Home/BMW/Z4/BMW Z4 E89 (2009-2013)/Repair manual/Testing & Diagnostics/Self Diagnosis - Theory & Operation (n52)
Contents Wiring diagrams Section: Testing & Diagnostics All sections

Self Diagnosis - Theory & Operation (n52) BMW Z4 E89

Testing & Diagnostics 24 illustrations ~11020 words

DIAGNOSTIC TROUBLE CODE INDEX

DTCDefinition
P0420, P0430Catalyst Monitoring
P0300, P0301, P0302, P0303, P0304, P0305, P0306, P1396Misfire Monitoring
P0440EVAP (Functional check canister purge solenoid)
P0442, P0456EVAP system leak measurement (Module DM-TL)
P1434, P1447, P1448, P1449EVAP System pump current (Comprehensive Component, appendant to EVAP)
P0171, P0174, P0172, P0175Fuel System Monitoring Lambda Adaptation
P2096, P2098, P2097, P2099Fuel System Monitoring Trim Control Plausibility Monitoring
P2068, P2067, P0463, P0462FLS electrical circuit continuity check
P144BFLS signal correlation check
P0131, P0151, P0132, P0152Upstream Oxygen Sensor - Short Circuit Monitoring
P112C, P112D, P2626, P2629, P2243, P2247Upstream Oxygen Sensor - Open Circuit Monitoring
P3022, P3023, P3024, P3025Upstream Oxygen Sensor - Signal Controller Monitoring
P2414, P2415Upstream Oxygen Sensor - Signal Activity Check
P0040Upstream Oxygen Sensor - Swapped Sensors Check
P2195, P2197, P2196, P2198Upstream Oxygen Sensor - Active Signal Check (Shift to lean/rich)
P0133, P0153Upstream Oxygen Sensor - Signal Dynamic Monitoring (Slow Response)
P2297, P2298Upstream Oxygen Sensor - Signal Monitoring During Fuel Cut-off
P0135, P0155, P165F, P166FUpstream Oxygen Sensor - Heater Monitoring
P0031, P0051, P0032, P0052, P0030, P0050Upstream Oxygen Sensor - Heater Circuit Monitoring
P0137, P157, P0138, P158, P0140, P0160Downstream Oxygen Sensor - Circuit Monitoring
P013E, P014ADownstream Oxygen Sensor - Signal Dynamic Check During Fuel Cut-off (DFCO)
P013A, P013CDownstream Oxygen Sensor - Dynamic/Transition Time in Sensor Midpoint Range Monitoring
P114A, P114C, P114B, P114DDOWNSTREAM OXYGEN SENSOR - Signal activity check
P2270, P2272, P2271, P2273, P0041Downstream Oxygen Sensor - Signal Check (Stuck lean/rich, Swap)
P0141, P0161DOWNSTREAM OXYGEN SENSOR - Heater Plausibility Monitoring
P0036, P0056, P0037, P0057, P0038, P0058Downstream Oxygen Sensor - Heater Circuit Monitoring
P0128THERMOSTAT - plausibility check
P0117, P0118Electrical Engine Coolant Temperature Diagnosis
P3198Engine Coolant Temperature Gradient Diagnosis (comprehensive component appendant to ECT)
P3199Engine Coolant Temperature Stuck Diagnosis
P316AEngine Coolant Temperature Stuck in Range Diagnosis
P1515Engine off timer monitoring
P0506, P0507, P1561, P1562Idle Speed Control Rationality Diagnosis
P1561, P1562Cold Start Emission Reduction Strategy Monitoring
P0012, P0015Variable Camshaft Timing (Vanos) (detection of mechanical IVVT error)
P13B4, P13B6, P13BA, P13BC, P0340, P0365, P1300, P130A, P13B0, P13B2Camshaft position sensor (CMP)
P0016Camshaft Crankshaft synchronization
P0335, P0336, P0370, P138FCrankshaft position sensor (CRK)
P0072, P0073CAN BASED AMBIENT TEMPERATURE - signal diagnosis
P0071Ambient Temperature (AAT) Signal Plausibility Check
P0112, P0113Electrical Intake Air Temperature Diagnosis
P0111, P111E, P111FIntake Air Temperature (IAT) Plausibility Check
P2100ETC Driver diagnosis
P169A, P1694Electronic Throttle Control (ETC) spring check (start routine)
P1632, P1633, P16BA, P1635, P1644Electronic Throttle Control (ETC) adaptation diagnosis
P11AA, P1639Electronic Throttle Control (ETC) Motor Control Performance
P1417Electronic Throttle Control (ETC) air supply rationality check
P1104, P1105Manifold Differential Pressure Sensor (MAP-DIP) - Rationality check
P1197, P1198Differential Pressure Sensor (MAP) - Electrical check
P1124DIFFERENTIAL PRESSURE SENSOR (MAP_DIP) - Offset check
P00BC, P00BDMass air Flow (MAF) Rationality check
P116C, P116EMass air Flow (MAF) Sensor
P0326, P0327, P0328, P1327, P1328, P135BDiagnosis of Knock Sensor
P1047, P1048, P1049, P1055, P1056, P1057, P103A, P1017, P1019, P1020, P1075, P1076, P1078, P107A, P107B, P107C, P1030, P101A, P1023, P1024, P1041, P105A, P105BVariable Valve Lift (VVL) - Electrical Diagnosis
P0503Vehicle Speed Sensor - signal plausibility check
P0500Vehicle speed sensor - signal check

DIAGNOSTIC TROUBLE CODE INDEX

1.1 Catalyst Monitoring

P0420/P0430

1.1.1 Diagnostic overview

Catalyst monitoring is based on the monitoring of the oxygen storage capability (OSC) by comparing the signals of the O2 sensor upstream and downstream the catalyst. The engine control stimulates the regular lambda oscillations of the exhaust gas. These oscillations are needed for best possible catalyst conversion. They are damped by the storage activity of the catalyst. The amplitude of the remaining lambda oscillations downstream the catalyst indicates the oxygen storage capability.

The efficiency of the catalyst system is tested during steady state driving by cycling the air fuel ratio LEAN and then RICH for a calibratable number of cycles while monitoring the OSC.

Prior to the catalyst test the canister purge valve is closed or opened with low canister purge value. This is to eliminate the influence of canister vapors on the downstream sensor during the test.

1.1.2 Monitoring function

If all monitoring conditions are fulfilled, then a special defined A/F-modulation will be done.

The first lean to rich cycle of the test is only used to establish an average voltage value of the downstream sensor voltage. During subsequent cycles the calculation of the OSC is based on the accumulated value of the difference between the average value of the previous lean to rich cycle and the measured instantaneous voltage during the current lean to rich cycle.

The relation of the deviation between the current downstream-sensor-signal to the average value of the downstream-sensor-signal is a lead for catalyst condition. The catalyst system is considered malfunctioning, if after a specified number of monitoring cycles the average of the accumulated deviation exceeds a threshold. The corresponding fault code is stored.

1.2 Heated Catalyst Monitoring

A Heated Catalyst is not built in.

1.3 Misfire Monitoring

P0300, P0301, P0302, P0303, P0304, P0305, P0306, P1396

1.3.1 Monitoring function

The method of engine misfire detection is based on evaluating the engine speed fluctuations. The engine torque is a function of engine speed, engine load and the moment of inertia.

In order to detect misfiring at any cylinder, the torque of each cylinder is evaluated by metering the time between two ignitions, which is a measure for the mean value of the speed of this angular segment. A change of the engine torque results in a change of the engine speed.

It is also an influence of the load torque, such as the influences of different road surface, e. g. pavement, potholes etc. If the mean engine speed is measured, influences caused by road surfaces have to be eliminated.

This method consists of following main parts

Data acquisition

The duration of the crankshaft segments is measured continuously for every combustion cycle.

Segment time adaptation (P1396)

Within a defined engine speed range and during fuel cut-off, the segment time adaptation, instead of the misfire detection, is carried out. If the segment time adaptation is out of the maximum adaptation range, failure P1396 is stored. With progressing adaptation the sensitivity of the misfire detection is increasing. The adaptation values are stored and taken into consideration for the calculation of the engine roughness.

Calculation of the engine roughness

The engine roughness is derived from the differences of the segment durations. Different statistical methods are used to distinguish between normal changes of the segment duration and the changes due to misfiring.

Determination of misfiring

Misfire detection is performed by comparing the engine roughness threshold value with the engine roughness value. If the threshold is exceeded, single misfire is detected. The decision, whether the threshold shortfall of the irregular running is evaluated, depends on the monitoring conditions.

Statistics, fault processing

Emission Limit

If the sum of cylinder(s) misfire counters within 1000 revolutions is 4 times exceeding a predetermined value during a driving cycle, or during the first 1000 revolutions, the fault code for emission relevant misfiring is temporary stored. If the following driving cycle is also above the emission limits, the MIL will be switched on and a cylinder selective or global fault will be stored.

Catalyst Damage

If the weighted sum of cylinder(s) misfire counters within 200 revolutions is exceeding a predetermined value the fault code for catalyst damage relevant misfiring is stored and the cylinder with the highest rate will be switched off and the MIL will be switched on immediately. If two cylinders are switched off and the misfire rate is still above the damage limits, MIL is flashed immediately. If one of the cylinder selective counters is exceeding the predetermined threshold the following measures take place

  1. The lambda closed loop system is switched to open-loop condition.
  2. The cylinder individual fault code is stored or if multiple cylinders, then the global fault code is set.
  3. Fuel supply of the misfiring cylinder(s) is cut-off (per customer request)
  4. No downstream fuel trim.

All misfire counters are reset after each interval.

1.4.1 EVAP (Functional check canister purge solenoid)

P0440

1.4.1.1 Monitoring function of the canister purge solenoid (CPS)

The diagnosis is used for the functional test of the CP solenoid (CPS).

The test consists of three checks.

The first check of the CPS is based on the active charcoal filter (ACF) amount. The "Canister Load diagnosis" is calculated permanently until the complete check CPS is finished.

If amount is above threshold ok is detected.

If amount is below threshold, the next step will be performed.

During the next check, the CPS is evaluated based on manifold pressure change or engine speed change (respectively in case of high manifold pressure -) at idle speed. To this effect, the CPS is opened for a short time and the engine speed monitored for a certain period. Additionally the deviation of lambda-controller (rich mixture) is monitored.

After this check has been enabled for the first time, it is requested during each idle speed phase as long as the conditions are met. This is repeated as long as a result has been reached. This check is not bound to one idle speed phase, but can be distributed to several idle speed phases.

If the CPS is detected to be not ok three times, the error is set.

If no error is detected then a third check will be performed (only in case of high manifold pressure)

The principle of the third CPS check is based on the measured mass air flow before and during a CPS opening phase.

If there is no change in mass air flow, then the error is set.

1.4.2 EVAP system leak measurement (Module DM-TL)

P0442, P0456

1.4.2.1 Monitoring function - leak detection

The evaporative system monitoring permits the detection of leaks in the evaporative system with a diameter of 0.02 inches and up.

