Detroit Diesel SPN 639 FMI 2: Meaning, Causes & Fix
Aftertreatment 1 Outlet NOx Sensor β data erratic, intermittent, or incorrect, NOx sensor signal unstable on Detroit Diesel DD15
Reviewed by ASE Certified Mechanics Β· Last updated July 15, 2026
Quick Answer
SPN 639 FMI 2 = Outlet NOx Sensor Signal Erratic
Severity: π‘ CHECK AT NEXT STOP Β· System: Outlet NOx Sensor / Wiring Harness / Aftertreatment Control Module Β· β οΈ Drive to next stop
Diagnostic Reference
| Field | Details |
|---|---|
| Code | SPN 639 FMI 2 |
| Protocol | J1939 SPN: 639 FMI: 2 |
| Component | Outlet NOx Sensor / Wiring Harness / Aftertreatment Control Module |
| Manufacturer | Detroit Diesel |
| Engine Series | DD15 |
| Severity | |
| SAE Reference | SAE J1939-73 Digital Annex β SPN 639, FMI 2 |
Possible Causes
- Outlet NOx sensor connector pin corrosion or loose fit causing intermittent signal
- NOx sensor heater circuit fault β sensor cannot reach operating temperature causing erratic readings
- Wiring harness intermittent open or short between NOx sensor and aftertreatment controller
- Outlet NOx sensor internal failure β degraded sensing element producing unstable readings
- Aftertreatment control module software version outdated β known NOx sensor communication bugs
Top Causes Ranked by Frequency
- Corroded or loose sensor connector pins (35% of sensor/electrical faults)
- Wiring harness chafing causing intermittent open or short circuits (25%)
- Failed sensor providing out-of-range signal to ECM (20%)
- ECM 5V reference circuit overload from multiple sensor failures (10%)
- CAN bus communication fault from terminating resistor or module failure (10%)
In-Depth Diagnostic Procedure
Follow these diagnostic steps to identify the root cause of SPN 639 FMI 2 on your Detroit Diesel DD15. A J1939-compatible diagnostic scan tool is recommended.
- Connect scan tool and retrieve all active and inactive fault codes, noting which modules are reporting communication errors
- Check battery voltage and ground connections β low system voltage (below 11V) or poor grounds cause erratic sensor readings and communication faults
- Backprobe the suspect sensor connector and measure reference voltage (typically 5V), signal voltage, and ground with a digital multimeter β compare readings to OEM specifications
- Inspect wiring harness for chafing, especially at common failure points: engine pass-through connectors, valve cover gasket connectors, and frame rail routing near sharp edges
- Perform wiggle test on the harness while monitoring live data β intermittent connections will cause sensor readings to spike or drop when the harness is moved
- If CAN bus faults are present, check terminating resistors (should measure 60 ohms across CAN high and CAN low with the key off and batteries disconnected)
Repair & Cost Estimate
| Item | Cost Range |
|---|---|
| Parts | $150 β $1,200 |
| Labor | 2β6 hours @ ~$150/hr = $300 β $900 |
| Estimated Total | $450 β $2,100 |
Sensor replacement or harness repair. Prices vary by location and dealer.
Frequently Asked Questions β Outlet NOx Sensor / Wiring Harness / Aftertreatment Control Module
How do I know if a sensor is bad or if the wiring is the problem?
Backprobe the sensor connector and measure reference voltage, signal, and ground. If the 5V reference is present and ground is good, but the signal is out of range, the sensor is likely bad. If reference voltage is missing or unstable, the problem is in the wiring or ECM. A wiggle test on the harness while monitoring live data will reveal intermittent connections.
Can I drive with a faulty sensor?
It depends on the sensor. Non-critical sensors (barometric pressure, fuel temperature) typically trigger CHECK SOON codes and the engine runs on a default value. Critical sensors (accelerator pedal, crankshaft position) can cause stalling or no-start conditions. If the engine runs normally despite the code, you can usually drive to a repair facility, but do not ignore the code indefinitely.
