Contents Section: Testing & Diagnostics All sections

5.0l/5.7l Vins [f,8] Pfi Cec Tests W/codes Chevrolet Camaro III рестайлинг

Testing & Diagnostics 60 illustrations ~9367 words

MODEL IDENTIFICATION

Repair procedures in this article are sometimes identified by a specific body code. The following table lists GM division, model name, and body types that apply to the body codes.

Body Type & GM DivisionModel Name
"F" Body
ChevroletCamaro
PontiacFirebird
"Y" Body
ChevroletCorvette

MODEL IDENTIFICATION

DESCRIPTION

The computerized engine control system monitors as many as 19 engine/vehicle functions. (Scheme 158) This system controls engine operation and lowers exhaust emissions while maintaining fuel economy and driveability. The Electronic Control Module (ECM) is the "brain" of the CCC system.

The computerized engine control system is primarily an emission control system, designed to maintain a 14.7:1 air/fuel ratio under all operating conditions. When the ideal air/fuel ratio is maintained, the 3-way catalytic converter can control Oxides of Nitrogen (NOx), Hydrocarbon (HC) and Carbon Monoxide (CO) emissions.

ECM Conditions Sensed & Systems Controlled. Scheme 158

Scheme 158: ECM Conditions Sensed & Systems Controlled

OPERATION

The ECM of computerized engine control system is equipped with a self-diagnostic system which detects system failures or abnormalities. As a bulb and system check, "SERVICE ENGINE SOON" light will glow when ignition switch is turned to "ON" position and engine is not running. When engine is started, light should go out. If not, a malfunction has been detected in the computerized engine control system or "SERVICE ENGINE SOON" light circuit is faulty.

When a malfunction occurs, ECM will illuminate the "SERVICE ENGINE SOON" light located on instrument panel. When malfunction is detected and light is turned on, a corresponding trouble code will be stored in ECM memory. Malfunctions are recorded as "hard failures" or as "intermittent failures".

"Hard Failures"

Hard failures cause "SERVICE ENGINE SOON" light to glow and remain on until the malfunction is repaired. If light comes on and remains on during vehicle operation, cause of malfunction must be determined using diagnostic charts. If a sensor fails, ECM will use a substitute value in its calculations to continue engine operation. In this condition, vehicle is driveable, but loss of good driveability will most likely be encountered.

"Intermittent Failures"

Intermittent failures cause "SERVICE ENGINE SOON" light to flicker or illuminate and go out about 10 seconds after the intermittent fault goes away. The corresponding trouble code, however, will be retained in ECM memory. If related fault does not reoccur within 50 engine restarts, related trouble code will be erased from ECM memory. Intermittent failures may be caused by sensor, connector or wiring related problems. Refer to INTERMITTENT PROBLEMS in the article CEC TESTING W/O CODES (TROUBLE SHOOTING) in the ENGINE PERFORMANCE section.

Note. Trouble codes will be recorded at various operating times. Some codes require operation of that sensor or switch for 5 seconds. Others may require operation for 5 minutes or longer under engine load.

DIAGNOSTIC PROCEDURE

Note. Most computerized engine control problems are the result of mechanical breakdowns, poor electrical connections or damaged vacuum hoses. Before considering the computer system as a possible cause of problems, ignition high tension wires, fuel supply, electrical connections and vacuum hoses should be checked. Failure to do so may result in lost diagnostic time.

Diagnosis of the computerized engine control system should be performed in the following order

  1. Make sure that all engine systems not related to the computer system are operating properly. Do not proceed with testing unless all other problems have been repaired.
  2. Perform appropriate DIAGNOSTIC CIRCUIT CHECK for that system. If trouble codes were displayed (other than Code 12), decide whether codes are "hard" or "intermittent" trouble codes. "Hard" codes will cause the "SERVICE ENGINE SOON" light to illuminate continuously while engine is running. See «ECM TROUBLE CODE DEFINITIONS»(/chevrolet/camaro/iii-1985-1992/remont/testing-diagnostics/#50l57l-vins-f8-pfi-cec-tests-wcodes__ecm-trouble-code-definitions) table in this article.
  3. If no trouble codes were displayed, perform FIELD SERVICE MODE CHECK procedures.
  4. If no trouble is indicated by the FIELD SERVICE MODE check and/or a driveability problem exists, refer to «DIAGNOSIS & TESTING»(/chevrolet/camaro/iii-1985-1992/remont/testing-diagnostics/#50l57l-vins-f8-pfi-cec-tests-wcodes) and/or «SCAN TESTER USAGE»(/chevrolet/camaro/iii-1985-1992/remont/testing-diagnostics/#50l57l-vins-f8-pfi-cec-tests-wcodes__scan-tester-usage) in this article.
  5. After any repairs are made, clear any trouble codes and perform FIELD SERVICE MODE check again.

Scheme 159

Scheme 159: ENTERING OR EXITING DIAGNOSTIC MODE (NON-SCAN)
  1. Turn ignition on. Do not start engine. "SERVICE ENGINE SOON" light should glow. Locate Assembly Line Data Link (ALDL) connector attached to ECM wiring harness under instrument panel, left or right of steering column. Insert jumper wire across terminal "B", "DIAGNOSTIC TERMINAL" and terminal "A", "GROUND". (Scheme 159) CAUTION: Inserting spade lug (jumper lead) into terminals of ALDL connector grounds "DIAGNOSTIC TERMINAL". Do not ground ALDL connector until after ignition is on (engine not running). (Scheme 159): ALDL Connector Terminal Identification NOTE: In some of the diagnostic and trouble shooting charts the Assembly Line Data Link (ALDL) may also be referred to as the Assembly Line Communication Link (ALCL). These are referring to the same connector. It is also the test point for connection of aftermarket "Scan" testers.
  2. "SERVICE ENGINE SOON" light should flash Code "12". Code "12" consists of "FLASH", pause, "FLASH", "FLASH" followed by a longer pause. Trouble Code "12" will be repeated 2 more times. If any other trouble codes are stored in ECM memory, they will be displayed in the same manner.
  3. To exit diagnostic mode, turn ignition off and remove jumper wire from ALDL connector.

READING TROUBLE CODES

The ECM stores component failure information for the CCC system under a related trouble code which can be recalled for diagnosis and repair. Trouble codes may be read by counting flashes of the "SERVICE ENGINE SOON" light, or by reading the output of a diagnostic "Scan" tester connected to the ALDL connector. The tester is faster, more accurate, and capable of reading information which otherwise would necessitate testing individual ECM and sensor/solenoid connector terminals with a volt/ohmmeter. Refer to SCAN TESTER - TEST DATA PARAMETERS table and SCAN TESTER USAGE in this article.

If "Scan" tester is not available, it is possible to read flashes of the dashboard "SERVICE ENGINE SOON" light by grounding the diagnostic terminal of the ALDL with ignition on and engine off. For example, "FLASH", "FLASH", pause, "FLASH", longer pause, identifies "21". The first series of flashes are the first digit of trouble code; second series of flashes are the second digit of trouble code. Trouble codes are displayed starting with the lowest numbered code. Each code is displayed 3 times. Codes will continue to repeat as long as ALDL "DIAGNOSTIC TERMINAL" is grounded.

Note. Trouble codes will be recorded at various operating times. Some codes require operation of that sensor or switch for 5 seconds; others may require operation for 5 minutes or longer at normal operating temperature, road speed and load. Therefore, some codes may not set in a service bay operational mode.

ECM TROUBLE CODE DEFINITIONS

Code No.Circuit Affected
12 (1)No RPM reference pulse
13Open oxygen sensor circuit
14Coolant sensor circuit shorted
15Coolant sensor circuit open
21TPS signal voltage high
22TPS signal voltage low
23MAT voltage high
24VSS circuit
25MAT sensor signal voltage low
32EGR vacuum control signal
33MAP sensor voltage high
34MAP sensor voltage low
36Mass Airflow (MAF) Sensor Burn-Off Failure
41No distributor reference (HEI)
41C(3)I ignition - cam sensor loss
41Cylinder select error (MEM-CAL)
42EST circuit open or grounded
43ESC retard signal too low
44Lean oxygen sensor value
45Rich oxygen sensor value
46Vehicle Anti-Theft System (VATS)
53Faulty alternator, voltage high
54Fuel pump voltage low
(1) Code "12" should be displayed only when no reference pulses are received by ECM (engine not running).
(1)Code "12" should be displayed only when no reference pulses are received by ECM (engine not running).