By means of a Diagnostic Module Tank Leakage (DM-TL), an electrical actuated pump located at the atmospheric connection of the evaporative canister, a pressure test of the evaporative system is performed in the following order

During the Reference Leak Measurement, the electrical actuated pump delivers through the reference restriction. The engine-management system measures the pump's electrical current consumption in this section.

Scheme 1

Scheme 1: 1.4.2.1 Monitoring function - leak detection

Scheme 2

Scheme 2

Scheme 3

Scheme 3

Scheme 4

Scheme 4
  1. During the Leak Measurement, the electrically actuated pump delivers through the charcoal canister into the fuel-tank system. The pressure in the evaporative system may be up to 2.5 kPa depending on the fuel level in the tank. The engine-management system measures the pump's electrical current consumption. A comparison of the currents of the reference leak measurement and the leak measurement is an indication of the leakage in the tank. 0.02 inch diagnosis, very small leak: P0456 The first step of the diagnosis is the reference measurement, the result of the pump reference current is stored (picture in chapter a). After the solenoid switches, the venting system is pressurized (picture in chapter b). In the small leak measurement the small leak threshold is reached, if the leak is smaller than 0.04 inch and then the small leak measurement phase follows. When the DM-TL current reaches the reference current within the very small leak time, the system is tight (leak smaller than 0.02 inch), otherwise a very small leak between 0.02 - 0.04 inches is detected. 0.04 inch diagnosis, small leak: P0442 The first step of the diagnosis is also the reference measurement, the result of the pump reference is stored (picture in chapter a). After the solenoid switches, the venting system is pressurized (picture in chapter b). In the small leak phase (time) the pump current must reach the small leak threshold 1: Small leak threshold 1 = idle current pump + K1 x (reference current - idle current). Factor K1 is between 0.16 and 0.28 depending on the characteristic current value of the pump (reference current - idle current), this value is various in every pump. If the small leak threshold 1 is not reached in the small leak time, the small leak threshold 2 must be reached in an additional time small leak threshold 2 = reference current pump - K2 x (reference current - idle current). Factor K2 is between 0.60 and 0.80 depending on the characteristic current value of the pump (reference current - idle current). If the small leak threshold 2 is also not reached, a leak > 0.04 inches is detected. In the diagram below is the typical current of a tight system, a 0.02 inch leak, and a leak > 0.04 inches.
  2. After the test the remaining pressure in the evaporative system is bled off through the charcoal canister by switching off the pump and solenoid.

1.4.2.2 Diagnosis Frequency and MIL illumination

Diagnosis Frequency and MIL illumination - no refueling detected, leak > 0.04 inches

Scheme 5

Scheme 5: 1.4.2.2 Diagnosis Frequency and MIL illumination

Diagnosis Frequency and MIL illumination - after refueling detected, leak > 0.02 inches

Scheme 6

Scheme 6

1.4.3.1 Monitoring function - pump current diagnosis

P1434, P1447, P1448, P1449

In the reference measurement phase the current of the DM-TL is checked, if the current consumption is smaller than 15 mA a defect pump/motor is detected, and P1448 is stored. If a current consumption of bigger than 40 mA is measured also a defect pump/motor is detected, and the P1449 is stored.

After the reference measurement the electrical solenoid is switched and the venting system is tight. The solenoid is checked by comparison of the reference current and the idle current immediately after the solenoid has switched.

If the difference between the two currents (reference current - idle current) < 2 mA is not reached, the DTC P1447 is stored.

The P1434 fault code is set, if current fluctuations (caused by humidity in the DM-TL) > 1 mA are detected.

1.5 Secondary Air System Monitoring

A secondary air system is not built in.

1.6.1.1 Monitoring function

P0171/P0174, P0172/P0175

The ECM monitors the fuel system control continuously during all engine states except deceleration fuel cut-off. After the enable conditions are met a counter is started. At this point the ECM evaluates the total percentage of short and long term fuel control. If no condition is present the end diagnostic counter will decrement from a calibratible value to zero and a passing decision is made.

If a lean condition is present and total fuel control is above the calibratible threshold two timers are started. If the lean threshold counter exceeds the calibratible threshold before the reset timer has decrement from calibratible threshold to zero a lean error is set.

If a rich condition is present and total fuel control is below the calibratible threshold two timers are started. If the rich threshold counter exceeds the calibratible threshold before the reset timer has decremented from a calibratible threshold to zero a rich error is set.

The time counter is increased while "lambda controller + lambda adaptation" exceed minimum or maximum threshold.

The error is detected as soon as the time counter reaches its maximum value.

Scheme 7

Scheme 7: 1.6.1.1 Monitoring function

1.6.2 Trim Control Plausibility Monitoring

P2096/P2098, P2097/P2099

1.6.2.1 Monitoring function

The trim control plausibility monitoring detects a high deviation of the I-share of lambda trim control. If it exceeds given thresholds the following malfunction is detected

  1. fuel trim above limit

If the above mentioned malfunction is detected, the corresponding fault code is stored.

B1S1B2S1
Air fuel mixture too richP2097P2099
Air fuel mixture too leanP2096P2098

AIR FUEL MIXTURE CHART

1.6.3.1 Monitoring overview

The diagnosis of the fuel level sensor signal consists of a circuit continuity check and a correlation check.

1.6.3.2 FLS electrical circuit continuity check

P2068, P2067, P0463, P0462

1.6.3.2.1 Monitoring function

The signal of the fuel level sensor is monitored concerning the valid range. This range depends on the used fuel level sensor.

If the left or right fuel level sensor signal is above the upper threshold, a short circuit plus is detected. If the left or right fuel level sensor signal is below the lower threshold, an appropriate fault code for the left or right sensor is set.

FLS electrical short-circuit to battery left/rightP0463/P2068
FLS electrical short-circuit to ground left/rightP0462/P2067

MONITORING FUNCTION CHART

1.6.3.2.2 FLS diagnosis frequency of FLS circuit continuity check

short circuit battery

Scheme 8

Scheme 8: 1.6.3.2.2 FLS diagnosis frequency of FLS circuit continuity check

short circuit ground

Scheme 9

Scheme 9

1.6.3.3 FLS signal correlation check

P144B

1.6.3.3.1 Monitoring function

The engine management system has the capability to calculate (sum up) the fuel consumption. For the fuel level sensor plausibility check, this calculated consumption is compared with the decreasing of the fuel level signal. When the calculated value for fuel consumption reaches an appropriate and predetermined value (e.g. five gallons), the calculated fuel consumption is compared to the difference of the fuel level as indicated by the fuel level sensors (between starting calculation and current). In case of the difference is greater than the applicable threshold value, a fuel level sensor fault is detected and an appropriate fault code is set.

If a fault is present, the OBD II EVAP leak monitor will run using a substitute value of 85% total fuel tank volume.

The 85% substitute value will assure that in every case the required 0.020 inch leak is detected by the OBD II system.

Fuel-signal correlationP144B

MONITORING FUNCTION CHART

Scheme 10

Scheme 10: 1.6.3.3.2 FLS diagnosis frequency of FLS correlation check (plausibility error)

1.7.1.1 Upstream Oxygen Sensor - Short Circuit Monitoring

P0131/P0151, P0132/P0152

1.7.1.1.1 Monitoring function

The oxygen sensor circuit monitoring detects the following malfunctions by evaluating the error information received from oxygen sensor microcontroller

  1. short circuit of sensor signal to battery voltage
  2. short circuit of sensor signal to ECM ground

If one of the above mentioned malfunctions is detected, the corresponding fault code is stored.

B1S1B2S1
Short circuit to groundP0131P0151
Short circuit to battery voltageP0132P0152

VOLTAGE SPECIFICATION

1.7.1.2 Upstream Oxygen Sensor - Open Circuit Monitoring

P112C/P112D, P2626/P2629, P2243/P2247

1.7.1.2.1 Monitoring function

The oxygen sensor circuit monitoring detects the following malfunctions by evaluating the error information received from oxygen sensor monitoring functions

B1S1B2S1
Reference voltage failure - (UN)P2243P2247
Virtual ground failure - (VM) and pumping current failure - (IP)P112CP112D
Trim current failure - (IA)P2626P2629

VOLTAGE REFERENCE

If one of the above mentioned malfunctions is detected, the corresponding fault code is stored.

1.7.1.2.2 Monitoring description

This function determines, if an open circuit in any of the four electric lines ( Reference Voltage, Virtual Ground, Pumping Current and Trim Current ) is present in the w ide r ange a ir fuel (WRAF) sensor.

This function shall be triggered only if one of the following diagnosis is active (to set the readiness bit), which are ' UPSTREAM OXYGEN SENSOR - SIGNAL MONITORING DURING FUEL CUT-OFF ' and ' UPSTREAM OXYGEN SENSOR - HEATER MONITORING '. The function shall go to the state = "active" only if one of the diagnoses above detected a fault.

(Reference Voltage)

If a heater error exists and sensor voltage is too low, while the internal resistance measurement is turned off, an open circuit in the line reference voltage occurred.

(Virtual Ground) or (Pumping Current)

An open circuit in line virtual ground or in the line pumping current can be detected if the sensor signal stocks near lambda 1. The sensor non-activity can be detected by the Oxygen Sensor Signal Monitoring during fuel cut-off (signal voltage below e.g. 2.1 V) in fuel cut-off).

(Trim Current)

If the sensor shows an augmented gain, i.e. the sensor signal is higher than the nominal characteristic line, the plausibility test during the fuel cut-off phase shall detect this symptom (signal voltage above e.g. 5.6 V) during fuel cut-off) and an open circuit is assigned to the line trim current.

1.7.1.3 Upstream Oxygen Sensor - Signal Controller Monitoring

P3022/P3023, P3024/P3025

1.7.1.3.1 Monitoring function

This function will detect an error during the initialization and/or operation of a WRAF sensor controller through SPI communication. Information communicated from the Basic Software (BSW) is used for initialization and communication between application software (ASW) and the controller. This is used to determine if the function is working properly.

After an ECU reset, the WRAF sensor controller is started and the diagnosis determines whether the initialization has been performed in the allowed time. If not successful, then a DTC will be stored. If this is successful, then the difference is checked between the present error counter and the stored value of this error counter at ECU reset, (switching from Key "OFF" to Key "ON") or at clearing error memory and after each function call, in case a difference between both counters was found.

If there is a difference, another counter is incremented. If this counter is higher than a threshold, a SPI communication error is stored.

B1S1B2S1
Communication errorP3022P3023
Initialization errorP3024P3025

COMMUNICATION ERROR CHART

All of the above checks are performed internal to the ECU.

1.7.1.4 Upstream Oxygen Sensor - Signal Activity Check

P2414/P2415

1.7.1.4.1 Monitoring description

The oxygen sensor signal activity check monitors if the sensor is attached to the exhaust pipe and whether the exhaust is sampled correctly (no leakage). A malfunction is detected if the oxygen sensor voltage is above a threshold (shows too lean mixture in part load or full load)

If the above mentioned malfunction is detected, the corresponding fault code is stored.

B1S1B2S1
P2414P2415

FAULT CODE CHART

1.7.1.5 Upstream Oxygen Sensor - Swapped Sensors Check

P0040

1.7.1.5.1 Monitoring description

This function will detect if the Oxygen Sensor wire harness has been cross connected, i.e., Bank 1 with Bank 2. This is performed by the use of the output of the fuel correction (lambda controller) of each bank. If this control is on opposite limit at bank 1 and bank 2, the sensors are swapped and the corresponding fault code is stored.