What causes CAN bus communication faults?
CAN bus faults are caused by wiring damage (chafed or cut wires), corroded connectors, failed terminating resistors, or a faulty module that corrupts bus communication. Heavy-duty trucks use J1939 CAN which requires 120-ohm terminating resistors at each end of the bus. Measuring 60 ohms across CAN high and CAN low (with power off) confirms the bus is intact.
How much does an ECM replacement cost?
A new ECM for a heavy-duty diesel engine costs $1,500β$4,000 for the part alone, plus 3β6 hours of labor for installation, programming, and parameter setup. Remanufactured ECMs are available for $800β$2,000. Always verify the ECM is truly faulty before replacing β many ECM codes are caused by wiring or sensor issues, not the ECM itself.
Why do sensor faults seem to happen more in wet weather?
Moisture ingress into sensor connectors causes corrosion and intermittent electrical contact. This is especially common at the engine harness pass-through connector (where wires enter the valve cover) and at under-hood sensor connectors that are not properly sealed. Dielectric grease on connector pins and OEM-rated weatherpack connectors help prevent moisture-related faults.
Diagnostic & Repair Procedure
- Step 1: Inspect outlet NOx sensor connector for corrosion, bent pins, or moisture intrusion
- Step 2: Verify NOx sensor heater circuit resistance β should be 5-20 ohms; open circuit indicates heater failure
- Step 3: Monitor outlet NOx sensor readings with Detroit DiagnosticLink at idle β stable readings should be 0-50 ppm
- Step 4: Check for TSB software updates for the aftertreatment control module β some versions cause false SPN 639 FMI 2
- Step 5: Replace outlet NOx sensor if signal remains erratic after connector and harness inspection
Frequently Asked Questions
How far can I drive with this code?
This CHECK AT NEXT STOP code allows continued operation to a safe service location, typically within 50β100 miles. Reduce engine load (avoid steep grades, reduce cruising speed) and monitor related gauges closely. If secondary symptoms develop β smoke, unusual noise, temperature spike β pull over immediately.
Will this cause permanent engine damage if I keep driving?
If addressed promptly at the next stop, permanent damage is unlikely. However, prolonged operation (200+ miles) with this fault active can escalate the issue. For example, DEF system faults will eventually trigger a full derate and speed limitation to 5 mph. Some CHECK NEXT STOP conditions degrade into STOP ENGINE faults if the root cause worsens β do not postpone service indefinitely.
Can I diagnose this myself or do I need a mechanic?
You can attempt the diagnostic steps listed above. Many CHECK NEXT STOP codes have straightforward causes β low fluid levels, clogged filters, or loose connectors β that an owner-operator can address. However, if the code returns after clearing, the underlying fault requires professional diagnosis with a scan tool capable of viewing live data and freeze-frame information.
Estimated Repair Cost
Typical repair: $200β1,500 (Parts: $150β1,000 + Labor: 1β4 hours) Β· Costs vary by make/model and location
Related Fault Codes β DD15
SPN 625 FMI 9
π΄ STOP ENGINE
SPN 100 FMI 1
π΄ STOP ENGINE
SPN 110 FMI 15
π΄ STOP ENGINE
SPN 164 FMI 18
π΄ STOP ENGINE
SPN 1761 FMI 18
SPN 520605 FMI 7
Associated Symptoms
References & Further Reading
- SAE J1939-73: Application Layer β Diagnostics. SAE International. Defines SPN 639 / FMI 2 fault code semantics for heavy-duty CAN networks. SAE J1939 Standard
- Detroit Diesel DD15 Service Manual: OEM diagnostic procedures for Outlet NOx Sensor / Wiring Harness / Aftertreatment Control Module faults. Consult the official Detroit Diesel service documentation for your specific engine serial number.
- TMC RP 1210: Recommended Practice for Windows-Based Vehicle Diagnostic Interface. Technology & Maintenance Council (TMC) of American Trucking Associations.