Oscilloscope

One of twelve instruments available on Moku:Lab

Oscilloscope

One of twelve instruments
available on Moku:Lab

Sampling rate

500 MSa/s

Bandwidth

200 MHz

Input voltage range

±5 V

Waveform Generator

Integrated

How can we assist?

How can we assist?

Oscilloscope overview

Moku:Lab’s Oscilloscope features two 500 MS/s analog input channels with 200 MHz analog bandwidth, 10 V_pp input voltage range, and user-configurable AC / DC coupling and 50 Ω / 1 MΩ impedance. The Oscilloscope also features two integrated waveform generators capable of producing sine waves at up to 250 MHz and square, sawtooth and triangle waves at up to 100 MHz, enabling it to stimulate a system and measure it’s response simultaneously.

Features

Two analog inputs with 200 MHz bandwidth
Built-in two-channel 250 MHz waveform generator
Visualization tools including measurement trends and histograms
TTL-compatible external trigger
Wireless or wired interface to iPad, Python, MATLAB and LabVIEW
Math channel with support for arbitrary functions

Specifications

< 30 nV/√Hz above 100 kHz at 1 V_pp input range
Vertical resolution of 12 bits at 500 MS/s up to 22 bits at 1 kS/s
Switchable AC/DC coupling and 50Ω/1MΩ input impedance
Over 20 waveform measurements
Linear, Sinc, and Gaussian interpolation

Intutive Shortcuts

Multitouch interface: Intuitively adjust time and voltage levels with pan and pinch gestures
Save data: Single tap data uploading to the Cloud, email or SD card

Even More

Cursors abound: Show up to 5 cursors on each channel and on the horizontal axis. Each one can be set as a reference or pinned to the waveform.
Histograms: Display live, full frame rate histograms, useful for diagnosing sources of error such as electronic crosstalk

Oscilloscope overview

Features

Two analog inputs with 200 MHz bandwidth
Built-in two-channel 250 MHz waveform generator
Visualization tools including measurement trends and histograms
TTL-compatible external trigger
Wireless or wired interface to iPad, Python, MATLAB and LabVIEW
Math channel with support for arbitrary functions

Specifications

< 30 nV/√Hz above 100 kHz at 1 V_pp input range
Vertical resolution of 12 bits at 500 MS/s up to 22 bits at 1 kS/s
Switchable AC/DC coupling and 50Ω/1MΩ input impedance
Over 20 waveform measurements
Linear, Sinc, and Gaussian interpolation

Intutive Shortcuts

Multitouch interface: Intuitively adjust time and voltage levels with pan and pinch gestures
Save data: Single tap data uploading to the Cloud, email or SD card

Even More

Cursors abound: Show up to 5 cursors on each channel and on the horizontal axis. Each one can be set as a reference or pinned to the waveform.
Histograms: Display live, full frame rate histograms, useful for diagnosing sources of error such as electronic crosstalk

Wirelessly monitor signals and configure your Moku:Lab hardware, all
from an intuitive iPad interface, or with Python, MATLAB, and LabVIEW.

Wirelessly monitor signals and configure your Moku:Lab hardware, all from an intuitive iPad interface, or with Python, MATLAB, and LabVIEW.

F.A.Q.

Can I set the channel offset in screen divisions while zooming?

To zoom in and out while keeping the channel offset fixed on the screen, simply pan up or down with two fingers held together. This 'rapid zooming' technique works horizontally and on other instruments as well!

What is the difference between "Normal" and "Precision" acquisition modes?

Moku:Lab records samples from the analog inputs at a rate of 500 MS/s. When looking at long time spans, the data's sample rate is reduced to display the trace on the screen. In "Normal" acquisition mode, the input is simply downsampled; that is, only every Mth sample is taken. This can cause aliasing of high frequency signals: for example, a high frequency sine wave may appear as a lower frequency sine wave when the oscilloscope timebase is zoomed out. In "Precision" mode, the input is lowpass filtered (averaged) before downsampling. This reduces aliasing artifacts and increases the resolution of the trace. Note that in this mode, high frequency signals can be filtered out, so the oscilloscope trace may appear to be zero even if a high frequency signal is present at the input.

F.A.Q.

Can I set the channel offset in screen divisions while zooming?

To zoom in and out while keeping the channel offset fixed on the screen, simply pan up or down with two fingers held together. This 'rapid zooming' technique works horizontally and on other instruments as well!

What is the difference between "Normal" and "Precision" acquisition modes?

Moku:Lab records samples from the analog inputs at a rate of 500 MS/s. When looking at long time spans, the data's sample rate is reduced to display the trace on the screen. In "Normal" acquisition mode, the input is simply downsampled; that is, only every Mth sample is taken. This can cause aliasing of high frequency signals: for example, a high frequency sine wave may appear as a lower frequency sine wave when the oscilloscope timebase is zoomed out. In "Precision" mode, the input is lowpass filtered (averaged) before downsampling. This reduces aliasing artifacts and increases the resolution of the trace. Note that in this mode, high frequency signals can be filtered out, so the oscilloscope trace may appear to be zero even if a high frequency signal is present at the input.