method enables the detection of misfire by evaluating engine speed fluctuations of the crankshaft.
The misfire detection system consists of various subfunctions, which together guarantee a complete detection of all misfires. Common to all methods is
the evaluation of segment durations, which are corrected by means of an adaption. The misfire detected by each of the individual methods are logically
OR'd together and then further processed in the fault code management system. The fault code management system determines, among others, when the
MIL is to be triggered.
Segment Time Formation
The heart of this stratetgy is the exact determination of engine speed. This is performed by the Motronic by scanning a 60x2-teeth gear by means of an
inductive sensor. The inductive sensor's signal is processed by the Motronic and used for the formation of angle segments. The period which elapses until
the angle segment travels past the inductive sensor will be refered to as the segment time. Its length corresponds to the interval between two ignitions.
Correction of the Segment Time
The adaption during fuel cutoff (fuel-off adaption) and during firing operation (fuel-on adaptation) learns the systematic differences of the segment times
dependant upon the individual cylinder's characteristics. The correction values are included in the processing such that after adaption the resulting
segment times are identical (apart from the stochastic signal-to-noise ratio in steady-state).
Formation of the Engine Roughness Test Value
The engine roughness (angular acceleration change) for each combustion is calculated from several temporary and consecutive segment times as follows:
An example of continuous misfire in a single cylinder is shown. Engine roughness is compared to a specific load / speed dependant threshold. If the
threshold is exceeded misfire is detected.
Misfire Detection by Means of Filtered Engine Roughness
This function allows detection of continuous misfire in one or more cylinders. For this the cylinder-specific engine roughness values are filtered by
means of recursive low pass filters and compared to an accompanying threshold / reference value.
The specific threshold value is calculated from a load and engine speed dependent offset value, which are added to the lowest filtered engine roughness
value per working cycle.
Misfire Detection by Means of Engine Roughness Minus Engine Roughness 360° Crankshaft Later
This function allows the detection of random and continuous misfires, as well as non-symmetrical multiple misfires.
The detection performance is independent of sensor wheel inaccuracies (crankshaft-synchronous segment time fluctuations). However, symmetrical
multiple misfires which can also generate crankshaft-synchronous segment time fluctuations cannot be detected. A calculated value is compared to a load
and speed dependant threshold. If this threshold is exceeded misfire is detected.
Fault Handling of Misfire Statistics
Each combustion, apart from those intentionally deactivated, must be checked for misfire since misfire can be distributed randomly. However, a reaction
will only take place if a certain misfire frequency is given. The different effects of the combustion misses, such as increase in exhaust emissions, and
catalyst damage, are evaluated separately.
During the fault setting a distinction is made on whether it is an exhaust gas relevant fault (after start or during a driving cycle) or a catalyst damaging
fault. Also, an identification of the misfiring cylinder is conducted. With catalyst damaging misfires it is possible to switch off the injector of the affected
cylinder to protect the catalyst (up to a maximum of two cylinders). If more than one cylinder misses, then in addition to the cylinder specific fault entry,
an additional entry for "multiple misfiring" is set.