ECM TROUBLE CODE DEFINITIONS

Note. Trouble code charts should only be used if "SERVICE ENGINE SOON" light is illuminated (indicating a current problem exists). Exceptions are Code 13, 15, 24, 44 and 45 charts, which may be used to help diagnose intermittent codes.

Note. Any time Codes 51, 52, 54 or 55 are displayed with another code, start with "50-series" code first, then proceed to low profile numbered code.

TROUBLE CODE DETERMINATION (HARD OR INTERMITTENT)

During any diagnostic procedure, you must decide between "hard" failure codes and "intermittent" failure codes. Diagnostic charts will not usually help analyze "intermittent" codes. To determine "hard" codes and "intermittent" codes, proceed as follows

  1. Manually enter diagnostic mode. Read and record all stored trouble codes. Exit diagnostic mode and clear trouble codes.
  2. Apply parking brake and place transmission in Neutral (man. trans.) or "P" (auto. trans.). Block drive wheels. Start engine. "SERVICE ENGINE SOON" light should go out. Run warm engine at specified curb idle for 2 minutes. Note "SERVICE ENGINE SOON" light.
  3. If "SERVICE ENGINE SOON" light comes on, enter diagnostic mode. Read and record trouble codes. This will reveal "hard failure" codes. Codes 13, 15, 24, 44, 45 and 55 may require a road test to reset "hard failure" after trouble codes were cleared.
  4. If "SERVICE ENGINE SOON" light does not come on, all stored trouble codes were "intermittent failures". Exceptions are noted under DIAGNOSTIC PROCEDURE.

CLEARING TROUBLE CODES

Turn ignition switch to "ON" position and ground "DIAGNOSTIC TERMINAL" lead at ALDL connector. Turn ignition switch to "OFF" position and remove ECM fuse from fuse block for 10 seconds. Replace fuse. Remove "DIAGNOSTIC TERMINAL" ground lead.

DIAGNOSTIC MATERIALS

Note. The charts described in the following paragraphs are arranged later in this article, by engine size and fuel system type.

Diagnostic Charts

The diagnostic charts are used to find and repair problems which the on-car diagnostics have found. These charts include

  1. Charts which test the reliability of the self-diagnostic system.
  2. Charts which help fix problems which are "SERVICE ENGINE SOON" light related.
  3. Charts which test the computerized fuel control system performance.
  4. Charts which help fix a problem when the on-car diagnostics don't work.
  5. ENGINE CRANKS BUT WON'T RUN charts. Refer to the appropriate SYMPTOM FLOW CHARTS ("A" CHARTS) in one of the following articles: «5.0L/5.7L VINS [F,8] PFI "A" CHARTS - CAMARO/FIREBIRD»(/chevrolet/camaro/iii-1985-1992/remont/testing-diagnostics/#50l57l-vins-f8-pfi-a-charts) «5.7L VIN [8] PFI "A" CHARTS - CORVETTE»(ref-130706)
  6. Charts where a stored trouble code leads you to a particular problem. See «ECM TROUBLE CODE DEFINITIONS»(/chevrolet/camaro/iii-1985-1992/remont/testing-diagnostics/#50l57l-vins-f8-pfi-cec-tests-wcodes__ecm-trouble-code-definitions) and DIAGNOSTIC AIDS in this section. Charts which are used because the FIELD SERVICE MODE CHECK found a problem.

Note. Although there are many charts connected with computer diagnosis, only 2 charts are needed to prove system is operating properly. Normally, only 3 charts are necessary to find a problem, if one exists.

Diagnostic Aids

Diagnostic aids (located in each "trouble code" chart box for each system) are additional tips used to help diagnose trouble codes when inspected circuit checks out okay. Diagnostic aids may help lead to a definitive solution to that trouble code problem.

Field Service Mode Check (Fuel Injected Models)

On fuel injected models, "SERVICE ENGINE SOON" light will indicate operational mode of engine if ALDL is grounded while engine is running. In closed loop mode, "SERVICE ENGINE SOON" light will flash at a rate of one flash per second. In open loop, light will flash at a rate of 2.5 flashes per second. If light is off all or most of the time, a lean exhaust is indicated. If light is on all or most of the time, a rich exhaust is indicated.

This test confirms proper operation of fuel system and verifies closed loop operation. Clear codes and perform this test after any repair is completed. When performing this check, always engage parking brake and block DRIVE wheels. Parking brake on front-wheel drive models does NOT hold drive wheels.

Note. On some engines, oxygen sensor will cool off after only a short period of time while engine is idling. This will cause engine to go into open loop. To restore closed loop mode, run engine at part throttle several minutes and accelerate from idle to part throttle several times.

SPECIAL DIAGNOSTIC TOOLS

Note. Special "Scan" testers plugged into the ALDL may be used to read trouble codes and check voltages in the system on the serial data line (terminal "E" on EFI and terminal "M" on EFI with P-4 systems). These testers can save a great deal of time. For additional information see SCAN TESTER USAGE and SCAN TESTER - TEST DATA PARAMETERS table in this article.

The computerized engine control system is most easily diagnosed using a "Scan" tester, however, other tools may aid in diagnosing problems if a "Scan" tester is unavailable. These tools are: a tachometer, a dwell meter, test light, ohmmeter, digital voltmeter with 10-megohm impedance (minimum), vacuum pump, vacuum gauge, fuel injector test lights (TBI and PFI) and 6 jumper wires 6" long (one wire with female connectors at both ends, one wire with male connector at both ends and 4 wires with male and female connectors at opposite ends). A test light, rather than a voltmeter, must be used when indicated by a diagnostic chart.

Note. If engine operation seems to change when dwell meter is connected to Green wire, remove dwell meter and use another type. A few brands are not compatible with computerized engine control system.

When engine is at operating temperature and idling, dwell meter needle should vary between 10-50 degrees. This indicates closed loop operation. Before engine reaches operating temperature, dwell should be fixed between 10-50 degrees, indicating open loop operation. If after reaching normal operating temperature dwell is fixed between 10-50 degrees, less than 10 degrees or more than 50 degrees, refer to appropriate CHART A - DWELL FIXED diagnostic chart for that system.

SCAN TESTER USAGE

Note. Prior to connection of scan tester to vehicle, diagnostic system should be checked to determine if system is operating properly and if information received by scan tester will be accurate. This is done by performing appropriate DIAGNOSTIC CIRCUIT CHECK for that system. If vehicle does not pass diagnostic circuit check, information received by scan tester may be invalid. CCC Scan tester is a specialized tester which, when plugged into ALDL, can be used to diagnose on- board computer control stems by providing instant access to circuit voltage information without need to crawl under dash or hood to back-probe sensors and connectors.

Scan testers cut down diagnostic time dramatically by furnishing input data (voltage signals) which can be compared to specification parameters. See SCAN TESTER - TEST DATA PARAMETERS table. They also furnish information on output device (solenoids and motors) status. Status parameters, however, are only an indication that output signals have been sent to devices by the ECM. It does not indicate if devices have responded properly to that signal. This will need to be verified at output device using a voltmeter or test light.

Note. Code 12 should always exist when ALDL is grounded with key on and engine not running but may not be indicated by all makes of scan tester.

If trouble codes are not present, this is not an indication that there is not a problem. CCC related problems are about 20 percent codes and 80 percent driveability. Sensors that are out of specification WILL NOT set a trouble code but WILL cause driveability problems. Use of a scan tester is easiest method of checking sensor specifications and other data parameters. Tester is also useful in finding intermittent wiring problems by wiggling wiring harnesses and connections (key on, engine off) while observing data parameters. See the SCAN TESTER - TEST DATA PARAMETERS table below.

