The Controls
This section briefly describes the basic controls found on analog and digital
oscilloscopes. Remember that some controls differ between analog and
digital oscilloscopes; your oscilloscope probably has controls not discussed
here.
Display systems vary between analog and digital oscilloscopes. Common
controls include:
- An intensity control to adjust the brightness of the waveform. As you
increase the sweep speed of an analog oscilloscope, you need to
increase the intensity level.
- A focus control to adjust the sharpness of the waveform. Digital
oscilloscopes may not have a focus control.
- A trace rotation control to align the waveform trace with the screen's
horizontal axis. The position of your oscilloscope in the earth's magnetic
field affects waveform alignment. Digital oscilloscopes may not have a
trace rotation control.
- Other display controls may let you adjust the intensity of the graticule
lights and turn on or off any on-screen information (such as menus).
Use the vertical controls to position and scale the waveform vertically. Your
oscilloscope also has controls for setting the input coupling and other signal
conditioning, described in this section. Figure 1 shows a typical front panel
and on-screen menus for the vertical controls.
Figure 1: Vertical Controls
The vertical position control lets you move the waveform up or down to
exactly where you want it on the screen.
The volts per division (usually written volts/div) setting varies the size of the
waveform on the screen. A good general purpose oscilloscope can
accurately display signal levels from about 4 millivolts to 40 volts.
The volts/div setting is a scale factor. For example, if the volts/div setting is
5 volts, then each of the eight vertical divisions represents 5 volts and the
entire screen can show 40 volts from bottom to top (assuming a graticule
with eight major divisions). If the setting is 0.5 volts/div, the screen can
display 4 volts from bottom to top, and so on. The maximum voltage you
can display on the screen is the volts/div setting times the number of vertical
divisions. (Recall that the probe you use, 1X or 10X, also influences the
scale factor. You must divide the volts/div scale by the attenuation factor of
the probe if the oscilloscope does not do it for you.)
Often the volts/div scale has either a variable gain or a fine gain control for
scaling a displayed signal to a certain number of divisions. Use this control
to take rise time measurements.
Coupling means the method used to connect an electrical signal from one
circuit to another. In this case, the input coupling is the connection from your
test circuit to the oscilloscope. The coupling can be set to DC, AC, or
ground. DC coupling shows all of an input signal. AC coupling blocks the
DC component of a signal so that you see the waveform centered at zero
volts. Figure 2 illustrates this difference. The AC coupling setting is handy
when the entire signal (alternating plus constant components) is too large
for the volts/div setting.
Figure 2: AC and DC Input Coupling
The ground setting disconnects the input signal from the vertical system,
which lets you see where zero volts is on the screen. With grounded input
coupling and auto trigger mode, you see a horizontal line on the screen that
represents zero volts. Switching from DC to ground and back again is a
handy way of measuring signal voltage levels with respect to ground.
Most oscilloscopes have a circuit that limits the bandwidth of the
oscilloscope. By limiting the bandwidth, you reduce the noise that
sometimes appears on the displayed waveform, providing you with a more
defined signal display.
Most oscilloscopes have an invert function that allows you to display a signal
"upside-down." That is, with low voltage at the top of the screen and high
voltage at the bottom.
On analog scopes, multiple channels are displayed using either an alternate
or chop mode. (Digital oscilloscopes do not normally use chop or alternate
mode.)
Alternate mode draws each channel alternately - the oscilloscope
completes one sweep on channel 1, then one sweep on channel 2, a
second sweep on channel 1, and so on. Use this mode with medium- to
high-speed signals, when the sec/div scale is set to 0.5 ms or faster.
Chop mode causes the oscilloscope to draw small parts of each signal by
switching back and forth between them. The switching rate is too fast for
you to notice, so the waveform looks whole. You typically use this mode with
slow signals requiring sweep speeds of 1 ms per division or less. Figure 3
shows the difference between the two modes. It is often useful to view the
signal both ways, to make sure you have the best view.
Figure 3: Multi-Channel Display Modes
Math Operations
Your oscilloscope may also have operations to allow you to add waveforms
together, creating a new waveform display. Analog oscilloscopes combine
the signals while digital oscilloscopes mathematically create new
waveforms. Subtracting waveforms is another math operation. Subtraction
with analog oscilloscopes is possible by using the channel invert function on
one signal and then use the add operation. Digital oscilloscopes typically
have a subtraction operation available. Figure 4 illustrates a third waveform
created by adding two different signals together.
Figure 4: Adding Channels
Use the horizontal controls to position and scale the waveform horizontally.
Figure 5 shows a typical front panel and on-screen menus for the
horizontal controls.