Corresponding fault code

P0040

1.7.1.6 Upstream Oxygen Sensor - Active Signal Check (Shift to lean/rich)

P2195/P2197, P2196/P2198

1.7.1.6.1 Monitoring description

This function shall deliver information indicating that the sensor characteristic line has a shift to lean (Characteristic Shift Down) or to rich, which shall be done by summarizing all similar failure symptoms of this kind.

In dependence of the shift strength there are three different paths followed by this diagnosis

  1. Strong shift to lean/rich: If the lambda sensor upstream shows a rich signal while downstream lambda sensor signal is lean (or vice versa) and additionally the lambda controller goes to its limit, this error is recognized by the upstream sensor plausibility check.
  2. Middle strong shift to lean/rich: If the trim controller goes to its limit but the lambda controller does not, the downstream oxygen sensor signal activity check (P114A, P114B, P114C, P114D) recognizes that the system has a problem and a failure code is stored. Referring to this failure entry, the «DOWNSTREAM ACTIVE TEST»(/bmw/z4/e89-2009-2013/remont/testing-diagnostics/#self-diagnosis-theory-operation-n52__17251-monitoring-function) is triggered. It detects that the problem is in the upstream oxygen sensor, which is showing a characteristic line shift to lean or to rich. The appropriate DTC will be stored along with the downstream sensor signal activity check DTC.
  3. Mild shift to lean/rich: The trim controller I-share goes to its limit but the lambda controller does not. The trim control plausibility monitoring (P2096, P2097, P2098, P2099) recognizes that the system has a problem and a failure code is stored. Referring to this failure entry, the «DOWNSTREAM ACTIVE TEST»(/bmw/z4/e89-2009-2013/remont/testing-diagnostics/#self-diagnosis-theory-operation-n52__17251-monitoring-function) is triggered. It detects that the problem is in the upstream oxygen sensor, which is showing a characteristic line shift to lean or to rich. The appropriate DTC will be stored along with the fuel correction DTC.

1.7.1.7 Upstream Oxygen Sensor - Signal Dynamic Monitoring (Slow Response)

P0133/P0153

1.7.1.7.1 Monitoring function

The oxygen sensor signal dynamic monitoring detects greater deviations of the dynamic behavior of the sensor signal compared to the nominal behavior, controlled by the lambda controller.

The change of the dynamic behavior is caused by problems of the electrical connection (e.g. open circuit), extreme aging of the sensor or a low sensor temperature which slows down the sensor compared to the nominal behavior.

The monitoring is based on an amplitude criterion, i.e. the relation between the amplification of the oxygen sensor and the model is monitored and detects the following malfunction

Sensor signal too slow

If the above mentioned malfunction is detected, the corresponding fault code is stored.

B1S1B2S1
P0133P0153

FAULT CODE CHART

1.7.1.8 Upstream Oxygen Sensor - Signal Monitoring During Fuel Cut-off

P2297/P2298

1.7.1.8.1 Monitoring function

The oxygen sensor signal monitoring during fuel cut-off detects if the oxygen sensor signal is not plausible during fuel cut-off. A malfunction is detected if the oxygen sensor voltage is outside the "normal operating voltage range during DFCO" ( (Scheme 11)below).

If the oxygen sensor signal voltage is within the range "operating voltage during DFCO not plausible" ( (Scheme 11)below) the signal is not plausible. If the above mentioned malfunction is detected, the corresponding fault code is stored.

B1S1B2S1
P2297P2298

MONITORING FUNCTION CHART

If the oxygen sensor signal voltage is above a threshold during fuel cut-off or below a threshold then the open circuit diagnostic function is triggered (see ' UPSTREAM OXYGEN SENSOR - OPEN CIRCUIT MONITORING ). The fault processing continues in this function.

Scheme 11

Scheme 11

1.7.1.9 Upstream Oxygen Sensor - Heater Monitoring

P0135/P0155, P165F/P166F

1.7.1.9.1 Diagnostic overview

The purpose of this function is to detect oxygen sensor heater failures that would lead to an increase in emissions beyond the thresholds stated in the appropriate regulations.

The diagnosis shall be carried out by determining whether the measured oxygen sensor ceramic temperature falls below set limits over a number of measurement cycles. The evaluations of the diagnosis cycle are determined after the completion of a limited number of monitoring cycles.

Deviations in the oxygen sensor ceramic temperature or the oxygen sensor not being operatively ready in a timely manner (because of a too low temperature) can lead to an increase in emissions above the applicable standards or prevent the sensor signal from being used as a diagnostic system monitoring device. Deviations may occur due to, for example, ageing of the heater element, defective wiring, increased heater circuit connector contact resistance, defective heater driver etc.

1.7.1.9.2 Monitoring function

The diagnosis strategy is based on a statistical evaluation of the oxygen sensor ceramic temperature over a pre-defined number of monitoring cycles.

The oxygen sensor ceramic temperature shall be obtained indirectly via the measured internal resistance of the sensor.

If the sensor is not ready after a defined time (e.g. 30 sec after start))* the sensor is set to forced readiness mode and the Upstream Oxygen Sensor Heater Monitoring is started.

Two cases can appear

  1. sensor temperature is invalid (no measurement of sensor temperature possible because of an ECU internal (electrical) failure) --> P165F/P166F is stored
  2. sensor temperature is below a threshold --> normal failure detection time

A low sensor temperature can be caused by a weak heater or a open circuit in the temperature measurement line (line UN). After a low sensor temperature has been detected, the open circuit diagnosis is triggered to check, if an open circuit in line UN is present. If there is an open circuit, then open circuit fault code (P2243/P2247) is stored (see OXYGEN SENSOR MONITORING - OPEN CIRCUIT and picture below). If there is no open circuit present, then the heater fault code is stored (P0135/P0155). The lambda controller is limited, but does not go open loop during this procedure.

B1S1B2S1
Heater power too lowP0135P0155
Sensor temperature invalidP165FP166F

HEATER POWER SPECIFICATION

Scheme 12

Scheme 12

1.7.1.10 Upstream Oxygen Sensor - Heater Circuit Monitoring

P0031/P0051, P0032/P0052, P0030/P0050

1.7.1.10.1 Monitoring function

The oxygen sensor heater circuit monitoring detects the following malfunctions by evaluating the error information received from the power stage

  1. Heater O2 sensor front short circuit to battery voltage
  2. Heater O2 sensor front short circuit to ground
  3. Heater O2 sensor front open circuit

If one of the above mentioned malfunctions is detected, the corresponding fault code is stored.

B1S1B2S1
Short circuit to groundP0031P0051
Short circuit to battery voltageP0032P0052
Open circuitP0030P0050

VOLTAGE SPECIFICATION

1.7.2.1 Downstream Oxygen Sensor - Circuit Monitoring

P0137/P157, P0138/P158, P0140/P0160

1.7.2.1.1 Monitoring function

The oxygen sensor electrical monitor detects the following malfunctions

  1. O2 Sensor rear signal short circuit to battery voltage
  2. O2 Sensor rear signal short circuit to ground
  3. O2 Sensor rear signal open circuit

If one of the above mentioned malfunctions is detected, the corresponding fault code is stored.

B1S2B2S2
Short circuit to groundP0137P0157
Short circuit to battery voltageP0138P0158
Open circuitP0140P0160

VOLTAGE SPECIFICATION

1.7.2.2 Downstream Oxygen Sensor - Signal Dynamic Check During Fuel Cut-off (DFCO)

P013E/P014A

1.7.2.2.1 Monitoring function

Sensor signal dynamic monitoring is performed at fuel cut-off during coasting conditions. To enable the diagnosis the voltage of the O2 sensor rear has to be above a threshold before entering DFCO.

After entering DFCO the signal falls from fuel trim correction set-point (e.g. 0.68 V) to a voltage near 0 mV. A malfunction is detected, if the sensor signal is not below a threshold after a short time on DFCO. This short time is needed to guarantee a completely purged exhaust pipe.

If this malfunction is detected, the corresponding fault code is stored.

B1S2B2S2
Failure during fuel cut-offP013EP014A

FAULT CODE CHART

1.7.2.3 Downstream Oxygen Sensor - Dynamic/Transition Time in Sensor Midpoint Range Monitoring

P013A/P013C

1.7.2.3.1 Monitoring function

This function monitors the transition time in sensor midpoint range of the downstream sensor voltage. When a fuel cut-off phase starts, the following steps will be executed

  1. sensor voltage must be above a threshold (signal must be rich enough, to measure the transition time)

Remark: Usually the signal starts at fuel trim control set-point (e.g.0.68 V)

  1. sensor voltage value is stored (= "start-value")
  2. transition time measurement is started, when the signal is at 70% of start value

Remark: The measurement start and stop-value are relative to the start value, to measure always the transition time around the sensor midpoint range

  1. transition time measurement is finished, when the signal is at 38% of start value
  2. measured transition time is corrected over mass air flow

The transition time is represented by a cycle counter. This transition time is measured over a defined number of fuel cut-off phases. The minimum value after the defined number of fuel cut-off phases is compared with a failure threshold.

If this value is above a threshold, a malfunction is detected and the corresponding fault code is stored.

B1S2B2S2
Transition time in the midpoint range too highP013AP013C

FAULT CODE CHART

Scheme 13

Scheme 13

1.7.2.4 Downstream Oxygen Sensor - Signal activity check

P114A/P114C, P114B/P114D

1.7.2.4.1 Monitoring function

The diagnosis monitors the downstream sensor voltage during active fuel trim controller p-share. If the fuel trim control is active, the downstream sensor voltage has to be in range between a maximum and minimum threshold. If all monitoring conditions are fulfilled a mass air flow integral is incremented (MAF_1). After reaching its threshold the integral is reset and incremented again as long as the conditions are fulfilled.

If the voltage is outside the mentioned band of maximum and minimum threshold)*, a second mass air flow integral is incremented simultaneously (MAF_2). If this integral is over a threshold before the first integral reaches its limit, a malfunction is detected.

This fault will be stored too, if the downstream sensor voltage does not switch to rich before the integral reaches a threshold after a fuel cut-off phase

If one of the above mentioned malfunctions is detected, the corresponding fault code is stored. Referring to this failure entry the " DOWNSTREAM ACTIVE TEST " is triggered to decide the root cause of the downstream sensor behavior (see DOWNSTREAM OXYGEN SENSOR - SIGNAL CHECK ).

B1S2B2S2
Downstream sensor voltage too lowP114BP114D
Downstream sensor voltage too highP114AP114C

DOWNSTREAM OXYGEN SENSOR CHART

1.7.2.5 Downstream Oxygen Sensor - Signal Check (Stuck lean/rich, Swap)

P2270/P2272, P2271/P2273, P0041

1.7.2.5.1 Monitoring function

Downstream Active Test

This monitor is an enhancement of the Downstream Oxygen Sensor - Signal activity check and the Trim Control Plausibility Monitoring. Its purpose is to determine, why the rear sensor signal is not plausible.

