Setting Up
This section briefly describes how to set up and start using an
oscilloscope - specifically, how to ground the oscilloscope, set the controls
in standard positions, and compensate the probe.
Grounding
Proper grounding is an important step when setting up to take
measurements or work on a circuit. Properly grounding the oscilloscope
protects you from a hazardous shock and grounding yourself protects your
circuits from damage.
Ground the Oscilloscope
Grounding the oscilloscope is necessary for safety. If a high voltage contacts
the case of an ungrounded oscilloscope, any part of the case, including
knobs that appear insulated, it can give you a shock. However, with a
properly grounded oscilloscope, the current travels through the grounding
path to earth ground rather than through you to earth ground.
To ground the oscilloscope means to connect it to an electrically neutral
reference point (such as earth ground). Ground your oscilloscope by
plugging its three-pronged power cord into an outlet grounded to earth
ground.
Grounding is also necessary for taking accurate measurements with your
oscilloscope. The oscilloscope needs to share the same ground as any
circuits you are testing.
Some oscilloscopes do not require the separate connection to earth ground.
These oscilloscopes have insulated cases and controls, which keeps any
possible shock hazard away from the user.
If you are working with integrated circuits (ICs), you also need to ground
yourself. Integrated circuits have tiny conduction paths that can be
damaged by static electricity that builds up on your body. You can ruin an
expensive IC simply by walking across a carpet or taking off a sweater and
then touching the leads of the IC. To solve this problem, wear a grounding
strap (see Figure 1). This strap safely sends static charges on your body to
earth ground.
Figure 1: Typical Wrist Type Grounding Strap
After plugging in the oscilloscope, take a look at the front panel. It is divided
into three main sections labeled Vertical, Horizontal, and Trigger. Your
oscilloscope may have other sections, depending on the model and type
(analog or digital).
Notice the input connectors on your oscilloscope. This is where you attach
probes. Most oscilloscopes have at least two input channels and each
channel can display a waveform on the screen. Multiple channels are handy
for comparing waveforms.
Figure 2: Front Panel Control Sections of an Oscilloscope
Some oscilloscopes have an AUTOSET or PRESET button that sets up the
controls in one step to accommodate a signal. If your oscilloscope does not
have this feature, it is helpful to set the controls to standard positions before
taking measurements.
Standard positions include the following:
- Set the oscilloscope to display channel 1
- Set the volts/division scale to a mid-range position
- Turn off the variable volts/division
- Turn off all magnification settings
- Set the channel 1 input coupling to DC
- Set the trigger mode to auto
- Set the trigger source to channel 1
- Turn trigger holdoff to minimum or off
- Set the intensity control to a nominal viewing level
- Adjust the focus control for a sharp display
These are general instructions for setting up your oscilloscope. If you are not
sure how to do any of these steps, refer to the manual that came with your
oscilloscope. The Controls section describes the controls in more detail.
Now you are ready to connect a probe to your oscilloscope. It is important
to use a probe designed to work with your oscilloscope. A probe is more
than a cable with a clip-on tip. It is a high-quality connector, carefully
designed not to pick up stray radio and power line noise.
Probes are designed not to influence the behavior of the circuit you are
testing. However, no measurement device can act as a perfectly invisible
observer. The unintentional interaction of the probe and oscilloscope with
the circuit being tested is called circuit loading. To minimize circuit loading,
you will probably use a 10X attenuator (passive) probe.
Your oscilloscope probably arrived with a passive probe as a standard
accessory. Passive probes provide you with an excellent tool for
general-purpose testing and troubleshooting. For more specific
measurements or tests, many other types of probes exist. Two examples are
active and current probes.
Descriptions of these probes follow, with more emphasis given to the
passive probe since this is the probe type that allows you the most flexibility
of use.
Using Passive Probes
Most passive probes have some degree of attenuation factor, such as 10X,
100X, and so on. By convention, attenuation factors, such as for the 10X
attenuator probe, have the X after the factor. In contrast, magnification
factors like X10 have the X first.
The 10X (read as "ten times") attenuator probe minimizes circuit loading and
is an excellent general-purpose passive probe. Circuit loading becomes
more pronounced at higher frequencies, so be sure to use this type of probe
when measuring signals above 5 kHz. The 10X attenuator probe improves
the accuracy of your measurements, but it also reduces the amplitude of the
signal seen on the screen by a factor of 10.
Because it attenuates the signal, the 10X attenuator probe makes it difficult
to look at signals less than 10 millivolts. The 1X probe is similar to the 10X
attenuator probe but lacks the attenuation circuitry. Without this circuitry,
more interference is introduced to the circuit being tested. Use the 10X
attenuator probe as your standard probe, but keep the 1X probe handy for
measuring weak signals. Some probes have a convenient feature for
switching between 1X and 10X attenuation at the probe tip. If your probe
has this feature, make sure you are using the correct setting before taking
measurements.
Many oscilloscopes can detect whether you are using a 1X or 10X probe
and adjust their screen readouts accordingly. However with some
oscilloscopes, you must set the type of probe you are using or read from the
proper 1X or 10X marking on the volts/div control.
The 10X attenuator probe works by balancing the probe's electrical
properties against the oscilloscope's electrical properties. Before using a
10X attenuator probe you need to adjust this balance for your particular
oscilloscope. This adjustment is called compensating the probe and is
further described in the next section. Figure 3 shows a simple diagram of
the internal workings of a probe, its adjustment, and the input of an
oscilloscope.
Figure 3: Typical Probe/Oscilloscope 10-to-1 Divider Network
Figure 4 shows a typical passive probe and some accessories to use with
the probe.
Figure 4: A Typical Passive Probe with Accessories
Using Active Probes
Active probes provide their own amplification or perform some other type of
operation to process the signal before applying it to the oscilloscope. These
types of probes can solve problems such as circuit loading or perform tests
on signals, sending the results to the oscilloscope. Active probes require a
power source for their operation.
Using Current Probes
Current probes enable you to directly observe and measure current
waveforms. They are available for measuring both AC and DC current.
Current probes use jaws that clip around the wire carrying the current. This
makes them unique since they are not connected in series with the circuit;
they, therefore, cause little or no interference in the circuit.
Where to Clip the Ground Clip
Measuring a signal requires two connections: the probe tip connection and
a ground connection. Probes come with an alligator-clip attachment for
grounding the probe to the circuit under test. In practice, you clip the
grounding clip to a known ground in the circuit, such as the metal chassis of
a stereo you are repairing, and touch the probe tip to a test point in the
circuit.
Before using a passive probe, you need to compensate it - to balance its
electrical properties to a particular oscilloscope. You should get into the
habit of compensating the probe every time you set up your oscilloscope. A
poorly adjusted probe can make your measurements less accurate. Figure 5
shows what happens to measured waveforms when using a probe not
properly compensated.
Figure 5: The Effects of Improper Probe Compensation
Most oscilloscopes have a square wave reference signal available at a
terminal on the front panel used to compensate the probe. You compensate
a probe by:
- Attaching the probe to an input connector
- Connecting the probe tip to the probe compensation signal
- Attaching the ground clip of the probe to ground
- Viewing the square wave reference signal
- Making the proper adjustments on the probe so that the corners of the
square wave are square
When you compensate the probe, always attach any accessory tips you will
use and connect the probe to the vertical channel you plan to use. This way
the oscilloscope has the same electrical properties as it does when you take
measurements.
Next Chapter: The Controls
Previous Chapter: Oscilloscope Terminology
Table of Contents: Table of Contents