Contents Wiring diagrams Section: Engine Control Systems All sections

Electronic Engine Controls (v8 S/c 5.0l Petrol) Land Rover Range Rover Sport L320

Engine Control Systems 33 illustrations ~5081 words

SPECIFICATIONS

DescriptionNm
Camshaft position (CMP) sensor(s) retaining bolt10
Crankshaft position (CKP) sensor retaining bolt10
Heated oxygen sensor(s) (HO2S)48
Catalyst monitor sensor(s)48
Knock sensor(s) (KS) retaining bolt20
Fuel rail pressure (FRP) sensor32
Manifold absolute pressure and temperature (MAPT) sensor5
Engine oil level sensor retaining bolts12
Variable valve timing (VVT) oil control solenoid(s) retaining bolts10
Engine control module (ECM) retaining bolts7
Engine control module (ECM) retaining nuts7
Mass air flow (MAF) sensor retaining bolts1.2

TORQUE SPECIFICATIONS

COMPONENT LOCATION - SHEET 1 OF 3

Item NumberDescription
1MAFT (mass air flow and temperature) sensor
2MAP (manifold absolute pressure) sensor
3Knock sensors
4MAFT sensor
5CKP (crankshaft position) sensor
6ECT (engine coolant temperature) sensor (ECT 2)
7CMP (camshaft position) sensors
8Electronic throttle
9CMP sensors

COMPONENT LOCATION - SHEET 2 OF 3

Item NumberDescription
1MAPT (manifold absolute pressure and temperature) sensor
2ECT sensor (ECT 1)
3Upstream HO2S (heated oxygen sensor)
4Downstream HO2S
5Downstream HO2S
6Upstream HO2S
7ECM (engine control module)

COMPONENT LOCATION - SHEET 3 OF 3

Item NumberDescription
1AAT (ambient air temperature) sensor
2APP (accelerator pedal position) sensor

INTRODUCTION

The electronic engine control (EEC) system operates the engine to generate the output demanded by the accelerator pedal and loads imposed by other systems. The electronic engine control (EEC) system has an engine control module (ECM) that uses a torque-based strategy to evaluate inputs from sensors and other systems, then produces outputs to engine actuators to produce the required torque.

The electronic engine control (EEC) system controls the following

  1. Charge air
  2. Fueling
  3. Ignition timing
  4. Valve timing
  5. Cylinder knock
  6. Noise feedback system
  7. Idle speed
  8. Engine cooling fan
  9. Evaporative emissions
  10. On-board diagnostics
  11. Immobilization system interface
  12. Speed control.

ENGINE CONTROL MODULE

Item NumberDescription
1ECM and cooling fan mounting bracket
2Cooling fan
3Screw (2 off)
4Nut (2 off)
5ECM

The engine control module (ECM) is installed in the passenger side protective box in the engine compartment, on a bracket attached to the engine bulkhead. The bracket also contains an electric cooling fan. The engine control module (ECM), which has an internal temperature sensor, controls the operation of the cooling fan. While the ignition is on, the cooling fan receives a power supply from the engine control module (ECM) relay in the engine junction box (EJB). When cooling is required, the engine control module (ECM) connects the cooling fan to ground.

The engine control module (ECM) has the capability of adapting its fuel and ignition control outputs in response to several sensor inputs.

The engine control module (ECM) receives inputs from the following

  1. crankshaft position (CKP) sensor.
  2. camshaft position (CMP) sensors (4 off).
  3. engine coolant temperature (ECT) sensors (2 off).
  4. Knock sensors (4 off).
  5. manifold absolute pressure (MAP) sensor.
  6. mass air flow and temperature (MAFT) sensors (2 off).
  7. manifold absolute pressure and temperature (MAPT) sensor.
  8. Throttle position sensor.
  9. Heated oxygen sensors (4 off).
  10. accelerator pedal position (APP) sensor.
  11. Ambient air temperature sensor.
  12. fuel rail pressure (FRP) sensor. Refer to «Fuel Charging and Controls»(/land-rover/range-rover-sport/l320-2009-2013/remont/fuel-system/#fuel-charging-and-controls-v8-sc-50l-petrol) .
  13. Engine cooling fan. Refer to «Engine Cooling»(/land-rover/range-rover-sport/l320-2009-2013/remont/cooling-fan/#engine-cooling) .
  14. Stoplamp switch. Refer to «Anti-Lock Control - Traction Control»(/land-rover/range-rover-sport/l320-2009-2013/remont/anti-locktraction-control/#anti-lock-control-traction-control) .
  15. Speed control cancel/suspend switch. Refer to «Speed Control»(/land-rover/range-rover-sport/l320-2009-2013/remont/cruise-control-systems/#speed-control) .
  16. Oil level and temperature sensor. Refer to «Engine»(/land-rover/range-rover-sport/l320-2009-2013/remont/mechanical/#engine-v8-sc-50l-petrol) .
  17. Fuel LP (low pressure) sensor. For additional information, refer to: Fuel Tank and Lines (310-01C, Description and Operation).
  18. Fuel pump driver module. For additional information, refer to: Fuel Tank and Lines (310-01C, Description and Operation).