Note. Information obtained by scan tester is only as accurate as the tester itself. If erroneous voltage signals are suspected, it will be necessary to verify tester information using a digital voltmeter and wiring schematic. If non- existent codes are in evidence, turn ignition off, remove tester, turn ignition on and ground ALDL "DIAGNOSTIC TERMINAL". If same codes are not flashed by "SERVICE ENGINE SOON" light that were indicated by scan tester, tester cannot be used on vehicle and information obtained by it will not be guaranteed accurate.

SCAN DATA

Note. Information in the following table is typical readings taken on vehicle with engine idling, upper radiator hose hot, closed throttle, transmission in Park or Neutral, "closed loop" status achieved and all accessories off (except as noted in tables). Data parameters are updated every 1 1/4 seconds. On systems using P-4 computers, parameter updates are virtually instantaneous. Not all devices & systems are used on all models.

Tester PositionUnits MeasuredNominal Data Value
A/C ClutchOn/OffOff (On with A/C)
A/C RequestYes/NoNo/Yes (with request)
AIR Divert SolenoidOn/OffOn (air to switching sol.)
AIR Divert SolenoidOn/OffOff (air to atmosphere)
AIR Switching SolenoidOn/OffOn (to exhaust manifold)
AIR Switching SolenoidOn/OffOff (to catalytic converter)
BAROVolts3-4.5
Battery VoltageVolts13.5-14.5
Block LearnCounts118-138 (128 normal)
Brake SwitchOn/OffOn when engaged
Canister Purge Sol.On/OffOn/engine cold (idle some)
Clear FloodOn/Off***See tester manual ***
Coolant FanOn/OffOff below 216°F (102° C)
Coolant Temp.°C85-105° (norm.temperature)
Crank RPMRPM100-900
Cross CountsCounts0-255
Cruise Control SwitchOn/OffWhen engaged
EGR SolenoidOn/OffOn when energized
EGR Duty Cycle0-100%0/closed-100/fully open
Fan RelayOn/OffOn when energized
Fan RequestOn/OffOn with request
Fuel BackupYes/NoYes when engaged
IACCounts0-50
Ignition/CrankOn/OffOn with ignition/crank
Injector Pulse WidthMil./Sec.8-3.0
INT (Integrator)Counts110-145 (128 normal)
Knock Retard (ESC)Counts0-255
Knock SignalYes/NoYes when knock exists
MAT Temperature°C10-90°
MAPVolts1 (idle)to 4.5(WOT)
Open/Closed Loop StatusOl/ClClosed/Open during extended idle
O2 SensorMillivolts100 (lean) to 999 (rich)
P/N SwitchP/N/RDLPark/Neutral
P/S SwitchNorm/HiNormal
PROM I.D.PROM #Original factory number
RPMRPMSpec. +/- 25 RPM Drive (Auto.)
RPMRPMSpec. +/- 50 RPM Neut. (man.)
Spark Advance# of Deg.Varies
TCCOn/OffOff (On with command)
TPSVolts1.25 (idle) to 5.0 (WOT)
Throttle Angle0-100%0 (idle) to 110 (WOT)
Trouble CodesCode #No Codes
Turbo BoostOn/OffOn when activated
Upshift Light (Man. Trans.)On/OffOff
VSSMPH0-actual
3rd Gear SwitchOn/OffOn/3rd & 4th gear
4th Gear SwitchOn/OffOn/4thgear

SCAN TESTER - TEST DATA PARAMETERS

Note. This ECM voltage chart can be used with a digital voltmeter to help save time in diagnosis. Voltages on the car being tested my vary slightly from these due to battery or alternator charging level.

SYMPTOM FLOW CHARTS ("A" CHARTS)

For "A" Charts see appropriate article

  1. «5.0L/5.7L VINS [F,8] PFI "A" CHARTS - Camaro/Firebird»(/chevrolet/camaro/iii-1985-1992/remont/testing-diagnostics/#50l57l-vins-f8-pfi-a-charts)
  2. «5.7L VIN [8] PFI "A" CHARTS - Corvette»(ref-130706)

CHART B1 - RESTRICTED EXHAUST SYSTEM CHECK

Before any components are replaced, exhaust system must be checked for restrictions. Check at AIR pipe or check at O2 sensor procedure may be used to diagnose condition, depending on engine or tool used.

Check At Air Pipe

Remove rubber hose at exhaust manifold AIR pipe check valve and remove check valve. Install fuel pump pressure gauge to hose and nipple via Propane Enrichment Device (J26911) as shown in Fig. (Scheme 160). Nipple should be inserted into exhaust manifold AIR pipe.

Restricted Exhaust System Check at Air Pipe. Scheme 160

Scheme 160: Restricted Exhaust System Check at Air Pipe

Check At O2 Sensor

Remove O2 sensor. Install back pressure tester in place of O2 sensor as shown in illustration. After test is completed, ensure that O2 sensor threads are coated with anti-seize compound before installation.

Restricted Exhaust System Check At O2 Sensor. Scheme 161

Scheme 161: Restricted Exhaust System Check At O2 Sensor

Diagnosis

  1. Start engine and bring to operating temperature. Allow engine to idle and observe exhaust system back pressure gauge. Reading should not exceed 1.25 psi (.09 kg/cm 2 ).
  2. Increase engine speed to 2000 RPM and note gauge. Reading should not exceed 3 psi (.21 kg/cm 2 ).
  3. If during steps 1) or 2), specification is exceeded, exhaust system restriction is indicated.
  4. Check complete exhaust system for collapsed pipe, heat distress and possible internal muffler failure.
  5. If none of the conditions in step 4) exist, check for restricted catalytic converter. Replace if necessary.

CODE 13 - OPEN OXYGEN SENSOR CIRCUIT

The ECM supplies a voltage of about .45 volt between circuits No. 412 and 413. If measured with a 10-megohm digital voltmeter, this may read as low as .32 volt. The oxygen sensor varies the voltage within a range of about one volt if the exhaust is rich, down to about .10 volt if exhaust is lean. The sensor is like an open circuit and produces no voltage when it is less than 600°F (316°C). An open sensor circuit or cold sensor causes "open loop" operation.

Note. Test numbers refer to test numbers on diagnostic chart.

  1. Code 13 will set when the following conditions occur: Engine at normal operating on temperature. At least 2 minutes elapsed since start-up. Oxygen signal voltage steady between .35 and .55 volt. Throttle angle greater than 5 percent (about .3 volt greater than closed throttle voltage). All conditions must be met for about 60 seconds. If conditions for a Code 13 exist, the system will not go "closed loop".
  2. This test will determine if the sensor, wiring or ECM is the cause of Code 13.
  3. When conducting this test, use only a high impedance (10-megohm) digital volt/ohmmeter. This test checks the continuity of circuits No. 412 and 413. If circuit No. 413 is open the ECM voltage on circuit No. 412 will be greater than .6 volt.

Normal "Scan" tester voltage varies between 100 and 999 mV while in "closed loop". Code 13 will set in one minute if voltage remains between .35-.55 volt, however, system will go "open loop" in about 15 seconds.

Code 13 Flow Chart - "F" & "Y" Bodies O2 Sensor Ckt. Scheme 162

Scheme 162: Code 13 Flow Chart - "F" & "Y" Bodies O2 Sensor Ckt

Code 13 Flow Chart - "F" & "Y" Bodies O2 Sensor Ckt. Scheme 163

Scheme 163: Code 13 Flow Chart - "F" & "Y" Bodies O2 Sensor Ckt

CODE 14 - COOLANT TEMPERATURE SENSOR (CTS) SIGNAL VOLTAGE LOW

The Coolant Temperature Sensor (CTS) uses a thermistor to control the signal voltage to the ECM. The ECM applies and monitors a voltage on circuit No. 410 to the sensor. When the engine is cold, the sensor resistance is high, therefore, the ECM will see high monitored voltage. As the engine warms, the sensor resistance becomes less and the monitored voltage drops. At normal operating temperature, the voltage will measure about 1.5-2.0 volts on circuit No. 410. Coolant temperature is one of the inputs used to control; fuel delivery, spark timing, idle speed, converter clutch, canister purge, air management (man. trans. only), EGR and cooling fan. Code 14 will set if monitored voltage indicates a coolant temperature greater than 266°F (130°C) on 5.0L and 5.7L engines for about 3 seconds.

