ONBOARD
DIAGNOSTICS DEMYSTIFIED
OBD II
Systems Diagnostic and Analysis
 Since
the mid-1990, no vehicle innovation has done more for vehicle service
and repair than on-board diagnostic (OBD) systems. But in order
for it to work, you must first break the OBD code.
Since the earliest
days of full-blown computerized engine-control systems, there has
always been some type of built-in self-diagnostic capability to
detect faults. A computerized engine control system uses inputs
from a wide variety of sensors and switches to regulate spark timing,
fuel delivery and other emission functions. If a sensor fails, reads
outside its normal range of values or can't send its input back
to the computer because of an open or shorted circuit, it can alter
engine performance and emissions. The computer has to have accurate
inputs to make the right commands and keep things running smoothly.
Likewise, the computer has to be able to carry out its command functions
and send its instructions to the ignition module, fuel injectors
and other control devices. If the proper commands can't get through,
that too will cause problems.
CHECK
ENGINE LIGHT (CEL)
Monitoring
the operation of the various inputs and outputs is what on-board
diagnostics is all about. When computerized engine controls went
nationwide in 1981 to comply with federal emission regulations,
the "Check Engine" light became a new feature on the instrument
panel.
The "Malfunction
Indicator Lamp" (or MIL as it is called today) is supposed
to alert the driver when a problem occurs in the engine control
system. Depending on how the system is configured and the nature
of the problem, the lamp may come on and go off, remain on continuously
or flash. Some types of intermittent problems will make the lamp
come on only while the fault is occurring. When the problem goes
away, the lamp goes off. Other types of problems will turn the light
on, and it will remain on until the fault is diagnosed and repaired.
The Check Engine
light has proven to be a great annoyance to many motorists (as well
as many professional technicians) because it seems to have a mind
of its own. For one thing, it doesn't tell you anything about the
nature of the problem. It might be something serious - or it might
not. There's no way to tell without plugging in a scantool, such
as AutoTap.
Consequently,
many motorists ignore the warning light and keep on driving if they
don't hear, feel or smell anything unusual (even then, some continue
to push onward until things get worse or the engine dies altogether).
It's amazing
the lengths some people will go to just to avoid a quick diagnosis
when the Check Engine lamp is on. Many people don't really want
to know what's wrong with their vehicles because they fear it will
end up costing them several hundred dollars to get it fixed. So
they'll put tape over the lamp, attempt to disconnect the bulb or
cut the wires to the bulb - in an attempt to make it go away. But
engine performance problems don't go away and they don't fix themselves.
And for motorists who live in areas with vehicle emission testing,
the day of reckoning arrives sooner or later since modern emissions
testing uses a scantool to check if the Check Engine lamp is on,
and if the light has been tampered with. Whenever the Check Engine
light comes on, a "diagnostic trouble code" (DTC) is also
recorded in the on-board computer's memory that corresponds to the
fault. Some problems can generate more than one fault code, and
some vehicles may suffer from multiple problems that also set multiple
codes.
SETTING
CODES
In most of
the first generation onboard diagnostic systems prior to OBD II,
disconnecting the computer's power source or disconnecting a battery
cable could erase fault codes. The loss of voltage wiped out the
computer's temporary memory causing the Check Engine light to magically
go out. But as soon as the original problem reoccurred, the code(s)
would be reset and the light would come back on.
In most newer
computer systems, fault codes are stored in a "nonvolatile"
memory that is not lost if the battery is disconnected. The codes
remain intact until they are cleared using AutoTap or another scan
tool. What's more, disconnecting the battery or computer's power
supply can have undesirable consequences because it causes the loss
of electronic presets in the radio and climate control system, as
well as the engine computer's "learned" memory - the adjustments
that are made over time to compensate for engine wear and driving
habits. On some vehicles where the computer also regulates the electronic
transmission, the computer may have to be put through a special
learning procedure to relearn the proper operation of the transmission
if power has been lost!
A SMARTER
APPROACH
Prior to OBD
II, fault detection was mostly limited to "gross failures"
within individual circuits or sensors. The first generation systems
couldn't detect engine misfire, how well the catalytic converter
was functioning or whether a vehicle was leaking fuel vapors into
the atmosphere. OBD II changed all of that by adding the ability
to monitor these things so emission problems can be detected as
they develop. OBD II still uses the Check Engine lamp to alert the
driver when a fault occurs, and it still stores fault codes that
correspond to specific kinds of problems, but it adds the unique
ability to track problems as they develop and to capture a snapshot
of what's going on when a problem occurs.
Almost any emission
problem that causes hydrocarbon emissions to exceed 1.5 times the
federal limit can cause the Check Engine light to come on with OBD
II - even if there is no noticeable drivability problem accompanying
the emission problem.