The engine control module (ECM) provides outputs to the following

  1. Electronic throttle.
  2. Main relay.
  3. Heaters elements of the heated oxygen sensors (4 off).
  4. Fuel injectors (8 off). Refer to «Fuel Charging and Controls»(/land-rover/range-rover-sport/l320-2009-2013/remont/fuel-system/#fuel-charging-and-controls-v8-sc-50l-petrol) .
  5. Ignition coils (8 off). Refer to «Engine Ignition»(/land-rover/range-rover-sport/l320-2009-2013/remont/ignition-system/#engine-ignition) .
  6. variable camshaft timing (VCT) solenoids (4 off). Refer to «Engine»(/land-rover/range-rover-sport/l320-2009-2013/remont/mechanical/#engine-v8-sc-50l-petrol) .
  7. Noise feedback system tuning valve. Refer to «Intake Air Distribution and Filtering»(/land-rover/range-rover-sport/l320-2009-2013/remont/mechanical/#intake-air-distribution-and-filtering-v8-sc-50l-petrol) .
  8. evaporative emission (EVAP) canister purge valve. Refer to «Evaporative Emissions»(/land-rover/range-rover-sport/l320-2009-2013/remont/auxiliary-emission-control-systems/#evaporative-emissions) .
  9. Engine starter relay. Refer to «Starting System»(/land-rover/range-rover-sport/l320-2009-2013/remont/starter/#starting-system) .
  10. Engine cooling fan. Refer to «Engine Cooling»(/land-rover/range-rover-sport/l320-2009-2013/remont/cooling-fan/#engine-cooling) .
  11. Intercooler water pump relay. Refer to «Supercharger Cooling»(ref-533355-S18158715702013022700000) .
  12. Generator. Refer to «Generator»(/land-rover/range-rover-sport/l320-2009-2013/remont/charging-system/#generator-and-regulator) .
  13. HP fuel pumps. For additional information, refer to: Fuel Tank and Lines (310-01C, Description and Operation).
  14. Fuel pump driver module. For additional information, refer to: Fuel Tank and Lines (310-01C, Description and Operation).
  15. DMTL (diagnostic module - tank leakage). Refer to «Evaporative Emissions»(/land-rover/range-rover-sport/l320-2009-2013/remont/auxiliary-emission-control-systems/#evaporative-emissions) .

CRANKSHAFT POSITION SENSOR

The crankshaft position (CKP) sensor is an inductive sensor that allows the engine control module (ECM) to determine the angular position of the crankshaft and the engine speed.

The crankshaft position (CKP) sensor is installed in the rear left side of the sump body, in line with the engine drive plate. The sensor is secured with a single screw and sealed with an O-ring. A two pin electrical connector provides the interface with the engine harness.

The head of the crankshaft position (CKP) sensor faces a reluctor ring pressed into the outer circumference of the engine drive plate. The reluctor ring has a 60 minus 2 tooth pattern. There are 58 teeth at 6° intervals, with two teeth removed to provide a reference point with a centerline that is 21° before top dead center (BTDC) on cylinder 1 of bank A.

If the crankshaft position (CKP) sensor fails, the engine control module (ECM)

  1. Uses signals from the camshaft position (CMP) sensors to determine the angular position of the crankshaft and the engine speed
  2. Adopts a limp home mode where engine speed is limited to a maximum of 3000 rev/min.

With a failed crankshaft position (CKP) sensor, engine starts will require a long crank time while the engine control module (ECM) determines the angular position of the crankshaft.

CAMSHAFT POSITION SENSORS

The camshaft position (CMP) sensors are MRE (magneto resistive element) sensors that allow the engine control module (ECM) to determine the angular position of the camshafts. MRE sensors produce a digital output which allows the engine control module (ECM) to detect speeds down to zero.

The four camshaft position (CMP) sensors are installed in the front upper timing covers, one for each camshaft.

Each camshaft position (CMP) sensor is secured with a single screw and sealed with an O-ring. On each camshaft position (CMP) sensor, a three pin electrical connector provides the interface with the engine harness.

The head of each camshaft position (CMP) sensor faces a sensor wheel attached to the front of the related variable camshaft timing (VCT) unit.

If an exhaust camshaft position (CMP) sensor fails, the engine control module (ECM) disables the variable camshaft timing (VCT) of both exhaust camshafts.

If an intake camshaft position (CMP) sensor fails, the engine control module (ECM) disables the variable camshaft timing (VCT) of both intake camshafts. This can result in the engine being slow, or failing, to start.

