The manifold absolute pressure (MAP) sensor measures the pressure inside the intake manifold. Pressure in the intake manifold is affected by turbocharger output, engine speed, accelerator pedal input, air temperature, and barometric pressure (BARO). A diaphragm within the MAP sensor is displaced by the pressure changes that occur from the varying load and operating conditions of the engine. The engine control module (ECM) supplies a regulated 5 volts to the sensor on the 5-volt reference circuit. The ECM supplies a ground on the low reference circuit. The MAP sensor provides a signal voltage to the ECM, relative to the pressure changes, on the MAP sensor signal circuit. The ECM converts the signal voltage input to a pressure value. Under normal operation, the lowest pressure that can exist in the intake manifold is equal to the BARO. This occurs when the vehicle is operating at idle or when the ignition is ON, while the engine is OFF. The ECM uses the MAP sensor to aid in diagnosis of the turbocharger performance. The highest manifold pressures occur when the turbocharger output is high. Manifold pressure can range from 58 kPa (8 psi) when pressure are low, to more than 240 kPa (34 psi) when pressures are high, depending on the BARO. The MAP sensor has a range of 43-253 kPa (6-36 psi).

The ECM detects that the BARO and MAP sensors disagree by more than 14 kPa with the ignition ON, for more than 10 seconds.

DTC P0106 is a Type A DTC.

Schematic Reference

Engine Controls Schematics

Connector End View Reference

Electrical Information Reference

DTC Type Reference

Powertrain Diagnostic Trouble Code (DTC) Type Definitions

Scan Tool Reference

Special Tools

1. Verify that DTCs P0698 or P0699 are not set .

⇒	If any of the DTCs are set, refer to DTC P0698 or P0699 .

2. Ignition ON, observe the scan tool Manifold Absolute Pressure (MAP) Sensor parameters. The reading should be BARO. Refer to Altitude Versus Barometric Pressure .
3. Verify that the engine is in good mechanical condition. Refer to Symptoms - Engine Mechanical .
4. Engine running, observe the scan tool MAP Sensor parameter. Slowly increase the engine speed to 2,000 RPM, then allow the engine speed to return to a stable idle. The MAP Sensor parameter should increment to a higher value at 2,000 RPM and return to near BARO at idle speed.
5. Ignition ON, observe the scan tool MAP and BARO parameters. Verify the MAP and BARO sensor parameters are within 5 kPa of each other.
6. Engine running, observe the DTC information with a scan tool. DTC P0106 should not set.
7. Operate the vehicle within the Conditions for Running the DTC. You may also operate the vehicle within the conditions that you observed from the Freeze Frame/Failure Records data.

Important: Perform the Circuit/System Verification before proceeding with the Circuit/System Testing.

1. Verify the integrity of the entire air induction system by inspecting for the following conditions:

•	Any damaged components

•	Loose or improper installation

•	An air flow restriction or leak

•	Verify that restrictions do not exist in MAP sensor port.

•	Any snow or ice build-up at the air cleaner, MAF, and MAP sensor

2. Determine the altitude for your area.
3. Ignition ON, engine OFF, observe the scan tool BARO parameter. Compare the BARO parameter to the range specified in the Altitude Vs. Barometric Pressure table. Refer to Altitude Versus Barometric Pressure .

⇒	If the BARO parameter is outside the range specified, replace the ECM.

4. Ignition OFF, disconnect the harness connector at the MAP sensor.
5. Ignition OFF and scan tool disconnected for 90 seconds, test for less than 5 ohms between the low reference circuit terminal A and ground.

⇒	If greater than the specified range, test the low reference circuit for an open/high resistance. If the circuit tests normal, replace the ECM.

6. Ignition ON, test for 4.8-5.2 volts between the 5-volt reference circuit terminal C and ground.

⇒	If less than the specified range, test the 5-volt reference circuit for a short to ground, or an open/high resistance. If the circuit tests normal, replace the ECM.

⇒	If greater than the specified range, test the 5-volt reference circuit for a short to voltage.

7. Verify the scan tool MAP parameter is less than 45 kPa.

⇒	If greater than 45 kPa, test the signal circuit terminal B for a short to voltage. If the circuit tests normal, replace the ECM.

8. Install a 3A fused jumper wire between the signal circuit terminal B and the 5-volt reference circuit terminal C. Verify the scan tool MAP parameter is greater than 253 kPa.

⇒	If less than 253 kPa, test the signal circuit for a short to ground or an open/high resistance. If the circuit tests normal, replace the ECM.

9. If all circuits test normal, test or replace the MAP sensor.

Important: You must perform the Circuit/System Testing in order to verify the integrity of the MAP sensor circuits before proceeding with Component Testing.

1. Ignition OFF, remove the MAP sensor.
2. Install a 3A fused jumper wire between the 5-volt reference terminal C and the corresponding terminal of the MAP sensor.
3. Install a jumper wire between the low reference terminal A of the MAP sensor and ground.
4. Install a jumper wire at the signal terminal B of the MAP sensor.
5. Connect a DMM between the jumper wire from terminal B of the MAP sensor and ground.
6. Ignition ON, with the J 23738-A or J 35555 , slowly apply vacuum to the sensor while monitoring the voltage on the DMM. The voltage should vary between 0-5.2 volts, without any spikes or dropouts.

⇒	If the voltage is erratic, replace the MAP sensor.

1. Engine running, observe the scan tool MAP and BARO parameters. The MAP and BARO sensor parameters should be within 5 kPa of each other.
2. Engine running, observe the scan tool MAP Sensor parameter while commanding the turbocharger Vane Pos. Ctrl. Solenoid Valve ON with a scan tool. Slowly increase the engine speed from idle to 2,000 RPM and return the engine to idle speed. The MAP sensor parameter should increment to a higher value and return to the BARO value at idle.