The primary (left) fuel level sender and the secondary (right) fuel level sender change resistance in response to fuel level. The engine control module (ECM) monitors the signal circuit of the primary (left) fuel level sender and the signal circuit of the secondary (right) fuel level sender in order to determine the fuel level. When the fuel tanks are full, the resistances of both fuel level senders are high, and the ECM senses a high signal voltage on both the signal circuit of the primary (left) fuel level sender and the signal circuit of the secondary (right) fuel level sender. When the fuel tanks are empty, the resistances of the fuel level senders are low, and the ECM senses a low signal voltage. The ECM uses the signal circuits of the primary (left) fuel level sender and the secondary (right) fuel level sender in order to calculate the percentage of remaining fuel in the tanks. The ECM sends the fuel level percentage via the class 2 serial data circuit to the instrument cluster in order to control the fuel gage. The fuel level information is also used for misfire and evaporative emission (EVAP) diagnostics. This diagnostic tests for a higher than normal secondary (right) fuel level sender signal. Refer to Fuel Level Specifications in order to verify the correct fuel level sensor readings.
This diagnostic procedure supports the following DTC:
DTC P2068 Fuel Level Sensor 2 Circuit High Voltage
The ignition is ON, with the engine ON.
• | The secondary (right) fuel level signal is greater than 4.5 volts. |
• | The above condition is present for greater than 6 seconds. |
• | The fuel gage reads inaccurately. |
• | The driver information center (DIC) illuminates the FUEL LEVEL LOW message. |
• | The ECM records the operating conditions at the time that the diagnostic test fails. The ECM displays the failure information in the Failure Records on the scan tool. |
• | The DTC becomes history when the conditions for setting the DTC are no longer present. |
• | The history DTC clears after 40 malfunction-free warm-up cycles. |
• | The ECM receives the clear code command from the scan tool. |
Use the Freeze Frame/Failure Records data in order to locate an intermittent condition. If you cannot duplicate the DTC, the information included in the Freeze Frame/Failure Records data may help in determining the number of miles since the DTC set. The Fail Counter and Pass Counter can also help in determining the number of ignition cycles that the diagnostic test reported a pass and/or fail. Operate the vehicle within the same Freeze Frame conditions, including those for RPM, for engine load, for vehicle speed, for temperature, and for others. This will isolate at what point the DTC failed.
Refer to Testing for Intermittent Conditions and Poor Connections in Wiring Systems.
The number below refers to the step number on the diagnostic table.
Step | Action | Value(s) | Yes | No |
---|---|---|---|---|
Schematic Reference: Instrument Cluster Schematics Connector End View Reference: Engine Controls Connector End Views in Engine Controls - 6.0L or Inline Harness Connector End Views in Wiring Systems | ||||
1 | Did you perform the Diagnostic System Check - Vehicle? | -- | Go to Step 2 | Go to Diagnostic System Check - Vehicle in Vehicle DTC Information |
2 |
Does the scan tool indicate that the Fuel Level Sensor Right parameter is greater than the specified value? | 4.5 V | Go to Step 3 | Go to Diagnostic Aids |
Does the scan tool indicate that the Fuel Level Sensor Right parameter is less than the specified value? | 0.5 V | Go to Step 6 | Go to Step 4 | |
4 | Test the signal circuit of the secondary (right) fuel level sensor for an open, high resistance, or a short to voltage. Refer to Circuit Testing and Wiring Repairs in Wiring Systems. Did you find and correct the condition? | -- | Go to Step 12 | Go to Step 5 |
5 | Test the low reference circuit of the secondary (right) fuel level sensor for an open or high resistance. Refer to Circuit Testing and Wiring Repairs in Wiring Systems. Did you find and correct the condition? | -- | Go to Step 12 | Go to Step 9 |
6 | Test the signal circuit of the secondary (right) fuel level sensor for an open, high resistance, or a short to voltage between C420 and the secondary (right) fuel level sensor. Refer to Circuit Testing and Wiring Repairs in Wiring Systems. Did you find and correct the condition? | -- | Go to Step 12 | Go to Step 7 |
7 | Test the low reference circuit of the secondary fuel level sensor for an open or high resistance between C420 and the secondary fuel level sensor. Refer to Circuit Testing and Wiring Repairs in Wiring Systems. Did you find and correct the condition? | -- | Go to Step 12 | Go to Step 8 |
8 | Inspect for poor connections at the harness connector of the secondary (right) fuel level sensor. Refer to Testing for Intermittent Conditions and Poor Connections and Connector Repairs in Wiring Systems. Did you find and correct the condition? | -- | Go to Step 12 | Go to Step 10 |
9 | Inspect for poor connections at the harness connector of the ECM. Refer to Testing for Intermittent Conditions and Poor Connections and Connector Repairs in Wiring Systems. Did you find and correct the condition? | -- | Go to Step 12 | Go to Step 11 |
10 | Replace the secondary sender module. Refer to Fuel Tank Fuel Pump Module Replacement - Right Side in Engine Controls - 6.0L. Did you complete the replacement? | -- | Go to Step 12 | -- |
11 | Replace the ECM. Refer to Control Module References in Computer/Integrating Systems for replacement, setup, and programming. Did you complete the replacement? | -- | Go to Step 12 | -- |
12 |
Does the DTC reset? | -- | Go to Step 2 | System OK |