ENGINE COOLANT TEMPERATURE SENSORS

The engine coolant temperature (ECT) sensors are negative temperature coefficient (NTC) thermistors that allow the engine control module (ECM) to monitor the engine coolant temperature.

There are two identical engine coolant temperature (ECT) sensors installed, which are identified as ECT 1 and ECT 2. Each sensor is secured with a twist-lock and latch mechanism, and is sealed with an O-ring. A two pin electrical connector provides the interface between the sensor and the engine harness.

ECT 1

ECT 1 is installed in the heater manifold, at the rear of the right-hand (RH) cylinder head. The input from this sensor is used in calibration tables and by other systems.

If there is an ECT 1 fault, the engine control module (ECM) adopts an estimated coolant temperature. On the second consecutive trip with an ECT 1 fault, the engine control module (ECM) illuminates the malfunction indicator lamp (MIL).

ECT 2

ECT 2 is installed in the lower hose connector which attaches to the bottom of the thermostat. The input from this sensor is used for on-board diagnostic (OBD) 2 diagnostics and, in conjunction with the input from ECT 1, to confirm that the thermostat is functional.

If there is an ECT 2 fault, the engine control module (ECM) illuminates the malfunction indicator lamp (MIL) on the second consecutive trip.

KNOCK SENSORS

The knock sensors are piezo-ceramic sensors that allow the engine control module (ECM) to employ active knock control and prevent engine damage from pre-ignition or detonation.

Two knock sensors are installed on the inboard side of each cylinder head, one mid-way between cylinders 1 and 2, and one mid-way between cylinders 3 and 4. Each knock sensor is secured with a single screw. On each knock sensor, a two pin electrical connector provides the interface with the engine harness.

The engine control module (ECM) compares the signals from the knock sensors with mapped values stored in memory to determine when detonation occurs on individual cylinders. When detonation is detected, the engine control module (ECM) retards the ignition timing on that cylinder for a number of engine cycles, then gradually returns it to the original setting.

The engine control module (ECM) cancels closed loop control of the ignition system if the signal received from a knock sensor becomes implausible. In these circumstances the engine control module (ECM) defaults to base mapping for the ignition timing. This ensures the engine will not become damaged if low quality fuel is used. The malfunction indicator lamp (MIL) will not illuminate, although the driver may notice that the engine 'pinks' in some driving conditions and displays a drop in performance and smoothness.

The ECM calculates the default value if one sensor fails on each bank of cylinders.

MANIFOLD ABSOLUTE PRESSURE SENSOR

The manifold absolute pressure (MAP) sensor allows the engine control module (ECM) to calculate the load on the engine, which is used in the calculation of fuel injection time.

The manifold absolute pressure (MAP) sensor is installed in the air inlet of the supercharger (SC). The sensor is secured with a single screw and sealed with an O-ring. A three pin electrical connector provides the interface with the engine harness.

If the manifold absolute pressure (MAP) sensor fails, the engine control module (ECM) adopts a default value of 1 bar (14.5 lbf/in. 2 ).

With a failed manifold absolute pressure (MAP) sensor, the engine will suffer from poor starting, rough running and poor driveability.

MASS AIR FLOW AND TEMPERATURE SENSORS

The mass air flow and temperature (MAFT) sensors allow the engine control module (ECM) to measure the mass flow and the temperature of the air flow into the engine. The mass air flow is measured with a hot film element in the sensor. The temperature of the air flow is measured with a negative temperature coefficient (NTC) thermistor in the sensor. The mass air flow is used to determine the fuel quantity to be injected in order to maintain the target air/fuel mixture required for correct operation of the engine and the catalytic converters.

There are two mass air flow and temperature (MAFT) sensors installed, one in each air cleaner outlet duct. Each mass air flow and temperature (MAFT) sensor is secured with two screws and sealed with an O-ring. On each mass air flow and temperature (MAFT) sensor, a five pin electrical connector provides the interface with the engine harness.

If the hot film element signal fails the engine control module (ECM) invokes a software backup strategy to calculate the mass air flow from other inputs. Closed loop fuel control, closed loop idle speed control and evaporative emissions control are discontinued. The engine will suffer from poor starting, poor throttle response and, if the failure occurs while driving, the engine speed may dip and surging may occur before recovering.

If the negative temperature coefficient (NTC) thermistor signal fails the engine control module (ECM) adopts a default value of 25 °C (77 °F) for the intake air temperature.

MANIFOLD ABSOLUTE PRESSURE AND TEMPERATURE SENSOR

The manifold absolute pressure and temperature (MAPT) sensor allows the engine control module (ECM) to calculate the air charge density immediately before it enters the cylinders. This is used to adjust the ignition timing relative to the boost pressure, and to monitor the performance of the charge air coolers.

The manifold absolute pressure and temperature (MAPT) sensor is installed in the left-hand (LH) charge air cooler outlet. The sensor is secured with a single screw and sealed with an O-ring. A four pin electrical connector provides the interface with the engine harness.