The monitor will only be enabled, if a fuel correction fault was detected and a malfunction code is stored (P2096 - P2097 - P2098 - P2099)

OR

if the rear sensor signal activity check has detected, that the rear sensor signal is very rich or very lean and the corresponding malfunction fault code is stored (P114A - P114B - P114C - P114C)

If one of the listed fault codes is stored, this diagnosis will be enabled to determine if the root cause of the malfunction is due to a stuck signal or characteristic line shift of the upstream O2 sensor or due to a stuck signal or a system malfunction (i.e. vacuum leak, injector, etc.) of the downstream O2 sensor.

If it has been determined that the upstream O2 signal was the root cause of the fuel correction fault, the appropriate DTC will be stored along with the fuel correction or with the downstream sensor signal activity DTC (see UPSTREAM OXYGEN SENSOR - ACTIVE SIGNAL CHECK (SHIFT TO LEAN/RICH) ).

If it has been determined that the downstream sensor signal was the root cause of the fuel correction fault, the appropriate DTC will be stored along with the fuel correction or with the downstream sensor signal activity DTC.

This function will also detect, if the oxygen sensor wire harness has been cross connected, i.e., Bank 1 with Bank 2. When this failure is present, the downstream sensor voltages of bank 1 and 2 are on opposite limits.

If one of the above mentioned malfunctions is detected, the corresponding fault code is stored.

B1S2B2S2
Downstream sensor stuck richP2271P2273
Downstream sensor stuck leanP2270P2272
Downstream sensors interchangedP0041

DOWNSTREAM OXYGEN SENSOR CHART

1.7.2.6 Downstream Oxygen Sensor - Heater Plausibility Monitoring

P0141/P0161

1.7.2.6.1 Monitoring function

For proper function of the oxygen sensor, the sensor element must be heated.

A non functioning heater delays the sensor readiness for closed loop control and thus influences emissions.

The monitoring strategy is based on the comparison of the O2 sensor resistance to a threshold in conditions where the exhaust temperature is low enough to cause an increase of internal resistance in cases where the heating power is insufficient.

The cooling energy of the exhaust gas is calculated and compared to a calibrated threshold, and the diagnosis is activated if the cumulated cooling energy is equal or exceeds the threshold.

Then the O2 sensor resistance is compared to a threshold. If the resistance is higher than the threshold, an O2 sensor heater malfunction is detected and the corresponding fault code is stored.

Corresponding fault code

O2 sensor heater rear bank 1 too weakP0141
O2 sensor heater rear bank 2 too weakP0161

FAULT CODE CHART

1.7.2.7 Downstream Oxygen Sensor - Heater Circuit Monitoring

P0036/P0056, P0037/P0057, P0038/P0058

1.7.2.7.1 Monitoring function

The purpose of this monitor is to detect errors within the O2 Sensor Heater Circuit. The signal for the O2 sensor heater is pulse-width modulated. The signal of the power stage is monitored internally by the integrated circuit (IC). This IC can distinguish between three symptoms

  1. Heater O2 sensor rear short circuit to battery voltage
  2. Heater O2 sensor rear short circuit to ground
  3. Heater O2 sensor rear open circuit

If one of the above mentioned symptoms is present, a malfunction is detected and the corresponding fault code is stored.

B1S2B2S2
Short circuit to groundP0037P0057
Short circuit to battery voltageP0038P0058
Open circuitP0036P0056

FAULT CODE CHART

1.8 Exhaust Gas Recirculation (EGR) System Monitoring

An Exhaust Gas Recirculation (EGR) System is not built-in.

1.9.1 General description of the PCV-System

There are 3 tubes connected to the engine: The first of them conducts the blow by gases from the cylinder head cover to the separator, where the oil is separated from the air and lead back by a second tube to the crankcase sump. A third tube directs the cleaned blow by gases via the intake system to the combustion. The pressure regulator makes sure that the high vacuum level between crankcase and ambient air will be reduced if needed.

1.9.2 Diagnosis of a leakage in the PCV-System

A disconnection or leakage in the PCV-System is indicated by a rough or stalling engine and results in a reaction within the fuel system (fuel trim deviation).

In this case a fault code will be stored by the fuel system monitoring.

Scheme 14

Scheme 14: 1.9.2 Diagnosis of a leakage in the PCV-System

Scheme 15

Scheme 15

1.10.1.1 Thermostat - plausibility check

P0128

1.10.1.1.1 Monitoring description

The coolant thermostat monitoring is done to detect a slow warm-up due to heat losses through thermostat and radiator. It is based on the comparison of the measured ECT sensor signal and the calculated ECT model (TCO_SUB).

The ECT model calculation is depending on the speed of the water pump, engine load and ambient temperature.

A malfunctioning coolant thermostat is detected, if the calculated ECT model (TCO_SUB) has exceeded the threshold 1 (thermostat regulation temperature) and the measured ECT sensor signal remains below threshold 2 (fault detection criteria).

Before a malfunctioning coolant thermostat is entered into failure memory, the conditions concerning low load, coasting duration and IAT during the monitoring are checked. If the monitoring conditions are met, the coolant thermostat is entered into failure memory. Otherwise the coolant thermostat monitoring is inhibited for this driving cycle.

Example of Monitoring Method

Scheme 16

Scheme 16: 1.10.1.1.1 Monitoring description

A comparison between the measured engine coolant temperature (ECT) and the fault detection criteria temperature is done after a specific time interval. The interval itself is based on the engine coolant temperature model.

If the measured engine coolant temperature (ECT) is higher than fault detection criteria (thermostat regulation temperature -11°K); the thermostat is concluded as normal thermostat.

If the measured coolant temperature (ECT) is lower than fault detection criteria (thermostat regulation temperature -11°K), the thermostat is concluded as opened stuck thermostat.

For E6xFor E83For E89x, E90 CAN
Thermostat regulation (opening) temperature103,5°C99 °C98 °C
Fault detection criteria (thermostat regulation temperature - 11°K)92.5°C88 °C87 °C

THERMOSTAT REGULATION TEMPERATURE CHART

1.10.2.1 Electrical Engine Coolant Temperature Diagnosis

P0117, P0118

1.10.2.1.1 General Description

The purpose of this diagnosis is to detect electrical faults of the sensor signal. The input signal is analog from a NTC and has to be in a calibratable range. Short circuit to ground can be detected immediately. Short circuit to voltage battery or open load is detected, if conditions of Intake Air Temperature and Time After Start are fulfilled. If an error symptom is detected, the error counter is de-bounced.

1.10.2.1.2 Error Symptoms

  1. Short circuit to voltage battery or open circuit
  2. Short circuit to ground

1.10.2.2 Engine Coolant Temperature Gradient Diagnosis (comprehensive component appendant to ECT)

P3198

1.10.2.2.1 General Description

The purpose of this diagnosis is to detect an implausible gradient on the coolant temperature signal. The diagnostic function checks whether the difference between one measured coolant temperature value and the succeeding value is too big.

1.10.2.2.2 Error Symptom

  1. ECT signal gradient error

1.10.2.2.3 Input parameters for monitoring

  1. measured ECT

1.10.2.3 Engine Coolant Temperature Stuck Diagnosis

P3199

1.10.2.3.1 General Description

The purpose of this diagnosis is to detect a stuck coolant temperature signal. The diagnostic function checks if after a variation of the calculated coolant temperature also a variation of the measured coolant temperature is detected. The range of required variation depends on ECT at engine start.

For RBM handling the Cold Start Denominator will be considered.

1.10.2.3.2 Error Symptom

  1. ECT signal stuck error

1.10.2.3.3 Input parameters for monitoring

  1. measured ECT
  2. calculated (modeled) ECT
  3. ECT at engine start

1.10.2.4 Engine Coolant Temperature Stuck in Range Diagnosis

P316A

1.10.2.4.1 General Description

The purpose of this diagnosis is to detect a coolant temperature signal that is stuck in high range. The diagnostic function checks if after a certain time engine stopped, the engine temperature has reached a plausible (low) value, i.e. the engine has cooled down.

If the measured engine temperature at engine start is above a calibratable threshold and the diagnosis conditions are fulfilled, the error is set. The threshold depends on Intake Air Temperature at Start and the Time Engine was stopped.

For RBM handling the Cold Start Denominator will be considered.

1.10.2.4.2 Error Symptom

  1. ECT signal stuck in range error

1.10.2.4.3 Input parameters for monitoring

  1. Measured ECT at engine start
  2. Intake temperature at engine start
  3. Time engine was stopped

1.10.3 Engine off timer monitoring

P1515

1.10.3.1 General description

The engine off time is calculated using a relative time counter obtained from the instrumentation via CAN message. The difference in value of the relative time counter at last engine stop and at current engine start is compared to the corresponding values of ECT. An error is detected when engine off time is adjudged too small after a relatively large drop in ECT, or, conversely, when engine off time is too large after a small drop in ECT.

1.10.3.2 Error Symptoms

  1. Engine off time not plausible to ECT (Symptom 3).

1.10.3.3 Input parameters for monitoring

  1. ECT at engine stop
  2. ECT
  3. relative time counter via CAN

1.11.1.1 Idle Speed Control Rationality Diagnosis

P0506, P0507

P1561, P1562

1.11.1.1.1 Idle Speed Control - General Description

This diagnosis monitors the stability of the idle speed. If the actual idle speed is not within a calibratible range, above or below the idle speed set-point then the failure criteria is fulfilled. The appropriate DTC will be stored.

Scheme 17

Scheme 17: 1.11.1.1.1 Idle Speed Control - General Description
EMS ParameterDescription
NEngine speed
N_SP_ISIdle speed setpoint
LV_CH_N_SP_ISCatalyst heating by increased idle speed
N_IS_MAXMaximum idle speed
N_IS_MINMinimum idle speed

EMS PARAMETER DESCRIPTION

1.11.2 Cold Start Emission Reduction Strategy Monitoring

All parameters, that are relevant during the cat heating phase, are monitored by standard monitoring functions

e.g. MSV80-N51/N52

Scheme 18

Scheme 18: 1.11.2 Cold Start Emission Reduction Strategy Monitoring

To fulfill the legal requirements, the monitoring of the idle speed is now extended to the cold start phase. In case of an error, the specific DTC's

  1. P1561 Cold Start Idle Air Control System RPM lower than expected
  2. P1562 Cold Start Idle Air Control System RPM higher than expected

are set. Look at illustration Idle speed control

During cat heating, it is essential to make sure, that enough thermal energy is applied to the catalyst to heat it up as quick as possible.

Therefore it is target to limit the ignition timing to the earliest possible value during the cat heating phase.

If there would be a demand for more torque and therefore for an advanced ignition timing beyond the limits, the engine would be allowed to stall instead of fulfilling the demand.

The torque limits are calibrated the way that the emissions stay below 1.5 times of the limits.

Scheme 19

Scheme 19

Known System

During normal driving, the ignition timing desired torque corresponds to the air mass desired torque, which determines the ignition timing. During the cat heating phase, the cat heating torque is added to the air mass desired torque, resulting in a higher reference air mass torque.

The efficiency, desired torque divided by the reference torque, determines the ignition timing.