Note. Test numbers refer to test numbers on diagnostic chart.

  1. Code 14 will set if signal voltage indicates high coolant temperature for 3 seconds.
  2. This test will determine if circuit No. 410 is shorted to ground which will cause the conditions for Code 14.

Check harness routing for a potential short to ground in circuit No. 410. The "Scan" tester displays engine temperature in degrees centigrade. After engine is started, the temperature should rise steadily to about 90°C, then stabilize when thermostat opens.

Code 14 Flow Chart - "F" Body CTS Voltage Low. Scheme 164

Scheme 164: Code 14 Flow Chart - "F" Body CTS Voltage Low

Code 14 Flow Chart - "F" Body CTS Voltage Low. Scheme 165

Scheme 165: Code 14 Flow Chart - "F" Body CTS Voltage Low

Code 14 Flow Chart - "Y" Body CTS Voltage Low. Scheme 166

Scheme 166: Code 14 Flow Chart - "Y" Body CTS Voltage Low

Code 14 Flow Chart - "Y" Body CTS Voltage Low. Scheme 167

Scheme 167: Code 14 Flow Chart - "Y" Body CTS Voltage Low

CODE 15 - COOLANT TEMP. SENSOR (CTS) SIGNAL VOLTAGE HIGH

The CTS uses a thermistor to control the signal voltage to the ECM. The ECM applies and monitors voltage on circuit No. 410 to the sensor. When the engine is cold, sensor resistance is high, therefore, the ECM will see a high monitored voltage. As the engine warms, the sensor resistance becomes less and the monitored voltage drops. At normal operating temperature, the voltage will measure about 1.5-2.0 volts on circuit No. 410. Coolant temperature is one of the inputs used to control: fuel delivery, spark timing, idle speed, converter clutch, canister purge, air management (manual transmission), EGR and cooling fan.

Note. Test numbers refer to test numbers on diagnostic chart.

  1. Code 15 will set if signal voltage indicates coolant temperature is less than -47°F (-44°C) for 3 seconds.
  2. This test simulates a Code 14. If the ECM recognizes the low signal voltage and the "Scan" tester reads 130°C or more, ECM and wiring are okay.
  3. This test will determine if circuit No. 410 is open. There should be 5 volts present at sensor connector if measured with a DVOM.

The "Scan" tester reads engine temperature in degrees centigrade. After engine is started, the temperature should rise steadily to about 90°C, then stabilize when thermostat opens.

A faulty connection, or an open in circuits No. 410 or 452 will result in a Code 15. If Code 22 or 23 is also set, check circuit No. 452 for faulty wiring or connections. Check terminals at sensor for a good contact.

Code 15 Flow Chart - "F" Body CTS Voltage High. Scheme 168

Scheme 168: Code 15 Flow Chart - "F" Body CTS Voltage High

Code 15 Flow Chart - "F" Body CTS Voltage High. Scheme 169

Scheme 169: Code 15 Flow Chart - "F" Body CTS Voltage High

Code 15 Flow Chart - "Y" Body CTS Voltage High. Scheme 170

Scheme 170: Code 15 Flow Chart - "Y" Body CTS Voltage High

Code 15 Flow Chart - "Y" Body CTS Voltage High. Scheme 171

Scheme 171: Code 15 Flow Chart - "Y" Body CTS Voltage High

CODE 21 - THROTTLE POSITION SENSOR SIGNAL VOLTAGE HIGH

The Throttle Position Sensor (TPS) provides a voltage signal that changes relative to throttle angle. Signal voltage will vary from about .5 volt at idle to about 4.5 volts at wide open throttle. Code 21 will set if the following conditions occur

  1. TPS voltage is greater than 2.5 volts for at least 2-5 seconds.
  2. Airflow less than 12 gm/sec.
  3. Engine speed less than 1200 RPM

Note. Test numbers refer to test numbers on diagnostic chart.

  1. Confirms Code 21 and that fault is present.
  2. With TPS sensor disconnected, the TPS voltage should go low if the ECM and wiring are okay.
  3. Probing circuit No. 452 with a test light checks the 5-volt return circuit. A faulty 5-volt return will cause a Code 21.

The "Scan" tester reads throttle position in volts. Reading should be less than .7 volt with throttle closed and ignition on or at idle. Voltage should increase at a steady rate as throttle is moved toward WOT. An open in circuit No. 452 will result in a Code 21. Some "Scan" testers measure throttle angle as a percent. A fully closed throttle should read zero percent and a wide open throttle should read 100 percent.

Code 21 Flow Chart - 5.0/5.7L "F/Y" Bodies TPS Voltage High. Scheme 172

Scheme 172: Code 21 Flow Chart - 5.0/5.7L "F/Y" Bodies TPS Voltage High

Code 21 Flow Chart - 5.0/5.7L "F/Y" Bodies TPS Voltage High. Scheme 173

Scheme 173: Code 21 Flow Chart - 5.0/5.7L "F/Y" Bodies TPS Voltage High

CODE 22 - THROTTLE POSITION SENSOR SIGNAL VOLTAGE LOW

The Throttle Position Sensor (TPS) provides a voltage signal that changes relative to throttle angle. Signal voltage will vary from about .5 volt at idle to 4.5 volts at wide open throttle. Code 22 will set if TPS signal voltage is less than about .2 volt for 3 seconds and the engine running.

Note. Test numbers refer to test numbers on diagnostic chart.

  1. Confirms Code 22 and that fault is present.
  2. Simulates Code 21. If the ECM recognizes the high signal voltage and sets Code 21, the ECM and wiring are okay.
  3. With throttle closed, the TPS voltage reading should be at idle specification. See DIAGNOSTIC AIDS below.
  4. This simulates a high signal voltage to check for an open in circuit No. 417.

Using a "Scan" tester, reading should be less than .7 volt with throttle closed and ignition on or at idle. Monitored voltage should increase at a steady rate as throttle is moved toward WOT. An open or short to ground in circuits No. 416 or 417 will result in a Code 22. Some "Scan" testers measure throttle angle as a percent. A fully closed throttle should read zero percent and a wide open throttle should read 100 percent.

Code 22 Flow Chart - 5.0/5.7L "F/Y" Bodies TPS Voltage Low. Scheme 174

Scheme 174: Code 22 Flow Chart - 5.0/5.7L "F/Y" Bodies TPS Voltage Low

Code 22 Flow Chart - 5.0/5.7L "F/Y" Bodies TPS Voltage Low. Scheme 175

Scheme 175: Code 22 Flow Chart - 5.0/5.7L "F/Y" Bodies TPS Voltage Low

CODE 23 - MANIFOLD AIR TEMPERATURE SENSOR SIGNAL VOLTAGE HIGH

The Manifold Air Temperature (MAT) sensor uses a thermistor to control the signal voltage to the ECM. The ECM applies and monitors voltage on circuit No. 472 to the sensor. When the air is cold, sensor resistance is high and the ECM will see a high monitored voltage. If the air is warm, the sensor resistance is low and ECM will see a low monitored voltage.

Note. Test numbers refer to test numbers on diagnostic chart.

  1. Code 23 will set if signal voltage indicates manifold air temperature is low, time since engine start is more than 8 minutes on "F" Body and 4 minutes on "Y" Body and no vehicle speed signal is present (vehicle not moving). Due to the conditions necessary to set a Code 23, the "SERVICE ENGINE SOON" light will only stay on when all 3 conditions are met.
  2. A Code 23 will set due to an open sensor, wire or connection. This test will determine if the wiring and ECM are okay. The MAT sensor is difficult to reach on some models so this test can be performed at the MAT sensor harness connector.
  3. This will determine if an open is present in the monitored signal circuit No. 472 or the 5-volt return circuit No. 452.

