In a testing device, a method for implementing automatic RF port testing. The method includes attaching a device under test having a plurality of RF pins to a load board, dynamically tuning a plurality of RF ports of the load board to the plurality of RF pins, and automatically matching the plurality of RF ports to the plurality of RF pins with respect to impedance. The method further includes implementing an RF port testing process on the device under test.

A device and method for testing a mixer. For testing, signals having essentially the same frequency are applied to local oscillator (LO) and radio frequency (RF) inputs of the mixer. The signals phase-shifted with respect to each other and an output of the mixer is measured to provide a result.

An apparatus and method for testing equipment is provided. An analog test signal is received by an analog-to-digital converter. The test signal is converted to a digital test signal. The digital test signal is received by a digital processor. The digital test signal is processed and received by a digital memory and a digital-to-analog converter. The processed digital signal is converted to an analog test signal.

A method for measuring modulated radio frequency (RF) signals from a device under test (DUT) includes inputting a test RF signal to the DUT, where the test RF signal is modulated with a repetitive complex waveform and a pulsed waveform, the repetitive complex waveform including multiple RF tones with an RF tone spacing and an RF repetition period, where a pulse width of the pulsed waveform is less than the RF repetition period; acquiring an output RF signal from the DUT responsive to the input test RF signal; down converting the output RF signal to an intermediate frequency (IF) signal; sampling the IF signal using an analog to digital converter (ADC) having an ADC clock frequency; measuring ADC samples of the IF signal; and reconstructing the test RF signal modulated with the repetitive complex waveform using the measured ADC samples.

The present invention discloses a test structure and a method for judging the de-embedding accuracy of RF devices, which comprises testing the S parameters of a target device test structure, an introduced device test structure and an auxiliary test structure, respectively. Then calculating de-embedding S parameters of the target device test structure and the introduced device test structure according to the above-tested results, respectively. Finally, calculating performance parameters of the target device test structure according to the above-calculated de-embedding S parameters. So, the accuracy of the de-embedding method is determined by comparing the consistency of the performance parameters. The present invention can directly judge the de-embedding accuracy and the applicable frequency range of a given de-embedding method by analyzing the testing data. Further, the using of the parallel test structure and the cascade test structure together can increase the reliability of the judgment results.

A time domain reflectometry measurement apparatus and method is provided. Measurement data of a time domain reflectometry measurement are analyzed with respect to previously acquired empirical measurement data of error-free or faulty devices with known failures. In this way, failures can be identified in the device under test without the need of opening the device.

A method for obtaining improved resolution pulsed radio frequency (RF) measurements with phase coherence for a device under test (DUT) using a vector network analyzer (VNA) includes generating a pulsed RF test signal, transmitting the pulsed RF test signal to the DUT and receiving a signal from the DUT at the VNA in response to the pulsed RF test signal. An intermediate frequency (IF) signal is generated using a local oscillator (LO) signal. A phase of the LO signal is shifted by a prescribed amount while generating the IF signal. The IF signal is then sampled over multiple pulses and measurements are constructed from the measurements. A discrete Fourier transform (DFT) is then applied to the constructed measurements.

A testing device includes a connecting module and a processor electrically connected to the connecting module. The connecting module is electrically coupled with a plurality of communication devices under tests (DUTs) synchronously. The processor determines a schedule for the communication DUTs and tests the communication DUTs according to the schedule. A testing method is applied to the testing device to implement the operations.

A probe that enables a circuit board for electronic components, which is a measurement subject, to be disposed more densely. The probe is capable of simultaneously measuring a plurality of locations. The probe includes a plurality of main body portions having central conductors that make contact with connectors, and a first member that binds the plurality of main body portions together. A recess portion, having a base surface from which tip ends of the plurality of central conductors project, is provided in the first member. The recess portion has a sloped surface that flares outward from a base portion of the recess portion toward an opening in the recess portion.

An Apparatus and Method for reliably sorting RFID chips, in inlays, labels, tags or other units of manufacture, into rows and columns, and using that information to report their exact position on a moving web, in support of further manufacturing processes, in the presence of crosstalk, with speed and accuracy exceeding prior art.