One integrated platform for the most demanding research and engineering applications
Multiple instruments in a single platform
Lock-in Amplifier
Arbitrary Waveform Generator
Oscilloscope
Frequency
Response Analyzer
Waveform Generator
PID Controller
Phasemeter
Data Logger
Spectrum Analyzer
Digital Filter Box
Laser Lock Box
FIR Filter Builder
Flexible research, faster development, scalable in an instant
Welcome to the next generation of test. Moku:Pro delivers both performance and flexibility through sophisticated FPGA-based architecture, a high-bandwidth, low noise analog front end, and robust networking and storage. All of the instruments you need are available in an instant without compromising performance for flexibility. An innovative hybrid front-end design performs frequency-dependent signal blending from multiple ADCs, delivering exceptional noise performance from acoustic to radio frequencies. With more than 10 instruments on one hardware platform, engineers and researchers can streamline their test benches or even bring the lab home with them.
4 Analog Inputs
Up to 600 MHz, 5 GSa/s
4 Analog Outputs
Up to 500 MHz, 1.25 GSa/s
High-Speed Onboard Storage
120 GB SSD
Noise Floor
30 nV/√Hz
Clock Stability
0.3 ppm
Input to Output Latency
< 650 ns
Modern Connectivity
WiFi, Ethernet, and USB
FPGA Powered
Xilinx Ultrascale+
Software-enabled hardware
Moku:Pro is the most advanced system from the Moku suite of software defined instrument platforms. Harnessing the power of the FPGA combined with a high-quality analog front-end, Moku:Pro is able to host multiple instruments on a single hardware platform without sacrificing specs or precision. This approach to test equipment makes it possible to scale and expand the scope of research easily. With Moku:Pro, researchers and engineers already have the right tool for the job.
Blended ADCs for industry-leading noise performance
In test and measurement, flexibility has typically demanded tradeoffs in performance. We overcome these tradeoffs by using signals from a 5 GSa/s, 10-bit ADC and a 10 MSa/s, 18-bit ADC in a patented blending scheme to deliver a low noise floor and high dynamic range from 10 Hz to 600 MHz. This is achieved through a digital crossover network consisting of balanced high- and low-pass filters that implement real-time blending of the dual ADC data streams.
Engineer anywhere
By integrating test bench essentials like an oscilloscope, waveform generator, and more into a single hardware platform, Moku:Pro enables engineering teams to work from home. With a small footprint, low power consumption at 115 W, and a suite of core test instruments, pivoting to remote work has never been easier.
Introducing new features & capabilities
Optimize your workflow with Multi-instrument Mode
Moku:Pro’s Multi-instrument Mode lets you run multiple instruments at the same time and lets you connect these instruments to each other to build a customized test system.
Instruments running in this mode can be chained together to build sophisticated signal-processing pipelines. For advanced capabilities, drop in custom features designed in Moku Cloud Compile to gain more flexibility than ever before.
Connections to the analog inputs, analog outputs, and adjacent instruments are run-time configurable for instant gratification. Your Moku:Pro is now even more powerful.
Develop and deploy in minutes with Moku Cloud Compile
Access Moku:Pro’s FPGA to implement custom digital signal processing by writing your own VHDL code. This cloud-based tool is accessed directly from a browser, allowing you to develop, compile, and deploy custom algorithms to your Moku:Pro without a single software download.
Exclusively available with Multi-instrument Mode, your custom code is compatible with any of Moku:Pro’s professional-grade instruments.
