RIGOL DS1054Z 50MHz OSCILLOSCOPE Unlocked 4 Channels up tp 1GS/s 7 In" WVGA 12Mpts Memory Digital Oscilloscope 30,000wfm

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The deep, 12Mpts as standard (now upgraded to 24Mpts!), memory allows you to make full use of the 1GSa/s sample rate – either for incredible zoom on a captured waveform or to maximise sample rate for a given time-sweep. The DS1054Z brings 4 channel oscilloscopes within reach of every service department, hobbyist workbench and educational laboratory around Australia. The Rigol DS1054Z Highlights your own code: from ds1054z import DS1054Z scope = DS1054Z ( '192.168.0.23' ) print ( "Connected to: " , scope . idn ) print ( "Currently displayed channels: " , str ( scope . displayed_channels )) Author

Modern oscilloscopes are often loaded with features, but every now and then you run into a feature that seems easy to implement yet isn’t available. [kgsws] wanted to use his Rigol DS1074 to show live measurements in his YouTube videos, but found out that this scope doesn’t support video output. Not to be deterred, [kgsws] decided to add this feature himself. In the video embedded below, he describes in detail the process of adding a USB Video Capture (UVC) interface to his oscilloscope. note: Nowhere is it written what "sin(x)/x turned off" should be, it's undefined, it's an error condition...)

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All products in the DS1000Z series features a high-quality screen with an excellent easy to use interface that lets you access signal information such as frequency, period, rise time, pulse width and much more! I’ll be using the scope for debugging low speed analog signals and digital protocols/ communication. Standard logic probe for DS1000Z Plus. Upgrades a DS1000Z Plus or DS1000Z-S Plus with 16 digital channels. USB-GPIB Converter. Connect USB directly to instrument and control it via GPIB. This does not connect to a PC directly. Do you know how to harvest data from your bench tools, like plotting bandwidth from your oscilloscope with a computer? It’s actually pretty easy. Many bench tools make this easy using a standard protocol with USB to make the connection.

I need a 4-channel scope mostly when debugging protocols and mainly never use more than 2-channels for just analog use. The ability to easily move between long record lengths, fast capture, a variety of persistence modes, and onboard waveform analysis makes RIGOL's core oscilloscope technology an important capability for engineers from maker projects to large scale R&D.After all the channels finish N samples at the same time, N can be 2, 4, 8, 16, 32, 64, 128, 256, 512 or 1024. Create standard waves from the front panel, convert captured waves to emulated signals, or build arbitrary waves in the UltraStation PC Software. The embedded waveform generators included in the "-S" models adds value and capability to the bench for a variety of applications. DS1000Z-E Datasheet & Specs (Spanish) DS1000Z-E Datasheet & Specs DS1000Z DataSheet & Specs (Spanish) DS1000Z DataSheet & Specs Compare Rigol Product Feature The Rigol DS1054Z represents a remarkable breakthrough in price and performance. It's one of the best general-purpose 4 channel digital storage oscilloscopes available for the maker electronics space.

The basic idea was to find the signals going into the scope’s display and read them out using a Cypress EZ-USB board. This is a development board that can be used to design USB devices, and supports the UVC mode. However, with no documentation of any of the Rigol’s internal circuitry [kgsws] had to probe the display connector to find out which pin carried which signal. And since he had no other scope available than this Rigol, he hooked up the various bits of the disassembled instrument so that it could (awkwardly) probe its own internal signals. The usage of this python script is as simple as plugging the DS1054Z into your USB port and running the script. A PNG of whatever is on the screen then appears on your drive. Testing has been done on OS X, and it probably works on Linux and Windows. It’s a simple tool that does one job, glory and hallelujah, people are still designing tools this way. One of the big differences is that the FFT on the Rigol is joke quality (both the function and the UI) while the one on the Siglent actually works pretty well and is decently configurable. Some others are:In the previous installment of this article we talked about the National Instruments VISA (Virtual Instrument Software Archetecture) standard for communicating with your instruments from a computer, and introduced its Python wrapper with a simple demonstration using a Raspberry Pi. We’ll now build on that modest start by describing a more useful application for a Raspberry Pi and a digital oscilloscope; we’ll plot the bandwidth of an RF filter. We’ll assume that you’ve read the previous installment and have both Python and the required libraries on your machine. In our case the computer is a Raspberry Pi and the instrument is a Rigol DS1054z, but similar techniques could be employed with other computers and instruments. Tired of squinting at the small numbers on the oscilloscope display, [Alfred] aka [Gaze@] decided to take matters into his own hands and wrote yet another tool to remotely view images from a Rigol DS1054Z. At least that was the initial idea. But, it grew unexpectedly — as [Alfred] says, “the more the project turned out to be fun, the more it got out of hand”. We know the feeling well. Products that weigh more than 0.5 KG may cost more than what's shown (for example, test equipment, machines, >500mL liquids, etc).