New System (BMW-development)

The earliest possible ignition timing is determined by the limitation of the torque reserve to a minimum value during the cat heating phase. For this, the required minimum cat heating torque is subtracted from the reference air mass torque. The thus reduced efficiency leads to a safe ignition retard and limits the ignition timing during the cat heating measures.

Limitation of ignition timing to the earliest possible ignition timing during the cat heating phase by limitation of torque reserve to the minimum required torque reserve.

Scheme 20

Scheme 20

The maximum ignition timing after cold start with new BMW method

Scheme 21

Scheme 21

1.12 Air Conditioning (A/C) System Component Monitoring

This diagnose system is not built in

1.13.1.1 Variable Camshaft Timing (Vanos) (detection of mechanical IVVT error)

P0012/P0015

The BMW-Vanos is a combined hydraulic and mechanical camshaft control unit, managed by the ECU. The double Vanos allows the engine to control valve-timing continuously for both intake and exhaust camshafts. The electronically control of the Vanos positions is dependant on engine speed, load and temperature.

The diagnosis is monitoring the correct mechanical function of the variable camshaft timing. The diagnosis carries out a continuous rationality check of the Vanos function. If a malfunction is detected, an error bit will be set and sent to the Error management module. This module produces the final information for setting the corresponding DTC.

The diagnostic strategy for inlet and exhaust camshaft is identical.

1.13.1.1.1 Description of Control deviation of the camshaft position controller: ("target + slow response")

In this diagnosis module the difference between the actual and target position of the Vanos units ("control deviation") is checked. If the calculated difference between these two positions exceeds the established threshold, a counter is started. The counter is incremented twice per crank revolution (but not exceeding 10 msec-rates).

If the counter exceeds a limit (also adjustable), a Rationality Fault (DTC) is stored.

The control deviation diagnosis has got an interface to the Rate-Based Monitoring module.

  1. In-use monitor performance Ratio: The incrementing of the numerator, denominator, and the ratio calculation for the Variable Camshaft Timing monitor is executed by the Rate-Based Monitoring module. Like all monitors for which a standardized track and report in-use performance is required, the Variable Camshaft Timing monitor reports to the RBM-module via status flags
  2. Conditions for incrementing the Numerator: The numerator is incremented if and only if the monitor is not inhibited due to stored faults and the diagnostic has been performed and a fault would have been detected.
  3. Conditions for incrementing the Denominator: The denominator is incremented if the monitor is not inhibited due to stored faults, the general driving conditions have been fulfilled and all additional physical conditions for incrementing have been fulfilled.

1.13.1.2 Camshaft position sensor (CMP)

P13B4, P13B6, P13BA, P13BC

P0340, P0365, P1300, P130A, P13B0, P13B2

1.13.1.2.1 Description

The purpose of the diagnosis is to detect when the camshaft reference position is outside the designed range relative to the engine position from crankshaft and to detect a signal which is not valid.

The diagnostic strategy for inlet and exhaust camshaft is identical.

1.13.1.2.2 Monitoring Function

The detection of each camshaft position is done by an active hall sensor and a cam wheel, "3 asymmetric teeth". The camshaft sensor delivers 3 high and 3 low phases of different length per 720°CRK. The high or low pegel of the signal at the reference gap of the crankshaft signal determines the position of the engine within the combustion cycle. With that information, a engine position is calculated from the crankshaft position sensor within a range from 0 to 720 °CRK.

The following malfunctions are detected

CMP sensor signal plausibilityP0340/P0365
CMP sensor signal segment periodP1300/P130A
CMP sensor signal loss of synchronizationP13B0/P13B2
CMP sensor signal reference to CRK positionP13B4/P13B6
CMP sensor signal jump of chainP13BA/P13BC

CMP SENSOR SIGNAL PLAUSIBILITY CHART

1.13.1.2.3 Diagnosis of signal plausibility

P0340, P0365

The monitor checks once per combustion cycle the edge counter of the camshaft. If the edge counter has not changed during the last cycle, a cycle counter is incremented. When the counter reaches a threshold, the error CAM_plaus is delivered to the error management.

1.13.1.2.4 Diagnosis of period length

P1300, P130A

The monitor checks at every edge of the CMP signal the length of the last signal period. If the difference to the designed length exceeds a max value, the corresponding debounce counter is incremented. When the counter reaches a threshold the error CAM_period is delivered to the error management.

1.13.1.2.5 Diagnosis of synchronization state

P13B0, P13B2

The camshaft signal acquisition synchronizes on the camshaft sensor signal by evaluating the pattern of the measured long and short periods of the signal. Synchronization is lost if the last measured period does not fit to the pattern. After a synchronization has been established, the monitor checks at every new signal edge whether the camshaft is still synchronized or not. If the camshaft is not synchronized, the corresponding debounce counter is incremented. If the camshaft is still synchronized, the debounce counter is incremented. When the counter reaches a threshold, the error CAM_sync is delivered to the error management.

1.13.1.2.6 Diagnosis of mechanical reference position

P13B4, P13B6

The monitor checks at least once per driving cycle the position of the camshaft signal edges compared to the crankshaft position while the camshaft is in lock position (VANOS passive).

The deviation of all camshaft edges compared to the designed position is averaged. Each time the deviation of one of the camshaft signal edges exceeds a max value, the corresponding debounce counter is incremented. When the counter reaches a threshold the error CAM_ref_crk_cam is delivered to the error management.

1.13.1.2.7 Diagnosis of mechanical chain jump

P13BA, P13BC

The diagnosis is performed after the reference position adaptation. The learned position of each camshaft signal edge is stored in the non volatile RAM of the ECU as an adaptation value. Before storing the value, the new adapted value is compared with the stored value. If the deviation exceeds a max value, the error CAM_one_tooth_off is delivered to the error management and the new value is not stored in RAM. With this diagnosis a chain jump of the timing chain is detected.

The diagnosis of the mechanical chain jump has got an interface to the Rate-Based Monitoring module.

  1. In-use monitor performance Ratio: The incrementing of the numerator and denominator for the diagnosis of chain jump is executed by the Rate-Based Monitoring module. Like all monitors for which a standardized track and report in-use performance is required, the diagnosis monitor reports to the RBM-module via status flags.
  2. Conditions for incrementing the Numerator: The numerator is incremented if and only if the monitor is not inhibited due to stored faults and the diagnostic has been performed and a fault would have been detected.
  3. Conditions for incrementing the Denominator: The denominator is incremented with every driving cycle.

1.13.1.3 Camshaft Crankshaft synchronization

P0016

1.13.1.3.1 Description

The purpose of the diagnosis is to validate the camshaft signal used for synchronization. First the intake camshaft is selected for synchronization. If validation fails, the exhaust camshaft signal will be selected for synchronization. If validation also fails, no synchronization will be established.

1.13.1.3.2 Monitoring Function

The diagnosis is performed at every edge of the selected camshaft signal and at the reference gap of the CKP sensor signal. The distance (in crankshaft degrees) between events is compared to the stored camshaft signal pattern. For each signal edge the distance must fit to the designed position in the pattern plus/minus a tolerance. The tolerance is expanded by the range of the variable valve timing, when the camshaft is not in lock position.

The following malfunctions are detected

Intake CMP sensor signal not valid for synchronizationP0016

MONITORING FUNCTION CHART

1.13.1.3.3 Diagnosis of camshaft crankshaft synchronization

The monitor eliminates with every event the edges from the list of all 6 cam edges, which are not insides the pattern. If a calibrated number of camshaft signal edges were detected and the list of remaining signal edges contains at least one edge, the camshaft signal is valid for synchronization. If no edge is left in the list, synchronization failed and is started again. If a calibrated number of synchronizations failed, the error is delivered to the error management. Afterwards, and only if synchronization fails with the intake camshaft, the same procedure is started with the exhaust camshaft.

1.13.2 Crankshaft position sensor (CRK)

P0335, P0336, P0370, P138F

1.13.2.1 Description

The purpose of this diagnostic is to check the integrity of the crankshaft sensor signal and/or electrical malfunctions. (Open line, SCG, SCVB)

1.13.2.2 Monitoring Function

The detection of crankshaft position is done by an active hall sensor and a crank wheel, "e.g. 60 minus 2 teeth". A reference gap, "e.g. of two teeth" allows the detection of the top dead center of cylinder 0. The crankshaft sensor delivers a certain number of high and low phases per 360°CRK. The transition from high to low is a falling edge; from low to high is a rising edge. Only the falling edges are counted. The difference between two falling edges is 6° CRK.

The following malfunctions are detected

Missing CRK sensor signalP0335
No plausible CRK signalP0336
Wrong tooth numberP0370
Wrong tooth periodP0370
Sync errorP138F

CRK SENSOR SIGNAL REFERENCE

A teeth counter is incremented at every falling edge of the CRK sensor signal. If plus or minus two teeth are detected during the last 360° CRK at the reference gap, the tooth number debounce counter will be incremented. If the counter exceeds a limit, a CRK tooth error is delivered to the error management.

If more then two teeth plus or minus are detected the CRK looses synchronization and a CRK sync debounce counter will be incremented. If the counter exceeds a limit, a CRK sync error is delivered to the error management.

The detection of a tooth period error is done by an acceptance window. The expected tooth period is multiplied and divided with an engine speed dependency factor. The result is a bottom and a top limit of tooth period, in which the transition from high to low of the electrical signal has to occur. If a tooth period is not valid, the tooth period error debounce counter will be incremented. If the counter exceeds a limit, a CRK tooth per error is delivered to the error management.

Detection of implausible crankshaft signal is based on the detection of CAM signals without receiving correct CRK signal. If 12 or more CAM edges are detected (eg. 2 working cycles), without valid synchronization of the crankshaft, then CRK plaus error is detected and delivered to the error management. If no CRK signal at all is received, the symptom is "missing signal", else the symptom is "implausible signal".

1.14 Direct Ozone Reduction

This diagnose system is not built in

1.15.1 Strategy

Principle

Sensors that can affect emissions or are used to monitor other component/system are monitored for circuit continuity and short to battery voltage and/or to ground using high and low voltage signal limit.

Actuators that can affect emissions or are used to monitor other component/system are monitored by power stage voltage check for valid signals.

For some of sensors or actuators, plausibility checks are included to ensure proper operation of the components.

1.15.1.1 Monitoring Strategy for sensors

Sensor signals out of a defined range are regarded as circuit malfunctions shorted to BATT, GND or Open circuit.

1.15.1.2 Monitoring Strategy for actuators

Invalid actuator output signals at power stage are regarded as circuit malfunctions shorted to BATT, GND or Open circuit.

1.15.1.3 Rationality Check

Components are checked for the integrity of their values. This is accomplished by the use of a model or other sensor inputs. If a component does not function as expected or the integrity is in question (values are not within a threshold) it is considered out of range/plausible.

1.15.2.1 CAN based Ambient Temperature - signal diagnosis

P0072, P0073

1.15.2.1.1 General Description

The purpose of this diagnosis is to detect electrical faults as defined in OBDI requirements. The input signal is a CAN message of instrument cluster. If an error is detected by the instrument cluster, the error symptom is sent via CAN to the ECU. The ECU then debounces the error and stores it in the error management.