Figure 5: Horizontal Controls
Position and Seconds per Division
The horizontal position control moves the waveform from left and right to
exactly where you want it on the screen.
The seconds per division (usually written as sec/div) setting lets you select
the rate at which the waveform is drawn across the screen (also known as
the time base setting or sweep speed). This setting is a scale factor. For
example, if the setting is 1 ms, each horizontal division represents 1 ms and
the total screen width represents 10 ms (ten divisions). Changing the sec/div
setting lets you look at longer or shorter time intervals of the input signal.
As with the vertical volts/div scale, the horizontal sec/div scale may have
variable timing, allowing you to set the horizontal time scale in between the
discrete settings.
Time Base Selections
Your oscilloscope has a time base usually referred to as the main time base
and it is probably the most useful. Many oscilloscopes have what is called a
delayed time base - a time base sweep that starts after a pre-determined
time from the start of the main time base sweep. Using a delayed time base
sweep allows you to see events more clearly or even see events not visible
with just the main time base sweep.
The delayed time base requires the setting of a delay time and possibly the
use of delayed trigger modes and other settings not described in this book.
Refer to the manual supplied with your oscilloscope for information on how
to use these features.
Trigger Position
The trigger position control may be located in the horizontal control section
of your oscilloscope. It actually represents "the horizontal position of the
trigger in the waveform record." Horizontal trigger position control is only
available on digital oscilloscopes.
Varying the horizontal trigger position allows you to capture what a signal
did before a trigger event (called pretrigger viewing).
Digital oscilloscopes can provide pretrigger viewing because they constantly
process the input signal whether a trigger has been received or not. A
steady stream of data flows through the oscilloscope; the trigger merely tells
the oscilloscope to save the present data in memory. In contrast, analog
oscilloscopes only display the signal after receiving the trigger.
Pretrigger viewing is a valuable troubleshooting aid. For example, if a
problem occurs intermittently, you can trigger on the problem, record the
events that led up to it and, possibly, find the cause.
Your oscilloscope may have special horizontal magnification settings that let
you display a magnified section of the waveform on-screen.
XY Mode
Most oscilloscopes have the capability of displaying a second channel
signal along the X-axis (instead of time). This is called XY mode; you will
find a longer discussion later in this book.
The trigger controls let you stabilize repeating waveforms and capture
single-shot waveforms. Figure 6 shows a typical front panel and on-screen
menus for the trigger controls.
Figure 6: Trigger Controls
The trigger makes repeating waveforms appear static on the oscilloscope
display. Imagine the jumble on the screen that would result if each sweep
started at a different place on the signal (see Figure 7).
Figure 7: Untriggered Display
Trigger Level and Slope
Your oscilloscope may have several different types of triggers, such as edge,
video, pulse, or logic. Edge triggering is the basic and most common type
and is the only type discussed in this book. Consult your oscilloscope
instruction manual for details on other trigger types.
For edge triggering, the trigger level and slope controls provide the basic
trigger point definition.
The trigger circuit acts as a comparator. You select the slope and voltage
level of one side of the comparator. When the trigger signal matches your
settings, the oscilloscope generates a trigger.
- The slope control determines whether the trigger point is on the rising or
the falling edge of a signal. A rising edge is a positive slope and a falling
edge is a negative slope.
- The level control determines where on the edge the trigger point occurs.
Figure 8 shows you how the trigger slope and level settings determine how
a waveform is displayed.
Figure 8: Positive and Negative Slope Triggering
The oscilloscope does not necessarily have to trigger on the signal being
measured. Several sources can trigger the sweep:
- Any input channel
- An external source, other than the signal applied to an input channel
- The power source signal
- A signal internally generated by the oscilloscope
Most of the time you can leave the oscilloscope set to trigger on the channel
displayed.
Note that the oscilloscope can use an alternate trigger source whether
displayed or not. So you have to be careful not to unwittingly trigger on, for
example, channel 1 while displaying channel 2.
The trigger mode determines whether or not the oscilloscope draws a
waveform if it does not detect a trigger. Common trigger modes include
normal and auto.
In normal mode the oscilloscope only sweeps if the input signal reaches the
set trigger point; otherwise (on an analog oscilloscope) the screen is blank
or (on a digital oscilloscope) frozen on the last acquired waveform. Normal
mode can be disorienting since you may not see the signal at first if the level
control is not adjusted correctly.
Auto mode causes the oscilloscope to sweep, even without a trigger. If no
signal is present, a timer in the oscilloscope triggers the sweep. This
ensures that the display will not disappear if the signal drops to small
voltages. It is also the best mode to use if you are looking at many signals
and do not want to bother setting the trigger each time.
