May I revisit this older thread? I have just started to work my way through Rudi's very helpful series of videos -- mainly with an interest in the hands-on demonstration of the SDS2104X plus, which I'm seriously considering as my next scope.
One thing that struck me in episode #4 (Measurements) is that the SDS came out last, by an order of magnitude (!), regarding the speed of collecting measurement statistics. See the attached table and the video linked below. Given how the strength of quantitative measurements and analysis is always stressed when discussing the Siglent scopes (and their LeCroy role models), I had not expected this.
I did not find any comments on this in the present thread. Is the slow measurement update rate just a reality with the SDS2000X plus? Are there some memory or acquisition settings that should be changed to get much faster measurements? Has anything been improved in recent firmware updates?
Thanks for your comments!
You have already named it – this is a MSO with main focus on analytic capabilities. Of course there is a difference between analytic scopes, which require deep measurements, and standard scopes, which prioritize speed and try to measure (estimate would be more appropriate) on heavily decimated data. To understand this, here’s a simple example:
SDS2354X_Plus_Meas_Pulse_10Mpts
This screenshot shows just a pulse train. Pulse width is 10 µs, transition times are ~1 ns and repetition rate is 4 kHz. At a time base of 500 µs/div and 2 GSa/s, this results in a record length of 10 Mpts. The key parameters of the pulse train shall be measured: period, amplitude, rise and fall times and pulse width. Everything is measured reasonably correctly. Of course, at 2 GSa/s this scope isn’t fast enough to measure a 1 ns transition time precisely, yet it’s well within reasonable expectations. For more accurate measurements on such short time intervals, we’d have to zoom in up to the point, where sin(x)/x reconstruction calculates additional data points. We cannot use a much faster timebase right from the start, because at faster time bases we lose the measurements, one by one: At < 25 µs/div we could not measure the period anymore, at <1 µs/div we lose the pulse width measurement and can only measure a single transition, I.e. either the rising or the falling edge.
Now try the same exercise with the fast Keysight, which uses 64 kpts decimated data – good luck!
It is worth to take a closer look at this screenshot. We see advanced measurements in M1 mode, where statistics and Histicons (small histogram icons) are enabled. If we look at the “count” in the measurement statistics, it becomes obvious that only the vertical (amplitude) related measurements appear to be slow. For the time measurements, the scope analyzes the entire record, hence a single acquisition yields some 20 measurements of period, rise and fall times and pulse width. It just so happened that not a single time related measurement was shown in this comparison.
Apart from that the SDS2000X Plus firmware has seen a few optimizations since this comparison. My measurements yielded at least twice the speed as the numbers found in this review. If I make the conditions a bit more equal, then the vertical measurement rate reaches >16 measurements per second if I reduce the record length to 100 kpts, thus getting into the ballpark of the measurements on decimated data of the competing instruments.
Furthermore we have these M1 and M2 measurement modes (limited to max. 12 measurements) only in the “advanced measurements” mode. But there is also a “simple” mode, which allows a lot more than just 12 measurements in parallel:
SDS2354X_Plus_Meas_Simple
You should be able to count not 6, also not 12 but no less than 52 measurements at once. The glitch, that the measurement window closes as soon as we select an item (so that we cannot read the help text and have to re-open the window if we need to add more measurements) is long fixed either.
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