1.15.2.1.2 Error Symptoms

  1. short circuit to vbatt or open line
  2. short circuit to ground

1.15.2.2 Ambient Temperature (AAT) Signal Plausibility Check

P0071

1.15.2.2.1 General Description

This diagnosis is performed in order to detect a stuck or not plausible AAT signal which cannot be detected by electrical range diagnosis.

The first part, just after start looks on the change of ambient temperature and compares the start and stop temperature. If the check is positive the diagnosis is finished. In negative case diagnosis runs to next step during warm up phase.

The error detection is only performed if the monitoring conditions for time after start, engine state idle speed, time of engine stop, ECT and ambient temperature are fulfilled. The plausibility error is detected if the absolute value of the temperature-difference between the arithmetic mean of engine coolant temperature ECT and temperature intake air IAT and the ambient temperature AAT (in formula: ABS (absolute value) of [(ECT+IAT) x 0,5 - AAT)]) exceeds the threshold for an anti-bounce time.

The error validation is only performed if ECT signal is valid and the vehicle was driven with a certain vehicle speed. If both conditions are true and an error was detected, then the error is set for this driving cycle and the diagnosis is switched off.

For RBM handling the Cold Start Denominator will be considered.

1.15.2.2.2 Error Symptoms

  1. ambient temperature not plausible

1.15.3.1 Electrical Intake Air Temperature Diagnosis

P0112, P0113

1.15.3.1.1 General Description

The purpose of this diagnosis is to detect electrical faults as defined in OBDI requirements. The input signal is analog from a NTC and has to be in a calibratable range. Short circuit to ground can be detected immediately, short circuit to voltage battery or open load after a delay time. If an error symptom is detected, the error counter is de-bounced.

1.15.3.1.2 Error Symptoms

  1. Short circuit to voltage battery or open load
  2. Short circuit to ground

1.15.3.2 Intake Air Temperature (IAT) Plausibility Check

P0111, P111E, P111F

1.15.3.2.1 General Description

This diagnosis checks IAT integrity for a plausible range and signal stuck.

For the range detection, IAT has to be within coolant temperature and ambient temperature window. If IAT is outside of the range plus an offset, the error symptom is set and the error counter is de-bounced.

If the vehicle was driven with a certain vehicle speed for a calibratable time (IAT sensor cool down) and afterwards the vehicle was in idle for a calibratable time (IAT sensor hot up), the IAT signal must have moved. If the signal has not moved after a calibratable number of cool down/hot up phases, a stuck IAT signal is detected and the error is de-bounced.

For RBM handling the Cold Start Denominator will be considered.

1.15.3.2.2 Error Symptoms

  1. Signal too high
  2. Signal too low
  3. Signal not plausible

1.15.3.2.3 Input parameters for monitoring

  1. ECT engine coolant temperature
  2. AAT ambient temperature at start and continuously
  3. IAT intake air temperature
  4. Vehicle speed
  5. Engine speed

1.15.4.1 Electronic Throttle Control (ETC) Motor Control Circuit

P1632, P1633, P16BA, P1635, P2100, P11AA, P1639, P1644, P169A, P1694

1.15.4.1.1 Monitoring Descriptions

P2100

ETC Driver diagnosis (H-bridge): The ETC - H-Bridge IC continually checks the MTC if there is a short circuit to battery voltage or ground. In addition the IC is able to detect over temperature. This is performed internally to the ECU.

1.15.4.2 Electronic Throttle Control (ETC) spring check (start routine)

P169A, P1694

This Diagnosis checks if the throttle spring is working correctly and if the throttle limp home position can be reached.

The diagnosis is performed at the beginning of every driving cycle at ignition "Key ON" position.

1.15.4.3 Electronic Throttle Control (ETC) adaptation diagnosis

P1632, P1633, P16BA, P1635, P1644

After the initial engine start and/or component change, the characteristic Potentiometer values for the limp home position and the lower mechanical stop are learned within an adaptation routine. The values are stored at the end of the driving cycle in the non-volatile memory.

If the conditions are not fulfilled, the malfunction errors (DTC's) are stored.

1.15.4.4 Electronic Throttle Control (ETC) Motor Control Performance

P11AA, P1639

This diagnosis is able to detect a too slow or jammed actuator. The given pulse width modulation signal (MTCPWM) exceeds the position controller permissible maximum value for longer than designated (Max short or Max Long) time.

If either of the times is exceeded, the appropriate DTC will be stored.

Also if a maximum allowed difference between throttle actual value and set point value is exceeded, a DTC is stored.

1.15.4.5 Electronic Throttle Control (ETC) air supply rationality check

P1417

If P1639 active OR

P1637 active OR

P1636 active OR

P1632 active OR

P1633 active OR

P1694 active OR

P1644 active OR

P1634 active OR

P169A active OR

P1635 active OR

[(P0122 active OR P0123 active) AND (P0222 active OR P0223 active)]

the composite error P1417 will be stored.

1.15.5.1 Manifold Differential Pressure Sensor (MAP-DIP) - Rationality check

P1104, P1105

1.15.5.1.1 Monitoring description

For a variable valve lift engine, the main function of the throttle body is to control the pressure in the intake manifold. Therefore the manifold differential pressure plausibility check is testing the plausibility of measured intake manifold pressure in comparison to the measured throttle position. So no throttle position acquisition error must be present.

The set-point of the differential intake manifold pressure is up to 60-70% of maximum torque request constant 5 kPa beneath ambient pressure. At higher load the differential pressure set-point becomes Zero.

In case the set-point of the differential pressure in the intake manifold is > 3 kPa beneath the ambient pressure, a differential pressure controller is active. The output of the controller is monitored. The output of the manifold pressure controller has to be between adjustable MIN/MAX-thresholds. If the MIN/MAX thresholds are exceeded a time counter is incremented. After this counter reaches the threshold within one diagnosis cycle, a manifold differential pressure sensor malfunction is detected.

1.15.5.2 Differential Pressure Sensor (MAP) - Electrical check

P1197, P1198

1.15.5.2.1 General Description

The purpose of the diagnosis is to detect electrical faults as defined in OBDI requirements. The input signal has to be in a calibratable voltage range. Short circuit to battery or open load and short circuit to ground can be detected. If an error symptom is detected, the error is de-bounced.

1.15.5.2.2 Error Symptoms

  1. Short circuit to voltage battery or open load
  2. Short circuit to ground

1.15.5.3 Differential Pressure Sensor (MAP_DIP) - Offset check

P1124

1.15.5.3.1 General Description

The purpose of the diagnosis is to detect a improper offset on the signal of differential manifold pressure sensor (e.g. because of ageing). The absolute signal deviation from a setpoint is estimated. The threshold for detecting a failure depends on modelled temperature of the differential manifold sensor. The diagnosis is active during powerlatch phase. The error symptom is de-bounced.

1.15.5.3.2 Input parameters for monitoring

  1. Modelled temperature of differential manifold pressure sensor
  2. Raw signal of differential manifold pressure sensor

1.15.5.3.3 Error Symptoms

  1. Signal offset out of limit

1.15.6 Mass air Flow (MAF)

P00BC, P00BD

1.15.6.1.1 Monitoring description

Depending on engine speed, valve-lift, inlet camshaft position, outlet camshaft position and manifold pressure an air mass flow into the cylinder is calculated. There is also a correction of the calculated air mass flow depending on intake air temperature, coolant temperature and ambient pressure. The ratio between the measured air mass flow and the calculated air mass flow must be between adjustable MIN/MAX-values. If the MIN/MAX thresholds are exceeded, a time counter is incremented. After this counter reaches the threshold within one diagnosis cycle, an air mass flow meter malfunction is detected.

1.15.6.2 Mass air Flow (MAF) Sensor

P116C, P116E

1.15.6.2.1 General Description

The purpose of the diagnosis is to detect electrical faults and range violations of the mass air flow sensor.

If the period time is over a threshold or no edges are measured, a electrical or upper range failure is indicated. A lower range failure is also checked with a threshold.

After setting the error symptoms, the failure is de-bounced.

1.15.6.2.2 Error Symptoms

  1. Period time too low
  2. Period time too high or electrical failure

1.15.7.1 Diagnosis of Knock Sensor

P0326, P0327, P0328, P1327, P1328, P135B

1.15.7.1.1 General Description

The purpose of the diagnosis is to detect faults of the knock sensor. Therefore the signal range and dynamics of a low pass filtered knock signal is checked.

If the signal range exceeds a upper or lower threshold a failure is detected.

An implausible knock signal is detected by using a statistical analysis. The difference between filtered knock signal and raw knock signal is estimated for a certain number of combustion cycles.

All error symptoms are de-bounced.

1.15.7.1.2 Error Symptoms

  1. Noise level above valid range
  2. Noise level below valid range
  3. Knock sensor signal not plausible

1.15.8 Variable Valve Lift (VVL) - Electrical Diagnosis

P1047, P1048, P1049, P1055, P1056, P1057, P103A, P1017, P1019, P1020, P1075, P1076, P1078, P107A, P107B, P107C, P1030, P101A, P1023, P1024, P1041, P105A, P105B

1.15.8.1 Monitoring overview

The electronic control of the Variable Valve Lift (VVL) is dependant on, Voltage Limits, Adaptations, current and power stage temperature. The following errors will be detected in this system.

Variable Valve Lift Electrical Diagram

Scheme 22

Scheme 22: 1.15.8.1 Monitoring overview

1.15.8.2 Monitoring function - electrical diagnosis of the DC motor lines

P1047, P1048, P1049

Is performed internally in order to detect the following errors: Short circuit to battery (SCVB), to ground (SCG) or short circuit to each other (S together)

The goal of this function is to detect a short circuit at the VVL output stage. The function uses temperatures from the sensor outputs of the power stage. If the temperature of one power stage is greater than a threshold the function checks the output stage. If a short circuit is detected an error is set.

Error Symptoms

Short circuit to battery voltageP1047
Short circuit to groundP1048
Short circuit to each otherP1049

SYMPTOMS CHART

1.15.8.3 Monitoring overview - DC Motor current, power stage temperature and DC Motor overload

DC Motor current, power stage temperature and DC Motor overload is monitored through the ECU. This diagnosis checks for over-temperature and short term/long term current overload conditions (looks for current spikes over a threshold, and time vs. current table based)

1.15.8.4 Monitoring function - power stage temperature diagnosis

P107C, P1076

Error Symptoms

There are two cases to be distinguished

The first warning threshold
VVL Power stage over temperature warning > 112°CP107C
The second critical threshold
VVL Power stage over temperature threshold > 126°CP1076

TEMPERATURE SPECIFICATION

1.15.8.5 Monitoring function - power stage current diagnosis (long term current)

P107A, P1075

If the long term power stage current (RMS) exceeds a calibrated current range in dependence of the power stage temperature a debounce counter will set.

Error Symptoms

There are two cases to be distinguished

The first warning threshold
VVL power stage warningP107A
The second critical threshold
VVL power stage overloadsP1075

SYMPTOM CHART

1.15.8.6 Monitoring function - power stage current diagnosis (short term current)

P103A

The purpose of this function is to detect fast a not allowed high current which can damage the Power stage. This case can not be covered by diagnosis functions which evaluate the temperature gradient information because it is not quickly enough.