The "Scan" tester reads temperature of the air entering the engine (should read close to ambient air temperature when engine is cold) and rises as underhood temperature increases. Carefully check harness and connections for possible open in sensor circuits. Use the TEMPERATURE-TO-RESISTANCE VALUES table to help determine if sensor calibration has shifted.

Code 23 Flow Chart - 5.0/5.7L "F"/"Y" Bodies MAT Sensor Voltage High. Scheme 176

Scheme 176: Code 23 Flow Chart - 5.0/5.7L "F"/"Y" Bodies MAT Sensor Voltage High

Code 23 Flow Chart - 5.0/5.7L "F"/"Y" Bodies MAT Sensor Voltage High. Scheme 177

Scheme 177: Code 23 Flow Chart - 5.0/5.7L "F"/"Y" Bodies MAT Sensor Voltage High

CODE 24 - VEHICLE SPEED SENSOR

The ECM applies and monitors 12 volts on circuit No. 437. Circuit No. 437 is connected to the vehicle speed sensor buffer in the instrument cluster. The speed sensor buffer alternately grounds circuit No. 437 when drive wheels are turning. This pulsing action takes place about 2000 times per mile and the ECM will calculate vehicle speed based on the time between pulses. "F" Bodies use a Permanent Magnet (PM) generator mounted in the transmission to send signals to the VSS buffer in the instrument panel. "Y" Bodies use a Hall Effect switch mounted in the speedometer head to signal the VSS buffer.

The "Scan" tester reading should closely match the speedometer reading with drive wheels turning.

Note. Test numbers refer to test numbers on diagnostic chart.

  1. To avoid possible damage to CV joints on FWD vehicles, always support control arms whenever drive wheels are turning off of ground. Code 24 will set if vehicle is stopped when the following conditions occur: Reference signal indicates engine speed is between 1400 and 4400 RPM. Throttle angle is less than 2 percent (closed throttle). Low load condition (low airflow or high vacuum). Transmission not in Park or Neutral. All conditions met for 4-5 seconds. These conditions are met during a road load deceleration. Disregard Code 24 that sets when drive wheels are not turning.
  2. A voltage of less than one volt at the IP connector indicates that circuit No. 437 is shorted to ground. If after disconnecting circuit No. 437 at the vehicle speed sensor, the voltage reads greater than 10 volts, the vehicle speed sensor is faulty. If voltage remains less than 10 volts, then it is possible that circuit No. 437 wire is grounded. If circuit No. 437 is not grounded, there is a faulty connection at the ECM, or a faulty ECM.

A "Scan" tester should indicate a vehicle speed whenever the drive wheels are turning greater than 3 MPH. A faulty or misadjusted Park/Neutral switch can result in a false Code 24. Use "Scan" tester and check for proper signal while wiggling shifter in Drive.

Code 24 Flow Chart - 5.0/5.7L "F" & "Y" Bodies VSS. Scheme 178

Scheme 178: Code 24 Flow Chart - 5.0/5.7L "F" & "Y" Bodies VSS

Code 24 Flow Chart - 5.0/5.7L "F" & "Y" Bodies VSS. Scheme 179

Scheme 179: Code 24 Flow Chart - 5.0/5.7L "F" & "Y" Bodies VSS

CODE 25 - MANIFOLD AIR TEMPERATURE SENSOR SIGNAL VOLTAGE LOW

The Manifold Air Temperature (MAT) sensor uses a thermistor to control the signal voltage to the ECM. The ECM applies and monitors voltage on circuit No. 472 to the sensor. When manifold air is cold, the sensor resistance is high and the ECM will see a high monitored voltage. As the air warms, the sensor resistance becomes less, and monitored voltage drops. Code 25 will set if monitored voltage indicates manifold air temperature greater than 275°F (134°C) for 3 seconds and time since engine start is 8 minutes or longer. Due to the conditions necessary to set a Code 25, the "SERVICE ENGINE SOON" light will remain on only while the signal is low and vehicle speed is present.

The "Scan" tester reads temperature of the air entering the engine. Parameter should read close to ambient air temperature when engine is cold, and rise as underhood temperature increases). A faulty connection, or an open in the MAT signal or ground circuit will result in a Code 23. Use the TEMPERATURE-TO-RESISTANCE VALUES table and the appropriate Flow Chart/Schematic to help determine if the sensor calibration has shifted.

Temperature °F (°C)Resistance
210 (100)185
160 (70)450
100 (38)1800
70 (20)3400
40 (4)7500
20 (-7)13,500
0 (-18)25,000
40 (-40)100,700

TEMPERATURE-TO-RESISTANCE

Code 25 Flow Chart - 5.0/5.7L "F/Y" Bodies MAT Sensor Voltage Low. Scheme 180

Scheme 180: Code 25 Flow Chart - 5.0/5.7L "F/Y" Bodies MAT Sensor Voltage Low

Code 25 Flow Chart - 5.0/5.7L "F/Y" Bodies MAT Sensor Voltage Low. Scheme 181

Scheme 181: Code 25 Flow Chart - 5.0/5.7L "F/Y" Bodies MAT Sensor Voltage Low

CODE 32 - EGR SYSTEM FAILURE

EGR vacuum is regulated by an ECM-controlled solenoid. The ECM turns the EGR on and off (duty cycle) by grounding and ungrounding circuit No. 435. The duty cycle is calculated by the ECM based on coolant temperature, airflow and engine RPM. There should be no EGR when vehicle is in Park or Neutral, TPS input is less than a specified value or TPS is indicating Wide Open Throttle (WOT). With the ignition on and engine stopped, the EGR solenoid is de-energized. By grounding the diagnostic "test" terminal, the solenoid should energize.

Code 32 means that the EGR solenoid switch was closed during start-up or that the switch was not detected closed under the following conditions

  1. Coolant temperature is greater than 176°F (80°C).
  2. EGR duty cycle command is greater than 48 percent.
  3. TPS less than Wide Open Throttle (WOT), but not at idle.
  4. Codes 21, 22, 33 and 34 not set.
  5. All conditions above must be met for about 4 minutes.

If the switch is detected closed during start-up, or if the switch is detected open when above conditions are met, the "SERVICE ENGINE SOON" light remains on unless the switch changes state.

Note. Test numbers refer to test numbers on diagnostic chart.

  1. This test will determine if the ECM set the code due to circuit No. 935 being grounded on start up. If the "Scan" tester does not indicate the switch is closed but the "SERVICE ENGINE SOON" light is on after start up, then this circuit should be checked carefully for an intermittent ground condition.
  2. If the "Scan" tester indicates the switch is no longer closed after disconnecting it, be sure the switch is not closed due to heat. Ensure EGR valve is open prior to test.
  3. This test will check for a possible open in circuit No. 935. The ECM supplies and monitors 9-12 volts on circuit No. 935. "Scan" tester should indicate switch being closed when circuit No. 935 is grounded.
  4. By grounding the diagnostic "test" terminal, the EGR solenoid should close and allow vacuum to be applied. Vacuum should hold.
  5. This test will determine if the electrical control part of the system is at fault, or if the connector or solenoid are at fault.
  6. By plugging the EGR valve side and ungrounding the diagnostic "test" terminal, the solenoid valve should open and allow vacuum to bleed off through the vent.
  7. With the engine not running and vacuum applied to the valve, the valve should move to the fully open position.
  8. Due to engine using a negative backpressure valve, the valve should close when the engine is started.