In practice, you will probably use both modes: normal mode because it is
more versatile and auto mode because it requires less adjustment.
Some oscilloscopes also include special modes for single sweeps,
triggering on video signals, or automatically setting the trigger level.
Trigger Coupling
Just as you can select either AC or DC coupling for the vertical system, you
can choose the kind of coupling for the trigger signal.
Besides AC and DC coupling, your oscilloscope may also have high
frequency rejection, low frequency rejection, and noise rejection trigger
coupling. These special settings are useful for eliminating noise from the
trigger signal to prevent false triggering.
Sometimes getting an oscilloscope to trigger on the correct part of a signal
requires great skill. Many oscilloscopes have special features to make this
task easier.
Trigger holdoff is an adjustable period of time during which the oscilloscope
cannot trigger. This feature is useful when you are triggering on complex
waveform shapes, so that the oscilloscope only triggers on the first eligible
trigger point. Figure 9 shows how using trigger holdoff helps create a usable
display.
Figure 9: Trigger Holdoff
Acquisition Controls for Digital Oscilloscopes
Digital oscilloscopes have settings that let you control how the acquisition
system processes a signal. Look over the acquisition options on your digital
oscilloscope while you read this description. Figure 10 shows you an
example of an acquisition menu.
Figure 10: Example of an Acquisition Menu
Acquisition modes control how waveform points are produced from sample
points. Recall from the first section that sample points are the digital values
that come directly out of the Analog-to-Digital-Converter (ADC). The time
between sample points is called the sample interval. Waveform points are
the digital values that are stored in memory and displayed to form the
waveform. The time value difference between waveform points is called the
waveform interval. The sample interval and the waveform interval may be but
need not be the same. This fact leads to the existence of several different
acquisition modes in which one waveform point is made up from several
sequentially acquired sample points. Additionally, waveform points can be
created from a composite of sample points taken from multiple acquisitions,
which leads to another set of acquisition modes. A description of the most
commonly used acquisition modes follows.
- Sample Mode: This is the simplest acquisition mode. The oscilloscope
creates a waveform point by saving one sample point during each
waveform interval.
- Peak Detect Mode: The oscilloscope saves the minimum and maximum
value sample points taken during two waveform intervals and uses these
samples as the two corresponding waveform points. Digital
oscilloscopes with peak detect mode run the ADC at a fast sample rate,
even at very slow time base settings (long waveform interval), and are
able to capture fast signal changes that would occur between the
waveform points if in sample mode. Peak detect mode is particularly
useful for seeing narrow pulses spaced far apart in time.
- Hi Res Mode: Like peak detect, hi res mode is a way of getting more
information in cases when the ADC can sample faster than the time
base setting requires. In this case, multiple samples taken within one
waveform interval are averaged together to produce one waveform
point. The result is a decrease in noise and an improvement in
resolution for low speed signals.
- Envelope Mode: Envelope mode is similar to peak detect mode.
However, in envelope mode, the minimum and maximum waveform
points from multiple acquisitions are combined to form a waveform that
shows min/max changes over time. Peak detect mode is usually used to
acquire the records that are combined to form the envelope waveform.
- Average Mode: In average mode, the oscilloscope saves one sample
point during each waveform interval as in sample mode. However,
waveform points from consecutive acquisitions are then averaged
together to produce the final displayed waveform. Average mode
reduces noise without loss of bandwidth but requires a repeating signal.
Stopping and Starting the Acquisition System
One of the greatest advantages of digital oscilloscopes is their ability to store
waveforms for later viewing. To this end, there are usually one or more
buttons on the front panel that allow you to stop and start the acquisition
system so you can analyze waveforms at your leisure. Additionally, you may
want the oscilloscope to automatically stop acquiring after one acquisition is
complete or after one set of records has been turned into an envelope or
average waveform. This feature is commonly called single sweep or single
sequence and its controls are usually found either with the other acquisition
controls or with the trigger controls.
In digital oscilloscopes that can use either real-time sampling or
equivalent-time sampling as described earlier, the acquisition controls will
allow you to choose which one to use for acquiring signals. Note that this
choice makes no difference for slow time base settings and only has an
effect when the ADC cannot sample fast enough to fill the record with
waveform points in one pass.
Other Controls
So far we have described the basic controls that a beginner needs to know
about. Your oscilloscope may have other controls for various functions.
Some of these may include:
- Measurement cursors
- Keypads for mathematical operations or data entry
- Print capabilities
- Interfaces for connecting your oscilloscope to a computer
Look over the other options available to you and read your oscilloscope's
manual to find out more about these other controls.
Next Chapter: Measurement Techniques
Previous Chapter: Setting Up
Table of Contents: Table of Contents