What Are Vertical Controls in Oscilloscopes?

Oscilloscopes use vertical controls to adjust the waveform's amplitude and position on the Y-axis and horizontal controls to manage its time scale on the X-axis.

• Vertical controls: The vertical controls adjust the voltage display. Key settings include Volts/Div for scaling the signal’s amplitude and Position for aligning it vertically. These controls ensure the waveform fits the display for accurate voltage measurements.
• Horizontal controls: The horizontal controls adjust the time display. The primary setting is Time/Div, which controls how much time each division represents. Horizontal adjustments help you analyze the waveform’s timing, duration, and frequency.

Together, these controls provide a complete view of the waveform, allowing you to accurately measure both voltage and timing characteristics.

Vertical controls let you manage how the waveform appears along the vertical (Y-axis) of the oscilloscope display. 
Here are the essential vertical controls you need to know:

This control adjusts the vertical placement of the waveform. Use it to align the waveform with the graticule for easier measurements. Centering the waveform before taking measurements improves accuracy.

The Volts/Div setting determines how many volts each division represents. Adjusting this setting helps scale waveforms of varying amplitudes to fit the display. For example, at 2 V/div, a waveform spanning 3 divisions has a peak-to-peak voltage of 6 volts.

Input coupling controls how the oscilloscope handles incoming signals.

• DC Coupling shows both AC and DC components of the signal.
• AC Coupling blocks DC components, displaying only the AC part of the signal.
• Ground (GND) disconnects the signal and sets the baseline to zero volts, providing a ground reference.

This function restricts the oscilloscope’s frequency response, typically to 20 MHz, to reduce high-frequency noise. It’s useful when measuring low-frequency signals that don’t require full bandwidth.

The oscilloscope probe attenuation matches the probe’s attenuation factor to the oscilloscope. The 1X setting applies no attenuation and works for low-voltage signals. The 10X setting attenuates the signal by a factor of 10, making it suitable for high-voltage measurements.

Vertical inversion flips the waveform vertically. This feature is useful for comparing signals or correcting inverted polarity.

Effectively using vertical controls ensures accurate waveform display and measurement. Here’s a detailed guide on how to use them:

Attach the probe to both the oscilloscope input channel and the signal source. Ensure the probe is securely connected to avoid interference or inaccurate readings.

Set the input coupling mode based on your measurement needs. 
Use DC coupling to observe both AC and DC components of the signal. If the DC component is large and masks the AC signal, switch to AC coupling to remove the DC offset. Choose Ground (GND) mode to establish a reference baseline at zero volts.

Select a Volts/Div setting that allows the waveform to fit well within the display without clipping. 
If the waveform is too large or too small, adjust this setting until the signal occupies a significant portion of the screen. For precise measurements, ensure you’re using an appropriate scale for the signal's amplitude.

Use the Position control to move the waveform up or down on the display until it aligns with the graticule lines. This makes measurements easier by establishing a clear reference point.

If high-frequency noise affects the signal, enable the Bandwidth Limit feature. 
A typical bandwidth limit, such as 20 MHz, filters out high-frequency components, providing a cleaner waveform for low-frequency signals.

Check that the oscilloscope’s probe attenuation setting matches the probe you’re using. 
For example, if using a 10X probe, ensure the oscilloscope is set to 10X. Incorrect attenuation settings can lead to inaccurate amplitude measurements.

Vertical controls play a crucial role in ensuring accurate oscilloscope measurements. Improper use of these controls can introduce errors and lead to incorrect interpretations of signals. 
Here are common issues caused by incorrect vertical control settings and ways to avoid them.

Issue: When the Volts/Div setting is too low for a high-amplitude signal, the waveform may extend beyond the screen's limits, resulting in clipping. 
This cuts off parts of the waveform and makes it impossible to see the true signal shape or measure peak values.

Solution:

• Increase the Volts/Div setting so the entire waveform fits within the display.
• Verify the waveform's amplitude by gradually decreasing the Volts/Div until you see the full signal without clipping.

Issue: High-frequency noise can obscure low-frequency signals, making it difficult to analyze the waveform accurately. 
This is common when measuring low-amplitude signals with a wide bandwidth setting.

Solution:

• Enable the Bandwidth Limit (e.g., 20 MHz) to filter out high-frequency noise.
• Use shielded probes and keep probe leads short to minimize noise pickup.
• Ensure good grounding between the oscilloscope and the circuit under test.

Issue: If the oscilloscope’s probe attenuation setting does not match the probe (e.g., using a 10X probe while the oscilloscope is set to 1X), the displayed voltage will be incorrect. This can lead to significant measurement errors.

Solution:

• Check the probe’s attenuation setting (1X, 10X, etc.) and ensure the oscilloscope matches this setting.
• Most modern oscilloscopes automatically detect probe attenuation, but always verify manually to be safe.

Issue: When a signal has a significant DC component, using DC Coupling can cause the waveform to be offset vertically, making it harder to analyze small AC variations.

Solution:

• Switch to AC Coupling to block the DC component and center the AC signal on the screen.
• Use DC Coupling when you need to measure both the AC and DC components.

Issue: Poorly calibrated probes can distort the waveform, especially for fast-changing signals. Distortion can cause inaccurate rise-time measurements or misrepresent the waveform shape.

Solution:
Regularly calibrate the probes using the oscilloscope’s built-in calibration output.
Adjust the probe compensation to ensure the displayed square wave is not rounded or overshooting.

Issue: When the waveform's ground reference is misaligned, measurements can be incorrect. This often happens when the Position Control is set improperly.

Solution:

• Use the Ground (GND) coupling mode to set a clear zero-volt baseline.
• Adjust the Position Control to align the baseline with the graticule's center line before switching back to DC or AC coupling.

1. Browse our Premium Used Oscilloscopes.
2. Call tech support US: +1 800 829-4444 
   Press #, then 2. Hours: 7 am – 5 pm MT, Mon– Fri
3. Talk to our sales support team by clicking the icon (bottom right corner) on every offer page
4. Create an account to get price alerts and access to exclusive waitlists.
5. Talk to your account manager about your specific needs.