THROTTLE POSITION SENSORS

The throttle position (TP) sensors allow the engine control module (ECM) to determine the position and angular rate of change of the throttle blade.

There are two throttle position (TP) sensors located in the electronic throttle. See below for details of the electronic throttle.

If a throttle position (TP) sensor fails, the engine control module (ECM)

  1. Adopts a limp home mode where engine speed is limited to a maximum of approximately 2000 rev/min
  2. Discontinues evaporative emissions control
  3. Discontinues closed loop control of engine idle speed.

With a failed throttle position (TP) sensor, the engine will suffer from poor running and throttle response.

HEATED OXYGEN SENSORS

The heated oxygen sensors allow the engine control module (ECM) to measure the oxygen content of the exhaust gases, for closed loop control of the fuel:air mixture and for catalytic converter monitoring.

An upstream heated oxygen sensor is installed in the outlet of each exhaust manifold, which enables independent control of the fuel:air mixture for each cylinder bank. A downstream heated oxygen sensor is installed in each catalytic converter, which enables the performance of the catalytic converters to be optimized and monitored.

Oxygen sensors need to operate at high temperatures in order to function correctly. To achieve the high temperatures required, the sensors are fitted with heater elements that are controlled by a pulse width modulation (PWM) signal from the engine control module (ECM). The heater elements are operated after each engine start, once it has been calculated that there is no moisture in the exhaust (between 0 and 2 minutes delay), and also during low load conditions when the temperature of the exhaust gases is insufficient to maintain the required sensor temperature. The pulse width modulation (PWM) duty cycle is carefully controlled to prevent thermal shock to cold sensors. A non-functioning heater delays the sensor's readiness for closed loop control and increases emissions.

The upstream heated oxygen sensors produce a constant voltage, with a variable current that is proportional to the lambda ratio. The downstream heated oxygen sensors produce an output voltage dependant on the ratio of the exhaust gas oxygen to the ambient oxygen.

The heated oxygen sensors age with mileage, increasing their response time to switch from rich to lean and lean to rich. This increase in response time influences the engine control module (ECM) closed loop control and leads to progressively increased emissions. Measuring the period of rich to lean and lean to rich switching monitors the response rate of the upstream sensors.

Diagnosis of electrical faults is continually monitored in both the upstream and downstream sensors. This is achieved by checking the signal against maximum and minimum threshold, for open and short circuit conditions.

If a heated oxygen sensor fails

  1. The engine control module (ECM) defaults to open loop fueling for the related cylinder bank
  2. The CO (carbon monoxide) and emissions content of the exhaust gases may increase
  3. The exhaust may smell of rotten eggs (hydrogen sulphide).

With a failed heated oxygen sensor, the engine will suffer from reduced refinement and performance.

ACCELERATOR PEDAL POSITION SENSOR

The accelerator pedal position (APP) sensor allows the engine control module (ECM) to determine the driver requests for vehicle speed, acceleration and deceleration. The engine control module (ECM) uses this information, together with information from the anti-lock brake system (ABS) module and the transmission control module (TCM), to determine the setting of the electronic throttle.

Three screws attach the accelerator pedal position (APP) sensor and integrated accelerator pedal to a bracket on the lower dash panel. A six pin electrical connector provides the interface with the vehicle harness.

The accelerator pedal position (APP) sensor is a twin track potentiometer. Each track receives an independent power supply from the engine control module (ECM) and returns an independent analog signal to the engine control module (ECM). Both signals contain the same positional information, but the signal from track 2 is half the voltage of the signal from track 1 at all positions.

If both signals have a fault, the engine control module (ECM) adopts a limp home mode, which limits the engine speed to 2000 rev/min maximum.

The engine control module (ECM) constantly checks the range and plausibility of the two signals and stores a fault code if it detects a fault.

AMBIENT AIR TEMPERATURE SENSOR

The AAT (ambient air temperature) sensor is a negative temperature coefficient (NTC) thermistor that allows the engine control module (ECM) to monitor the temperature of the air around the vehicle. The engine control module (ECM) uses the AAT input for a number of functions, including engine cooling fan control. The engine control module (ECM) also transmits the ambient temperature on the high speed controller area network (CAN) bus for use by other control modules.

The AAT sensor is installed on a bracket in the front bumper ducting, on the vehicle centerline.

The engine control module (ECM) supplies the sensor with a 5 V reference voltage and a ground, and translates the return signal voltage into a temperature.

If there is a fault with the AAT sensor, the engine control module (ECM) calculates the AAT from the temperature inputs of the mass air flow and temperature (MAFT) sensors. If the AAT sensor and the temperature inputs of the mass air flow and temperature (MAFT) sensors are all faulty, the engine control module (ECM) adopts a default ambient temperature of 25 °C (77 °F).