Analog I/O
| Analog inputs | Channels | 4 |
|---|---|---|
| Bandwidth | 600 MHz (up to 2 channels). 300 MHz (up to 4 channels) | |
| Sampling rate | 5 GSa/s (1 channel), 1.25 GSa/s (4 channels) | |
| Resolution | 10-bit and 18-bit ADCs with automatic blending | |
| Maximum voltage range | 40 Vpp | |
| Input Impedance | 50 Ω or 1 MΩ | |
| Input coupling | AC or DC | |
| AC coupling corner | 16 kHz into 50 Ω, 1.6 Hz into 1 MΩ | |
| Input voltage noise | 30 nV√Hz at 100 Hz | |
| Input referred noise | 500 μV RMS | |
| Analog outputs | Channels | 4 |
| Bandwidth | 500 MHz (± 1 V), 100 MHz (± 5 V) | |
| Sampling rate | 1.25 GSa/s | |
| Resolution | 16-bit | |
| Voltage Range | 10 Vpp into 50 Ω | |
| Output impedance | 50 Ω | |
| Output coupling | DC |
Features & Accessories
| User Interface | iPad App |
|---|---|
| Windows and Mac Apps | |
| Programming Environment | Python |
| MATLAB | |
| Additional Ports | Ethernet |
| USB-C | |
| 10 MHz reference clock in and | |
| out |
External trigger input
| External trigger | Trigger waveform | TTL compatible |
|---|---|---|
| Trigger bandwidth | DC to 5 MHz | |
| Trigger impedance | Hi-Z | |
| Min trigger level | 1.8 V | |
| Max trigger level | 5 V | |
| Connector | BNC |
Clock reference
| On-board clock | Frequency | 10 MHz |
|---|---|---|
| Stability | < 300 ppb | |
| 10 MHz reference input | Expected waveforms | Sine / square |
| Frequency | 10 MHz ± 20 kHz | |
| Input range | -6 dBm to +10 dBm | |
| Connector | BNC | |
| 10 MHz reference output | Waveform type | Square |
| Output frequency | 10 MHz | |
| Output level | 6 dBm | |
| Connector | BNC |
Input voltage noise
Input voltage noise describes the noise floor of the analog inputs and is represented as an amplitude spectral density (magnitude of input voltage noise at different frequencies normalized to a 1 Hz bandwidth). Input voltage noise is a key specification for a variety of instruments including lock-in amplifiers, spectrum analyzers, and oscilloscopes as it can limit the signal-to-noise ration (SNR) in weak-signal applications.
In this figure, you can see the noise of 30 nV√Hz at 100 Hz and it remains low across the entire frequency range.
Blended ADCs
Our FPGA algorithms automatically and intelligently blend the high-speed and low-speed signals from the 10-bit and 18-bit ADCs to optimize noise performance across the entire frequency range.
Rather than simply focusing on minimizing overall noise, the filtering network is designed in a way that preserves a unity-gain frequency response for the signal.
Specs
- Moku:Pro Spec Sheet - Download
Getting Started
- Moku:Pro Quick Start Guide - Download
Datasheets
- Moku:Pro Datasheet - Download
- Moku:Pro Multi-Instrument Mode - Download
- Moku:Pro’s Arbitrary Waveform Generator Datasheet - Download
- Moku:Pro’s Data Logger Datasheet - Download
- Moku:Pro's Digital Filter Box Datasheet - Download
- Moku:Pro’s Frequency Response Analyzer Datasheet - Download
- Moku:Pro's Laser Lock Box Datasheet - Download
- Moku:Pro’s Lock-in Amplifier Datasheet - Download
- Moku:Pro’s Oscilloscope Datasheet - Download
- Moku:Pro’s Phasemeter Datasheet - Download
- Moku:Pro’s PID Controller Datasheet - Download
- Moku:Pro’s Spectrum Analyzer Datasheet - Download
- Moku:Pro’s Waveform Generator Datasheet - Download
User Manuals
- Moku:Pro’s Arbitrary Waveform Generator User Manual - Download
- Moku:Pro’s Data Logger User Manual - Download
- Moku:Pro’s Frequency Response Analyzer User Manual - Download
- Moku:Pro's Laser Lock Box User Manual - Download
- Moku:Pro’s Lock-in Amplifier User Manual - Download
- Moku:Pro’s Oscilloscope User Manual - Download
- Moku:Pro’s Phasemeter User Manual - Download
- Moku:Pro’s PID Controller User Manual - Download
- Moku:Pro’s Spectrum Analyzer User Manual - Download
- Moku:Pro’s Waveform Generator User Manual - Download