Abstract: A method and apparatus are provided for calculating s-parameters of a device under test from step waveforms acquired by a time domain network analyzer.

Abstract: A system for estimating bit error rates (BER) may include using a normalization factor that scales a BER to substantially normalize a Q-scale for a distribution under analysis. A normalization factor may be selected, for example, to provide a best linear fit for both right and left sides of a cumulative distribution function (CDF). In some examples, the normalized Q-scale algorithm may identify means and probabilistic amplitude(s) of Gaussian jitter contributors in the dominant extreme behavior on both sides of the distribution. For such contributors, means may be obtained from intercepts of both sides of the CDF(Qnorm(BER) with the Q(BER)=0 axis, standard deviations (sigmas) may be obtained from reciprocals of slopes of best linear fits, and amplitudes may be obtained directly from the normalization factors. In an illustrative example, a normalized Q-scale algorithm may be used to accurately predict bit error rates for sampled repeating or non-repeating data patterns.

Abstract: A method is provided which measures PCB trace characteristics from measurements of a PCB trace structure.

Abstract: A method for improving bandwidth of an oscilloscope involves, in preferred embodiments, the use of frequency up-conversion and down-conversion techniques. In an illustrative embodiment the technique involves separating an input signal into a high frequency content and a low frequency content, down-converting the high frequency content in the analog domain so that it may be processed by the oscilloscope's analog front end, digitizing the low frequency content and the down-converted high frequency content, and forming a digital representation of the received analog signal from the digitized low frequency content and high frequency content.

Abstract: A method for improving bandwidth of an oscilloscope involves, in preferred embodiments, the use of frequency up-conversion and down-conversion techniques. In an illustrative embodiment the technique involves separating an input signal into a high frequency content and a low frequency content, down-converting the high frequency content in the analog domain so that it may be processed by the oscilloscope's analog front end, digitizing the low frequency content and the down-converted high frequency content, and forming a digital representation of the received analog signal from the digitized low frequency content and high frequency content.

Abstract: A method is provided for de-embedding measurements from a given network containing mixtures of devices with known and unknown S-parameters given a description of the network and the known S-parameters of the overall system.

Abstract: A method and apparatus for determining a trigger in a test and measurement apparatus are provided. The method comprises the steps of loading a first trigger configuration to a first trigger element of the test and measurement apparatus and loading a second trigger configuration to a second trigger element of the test and measurement apparatus so that these trigger elements operate substantially simultaneously, It is then determined whether the input signal generates a trigger in accordance with the one or more trigger configurations.

Abstract: A method and apparatus for displaying information on a device acquiring data is provided. The method includes the steps of receiving an input data, generating a version of the received input data to be displayed in accordance with one or more display parameters and displaying the generated version of the received input data. A requested change in one or more display parameters is received and the requested change of the one or more display parameters is implemented on the displayed data. Processing continues on the further received input data in accordance with the requested change in the one or more display parameters and the display is ultimately updated with the processed further received input data.

Abstract: A method and an apparatus for performing link equalization testing via a physical layer test and measurement system. The system includes a protocol aware test apparatus for transmitting testing data, a device under test for receiving the transmitted testing data, and an oscilloscope for receiving an output waveform from the device under test. The protocol aware test apparatus selects a first of a plurality of preset values, sends an equalization signal from the protocol aware test apparatus to the device under test, and changes a speed of communication to a predetermined speed and sends a compliance pattern to the device under test after placing the device under test in a loopback mode. A waveform output from the device under test is captured by the oscilloscope, and is analyzed to determine compliance of the device under test with a predetermined link equalization speed in accordance with a predetermined protocol.

Abstract: A locater tool for positioning a support device for supporting a test probe head or a test probe tip, the locater tool including a template, means for indicating a support device position associated with the template, and means for indicating an achievable probing zone on a surface having connection points when the support device is in the support device position. The locater tool may be a device-attachable locater tool or a pre-positioning locater tool.

Abstract: A system and method for performing a time domain reflectometry measurement. The system includes a coherent interleaved sampling timebase, a sampling strobe generator for generating one or more sampling strobes in accordance with the coherent interleaved sampling timebase, a time domain reflectometry sampling strobe generator for generating one or more time domain reflectometry strobes in accordance with one or more of the generated sampling strobes; and a sampling module for sampling a time domain reflectometry signal in accordance with one or more of the one or more generated sampling strobes and one or more of the one or more generated time domain reflectometry strobes. The system further includes an analog to digital converter for analog to digital converting the samples of the time domain reflectometry signal and a memory for storing the converted samples of the time domain reflectometry signal.

Abstract: A method and apparatus for determining a trigger in a test and measurement apparatus are provided. The method includes the steps of indicating one or more anomalies to be found, loading a first trigger configuration to the test and measurement apparatus and determining for a first predetermined time period whether an input signal generates a trigger related to one or more of the one or more anomalies. A second trigger configuration is loaded to the test and measurement apparatus upon the conclusion of the first predetermined time, and for a second predetermined time it is determined whether the input signal generates a trigger related to one or more of the one or more anomalies.

Abstract: A method and an apparatus for testing the physical layer of high speed serial communication devices and systems with protocol awareness is disclosed. The apparatus comprises of two major blocks: a General Purpose Platform (GPP) and an Analog Front End (AFE). Physical layer testing is divided into two sets of testing procedures: Receiver and Transmitter testing. This test system can be used in a traditional BERT setting where the test system commands the Device Under Test (DUT) to be placed into either a loop back mode, or into a more advanced mode where the test system is communicating with the DUT on a protocol level and counts the frame error ratio (FER). This FER is protocol dependent and each protocol receiver has its own way of reporting transmission errors to the transmitter. The protocol awareness of this invention is capable of detecting such a level of errors.

Abstract: In exemplary embodiments, a waveform processor system may update pixel state information as a function of current pixel state information (e.g., intensity, color) by comparing a randomized value to a set of predetermined threshold values that correspond to different permitted pixel states. In an illustrative example, each time a display screen is updated, the image may represent multiple (e.g., 2000) triggered sweeps of the waveform. For each triggered sweep, the waveform data is associated with specific pixels on the display screen. To determine how to update each pixel's state (e.g., brightness, color) for the next screen update, each waveform hit on a pixel may initiate a comparison between a randomized value (e.g., pseudorandom number) and the predetermined threshold value for the pixel's current pixel state. In some examples, the pixel state may be increased to the next level if the randomized value exceeds the predetermined threshold value.

Abstract: Apparatus and associated systems and methods may relate to a data traffic modification system that may receive operating code developed using a graphical user interface (GUI) that permits substantially real-time editing of instructions that have been determined to include errors. In various implementations, a data traffic modification device may selectively modify data traffic upon the occurrence of a predetermined condition. In one illustrative example, operating code may be developed by sequentially editing individual instructions. Upon modifying each instruction, the validity of the operating code with the edited instruction may be checked, and the GUI may display the updated code substantially in real time during an editing session. The GUI may display an indication of the validity status of the set of instructions. In some embodiments, the user may be permitted to continue editing the code within the GUI while the set of instructions contains errors.