ELECTRONIC THROTTLE

The engine control module (ECM) uses the electronic throttle to help regulate engine torque.

The electronic throttle is installed between the T piece duct, of the intake air distribution and filtering system, and the inlet of the supercharger (SC). Refer to Intake Air Distribution and Filtering .

The throttle plate is operated by an electric DC (direct current) motor integrated into the throttle body. The engine control module (ECM) uses a pulse width modulation (PWM) signal to control the DC motor. The engine control module (ECM) compares the accelerator pedal position (APP) sensor inputs against an electronic request or value to determine the required position of the throttle plate. The engine control module (ECM) and electronic throttle are also required to

  1. Monitor requests for cruise control operation
  2. Automatically operate the electronic throttle for accurate cruise control
  3. Perform all dynamic stability control engine interventions
  4. Monitor and carry out maximum engine speed and road speed cut outs
  5. Provide different engine maps for the ride and handling optimization system.

A software strategy within the engine control module (ECM) calibrates the position of the throttle plate at the beginning of each ignition cycle. When the ignition is turned on, the engine control module (ECM) performs a self test and calibration routine by fully closing the throttle plate and then opening it again. This tests the default position springs and allows the engine control module (ECM) to learn the fully closed position.

ECM RELAY

The engine control module (ECM) relay is used to initiate the power up and power down routines within the engine control module (ECM). The engine control module (ECM) relay is installed in the engine junction box (EJB).

When the ignition is turned on, battery voltage is applied to the ignition sense input. The engine control module (ECM) then starts its power up routines and energizes the engine control module (ECM) relay.

When the ignition is turned off, the engine control module (ECM) maintains its powered up state while it conducts the power down routines. This can be for

  1. Up to 20 minutes in extreme cases, when the DMTL system is running (NAS markets) or the transmission control module (TCM) is 'kept awake' because of a 'not in park' condition
  2. Up to 5 minutes when cooling fans are required.

On completion of the power down routines the engine control module (ECM) de-energizes the engine control module (ECM) relay.

CONTROL DIAGRAM

Item NumberDescription
1Battery
2EJB (engine junction box)
3ECM
4LH (left hand) intake CMP sensor
5LH exhaust CMP sensor
6LH MAFT sensor
7LH front knock sensor
8LH rear knock sensor
9RH (right hand) front knock sensor
10RH rear knock sensor
11RH intake CMP sensor
12RH exhaust CMP sensor
13RH MAFT sensor

Note. A = Hardwired.

Item NumberDescription
1MAP sensor
2ECT sensor (ECT 2)
3CKP sensor
4Diagnostic socket
5To other system control modules
6ECM
7Electronic throttle
8APP sensor
9AAT sensor
10ECT sensor (ECT 1)
11ECM cooling fan
12LH downstream HO2S
13LH upstream HO2S
14MAPT sensor
15RH downstream HO2S
16RH upstream HO2S

Note. A = Hardwired; D = High speed controller area network (CAN) bus.

ECM ADAPTIONS

The engine control module (ECM) has the ability to adapt the input values it uses to control certain outputs. This capability maintains engine refinement and ensures the engine emissions remain within the legislated limits. The components which have adaptions associated with them are

  1. The accelerator pedal position (APP) sensor
  2. The heated oxygen sensors
  3. The mass air flow and temperature (MAFT) sensors
  4. The crankshaft position (CKP) sensor
  5. Electronic throttle.
  6. Knock sensors.

OXYGEN AND MASS AIR FLOW AND TEMPERATURE (MAFT) SENSORS

There are several adaptive maps associated with the fueling strategy. Within the fueling strategy the engine control module (ECM) calculates short-term adaptions and long term adaptions. The engine control module (ECM) will monitor the deterioration of the heated oxygen sensors over a period of time. It will also monitor the current correction associated with the sensors.

The engine control module (ECM) will store a fault code in circumstances where an adaption is forced to exceed its operating parameters. At the same time, the engine control module (ECM) will record the engine speed, engine load and intake air temperature.

The characteristics of the signal supplied by the crankshaft position (CKP) sensor are learned by the engine control module (ECM). This enables the engine control module (ECM) to set an adaption and support the engine misfire detection function. Due to the small variation between different drive plates and different crankshaft position (CKP) sensors, the adaption must be reset if either component is renewed, or removed and refitted. It is also necessary to reset the drive plate adaption if the engine control module (ECM) is renewed or replaced. The engine control module (ECM) supports four drive plate adaptions for the crankshaft position (CKP) sensor. Each adaption relates to a specific engine speed range. The engine speed ranges are detailed in the table below

AdaptionEngine Speed, rev/min
11800 - 3000
23001 - 3800
33801 - 4600
44601 - 5400

MISFIRE DETECTION

Legislation requires that the engine control module (ECM) must be able to detect the presence of an engine misfire. It must be able to detect misfires at two separate levels. The first level is an amount of misfire that could lead to the legislated emissions limit being exceeded by a given amount. The second level is a misfire rate that causes degradation in catalytic converter efficiency.