Error Symptoms

Power stage current short terms overloadP103A

SYMPTOM CHART

1.15.8.7 Monitoring function - DC motor overload temperature

P107B, P1078

The purpose is to estimate the bus conductor temperature of the VVL DC Motor to protect the component for overload.

Error Symptoms

The first warning threshold
VVL DC Motor bus conductor temp > 190°CP107B
The second critical threshold
VVL DC Motor bus conductor temp > 200°CP1078

VVL DC MOTOR BUS CONDUCTOR TEMPERATURE CHART

1.15.8.8 Monitoring function - power stage self diagnosis

P105A, P105B

Power stage self diagnosis realize if power stage diagnosis has detected under voltage or over current of high side or low side switches. The diagnosis is a self check realized therefore in the specific hardware (power stage).

Error Symptoms

Over current detection on high side/low side of power stageP105A
Under voltage of driverP105B

SYMPTOMS CHART

1.15.8.9 Monitoring function - power supply control motor

P1055, P1056

Power supply control motor is monitored through the VVL relay and checks over and under voltage conditions. If this occurs, the following DTC's will be stored

Error Symptoms

Power supply over voltageP1055
Power supply under voltageP1056

SYMPTOM CHART

1.15.8.10 Monitoring function - VVL relay diagnosis

P1057

VVL relay diagnosis is performed internally to the ECU and does a comparison of the main relay voltage to the variable valve lift capacitors. If the difference is greater than a threshold then an appropriate DTC will be stored.

Error Symptoms

Relay diagnosis (battery voltage - capacitor voltage)P1057

SYMPTOM CHART

1.15.8.11 Monitoring overview - sensor diagnosis

Sensor diagnosis is performed internally to the ECU and checks the sensor supply voltage to tunable boundaries. A sensor signal versus an internal sensor self check will determine the integrity of the sensor.

1.15.8.12 Monitoring function - sensor short circuit diagnosis

P1019, P1020

The Power Supply sensor diagnosis checks short circuit to battery (SCVB) and to ground (SCG). If any of these errors is detected, the appropriate DTC will be stored.

Error Symptoms

Power supply sensor short circuit to battery voltageP1019
Power supply sensor short circuit to groundP1020

SYMPTOM CHART

1.15.8.13 Monitoring function - global sensor fault diagnosis

P1017

Error Symptoms

Global sensor faultP1017
(Sensor signal check and internal sensor self check for guide and reference sensor)

SYMPTOM CHART

1.15.8.14 Monitoring function - control position diagnosis

P1030

Control position diagnosis is used to monitor the movement of the variable valve train system. If the actual angle movement is determined to be lower than a threshold and the current PWM signal (depending on battery voltage) is greater than a threshold an error is detected. If an error is detected, the appropriate DTC will be stored

Error Symptoms

Control position faultP1030

SYMPTOM CHART

1.15.8.15 Monitoring function - self learning/adaptation diagnosis

P101A, P1023, P1024, P1041

There are three adaptation diagnoses performed in this function: Top, bottom and both limits are out of range.

Furthermore the ECU self check diagnosis is performed, which is basically a check sum error. If any of these errors is detected, the appropriate DTC will be stored.

Error Symptoms

Both adaptations failsP101A (both limits are not learned)
Range faultP1023 (range failure)
Bottom limit faultP1024 (bottom position not learned)
ECU check sum errorP1041 (adaptation EEPROM Memory failure)

SYMPTOM CHART

1.15.9.1 Vehicle Speed Sensor - signal plausibility check

P0503

1.15.9.1.1 Monitoring function

An vehicle speed signal plausibility error is detected if at calibratable engine speed-, mass air flow- and time thresholds the vehicle speed signal = 0.

Error symptom

Vehicle speed not plausibleP0503

SYMPTOM CHART

1.15.9.2 Vehicle speed sensor - signal check

P0500

1.15.9.2.1 Monitoring function

A vehicle speed signal error is set if neither a vehicle speed signal is available from ECU-PIN nor a signal is received from CAN (11H/12H).