Code 32 Schematic - EGR Sys Failure. Scheme 182

Scheme 182: Code 32 Schematic - EGR Sys Failure

Code 32 Flow Chart - EGR Sys Failure. Scheme 183

Scheme 183: Code 32 Flow Chart - EGR Sys Failure

Code 32 Flow Chart - EGR System Failure (1 Of 2). Scheme 184

Scheme 184: Code 32 Flow Chart - EGR System Failure (1 Of 2)

Code 32 Flow Chart - EGR System Failure (2 Of 2). Scheme 185

Scheme 185: Code 32 Flow Chart - EGR System Failure (2 Of 2)

CODE 33 - MASS AIRFLOW (MAF) SENSOR VOLTAGE HIGH

The Mass Airflow (MAF) sensor measures the amount of air entering the engine. The ECM uses this information to determine the operating condition of the engine and to control fuel delivery. The oil pressure switch or ECM, through control of the fuel pump relay, will provide 12 volts for the MAF power relay. This 12-volt signal is used by the Bosch MAF sensor to maintain a "hot wire" sensor circuit within the sensor body. The flow of air across this "hot wire" causes the wire to cool off. The sensor compensates by increasing current flow through the "hot wire" to maintain a calibrated temperature.

The ECM applies and monitors a current limiting 5 volts on circuit No. 998. As the MAF sensor varies current on the "hot wire" circuit, internal sensor circuitry changes the monitored 5-volt signal. Sensor circuitry will drop the voltage proportionately so that with low airflow, the ECM sees voltage as low as .4 volt and with high airflow, the ECM will see near the full 5-volt supply.

Due to the "hot wire" being exposed to air which always contains some contaminants, deposits may form on the "hot wire". To keep the system functioning properly, whenever the ignition is shut off, the sensor wire is heated to a temperature of 1000°F (538°C) by the MAF burn-off relay. With the relay energized, the ECM then monitors the MAF signal line to determine if the burn-off took place. If it did not occur, Code 36 will set in memory and the "SERVICE ENGINE SOON" light will come on the next time the vehicle is started.

Note. Test numbers refer to test numbers on diagnostic chart.

Code 33 indicates ECM has seen flow in excess of 45 grams per second (greater than about 2.2 volts) for one second when engine is first started, or TPS is less than 1/4 throttle and engine speed is less than 2000 RPM. Due to the 5-volt pull-up resistor in ECM circuit, if circuit No. 998 becomes open, the ECM will see a high monitored voltage signal and set Code 33.

Note. Test numbers refer to test numbers on diagnostic chart.

  1. Determines if the conditions to set Code 33 exist.
  2. With the ALDL terminal "G" jumpered to 12 volts, there should be 12 volts at the sensor. If no voltage is present, make sure that the fuel pump is running. If not, repair fuel pump circuit.
  3. If a burn-off signal is present at the MAF sensor with the engine running, a Code 33 will set. Be sure no voltage is present on circuit No. 994 for the first 2 seconds after the ignition is turned on or the first 25 seconds that the fuel pump is running.
  4. The ECM supplies a voltage of 4-6 volts to the MAF sensor on circuit No. 998. This test checks for that voltage.

By jumpering the fuel pump test terminal (terminal "G" of ALDL) to 12 volts, the MAF sensor will stay powered up and the monitored signal line should see a low voltage (less than 250 mV or low gram per second on the "Scan" tester). By wiggling the related wiring, the intermittent may be detected. Also, an erratic signal with the engine running may indicate faulty wiring or components.

Code 33 Flow Chart - MAP Sensor (5.0/5.7L "F" & "Y" Bodies). Scheme 186

Scheme 186: Code 33 Flow Chart - MAP Sensor (5.0/5.7L "F" & "Y" Bodies)

Code 33 Flow Chart - MAP Sensor (5.0/5.7L "F" & "Y" Bodies) (1 Of 2). Scheme 187

Scheme 187: Code 33 Flow Chart - MAP Sensor (5.0/5.7L "F" & "Y" Bodies) (1 Of 2)

Code 33 Flow Chart - MAP Sensor (5.0/5.7L "F" & "Y" Bodies) (1 Of 2). Scheme 188

Scheme 188: Code 33 Flow Chart - MAP Sensor (5.0/5.7L "F" & "Y" Bodies) (1 Of 2)

CODE 34 - MASS AIRFLOW (MAF) SENSOR VOLTAGE LOW

The Mass Airflow (MAF) sensor measures the amount of air entering the engine. The ECM uses this information to determine the operating condition of the engine and to control fuel delivery. The oil pressure switch or ECM, through control of the fuel pump relay, will provide 12 volts for the MAF power relay. This 12-volt signal is used by the Bosch MAF sensor to maintain a "hot wire" sensor circuit within the sensor body. The flow of air across this "hot wire" causes the wire to cool off. The sensor compensates by increasing current flow through the "hot wire" to maintain a calibrated temperature.

The ECM applies and monitors a current limiting 5 volts on circuit No. 998. As the MAF sensor varies current on the "hot wire" circuit, internal sensor circuitry changes the monitored 5-volt signal. Sensor circuitry will drop the voltage proportionately, so that with low airflow, the ECM sees voltage as low as .4 volt and with high airflow, the ECM will see near the full 5-volt supply.

Due to the "hot wire" being exposed to air which always contains some contaminants, deposits may form on the "hot wire". To keep the system functioning properly, whenever the ignition is shut off, the sensor wire is heated to a temperature of about 1000°F (538°C) by the MAF burn-off relay. With the relay energized, the ECM monitors the MAF signal line to determine if the burn-off took place. If it did not occur, Code 36 will set in memory and the "SERVICE ENGINE SOON" light will come on the next time the vehicle is started.

Note. Test numbers refer to test numbers on diagnostic chart.

  1. A Code 34 may be caused by an engine that exhibits a low, rough, unstable or incorrect idle problem. If this condition exists, disconnect MAF sensor. If condition improves with sensor disconnected, replace sensor.
  2. Tests to determine if the conditions still exist to set Code 34. With the MAF sensor disconnected, the ECM should see a high signal voltage and set Code 33. If Code 34 resets, wiring or ECM is faulty.

Be sure air ducts are clean and tight. Code 34 could result from a dirty or misadjusted throttle body.

Code 34 Flow Chart - MAF Sensor. Scheme 189

Scheme 189: Code 34 Flow Chart - MAF Sensor

Code 34 Flow Chart - MAF Sensor. Scheme 190

Scheme 190: Code 34 Flow Chart - MAF Sensor

CODE 36 - MASS AIRFLOW (MAF) SENSOR BURN-OFF FAILURE

The Mass Airflow (MAF) sensor measures the amount of air which passes through it. The ECM uses this information to determine the operating condition of the engine to control fuel delivery. Due to contaminates in the atmosphere, a residue may build up on the MAF sensor "hot wire". To maintain an accurate reading from the sensor, a burn-off cycle will occur when the ignition is turned off after the engine has been running a specified amount of time and engine is at operating temperature. The burn-off function takes place when the ECM grounds circuit No. 900 which energizes the MAF sensor burn-off relay. With the MAF sensor burn-off relay energized, voltage will be supplied to the MAF sensor terminal "D". Voltage will also be supplied through the normally closed set of contacts in the MAF power relay which will supply 12 volts to terminal "E" of the MAF sensor. During the burn-off cycle, the ECM monitors the 5-volt MAF signal line (circuit No. 998). The increase in temperature, up to 1000°F (538°C), on the MAF "hot wire" will be reflected as a voltage change on circuit No. 998. If this change is not reflected at the ECM, a Code 36 will be set in memory and the "SERVICE ENGINE SOON" light will come on the next time the vehicle is started.

Note. Test numbers refer to test numbers on diagnostic chart.

  1. This test will determine if the burn-off function is operative or if the code was set due to an intermittent condition.
  2. Check for continuous 12-volt supply to burn-off relay.
  3. Grounding circuit No. 900 should energize the burn-off relay and close the contacts.
  4. With the burn-off relay energized, there should be 12 volts supplied to the MAF sensor on terminals "D" and "E" (circuits No. 993 and 994).

Code 36 could have been set due to a poor connection at any of the relays or the MAF sensor. Be sure that these connections and terminals are okay. A faulty MAF sensor should not be considered as the cause if Code 36 is set.