The engine control module (ECM) monitors the number of misfire occurrences within two engine revolution ranges. If the engine control module (ECM) determines a misfire failure within either of these two ranges, over two consecutive journeys, it will record a fault code and details of the engine speed, engine load and engine coolant temperature. In addition, if the second level of misfire occurs, on any trip, the engine control module (ECM) flashes the malfunction indicator lamp (MIL) while the fault is occurring.

The signal from the crankshaft position (CKP) sensor indicates how fast the poles on the drive plate are passing the sensor tip. A sine wave is generated each time a pole passes the sensor tip. The engine control module (ECM) can detect variations in drive plate speed by monitoring the sine wave signal supplied by the crankshaft position sensor. By assessing this signal, the engine control module (ECM) can detect the presence of an engine misfire. The engine control module (ECM) will evaluate the signal against a number of factors and will decide whether to record the occurrence or ignore it. The engine control module (ECM) can assign a misfire judgement to an individual cylinder, which can be viewed on Land Rover approved diagnostic equipment.

DIAGNOSTICS

The engine control module (ECM) stores each fault as a diagnostic trouble code (DTC). The diagnostic trouble code (DTC) and associated environmental and freeze frame data can be read using Land Rover approved diagnostic equipment, which can also read real time data from each sensor, the adaption values currently being employed and the current fueling, ignition and idle speed settings.

For additional information. Refer to Electronic Engine Controls .

POWERTRAIN CONTROL MODULE (PCM) LONG DRIVE CYCLE SELF-TEST

WARNINGWhere possible, all road tests should be on well surfaced and dry roads. Always comply with speed limits and local traffic regulations.

Note. This procedure is an overcheck only. If fault codes are found, interrogation of the relevant system must be carried out and claimed against.

Note. The vehicle must exceed 50mph (80 km/h) during the road test.

  1. Connect the diagnostic equipment to the vehicle.
  2. Follow on screen prompts and check for engine management fault codes.
  3. Clear the fault codes following the on screen procedure.
  4. Disconnect the diagnostic equipment from the vehicle.
  5. Carry out a road test and perform the following operations. Accelerate to 55 mph (88 km/h) in 5th gear and cruise for 2 minutes with the engine speed at or above 1800rpm. Lift off the throttle and allow the vehicle to decelerate until the engine speed is less than 1000 rpm. Stop the vehicle. Release brake, allow the vehicle to move with no throttle for 1 minute. Road test is now complete.
  6. Connect the diagnostic equipment to the vehicle.
  7. Follow on screen prompts and check for engine management fault codes.
  8. Disconnect the diagnostic equipment from the vehicle.

POWERTRAIN CONTROL MODULE (PCM) SHORT DRIVE CYCLE SELF-TEST

Note. This procedure is an overcheck only. If fault codes are found, interrogation of the relevant system must be carried out and claimed against.

  1. Connect the diagnostic equipment to the vehicle.
  2. Follow on screen prompts and check for engine management fault codes.
  3. Clear the fault codes following the on screen procedure.
  4. Start the engine. Allow the engine to idle for 30 seconds. Raise the engine speed to 1500 rpm and hold for 3 minutes until a temperature of 70°C (158 °F) is achieved. Allow the engine to idle for 30 seconds. Switch off the engine.
  5. Follow on screen prompts and check for engine management fault codes.
  6. Disconnect the diagnostic equipment from the vehicle.

Scheme 1

Scheme 1: CHECK
  1. Remove the brake pedal rubber.
  2. Position the DTI gauge on a suitable mounting block, as illustrated.
  3. With the aid of another technician, gently press the brake pedal until the stoplamps illuminate.
  4. Note the measurement of the brake pedal travel from rest position until the stoplamps illuminated.

ADJUST

  1. Remove the stoplamp switch. Refer to «Stoplamp Switch»(/land-rover/range-rover-sport/l320-2009-2013/remont/exterior-lights/#exterior-lighting) .
  2. Install the stoplamp switch. Refer to «Stoplamp Switch»(/land-rover/range-rover-sport/l320-2009-2013/remont/exterior-lights/#exterior-lighting) .
  3. Check the adjustment of the stoplamp switch by following the Check procedure in this procedure and carry out the Adjust procedure if required.

Scheme 2

Scheme 2: REMOVAL
  1. Disconnect the battery ground cable. Refer to «Specifications»(/land-rover/range-rover-sport/l320-2009-2013/remont/charging-system/#battery-charging-system-general-information) .
  2. Raise and support the vehicle.
  3. Refer to «Thermostat Housing - Vehicles With: Supercharger»(/land-rover/range-rover-sport/l320-2009-2013/remont/cooling-fan/#engine-cooling) .
  4. Torque: 10 Nm

INSTALLATION

  1. To install, reverse the removal procedure.

REMOVAL

Note. Removal steps in this procedure may contain installation details.

