A stand for receiving a portable test and measurement instrument includes a base plate, a first portion extending orthogonally from the generally flat base, the first portion including one or more holes spaced in a pattern through which one or more fasteners may attach the test and measurement instrument to the stand, and a second portion adjacent to and extending at an angle from the first portion, the second portion including one or more holes spaced in a pattern through which one or more fasteners may attach the test and measurement instrument to the stand.

A test and measurement instrument includes a spectrogram generator for producing a first spectrogram image from an input signal, a display for showing the spectrogram image, and a user interface operating in conjunction with the display, the user interface including one or more user controllable inputs and the user interface configured to detect a user action, where the spectrogram generator is structured to produce a second spectrogram image, different from the first spectrogram image, based on the detected user action by the user interface. Methods of automatically generating spectrograms based on user actions are also described.

A test and measurement instrument includes an input port for accepting an input signal for measurement, a display having a first window for showing measurements of the input signal in a time domain, and having a second window for showing measurements of the input signal in a frequency domain, where the time domain of the first window and the frequency domain of the second window are related through a transform having a pre-determined resolution bandwidth, a cursor generator structured to generate a cursor at a specific location in time in the first window, a spectral generator to produce a spectral display of a portion of the input signal that is centered around the cursor and has the pre-determined resolution bandwidth, and an image generator configured to present the generated spectral display in the second window. Methods of generating spectral displays based on user-defined cursor locations are also described.

A system and method are provided for displaying input signals from a DUT on a display screen. The method includes sending a data stream of digitized data received from the DUT to an FPGA for serial decoding; receiving decoded symbols from the FPGA; identifying valid symbols among the decoded symbols indicating transitions between the decoded symbols; storing the valid symbols with corresponding time-tags as valid packets in memory, and discarding ones of the decoded symbols occurring between the valid symbols; and plotting on the display screen the valid packets occurring between beginning and ending valid packets of the stored valid packets. The beginning valid packet has a corresponding time-tag occurring immediately before a first point time-tag associated with a left edge of the display screen, and the ending valid packet has a corresponding time-tag occurring at or immediately before a last point time-tag associated with a right edge of the display screen.

Methods of triggering a test and measurement instrument having a plurality of inputs include the step of generating a trigger signal in response to every occurrence of any one of a plurality of specified trigger events. A first specified trigger event occurs in at least a first one of the inputs and a second specified trigger event occurs in at least a second one of the plurality of inputs. A specified trigger event may include at least one selected input from the plurality of inputs and a selected activity type. Some methods include configuring each of a plurality of event activity detectors to produce a pulse in a logic signal in response to every occurrence of one of the specified trigger events. The plurality of logic signals are combined in a logical OR circuit to generate the trigger signal. Trigger circuits configured according to these methods are also disclosed.

A test and measurement instrument including a signal generator configured to generate a waveform to be sent over a cable to a device under test (DUT) and a real-time waveform monitor (RTWM) circuit. The RTWM is configured to determine a propagation delay of the cable, capture a first waveform, including an incident waveform and a reflection waveform at a first test point between the signal generator and the DUT, capture a second waveform including at least the incident waveform at a second test point between the signal generator and the DUT, determine a reflection waveform and the incident waveform based on the first waveform and the second waveform, and determine a DUT waveform based on the incident waveform, the reflection waveform, and the propagation delay. The DUT waveform represents the waveform generated by the signal generator as received by the DUT.

The invention relates to a method for diagnosing a fieldbus type network. The method comprises the steps of measuring, using a signal measuring device such as an oscilloscope, a bus signal of the fieldbus type network, providing the measured bus signal to a computer system, and generating, by the computer system, a diagnosis. The diagnosis is performed by executing a step of comparing, by the computer system, the measured bus signal with signals in a database of bus signals and corresponding diagnoses; and/or feeding, by the computer system, the measured bus signal to a trained statistical model trained to diagnose the fieldbus type network; as well as a step of outputting the diagnosis based on the output of the comparison and/or the output of the statistical model.

Methods and apparatus are described for detecting anomalies in a clock signal. Example methods include sensing a clock signal that exhibits alternating phases during normal operation; responsive to sensing the start of a first phase, generating a pulse; and if the pulse terminates before sensing the end of the first phase, asserting a clock stopped detection signal. Example clock anomaly detection apparatus includes a clock signal input for coupling to a clock signal that, during normal operation, oscillates between first and second clock states. An anomaly detection output is asserted if the clock signal remains in the first clock state longer than a first phase expected duration or remains in the second clock state longer than a second phase expected duration.

The disclosure relates to a test and measurement instrument. The test and measurement instrument comprises a digitizer for digitizing an analog input signal, thereby generating a digitized input signal. The test and measurement instrument also has a digital trigger for detecting a trigger event in the digitized input signal. The test and measurement instrument also comprises an acquisition memory for acquiring the digitized input signal at least segmentally upon a first trigger event detected by the digital trigger. The acquisition memory is configured to acquire a first signal segment prior to the first trigger event. The acquisition memory is further configured to acquire a second signal segment starting at the first trigger event. The length of the second signal segment is dynamically adjustable. Moreover, a method of analyzing an input signal by a test and measurement instrument is described.

A measurement apparatus and a method for controlling a measurement apparatus is provided. The measurement apparatus comprises an ultrasonic sensor for receiving a further user input. The further user input may be used to identify a specific user. Accordingly, the measurement apparatus can be automatically configured based on data related to the identified user. Since the ultrasonic sensor may be operated even if the ultrasonic sensor is covered by a protecting element, the robustness of the measurement apparatus can be further improved.