Technical data
Table Of Contents
- Agilent 3000 Series Oscilloscopes-At a Glance
- In This Book
- Contents
- Figures
- Tables
- Getting Started
- Step 1. Inspect the package contents
- Step 2. Turn on the oscilloscope
- Step 3. Load the default oscilloscope setup
- Step 4. Input a waveform
- Step 5. Become familiar with the Front Panel Controls
- Step 6. Become familiar with the oscilloscope display
- Step 7. Use Auto-Scale
- Step 8. Compensate probes
- Step 9. Use the Run Control buttons
- Displaying Data
- Capturing Data
- Making Measurements
- Saving, Recalling, and Printing Data
- Oscilloscope Utility Settings
- Specifications and Characteristics
- Service
- Safety Notices
- Index
Capturing Data 3
Agilent 3000 Series Oscilloscopes User’s Guide 65
So, in practice, an oscilloscope’s sample rate should be four or more times
its bandwidth: f
S
=4f
BW
. This way, there is less aliasing, and aliased
frequency components have a greater amount of attenuation.
See Also Evaluating Oscilloscope Sample Rates vs. Sampling Fidelity: How to
Make the Most Accurate Digital Measurements, Agilent Application Note
1587 (http://cp.literature.agilent.com/litweb/pdf/5989- 5732EN.pdf)
Oscilloscope Rise Time
Closely related to an oscilloscope’s bandwidth specification is its rise time
specification. Oscilloscopes with a Gaussian- type frequency response have
an approximate rise time of 0.35/f
BW
based on a 10% to 90% criterion.
Figure 29 Sample Rate and Oscilloscope Bandwidth
f
S
f
N
f
S
/4
-3dB
Attenuation
Aliased frequency
components
Frequency
Limiting oscilloscope bandwidth (f
BW
) to 1/4 the sample rate (f
S
/4) reduces
frequency components above the Nyquist frequency (f
N
).
0dB