An integrated circuit device includes general purpose input/output (I/O) circuitry having a transmit level shifter circuit in a transmit I/O circuit and a receive level shifter circuit in a receive I/O circuit. The integrated circuit device also includes an I/O pad which couples an output of the transmit level shifter circuit to an input of the receive level shifter circuit, a counter circuit, an inverter circuit coupled between the receive level shifter circuit and the counter circuit, and a logic gate. The logic gate includes a first input coupled to an output of the inverter circuit, a second input coupled to a counter_done signal from the counter circuit, and an output coupled to provide a data_out signal to an input of the transmit level shifter circuit.

The present disclosure provides a method and a system for testing semiconductor device. The method includes providing a device under test (DUT) having an input terminal and an output terminal; applying a voltage having a first voltage level to the input terminal of the DUT during a first period; applying a stress signal to the input terminal of the DUT during a second period subsequent to the first period; obtaining an output signal in response to the stress signal at the output terminal of the DUT; and comparing the output signal with the stress signal. The stress signal includes a plurality of sequences, each having a ramp-up stage and a ramp-down stage. The stress signal has a second voltage level and a third voltage level.

The present application discloses a method and apparatus for calculating the kink current of SOI device, which is used to solve the problem that the kink current calculation in the prior art is not accurate and is not suitable for circuit simulation. The method includes: obtaining the impact ionization factor, the parasitic transistor effect factor, and the drain saturation current of the SOI device respectively; and calculating the kink current of the SOI device according to the impact ionization factor, the parasitic transistor effect factor, and the drain saturation current.

Circuits and methods for testing voltage monitor circuits are provided. In one embodiment, a method includes setting voltage monitor circuits to test mode; setting, a monitor reference in each voltage monitor circuit, to a respective targeted threshold voltage using a corresponding trim code; ramping, a voltage provided to a subset of voltage monitor circuits, from a first voltage to a second voltage using a test voltage supply, voltages between the first voltage and the second voltage corresponding with targeted threshold voltages of the subset of voltage monitor circuits; determining, for each voltage monitor circuit in the subset of voltage monitor circuits, a voltage value of the test voltage supply resulting in a change in a logic state at an output of a corresponding voltage monitor circuit.

A full load test system of an electrical power converter and the test method thereof is disclosed. The full load test method of the electrical power converter comprises the following steps: (a) providing a power converter under test (PCUT); (b) configuring the PCUT in/on a test circuit; (c) serially connecting the PCUT with at least one bidirectional power converter in the test circuit; (d) connecting the test circuit to an alternating current low voltage three-phase power source; and (e) performing a test of the PCUT under full-load condition.

The present invention relates to processor testing technology, specifically relating to a method for automatically testing a processor, the method comprising: S1, carrying out test preparation; S2, setting an operation voltage and a clock frequency of a processor to be tested; S3, carrying out load testing at the current operation voltage and clock frequency; S4, determining whether the processor is normal during current load testing; if yes, then turning to step S5; if no, then raising the current operation voltage by a first growth value and returning to step S2; and S5, recording an operation voltage, subject to load testing, which corresponds to the current clock frequency as a test result and determining whether the current clock frequency reaches an upper limit; if yes, then ending the operation; if no, then raising the current clock frequency by a second growth value and returning to step S2. The described method is capable of implementing the automatic testing of processors and rapidly and effectively obtaining operation voltages corresponding to clock frequencies when the processors are operating normally, and is thus suitable for a plurality of platforms.

An apparatus comprising: a functional circuit comprising one or more circuit components configured to perform a function based on one or more first input signals; at least one failure-prediction circuit for use in predicting failure of the functional circuit, the failure-prediction circuit comprising a replica of the functional circuit in terms of constituent circuit components; wherein the failure-prediction circuit is configured to be more susceptible to failure than said functional circuit, wherein the apparatus is configured to provide a prediction of failure of the functional circuit based on a determination of failure of the failure-prediction circuit.

Obtaining a periodic test signal, sampling the periodic test signal using a sampling element according to a sampling clock to generate a sampled periodic output, the sampling element operating according to a supply voltage provided by a voltage regulator, the voltage regulator providing the supply voltage according to a supply voltage control signal, comparing the sampled periodic output to the sampling clock to generate a clock-to-Q measurement indicative of a delay value associated with the generation of the sampled periodic output in response to the sampling clock, generating the supply voltage control signal based at least in part on an average of the clock-to-Q measurement, and providing the supply voltage to a data sampling element connected to the voltage regulator, the data sampling element being a replica of the sampling element, the data sampling element sampling a stream of input data according to the sampling clock.

In an embodiment, a method includes filtering, with a low-pass filter, a voltage signal (V.sub.dd) of a chip to create a filtered signal (V.sub.ref). The method further includes dividing V.sub.ref by a given factor. The method further includes determining whether a voltage droop occurred in V.sub.dd by comparing V.sub.dd to the divided V.sub.ref. The method further includes outputting a droop detection signal if V.sub.dd is less than the divided V.sub.ref. In an embodiment, dividing V.sub.ref by the given factor includes selecting, with a multiplexer, one of a plurality of divided V.sub.ref signals outputted by a voltage divider. The selecting is based on a selection signal.

An apparatus for testing components for use in a power system includes at least one power amplifier circuit configured to be coupled to the component and a control circuit configured to operate the power amplifier circuit responsive to at least one state of a component emulator for the component included in a system emulator for the power system. The component emulator may include at least one power electronics converter circuit and the control circuit may be configured to control at least one of a voltage and a current of the at least one power amplifier circuit responsive to at least one of a voltage and a current of the at least one power electronics converter circuit. The control circuit may be further configured to control the component emulator responsive to at least one state of the at least one power amplifier circuit.