Code 36 - MAF Burn-Off Failure Schematic ("F" Body). Scheme 191

Scheme 191: Code 36 - MAF Burn-Off Failure Schematic ("F" Body)

Code 36 - MAF Burn-Off Failure Schematic ("Y" Body). Scheme 192

Scheme 192: Code 36 - MAF Burn-Off Failure Schematic ("Y" Body)

Code 36 - MAF Burn-Off Failure Flow Chart ("F/Y" Bodies). Scheme 193

Scheme 193: Code 36 - MAF Burn-Off Failure Flow Chart ("F/Y" Bodies)

CODE 41 - CYLINDER SELECT ERROR (5.7L "Y" BODY)

Note. Test numbers refer to test numbers on diagnostic chart.

  1. The ECM used for this engine can also be used for other engines. The difference is in the MEM-CAL. If a Code 41 sets, the incorrect MEM-CAL has been installed or MEM-CAL is faulty and must be replaced.

Check MEM-CAL to be sure locking tabs are secure. Also check the pins on both the MEM-CAL and ECM to verify they are making proper contact. Check the MEM-CAL part number for proper application. If the correct MEM-CAL is installed and is defective, it is possible the ECM will also need to be replaced.

Code 41 Flow Chart - Cyl. Select Error (5.7L "Y" Body). Scheme 194

Scheme 194: Code 41 Flow Chart - Cyl. Select Error (5.7L "Y" Body)

Code 41 Flow Chart - Cylinder Select Error (5.7L "Y" Body). Scheme 195

Scheme 195: Code 41 Flow Chart - Cylinder Select Error (5.7L "Y" Body)

CODE 42 - EST (W/HEI)

When the system is running on the ignition module (no voltage on the by-pass line), the ignition module grounds the EST signal. The ECM expects to see no voltage on the EST line during this condition. If it sees a voltage, it sets Code 42 and won't go into the EST mode.

When the RPM for EST operation is reached (400 RPM), by-pass voltage is applied. At this time, the EST should no longer be grounded in the ignition module, so the EST voltage should be varying. If the by-pass line is open or grounded, the ignition module will not switch to EST mode, so the EST voltage will be low and Code 42 will be set. If the EST line is grounded, the ignition module will switch to EST, but because the line is grounded, there will be no EST signal and Code 42 will be set.

Note. Test numbers refer to test numbers on diagnostic chart.

  1. Code 42 means the ECM has seen an open or short to ground in the EST or by-pass circuits. This test confirms Code 42 and that the fault causing the code is present.
  2. Checks for a normal EST ground path through the ignition module. If EST circuit No. 423 is shorted to ground, it will also read less than 500 ohms. This will be checked later.
  3. As the test light voltage touches circuit No. 424, the module should switch, causing the ohmmeter to overrange if the meter is in the 1000-2000 ohms position. Selecting the 10,000-20,000 ohms position will indicate a reading greater than 5000 ohms. The important thing is that the module switched.
  4. The module did not switch and this test checks for EST circuit No. 423 for being shorted to ground, by-pass circuit No. 424 open, faulty ignition module connections or module.
  5. Confirms that Code 42 is a faulty ECM and not an intermittent in circuits No. 423 or 424.

The "Scan" tester does not have the ability to help diagnose a Code 42 problem. A PROM/Mem-Cal not fully seated in the ECM can result in a Code 42.

Code 42 Flow Chart - EST (5.0L & 5.7L "F" & "Y" Bodies). Scheme 196

Scheme 196: Code 42 Flow Chart - EST (5.0L & 5.7L "F" & "Y" Bodies)

Code 42 Flow Chart - EST (5.0L & 5.7L "F" & "Y" Bodies). Scheme 197

Scheme 197: Code 42 Flow Chart - EST (5.0L & 5.7L "F" & "Y" Bodies)

CODE 43 - ELECTRONIC SPARK CONTROL (ESC)

Electronic Spark Control (ESC) is accomplished using a knock sensor and a control module which sends a voltage signal to the ECM. As the knock sensor detects engine knock, the voltage from the ESC module to the ECM drops, signaling the ECM to retard timing. The ECM will retard the timing when knock is detected and engine speed is greater than 900 RPM.

Code 43 means the ECM has seen low voltage on circuit No. 485 (terminal "B7") for longer than 5 seconds with the engine running, or the system has failed the functional check. This system performs a functional check once per start-up to check the ESC system. To perform this test, the ECM will advance the spark when coolant temperature is greater than 194°F (95°C) and a high load condition exists (near WOT). If knock occurs, the functional test has passed. If the ECM detected knock before coolant temperature reached 194°F (95°C), the system is operating properly and the functional check will not be run. If the functional check fails, the "SERVICE ENGINE SOON" light will remain on until ignition is turned off, or until a knock signal is detected.

Note. Test numbers refer to test numbers on diagnostic chart.

  1. If the conditions for a Code 43 exist, the "Scan" tester will always display "Yes". There should not be a knock at idle unless an internal engine problem or a system problem exists.
  2. This test will determine if the system is functioning properly at this time. Usually, a knock signal can be generated by tapping on the right exhaust manifold. If no knock signal is generated, try tapping on block closer to the area of the sensor.
  3. Because Code 43 sets when the signal voltage on circuit No. 485 remains low, this test should cause the signal on circuit No. 485 to go high. The 12-volt signal should be seen by the ECM as "no knock" if the ECM and wiring are okay.
  4. This test will determine if the knock signal is being detected on circuit No. 496, or if the ESC module is at fault.
  5. If circuit No. 496 is routed to close to secondary ignition wires, the ESC module may see the induced interference as a knock signal.
  6. This checks the ground circuit to the module. An open ground will cause the voltage on circuit No. 485 to be about 12 volts, which would cause the Code 43 functional tests to fail.
  7. Touching circuit No. 496 with a test light to 12 volts should generate a knock signal. This will determine if the ESC module is operating correctly.

Code 43 can be caused by a faulty connection at the knock sensor, ESC module or at the ECM. Also, check circuit No. 485 for possible open or short to ground.

Code 43 Flow Chart - ESC (5.0L & 5.7L "F" & "Y" Bodies). Scheme 198

Scheme 198: Code 43 Flow Chart - ESC (5.0L & 5.7L "F" & "Y" Bodies)

Code 43 Flow Chart - ESC (5.0L & 5.7L "F" & "Y" Bodies). Scheme 199

Scheme 199: Code 43 Flow Chart - ESC (5.0L & 5.7L "F" & "Y" Bodies)

CODE 44 - LEAN EXHAUST INDICATION

The ECM supplies a voltage of about .45 volt between circuits No. 412 and 413. If measured with a 10-megohm digital voltmeter, this may read as low as .32 volt. The oxygen sensor varies the voltage within a range of about one volt if the exhaust is rich, down to about .10 volt if exhaust is lean. The sensor is like an open circuit and produces no voltage when it is less than about 600°F (360°C). An open sensor circuit or cold sensor causes "open loop" operation.

Note. Test numbers refer to test numbers on diagnostic chart.

  1. Code 44 is set when the oxygen sensor signal voltage on circuit No. 412 remains less than .2 volt for at least 60 seconds and the system is operating in "closed loop".

Using the "Scan" tester, observe the block learn values under different RPM and airflow conditions. If the conditions for Code 44 exists, the block learn values will be around 150.

  1. Oxygen sensor pigtail may be mispositioned and contacting the exhaust manifold.
  2. Check for intermittent ground in wire between connector and sensor.
  3. A MAF sensor output that causes the ECM to sense a less than normal airflow will cause the system to go lean. If this occurs, disconnect the MAF sensor. If the lean condition is gone, replace the MAF sensor. MAF Tester (J 36101) may be used to test for an out-of-calibration sensor.
  4. Water, even in small amounts, near the in-tank fuel pump inlet can be delivered to the injectors. The water causes a false lean exhaust condition and can set a Code 44.
  5. System will be lean if pressure is too low. It may be necessary to monitor fuel pressure while driving the vehicle at various speeds. Check fuel volume from pump (one pint in 30 seconds) as well as pressure. Also check rubber fuel lines for internal collapse.
  6. If there is an exhaust leak, outside air may be pulled into the exhaust and past the sensor. Vacuum or crankcase leaks can cause A lean condition.
  7. If the above tests are okay, replace oxygen sensor.

