P0118 on a 2017 Toyota Camry
Coolant Temp Sensor High Input
What does P0118 mean on a 2017 Toyota Camry?
P0118 is set when the engine control module reads the engine coolant temperature sensor signal voltage above the calibrated maximum — typically a reading that would represent an unrealistically cold coolant temperature (often −40 °F / −40 °C). This is the open-circuit fingerprint for the ECT sensor: a disconnected sensor, a broken signal wire, or a sensor failed open internally.
Symptoms on a 2017 Toyota Camry
- Check Engine Light is illuminated
- Temperature gauge reads zero or stays cold
- Difficult cold start with rich-running symptoms
- Cooling fans may run constantly (ECM thinks coolant is dangerously cold)
- Slightly reduced fuel economy
- Cold-running engine doesn't warm up properly per the gauge
- Possible hard start when the engine is hot (ECM commands cold-start enrichment)
Likely causes on a 2017 Toyota Camry
- Disconnected or unlatched ECT sensor connector Most commonEstimated repair: $0– $50
- Broken or chafed ECT signal wire (open circuit) CommonEstimated repair: $80– $350
- Internally failed ECT sensor (element opened) CommonEstimated repair: $30– $200
- Corroded sensor connector pins CommonEstimated repair: $30– $200
- Damaged sensor body from coolant leak or freeze OccasionalEstimated repair: $50– $250
- Failed PCM signal input (rare) RareEstimated repair: $400– $1,500
How to diagnose this on a 2017 Toyota Camry
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Read ECT temperature with a scan tool
A working ECT reads close to ambient air temperature when the engine has been off long enough to cool. A reading of "−40 °F" or "−40 °C" is the classic open-circuit fingerprint.
Tools: Scan tool with ECT PID
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Inspect the connector and visible wiring
Locate the ECT sensor (usually threaded into the intake manifold or thermostat housing). Unplug, inspect for corrosion, water, bent pins. Re-seat and clear the code — if it stays clear, the connector was the problem.
Tools: Electrical contact cleaner, Flashlight
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Bench-test the ECT sensor resistance
Remove the sensor (place a rag — coolant will drip). Measure resistance across its terminals at room temperature. Compare to the service manual — most NTC ECTs read 2.0–4.5 kΩ at 68 °F (20 °C). Infinite resistance means the sensor is open and needs replacement.
Tools: Multimeter, Service spec sheet, Coolant catch and replacement
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Verify signal-wire continuity to the PCM
With the ECT disconnected, check continuity from the sensor's signal wire to the corresponding PCM pin. Open circuit confirms a broken wire somewhere along the path. Visual inspection of the harness — particularly where it routes near hot exhaust or moving accessories — often reveals the chafe point.
Tools: Multimeter, Wiring diagram
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Jumper-test the signal wire
With the ECT disconnected, briefly jumper the signal wire to ground and observe the scan tool — the reading should swing from "very cold" to "very hot." No swing points at the wiring or PCM input rather than the sensor.
Tools: Jumper wire, Scan tool
Known Technical Service Bulletins for the 2015-2019 Toyota Camry
Manufacturers publish Technical Service Bulletins (TSBs) when a known issue affects a specific vehicle. These bulletins come from the NHTSA database for your Toyota Camry.
- ENGINE Feb 12, 2026
This bulletin includes basic procedures for performing a rescue charge on Ni-MH high voltage (HV) batteries. This bulletin should be used in conjunction with the applicable model and model year Repair Manual while performing a rescue charge. The GRX-5100 should be used wherever the Repair Manual references the Toyota Hybrid System (THS) charger.
NHTSA #11029893 - ENGINE Feb 12, 2026
OBSOLETE NOTICE February 13, 2026: This bulletin is now obsolete. Please see T-SB-0009-26.
