Fast analysis of sporadic errors with the history function and 160/460 Msample memory

Long acquisitions at maximum resolution with the history function

Your requirements

Single shot versus segmented acquisition

Sporadic errors cost valuable time during the development of new products. Debugging protocol-based buses is especially difficult and time-consuming because the communications pauses between the individual data packets can be very long. For example, a sensor will send a value over an I2C bus only once per minute. The oscilloscope memory typically limits the record length for analyzing errors and their history to a few milliseconds.

T&M solution

A deep, segmented memory combined with dedicated trigger conditions solves this problem by permitting the acquisition of relevant sequences without long pauses. Equipped the R&S®RTB-K15 and the R&S®RTM-K15 options, this is exactly what the R&S®RTB2000 and the R&S®RTM2000 offer.

Single shot

Long data sequences are usually acquired in a seamless single shot. The maximum record length depends on the available memory and the selected sampling rate. With a maximum record length of only a few milliseconds, acquisition is often limited to a single protocol packet.

Limiting the acquisition to active signal elements only

During signal acquisition with segmented memory, the available memory is divided into segments, each with a defined number of samples. The user defines the length of the segments based on the maximum packet length in the signal. At the trigger point, the signal segment of interest is stored in memory along with the trigger timestamp. Time periods without activity are not acquired.

The R&S®RTM2000 offers an additional ultra-segmented mode. When this mode is activated, immediate postprocessing and display of the signal are suppressed, reducing the blind time between two acquisitions to a minimum. The acquired data is analyzed at a later time.

Segmented memory setting

History and segmented memory

Equipped with the R&S®RTB-K15 and the R&S®RTM-K15 options, the R&S®RTB2000 and the R&S®RTM2000 offer a history function with a segmented memory of 160/460 Msample per channel that is unique in this class, covering both analog and digital channels. The memory can be divided into several steps (see table). When the ultra-segmented mode is activated, the blind time on the R&S®RTM2000 is reduced to less than 5 μs.

In history mode, all acquisitions can be analyzed at a later time. A highly precise timestamp permits precise time correlation of signal events. Individual marked segments can be selected in the acquisition table for display. Alternatively, the history function can be used to automatically play back all segments. All R&S®RTB2000 and R&S®RTM2000 measurement tools, including the QuickMeas function, mask tests and protocol decoding, are available for analyzing the faulty segment.

Easy configuration and fast results

The I²C signal in the figure shows protocol packets approximately 500 μs in length. These protocol packets are interrupted by communications pauses of one minute. Activating the R&S®RTB-K1/RTM-K1 protocol decoding option quickly shows that a segment length of 10 ksample (20 Msample/s sampling rate) is sufficient for reliably decoding and detecting typical signal faults. The user sets this value, and the option automatically calculates how many segments are available. In the example, there are 45 000 segments, which corresponds to a maximum record length of one month.

Decoded I²C signal with analog waveforms on the R&S®RTM2000.

Previous acquisitions can be accessed by pressing the history function button – both during or after the acquisition. Standard mask tests and the navigation options provided by the history function help users to quickly identify signal faults and their causes. In the example, a glitch in the system clock signal several packets before the faulty packet was the key to identifying the cause of the error. The timestamp shows that the error occurred periodically (always in the morning). Systematic tests confirmed that inadequate shielding on the line caused it to pick up a pulse generated when the lab's fluorescent lights were switched on. The problem was solved by improving the shielding.

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