The most powerful
(and controversial) feature of OBD II is its ability to detect engine
misfire. First generation OBD systems couldn't do that directly
so there was no way to know if the engine was performing properly
or not. OBD II misfire detection strategies vary somewhat from one
vehicle manufacturer to another, but most currently use the input
from the crankshaft position sensor to monitor changes in crankshaft
speed. A single misfire will cause a slight variation in the rotational
velocity of the crank. By knowing the position of the crank and
which cylinder is supposed to be firing, the OBD II system can correlate
each misfire that occurs with a specific cylinder. The misfires
are tracked and tabulated, and if a pattern occurs it can set a
misfire code and turn on the Check Engine light.
BREAKING
THE CODE
A misfire that
occurs in a given cylinder will set a P030X code where "X"
will be the number of the cylinder that is misfiring. For example,
a P0302 code would tell you cylinder number two is misfiring. But
here's the important point: The code does not tell you why the cylinder
is misfiring. You have to figure that out for yourself by performing
other diagnostic tests. The misfire might be due to a fouled spark
plug, a bad plug wire, a defective ignition coil in a DIS system,
a clogged or dead fuel injector or a loss of compression due to
a leaky exhaust valve, leaky head gasket or worn cam lobe.
On some vehicles,
the OBD II system itself will disable a cylinder if it detects a
high enough rate of misfire. This is done to protect the catalytic
converter. By shutting off the cylinder's fuel injector, the OBD
II system prevents unburned fuel from passing through the cylinder
and entering the exhaust. Raw fuel in the exhaust is bad news because
it makes the converter overheat, and if it gets too hot it can suffer
damage. What else does OBD II add to the equation? It also monitors
the operation of the catalytic converter with a second oxygen sensor
on the tailpipe side of the converter. By comparing upstream and
downstream O2 sensor readings, it can determine how well the converter
is doing its job. If converter efficiency drops below a certain
threshold, the OBD II system will set a code and turn on the Check
Engine light.
OBD II can also
detect fuel vapor leaks (evaporative emissions) in the charcoal
canister, evap plumbing or fuel tank by pressurizing or pulling
a vacuum on the fuel system. It can even detect a loose or missing
gas cap. In addition, OBD II can also generate codes for various
electronic transmission problems and even air condition failures
such as a compressor failure.
TWO
KINDS OF CODES
The diagnostic
codes that are required by law on all OBD II systems are "generic"
in the sense that all vehicle manufacturers use the same common
code list and the same 16-pin diagnostic connector. Thus, a P0301
misfire code on a Ford means the same thing on a Chevy, Chrysler,
Toyota or Mercedes. But each vehicle manufacturers also have the
freedom to add their own "enhanced" codes to provide even
more detailed information about various faults. Enhanced codes also
cover non-emission related failures that occur outside the engine
control system. These include ABS codes, HVAC codes, airbag codes
and other body and electrical codes.
The "generic"
codes that are common to all vehicle manufacturers can be accessed
using any basic scan tool that is OBD II compliant. Unfortunately,
most older scan tools won't work on the newer OBD II systems, and
have to be replaced with ones that have the proper hardware and
software to read OBD II codes and other diagnostic information.
When shopping for a scantool, be sure and check if it supports more
than just the "generic" codes.
A challenge
for the tool manufactures is access to the vehicle manufacturer
enhanced codes. Many of the low-cost scan tools on the market get
around this by only supporting the "generic" codes and
information. While this provides basic information on a failure,
it often doesn't give you the entire picture to make your diagnosis.
The advantage of the AutoTap
OBDII scan tool is that it's available both in Generic
or Enhanced versions, and it's simple to upgrade from Generic to
Enhanced.
THE
IMPACT OF OBD II
On one hand,
OBDII has made diagnosis easier by providing more codes, detecting
problems earlier and pinpointing misfires within specific cylinders.
But on the other hand, OBD II has increased the complexity and sophistication
of engine control systems to the point where you must have an OBDII
scantool to diagnose and repair today's drivability and emissions
problems. OBD II is helping Do-It-Yourselfers and professional technicians
do a better job of fixing problems the first time. This is reducing
the number of parts that are replaced unnecessarily and reducing
comebacks and warranty returns.
WATCH
OUT FOR FALSE CODES!
Today's OBD
II systems are so sensitive to misfires that they will set a misfire
code if they detect as few as five misfires in 200 engine revolutions!
Unfortunately, this high level of sensitivity can sometimes generate
false misfire readings under certain operating conditions. Driving
on an extremely rough road, for example, can produce the same kind
of variations in crank speed that appear to be misfires to the OBD
II monitor. Some newer OBD II systems compensate for rough road
operation by reducing the level of misfire sensitivity. Others use
a different method to detect misfires. Instead of monitoring crankshaft
speed, the system watches the firing voltage of each spark plug
to detect problems (a lean misfire typically causes a large jump
in the firing voltage while a shorted or fouled plug causes a drop
in the firing voltage). Random misfires that are not isolated to
a particular cylinder will also set a misfire code. In these cases,
a scan tool like the AutoTap
Diagnostic System that allows you to view a vehicle's
real-time sensor data is invaluable in distinguishing a real misfire
problem from a false code.
Article courtesy
of AutoTap
- Auto Diagnostic Scanner
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