Error symptom

No vehicle speed signalP0500

SYMPTOM CHART

1.16 Listing of all ECM Input and Output Signals

BMW signal namingBMW N52KPPinSIEMENS signal namingMSV80OBD II relevant
Fahrzeug CAN-Schnittstelle 1 LOWD_PT_CANL11_01CAN-Low1CAN1_LNo
Start(er)-Relais (Automatikstart)A_S_START1_02Start relayRLY_STARTNo
GeneratorschnittstelleD_BSD1_03Generator interfaceBSDNo
BremslichtschalterE_S_BLS1_04Brakelight switchBLSNo
AbgasklappeA_S_AKL1_05Exhaust flapEFNo
Masse Temperatur KuhlwasseraustrittM_TKA1_06Ground coolant outlet temperatureTCO_EX_GNDGNDNot used
Fahrerwunsch Geber 2E_A_FWG21_07Pedal value sensor 2PVS_2No
Elektr. Lufter getaktetA_T_ELUE1_08Cooling fanCFANo
LuftklappeA_T_LKS1_09Air flapAFNo
Masse Pedalwertgeber 1M_FWG11_10Ground pedal value sensor 1GNDNo
Spannungsversorgung 5V (PWG1)A_U_FWG11_11Supply voltage PVS1PVS1_VCCNo
Lin BusLIN_BUS_MS1_12Lin BusLINNo
Sekundarluftpumpe Stufe 1A_S_SLP1_13Secondary air pumpSAPNot used
Fahrzeug CAN-Schnittstelle 1 HIGHD_PT_CANH11_14CAN-High1CAN1_HNo
Wegfahrsperre, EWS4D_EWS1_15Imobilizer EWS4IMOBNo
BremslichtschalterE_S_BLTS1_16Brakelight test switchBTSNo
FahrzeuggeschwindigkeitE_F_DFAHR1_17Wheel speedWHEELYes
KupplungsschalterE_S_KUP1_18Clutch switchCLU_SWINo
Temperaturfuhler KuhlwasseraustrittE_A_TKA1_19Coolant outlet temperatureTCO_EXNot used
Fahrerwunsch Geber 1E_A_FWG11_20Pedal value sensor 1PVS_1No
DrehzahlA_F_TD1_21Engine speed signalESSYes
Fzg. Pin KI 15/3E_S_KL15_31_22Ignition key KI. 15/3V_IG_3No
Masse Pedalwertgeber 2M_FWG21_23Ground pedal value sensor 2GNDNo
Spannungsversorgung 5V (PWG2)A_U_FWG21_24Supply voltage PVS2PVS2_VCCNo
SekundarluftE_A_HFMS1_25Mass air flow metersecondary airMAFMSNot used
EBox-LufterA_S_EBOXL1_26Cooling fan EboxCFA_EBOXNo
Fzg. Pin Kl.15E_S_KL152_01Ignition key Kl.15V_IGNo
Lin BusLIN_BUS_MS2_02Lin BusLINNo
FahrdynamikkontrolleE_A_FDC2_03Sound flap switchSOF_SWINo
MultifunktionslenkradD_FGRD2_04Multifunctional steering wheelMSWNo
Pumpstrom, Stetige-Lambdas. v Kat 2A_I_LSVP22_05Pump current output 2LSL_IA_2Yes
Pumpzelle, Stetige-Lambdas. v Kat 1E_A_LSVP12_06Pump current measurement 1LSL_IP_1Yes
Pumpzelle, Stetige-Lambdas. v Kat 2E_A_LSVP22_07Pump current measurement 2LSL_IP_2Yes
Lambdasonde/Referenzzelle vor Kat 1E_A_LSVR12_08Lambda sensor upstream 1LS_UP_1Yes
Lambdasonde/Referenzzelle vor Kat 2E_A_LSVR22_09Lambda sensor upstream 2LS_UP_2Yes
Masse Lambdasonde vor Kat 1M_LSV12_10Ground lambda sensor upstream 1LS_UP_1_GNDYes
Masse Lambdasonde vor Kat 2M_LSV22_11Ground lambda sensor upstream 2LS_UP_2_GNDYes
Heizung Lambdasonde vor Kat 1A_T_LHV12_12Lambda sensor heater upstream 1LSH_UP_1Yes
Heizung Lambdasonde vor Kat 2A_T_LHV22_13Lambda sensor heater upstream 2LSH_UP_2Yes
Haupt-Relais (AAnsteuerung)A_S_HR2_14Main relayRLY_MAINNo
Ventil TankleckdiagnoseA_S_DMTLV2_15Tank leakage detection valveDMTLVYes
Pumpe TankleckdiagnoseA_S_DMTLP2_16Tank leakage detection pumpDMTLPYes
DMTL HeizungA_S_DMTLH2_17DMTL heaterDMTLHYes
Pumpstrom, Stetige-Lambdas. v Kat 1A_I_LSVP12_18Pump current output 1LSL_IA_1Yes
Lambdasonde hinter Kat 2E_A_LSH22_19Lambda sensor downstream 2LS_DOWN_2Yes
Lambdasonde hinter Kat 1E_A_LSH12_20Lambda sensor downstream 1LS_DOWN_1Yes
Relais KlimakompressorA_S_KOREL2_21Relay air conditioning compressorRLY_ACCNo
Reserve Analogeingang 1E_A_RES12_22Reserve analog 1SPARE_AN_1Not used
Masse Lambdasonde hinter Kat 1M_LSH12_23Ground lambda sensor downstream 1LS_DOWN_1_GNDYes
Masse Lambdasonde hinter Kat 2M_LSH22_24Ground lambda sensor downstream 2LS_DOWN_2_GNDYes
Heizung Lambdasonde hinter Kat 2A_T_LHH22_25Lambda sensor heater downstream 2LSH_DOWN_2Yes
Heizung Lambdasonde hinter Kat 1A_T_LHH12_26Lambda sensor heater downstream 1LSH_DOWN_1Yes
Dauerplus Kl.30E_U_303_01Direct battery Kl.30VBNo
HauptrelaisE_U_HR3_02Main relay Kl.87V_ELNo
Masse ZundungM_ZUE3_03Ground ignitionGND_IGNo
Masse Elektronik EinspritzventileM_EL/EV3_04Ground electronic, injectionGND_ELYes
Masse VVTM_VVT3_05Ground VVTGND_VVTYes
Masse VVTM_VVT3_06Ground VVTGND_VVTYes
Spannungsversorgung VVTE_U_VVTR14_01Supply voltage from VVT relayV_VVTYes
Spannungsversorgung VVTE_U_VVTR14_02Supply voltage from VVT relayV_VVTYes
Motorausgang 2 VVTA_T_VVT2M14_03Motor output 2 VVTVVT2M1Yes
Motorausgang 1 VVTA_T_VVT1M14_04Motor output 1 VVTVVT1M1Yes
Motorausgang 2 VVTA_T_VVT2M14_05Motor output 2 VVTVVT2M1Yes
Motorausgang 1 VVTA_T_VVT1M14_06Motor output 1 VVTVVT1M1Yes
Masse (nicht angeschlossen)N. c. (Masse)5_01GND (not connectedN. c.Not used
Masse (nicht angeschlossen)N. c. (Masse)5_02GND (not connectedN. c.Not used
Masse (nicht angeschlossen)N. c. (Masse)5_03GND (not connectedN. c.Not used
MAF FrequenzsignalE_P_HFM5_04SIMAFSIMAFNot used
Masse OldrucksensorM_OLD5_05Ground oil pressure sensorOILP_GNDNot used
Reserve Analogeingang 3E_A_RES35_06Reserve analog 3SPARE_AN3Not used
Spannungsversorgung 5V (Oldrucksensor)A_U_OLD5_07Supply voltage OILPOILP_VCCNo
NTC-Wasser (Motortemperatur)E_A_TMOT5_08Coolant temperatureTCOYes
Masse MotortemperaturfuhlerM_TMOT5_09Ground coolant temperature sensorTCO_GNDYes
OldruckE_S_OLD5_10Oil pressurePOILNo
OldruckventilA_T_OLP5_11Oil pressure valveSAV_OILPNot used
KraftstoffpumpeA_S_EKP5_12Electrical fuel pumpEFPNo
Haupt-Relais (Ansteuerung)A_S_HR5_13Main relayRLY_MAINNo
Spannungsversorgung 5V (DKG1,2)A_U_DKG5_14Supply voltage TPSPVS1TPS_VCCYes
Ansteuerung 1 DrosselklappeA_T_MDK15_15Throttle actuator out 1MTC1Yes
Ansteuerung 2 DrosselklappeA_T_MDK25_16Throttle actuator out 2MTC2Yes
Masse reserve 2M_RES15_17Ground spare 2SPARE2_GNDNot used
Schaltsaugrohr 2A_T_DISA25_18Variable intake manifold 2VIM2No
Klopfsensor 1B (Diff.- Signal)E_A_KS1B5_19Knock sensor 1BKNKS_1_BYes
Klopfsensor 2B (Diff.- Signal)E_A_KS2B5_20Knock sensor 2BKNKS_2_BYes
Applikation CAN-Schnittstelle 3 HIGHD_APPLI_CANH5_21CAN-High3CAN3_HNo
Lokaler CAN-HighD_LO_CANH5_22Local CAN-HighLOCAN_HNo
TankentlluftungsventilA_T_TEV5_23Canister purge solenoidCPSYes
SoundklappeA_S_ESK5_24Sound flapSFNo
Spannungsversorgung 5V (Reserve)A_U_RES15_25Supply voltage spareSPARE_VCCNot used
Reserve Analogeingang 2E_A_RES25_26Reserve analog 2SPARE_AN_2Not used
Masse HeiβfilmluftmassenmesserM_HFM5_27Ground mass air flow meterMAFM_GNDYes
AnsauglufttemperaturE_A_TANS5_28Intake air temperatureIATYes
KurbelwellensensorE_P_KWG5_29Crankshaft position sensorCRKYes
Masse KurbelwellensensorM_KWG5_30Ground crankshaft position sensorCRK_GNDYes
Spannungsversorgung 5V (SDF)A_U_SDF5_31Supply voltage MAPMAP_VCCYes
Masse SaugrohrdrucksensorM_SDF5_32Ground manifold air pressureMAP_GNDYes
SaugrohrdrucksensorE_A_SDF5_33Manifold air pressureMAP (IAP)Yes
Reserve Analogeingang 1E_A_RES15_34Reserve analog 1SPARE_AN_1Not used
GeneratorschnittstelleD_BSD5_35Generator interfaceBSDNo
Drosselklappengeber2E_A_DKG25_36Throttle position sensor 2TPS_2Yes
Drosselklappengeber1E_A_DKG15_37Throttle position sensor 1TPS_1Yes
Masse DrosselklappengeberM_DKG5_38Ground throttle position sensorTPS_GNDYes
OldrucksensorE_A_OLD5_39Oil pressure sensorOILPNot used
Schaltsaugrohr1A_T_DISA15_40Variable intake manifold 1VIM1No
Klopfsensor 1A (Diff.- Signal)E_A_KS1A5_41Knock sensor 1AKNKS_1_AYes
Klopfsensor 2A (Diff.- Signal)E_A_KS2A5_42Knock sensor 2AKNKS_2_AYes
Applikation CAN Schnittstelle 3 LOWD_APPLI_CANL5_43CAN-Low3CAN3_LNo
Lokalerr CAN-LowD_LO_CANL5_44Local CAN-LowLOCAN_LNo
Zundspule 1A_P_ZSZ16_01Ignition coil 1IGC0No
Zundspule 5A_P_ZSZ26_02Ignition coil 5IGC4No
Zundspule 3A_P_ZSZ36_03Ignition coil 3IGC2No
Zundspule 6A_P_ZSZ46_04Ignition coil 6IGC5No
Zundspule 2A_P_ZSZ56_05Ignition coil 2IGC1No
Zundspule 4A_P_ZSZ66_06Ignition coil 4IGC3No
Masse (nicht angeschlossen)M_ZUE6_07GND (not connected)IG_GNDNot used
Masse (nicht angeschlossen)M_ZUE6_08GND (not connected)IG_GNDNot used
Masse (nicht angeschlossen)M_ZUE6_09GND (not connected)IG_GNDNot used
Masse (nicht angeschlossen)M_ZUE6_10GND (not connected)IG_GNDNot used
Masse (nicht angeschlossen)M_ZUE6_11GND (not connected)IG_GNDNot used
Masse (nicht angeschlossen)M_ZUE6_12GND (not connected)IG_GNDNot used
Einspritzventil 1A_P_EVZ17_01Injection valve 1IV_0Yes
Einspritzventil 5A_P_EVZ27_02Injection valve 5IV_4Yes
Einspritzventil 3A_P_EVZ37_03Injection valve 3IV_2Yes
NTC-Wasser (Motortemperatur)E_A_TMOT7_04Coolant temperatureTCOYes
VANOS EinlassA_T_NWE7_05Infinitely variable valve timing inletIVVT_INYes
Datenclock VVT SensorA_P_CLKS17_06Data clock VVT sensorPCLK1S1Yes
Dateneingang Fuhrungssensor VVTE_T_DAT1S17_07Data input main sensor VVTTDAT1S1Yes
Chip Select Referenzsensor VVTA_P_CS2S17_08Chip select reference sensor VVTPCS2S1Yes
Dateneingang Referenzsensor VVTE_T_DAT2S17_09Data input reference sensor VVTTDAT2S1Yes
Schirm VVTW_VVTS17_10Shield VVTVVT_SHIELDYes
Nockenwellengeber EinlaβE_P_NWGE7_11Camshaft position sensor inletCAM_INYes
Nockenwellengeber AuslaβE_P_NWGA7_12Camshaft position sensor exhaustCAM_EXYes
OldruckE_S_OLD7_13Oil pressurePOILNo
Einspritzventil 6A_P_EVZ47_14Injection valve 6IV_5Yes
Einspritzventil 2A_P_EVZ57_15Injection valve 2IV_1Yes
Einspritzventil 4A_P_EVZ67_16Injection valve 4IV_3Yes
Masse MotortemperaturfuhlerM_TMOT7_17Ground coolant temperature sensorTCO_GNDYes
Vanos AuslassA_T_NWA7_18Infinitely variable valve timing exhaustIVVT_EXYes
Elektr. Geregeltes ThermostatA_S_KFK7_19El. controlled thermostatECTYes
Masse VVT-SensorM_VVTS17_20Ground variable valve timingVVTS1_GNDYes
Spannungsversorgung 5V (VVT-Sensor)A_U_VVTS17_21Supply voltage to VVT sensorVVTS1_VCCYes
Chip Select Fuhrungssensor VVTA_P_CS1S17_22Chip select main sensor VVTPCS1S1Yes
Schaltsignal VVT RelaisA_S_VVTR17_23VVT relayRLY_VVTYes
Masse Nockenwellengeber 1 EinlaβM_NWGE7_24Ground camshaft position sensor inlet 1CAM_IN_GNDYes
Masse Nockenwellengeber 1 AuslaβM_NWGA7_25Ground camshaft position sensor exhaust 1CAM_EX_GNDYes
GeneratorschnittstelleD_BSD7_26Generator interfaceBSDNo

SYMPTOM CHART

328xi, 328Cxi, 328Ci conv

128i, 128i Conv

Scheme 23

Scheme 23: 1.17.1 Location of the Data Link Connector for following models

The DLC is located at the lower left A-pillar and under a cover. This cover has the letters OBD on it.

1.18.1 Drawing and Location of the Malfunction Indicator Light for following models

328xi, 328Cxi, 328Ci conv.

128i, 128i Conv.

Complete Instrument panel (European Version)

Scheme 24

Scheme 24: 1.18.1 Drawing and Location of the Malfunction Indicator Light for following models

1.19 Calculated load and fuel trim determination

The calculated engine load "LOAD_CLC [%]" is based on the calculated mass air flow) Speed Density-System - The Air Mass Flow for a suction stroke is a function of the intake system manifold pressure and the air temperature

Strategy

A 2-dimensional map is used to interpolate the calculated engine load "LOAD_CLC [%]" depending on calculated mass air flow and engine speed. A weighting factor is applied to compensate the altitude influence.

The calculation is performed as follows

LOAD_CLC [%] = LOAD_CLC_RAW f (calculated mass air flow, engine speed) x (1013hPa/ambient pressure) x 100%

with

LOAD_CLCCalculated engine load in % with altitude correction
LOAD_CLC_RAWCalculated engine load in % without altitude correction

CALCULATED LOAD AND FUEL TRIM DETERMINATION CHART

See also:
P0420, P0430
P0300, P0301, P0302, P0303, P0304, P0305, P0306, P1396
P0440
P0442, P0456
P1434, P1447, P1448, P1449
P2096, P2098, P2097, P2099
P2068, P2067, P0463, P0462
P144B
P0131, P0151, P0132, P0152
P112C, P112D, P2626, P2629, P2243, P2247
P3022, P3023, P3024, P3025
P2414, P2415
P0040
P2195, P2197, P2196, P2198
P0133, P0153
P2297, P2298
P0135, P0155, P165F, P166F
P0031, P0051, P0032, P0052, P0030, P0050
P0137, P157, P0138, P158, P0140, P0160
P013E, P014A
P013A, P013C
P114A, P114C, P114B, P114D
P2270, P2272, P2271, P2273, P0041
P0141, P0161
P0036, P0056, P0037, P0057, P0038, P0058
P0128
P0117, P0118
P3198
P3199
P316A
P1515
P0506, P0507, P1561, P1562
P1561, P1562
P0012, P0015
P13B4, P13B6, P13BA, P13BC, P0340, P0365, P1300, P130A, P13B0, P13B2
P0016
P0335, P0336, P0370, P138F
P0072, P0073
P0071
P0112, P0113
P0111, P111E, P111F
P2100
P169A, P1694
P1632, P1633, P16BA, P1635, P1644
P11AA, P1639
P1417
P1104, P1105
P1197, P1198
P1124
P116C, P116E
P0326, P0327, P0328, P1327, P1328, P135B
P1047, P1048, P1049, P1055, P1056, P1057, P103A, P1017, P1019, P1020, P1075, P1076, P1078, P107A, P107B, P107C, P1030, P101A, P1023, P1024, P1041, P105A, P105B
P0503
P0500
DOWNSTREAM ACTIVE TEST