Scheme 3

Scheme 3: REMOVAL
  1. Disconnect the battery ground cable. Refer to «Specifications»(/land-rover/range-rover-sport/l320-2009-2013/remont/charging-system/#battery-charging-system-general-information) .
  2. Raise and support the vehicle.
  3. Refer to «Thermostat Housing - 5.0L SC V8 - AJ133»(/land-rover/range-rover-sport/l320-2009-2013/remont/cooling-fan/#engine-cooling) .
  4. Torque: 10 Nm
  1. To install, reverse the removal procedure.

Note. Removal steps in this procedure may contain installation details.

Scheme 4

Scheme 4: REMOVAL

Scheme 5

Scheme 5

Scheme 6

Scheme 6
  1. Raise and support the vehicle.
  2. Torque: 10 Nm
  3. See graphic
  4. Torque: 48 Nm
  1. To install, reverse the removal procedure.

Note. Removal steps in this procedure may contain installation details.

Scheme 7

Scheme 7

Scheme 8

Scheme 8
  1. Raise and support the vehicle.
  2. Torque: 10 Nm
  3. See graphic
  4. See graphic
  5. Torque: 48 Nm
  1. To install, reverse the removal procedure.

Note. Removal steps in this procedure may contain installation details.

Scheme 9

Scheme 9: REMOVAL
  1. Disconnect the battery ground cable. Refer to «Specifications»(/land-rover/range-rover-sport/l320-2009-2013/remont/charging-system/#battery-charging-system-general-information) .
  2. Raise and support the vehicle.
  3. Refer to «Engine Undershield»(/land-rover/range-rover-sport/l320-2009-2013/remont/exterior-body-panels/#front-end-body-panels) .
  4. Torque: 10
  1. To install, reverse the removal procedure.
  2. Using the approved diagnostic equipment, clear the powertrain control module (PCM) adaptions.

Note. Removal steps in this procedure may contain installation details.

Scheme 10

Scheme 10: REMOVAL

Scheme 11

Scheme 11
  1. Remove the battery. Refer to «Battery»(/land-rover/range-rover-sport/l320-2009-2013/remont/charging-system/#battery-mounting-and-cables) .
  2. Torque: 7 Nm
  1. To install, reverse the removal procedure.

Note. Removal steps in this procedure may contain installation details.

Scheme 12

Scheme 12: REMOVAL
  1. Raise and support the vehicle.
  2. Refer to «Engine Cover - 5.0L»(/land-rover/range-rover-sport/l320-2009-2013/remont/exteriorinterior-trim/#interior-trim-and-ornamentation) .
  3. Refer to «COOLING SYSTEM DRAINING, FILLING AND BLEEDING (V8 S/C 5.0L PETROL)»(/land-rover/range-rover-sport/l320-2009-2013/remont/cooling-fan/#engine-cooling) .
  1. To install, reverse the removal procedure.

Note. Removal steps in this procedure may contain installation details.

Scheme 13

Scheme 13: REMOVAL
  1. Raise and support the vehicle.
  2. Engine Oil Draining and Filling.
  3. Torque: 12 Nm
  1. To install, reverse the removal procedure.

Note. Removal steps in this procedure may contain installation details.

Scheme 14

Scheme 14: REMOVAL
  1. Raise and support the vehicle.
  2. Refer to «Supercharger»(/land-rover/range-rover-sport/l320-2009-2013/remont/mechanical/#intake-air-distribution-and-filtering-v8-sc-50l-petrol) .
  3. Torque: 20 Nm
  1. To install, reverse the removal procedure.

Note. Removal steps in this procedure may contain installation details.

Scheme 15

Scheme 15: REMOVAL
  1. Raise and support the vehicle.
  2. Refer to «Supercharger»(/land-rover/range-rover-sport/l320-2009-2013/remont/mechanical/#intake-air-distribution-and-filtering-v8-sc-50l-petrol) .
  3. Torque: 20 Nm
  1. To install, reverse the removal procedure.

Note. Removal steps in this procedure may contain installation details.

  1. Refer to «Petrol and Petrol-Ethanol Fuel Systems Health and Safety Precautions»(/land-rover/range-rover-sport/l320-2009-2013/remont/oem-general-information/#general-information-1-of-2) .
  2. Refer to «Fuel System Pressure Release - 5.0L»(/land-rover/range-rover-sport/l320-2009-2013/remont/fuel-system/#fuel-system-general-information) .
  3. Disconnect the battery ground cable. Refer to «Specifications»(/land-rover/range-rover-sport/l320-2009-2013/remont/charging-system/#battery-charging-system-general-information) .
  4. Refer to «FUEL INJECTION COMPONENT CLEANING»(/land-rover/range-rover-sport/l320-2009-2013/remont/fuel-system/#fuel-charging-and-controls-v8-sc-50l-petrol__fuel-injection-component-cleaning) .
  5. Refer to «Engine Cover - 5.0L»(/land-rover/range-rover-sport/l320-2009-2013/remont/exteriorinterior-trim/#interior-trim-and-ornamentation) .
  6. Torque: 32
  1. To install, reverse the removal procedure.