NHTSA #11029892 - UNKNOWN OR OTHER Jan 6, 2026
Some 2005 – 2026 Toyota vehicles that have undergone water intrusion may exhibit a condition in which a musty odor is present. Follow the procedures in this bulletin to remediate the odor and address this condition. The purpose of this Service Bulletin is to provide general guidelines and procedures for odor remediation. This Service Bulletin provides a guide on how to prepare and treat the interior of the vehicle for odor remediation. Refer to the applicable model and model year Repair Manual and the EPA (Environmental Protection Agency) website for the most up-to-date safety and precautionary guidelines.
NHTSA #11028712 - ELECTRICAL SYSTEM Jun 12, 2025
The air conditioning dye injection tool kit has been developed to aid in identifying the location of air conditioning refrigerant leaks. The procedures outlined in this Service Bulletin aid in locating, inspecting, and repairing refrigerant leaks.
NHTSA #11020657 - STRUCTURE Dec 5, 2024
To prevent brake rotor rust from forming during transportation and storage, wheel film will be used instead of a cardboard type of anti-rust cover. The purpose of the wheel film is to shield the disc brake rotor from weather elements and initial rust before the vehicle is delivered to the customer. Consequently, the film should remain on the wheel for as long as possible.
NHTSA #11012743 - STRUCTURE Dec 5, 2024
The condition known as acid rain is caused by airborne chemicals or particles in the atmosphere, which mix with rainwater, nighttime dew, or high humidity to form acidic compounds. If these contaminants settle and remain on a painted vehicle surface, especially the horizonal areas of the hood, roof, and decklid, significant damage can occur. This damage is the result of actual etching of the paint and appears as pitting or water spots. As acid rain droplets on the vehicle surface evaporate, the concentration strength of the acid increases, causing deeper and more rapid damage. This evaporation and corrosive action also occur more rapidly on dark colored cars as direct sun heat increases. It is the dealer’s responsibility to protect and maintain the quality of the vehicle’s paint finish after receipt at the dealership prior to the first sale. In areas known for high frequency and/or concentration of acid rain, frequent vehicle washing during high heat or humidity periods will minimize the potential for paint damage caused by acid rain. It is further recommended that either reverse osmosis or deionized water be used to prevent water spotting.
NHTSA #11012744
+14 more TSBs available in MECH AI's TSB explorer for this vehicle.
Common fixes
- Reconnect the ECT sensor connector
- Replace the ECT sensor with an OEM part
- Repair the broken ECT signal wire
- Clean corroded connector pins
About the 2015-2019 Toyota Camry
The 2015-2019 Toyota Camry was commonly sold with the following powertrains: 2.5L I4, 3.5L V6, 2.5L Hybrid I4. Common trims include LE, SE, XLE, XSE.
P0118 vs P0117
These are the two ends of the same circuit:
- P0117 — ECT signal too low (sensor reads very high temperature like “300 °F”). Usually a shorted-to-ground wire or sensor failed closed.
- P0118 — ECT signal too high (sensor reads very low temperature like “−40 °F”). Usually an open circuit — disconnected, broken wire, or sensor open internally.
Why P0118 causes a hot engine to run rich
When the ECT signal goes missing or reads “very cold,” the ECM commands cold-start enrichment continuously — even on a hot engine. The result: fouled spark plugs, rich-running symptoms, possibly a hard start when the engine is actually warm because flooding occurs. This is why P0118 is worth fixing promptly even though it doesn’t look like a serious code.
Multi-sensor confusion: ECT vs IAT vs CHT
Modern engines may have multiple temperature sensors:
- ECT (Engine Coolant Temperature) — in coolant passage
- IAT (Intake Air Temperature) — in air intake tract
- CHT (Cylinder Head Temperature) — bolted to head, no coolant contact
- TFT (Transmission Fluid Temperature) — in transmission
Their codes are similar — P0118 (ECT high), P0113 (IAT high), P0119 (ECT erratic). Make sure the connector you are pulling is for the sensor referenced in the code.