Code 44 Flow Chart - Lean Exhaust Indication. Scheme 200

Scheme 200: Code 44 Flow Chart - Lean Exhaust Indication

Code 44 Flow Chart - Lean Exhaust Indication. Scheme 201

Scheme 201: Code 44 Flow Chart - Lean Exhaust Indication

CODE 45 - RICH EXHAUST INDICATION

The ECM supplies a voltage of about .45 volt between circuits No 412 and 413. The oxygen sensor varies the voltage within a range of about one volt if the exhaust is rich, down to about .10 volt if exhaust is lean. The oxygen sensor is like an open circuit and produces no voltage when it is less than about 600°F (360°C). An open sensor circuit or cold sensor causes "open loop" operation.

Note. Test numbers refer to test numbers on diagnostic chart.

  1. Code 45 is set when the oxygen sensor signal voltage on circuit No. 412 remains greater than .7 volt for 30 seconds, in "closed loop", engine time after start is one minute or more and throttle angle is greater than 2 percent.

Using the "Scan" tester, observe the block learn values at different RPM and airflow conditions. If the conditions for Code 45 exists, the block learn values will be around 115.

  1. Fuel system will go rich if pressure is too high. The ECM can compensate for some increase, however, if it gets too high, a Code 45 may be set.
  2. Check for fuel contaminated oil.
  3. An open ground circuit No. 453 (ignition module ground to ECM) may result in induced electrical "noise". The ECM looks at this "noise" as reference pulses (RPM). The additional pulses result in a higher than actual engine speed signal. The ECM then delivers too much fuel, causing system to go rich. If this problem occurs, "Scan" tester will show a greater than actual engine speed, which can help in diagnosing this problem.
  4. Check vapor canister for fuel saturation. If canister is full of fuel, check canister liquid/vapor control and hoses.
  5. An output that causes the ECM to sense a higher than normal airflow can cause the system to go rich. Disconnecting the MAF sensor will allow the ECM to set a fixed value for the sensor. Substitute a different MAF sensor, if the rich condition is gone when the sensor is disconnected, or test MAF sensor using MAF Tester (J 36101).
  6. Check for leaking fuel pressure regulator diaphragm by checking vacuum line to regulator for fuel.
  7. An intermittent TPS output will cause the system to go rich due to a false indication of the engine accelerating.

Code 45 Flow Chart - Rich Exhaust Indication. Scheme 202

Scheme 202: Code 45 Flow Chart - Rich Exhaust Indication

Code 45 Flow Chart - Rich Exhaust Indication. Scheme 203

Scheme 203: Code 45 Flow Chart - Rich Exhaust Indication

CODE 46 - VEHICLE ANTI-THEFT SYSTEM (VATS) (5.7L "Y" BODY)

The Vehicle Anti-Theft System (VATS) is designed to disable vehicle operation if the incorrect key or starting procedure is used. The anti-theft decoder module sends a signal to the ECM if the correct key is being used. If the proper signal does not reach the ECM on circuit No. 963, the ECM will not pulse the injectors and thus not allow the vehicle to be started and Code 46 will set.

Note. Test numbers refer to test numbers on diagnostic chart.

  1. If the engine cranks and a Code 46 is stored, it indicates that the portion of the module which generates the signal to the ECM is not operating or circuit No. 963 is open or shorted to ground. If the VATS decoder module is found to be okay, the ECM may be at fault, but this is not a likely condition.
  2. If Code 46 is stored and the engine will not start, it indicates that there is an anti-theft system problem or an incorrect key or starting procedure is being used.

Code 46 Flow Chart - Vehicle Anti-Theft System (5.7L "Y" Body). Scheme 204

Scheme 204: Code 46 Flow Chart - Vehicle Anti-Theft System (5.7L "Y" Body)

Code 46 Flow Chart - Vehicle Anti-Theft System (5.7L "Y" Body). Scheme 205

Scheme 205: Code 46 Flow Chart - Vehicle Anti-Theft System (5.7L "Y" Body)

CODE 53 - SYSTEM OVERVOLTAGE

This code indicates there is a basic generator problem. Code 53 will set if voltage at the ECM ignition input pin is greater than 17.1 volts for 2 seconds. Check and repair charging system.

CODE 54 - FUEL PUMP VOLTAGE LOW ("F" & "Y" BODIES)

Fuel pump circuit No. 120 is monitored by the ECM and is used to compensate fuel delivery based on system voltage. This signal is also used to store a trouble code if the fuel pump relay is defective or if fuel pump voltage is lost while the engine is running. There should be about 12 volts on circuit No. 120 for 2 seconds after the ignition is turned on, or any time references pulses are being received by the ECM.

Code 54 sets if the voltage on circuit No. 120 is less than 2 volts for 1.5 seconds since the last reference pulse is cycled off, however, if the voltage is detected less than 2 volts with the engine running, the light will only remain on while the condition exists.

Check that all pins are fully inserted into the ECM socket. If okay, replace PROM. Clear memory and recheck. If Code 51 reappears, replace the ECM.

Code 54 Flow Chart - Fuel Pump Voltage Low ("F" Body). Scheme 206

Scheme 206: Code 54 Flow Chart - Fuel Pump Voltage Low ("F" Body)

Code 54 Flow Chart - Fuel Pump Voltage Low ("F" Body) (1 Of 2). Scheme 207

Scheme 207: Code 54 Flow Chart - Fuel Pump Voltage Low ("F" Body) (1 Of 2)

Code 54 Flow Chart - Fuel Pump Voltage Low ("F" Body) (2 Of 2). Scheme 208

Scheme 208: Code 54 Flow Chart - Fuel Pump Voltage Low ("F" Body) (2 Of 2)

Code 54 Flow Chart - Fuel Pump Voltage Low ("Y" Body). Scheme 209

Scheme 209: Code 54 Flow Chart - Fuel Pump Voltage Low ("Y" Body)

Code 54 Flow Chart - Fuel Pump Voltage Low ("Y" Body) (1 Of 2). Scheme 210

Scheme 210: Code 54 Flow Chart - Fuel Pump Voltage Low ("Y" Body) (1 Of 2)

Code 54 Flow Chart - Fuel Pump Voltage Low ("Y" Body) (1 Of 2). Scheme 211

Scheme 211: Code 54 Flow Chart - Fuel Pump Voltage Low ("Y" Body) (1 Of 2)

COMPONENT CHECK FLOW CHARTS (C CHARTS)

  1. «5.0L/5.7L VINS [F,8] PFI "C" CHARTS - Camaro/Firebird»(/chevrolet/camaro/iii-1985-1992/remont/testing-diagnostics/#50l57l-vins-f8-pfi-c-charts)
  2. «5.7L VIN [8] PFI "C" CHARTS - Corvette»(ref-130707)

5.0L VIN F & 5.7L VIN 8, "F" Body Camaro - Component Locations. Scheme 212

Scheme 212: 5.0L VIN F & 5.7L VIN 8, "F" Body Camaro - Component Locations

5.0L VIN F & 5.7L VIN 8, "F" Body Firebird - Component Locations. Scheme 213

Scheme 213: 5.0L VIN F & 5.7L VIN 8, "F" Body Firebird - Component Locations

Component Locations, "Y" Body 5.7L (VIN 8). Scheme 214

Scheme 214: Component Locations, "Y" Body 5.7L (VIN 8)

ECM Terminal Identification, 5.0L & 5.7L Engines. Scheme 215

Scheme 215: ECM Terminal Identification, 5.0L & 5.7L Engines

Wiring Diagram, "F" Body 5.0L (VIN F) & 5.7L (VIN 8). Scheme 216

Scheme 216: Wiring Diagram, "F" Body 5.0L (VIN F) & 5.7L (VIN 8)

Wiring Diagram, "Y" 5.7L (VIN 8). Scheme 217

Scheme 217: Wiring Diagram, "Y" 5.7L (VIN 8)