HEATED OXYGEN SENSOR (HO2S) LH

SPECIAL TOOL(S) 310-121 Wrench, H02S

Scheme 16

Scheme 16: HEATED OXYGEN SENSOR (HO2S) LH

Note. Removal steps in this procedure may contain installation details.

Scheme 17

Scheme 17: REMOVAL

Scheme 18

Scheme 18
  1. Raise and support the vehicle.
  2. Refer to «Exhaust System»(/land-rover/range-rover-sport/l320-2009-2013/remont/exhaust/#exhaust-system) .
  3. Torque: 11 Nm
  4. Special Tool(s): 310-121 Torque: 48 Nm
  1. To install, reverse the removal procedure.
  2. Using the approved diagnostic equipment, clear the powertrain control module (PCM) adaptions.

HEATED OXYGEN SENSOR (HO2S) RH

SPECIAL TOOL(S) 310-121 Wrench, H02S

Note. Removal steps in this procedure may contain installation details.

Scheme 19

Scheme 19: REMOVAL

Scheme 20

Scheme 20

Scheme 21

Scheme 21
  1. Raise and support the vehicle.
  2. Refer to «Exhaust System»(/land-rover/range-rover-sport/l320-2009-2013/remont/exhaust/#exhaust-system) .
  3. Torque: 9 Nm
  4. Special Tool(s): 310-121 Torque: 48 Nm
  1. To install, reverse the removal procedure.

Note. Removal steps in this procedure may contain installation details.

Scheme 22

Scheme 22: REMOVAL

Scheme 23

Scheme 23

Scheme 24

Scheme 24

Scheme 25

Scheme 25
  1. Raise and support the vehicle.
  2. Refer to «COOLING SYSTEM DRAINING, FILLING AND BLEEDING (V8 S/C 5.0L PETROL)»(/land-rover/range-rover-sport/l320-2009-2013/remont/cooling-fan/#engine-cooling) .
  3. Torque: 10 Nm
  4. Torque: 10 Nm
  5. Torque: 5 Nm
  1. To install, reverse the removal procedure.

Note. Removal steps in this procedure may contain installation details.

Scheme 26

Scheme 26: REMOVAL
  1. Torque: 1.2 Nm
  1. To install reverse the removal procedure.
  2. Using the approved diagnostic equipment, clear the powertrain control module (PCM) adaptions.

Note. Removal steps in this procedure may contain installation details.

Scheme 27

Scheme 27: REMOVAL
  1. Raise and support the vehicle.
  2. Refer to «Supercharger»(/land-rover/range-rover-sport/l320-2009-2013/remont/mechanical/#intake-air-distribution-and-filtering-v8-sc-50l-petrol) .
  3. Torque: 20 Nm
  1. To install, reverse the removal procedure.

Note. Removal steps in this procedure may contain installation details.

Scheme 28

Scheme 28: REMOVAL
  1. Raise and support the vehicle.
  2. Refer to «Supercharger»(/land-rover/range-rover-sport/l320-2009-2013/remont/mechanical/#intake-air-distribution-and-filtering-v8-sc-50l-petrol) .
  3. Torque: 20 Nm
  1. To install, reverse the removal procedure.

Note. Removal steps in this procedure may contain installation details.

Scheme 29

Scheme 29: REMOVAL

Scheme 30

Scheme 30
  1. Disconnect the battery ground cable. Refer to «Specifications»(/land-rover/range-rover-sport/l320-2009-2013/remont/charging-system/#battery-charging-system-general-information) .
  2. Raise and support the vehicle.
  3. Refer to «Thermostat Housing - Vehicles With: Supercharger»(/land-rover/range-rover-sport/l320-2009-2013/remont/cooling-fan/#engine-cooling) .
  4. Torque: 10 Nm
  1. To install, reverse the removal procedure.

Note. Removal steps in this procedure may contain installation details.

Scheme 31

Scheme 31: REMOVAL

Scheme 32

Scheme 32

Scheme 33

Scheme 33
  1. Disconnect the battery ground cable. Refer to «Specifications»(/land-rover/range-rover-sport/l320-2009-2013/remont/charging-system/#battery-charging-system-general-information) .
  2. Raise and support the vehicle.
  3. Refer to «Thermostat Housing - Vehicles With: Supercharger»(/land-rover/range-rover-sport/l320-2009-2013/remont/cooling-fan/#engine-cooling) .
  4. Torque: 10 Nm
  1. To install, reverse the removal procedure.