A signal processing method is provided. The signal processing method is used in a Gigabit Ethernet system including a device under test (DUT) and a link partner (LP), and includes the following steps. Firstly, an interference detector is configured to detect whether the Gigabit Ethernet system is interfered by other signal sources. Next, a physical layer (PHY) of the DUT or a PHY of the LP is used to, in response to the Gigabit Ethernet system being interfered by the other signal sources, set a request signal indicating whether or not the physical layer enters a low power idle (LPI) mode as FALSE. Which PHY of the DUT and the LP is used to set the request signal indicating whether or not the PHY enters the LPI mode as FALSE depends upon which one of the DUT and the LP is provided with the interference detector.

An automated test equipment for testing devices under test is configured to combine different output signals from multiple pins of a single device under test or from pins of a plurality of devices under test to obtain a combined signal; and to extract individual signals or properties of the individual signals from the combined signal.

A test system has ovens configured to hold devices under test (DUTs), DUT switches, each connected to the DUTs in an oven, splitters, each splitter connected to a DUT switch, an instrument switch connected to one output of each splitter, the other output of each splitter connected to a test instrument, and one or more processors to control the instrument switch to select one of the DUT switches connected to an oven, control the selected DUT switch to connect each DUT in the oven to a channel of the test and measurement instrument, use machine learning to tune the DUT to a set of parameters until the DUT passes or fails, repeat the connecting, tuning, and testing of each DUT until all DUTs in an oven have been tested, and repeat the selection and control of the DUT switches until each DUT in each oven has been tuned and tested.

An automated test equipment comprises a main test flow control configured to operate a test flow in multiple device communication units and/or to provide the trigger configuration information to a local compute unit. The automated test equipment further comprises a device communication unit comprising a trigger generation unit configured to generate a trigger signal. The trigger generation unit further configured to extract payload data from a protocol-based data stream received from the device under test, and to generate the trigger signal in response to the extracted payload data or in response to one or more protocol events. A method and a computer program for testing one or more devices under test in an automated test equipment are also disclosed.

Apparatus for testing an integrated circuit is described, including a set of signal conductors for communicating signals to respective external conductors of the integrated circuit. The apparatus also includes a tester comprising circuitry for outputting a signal. An interposer is electrically coupled between the set of signal conductors and the tester. The interposer comprises circuitry for selecting a set of signals between the set of signal conductors and the tester and outputting the set of signals. A signal processing apparatus is coupled to receive the set of signals, and the signal processing apparatus is operable to evaluate a parameter associated with each signal in the set of signals.

A board adapter device includes: a first adapter structure provided with a gold finger matched with a board of a target memory module, a second adapter structure provided with a connector matched with the gold finger, and a signal transmission structure including a first and second transmission module. The first transmission module is for connecting a data signal line, a clock signal line, an address signal line, and a control signal line of the gold finger to corresponding connecting lines of the connector. The second transmission module is configured to, when receiving a power input signal, convert the power input signal into a power output signal matched with a power supply of the target memory module, and transmit the power output signal to a power signal line of the connector.

Embodiments relate to a system, program product, and method for integrating compiler-based testing in post-silicon validation. The method includes generating a test program through a device-under-test (DUT). The method also includes generating a plurality of memory intervals and injecting the plurality of memory intervals into the test program. The method further includes injecting a plurality of compiled test snippets into the test program and executing one or more post-silicon validation tests for the DUT with the test program.

Device under test (DUT) simulation equipment includes: a first circuit board including a first field programmable gate array (FPGA); a second circuit board including a processor; and a power distribution board, wherein the first circuit board is connected to the power distribution board, and the power of the first circuit board is supplied by the power distribution board, wherein the second circuit board is connected to the power distribution board, and the power of the second circuit board is supplied by the power distribution board, wherein when the DUT simulation equipment is connected to a tester to perform testing, the DUT simulation equipment simulates the performance of a DUT providing a response signal after receiving a test signal from the tester, and wherein, in the DUT simulation equipment, only the first circuit board receives the test signal from the tester, and the second circuit board controls the first circuit board by means of a control signal.

A new test system includes a programmed device having an input port for receiving a signal for testing or measuring on the programmed device, and a reprogrammable test accessory having an output coupled to the input port of the programmed device. The reprogrammable test accessory further includes a test port structured to accept one or more test signals from a Device Under Test (DUT), and a reprogrammable processor. The reprogrammable processor may further include reprogrammable standards and protocols, reprogrammable triggers and margin detection, reprogrammable link training, reprogrammable handshaking, and reprogrammable setup and control facilities for either or both of the DUT and the programmed device.

Presented embodiments facilitate efficient and effective diagnostic of test system operations, including temperature control of test equipment components. In one embodiment a test equipment diagnostic method includes applying a known/expected first bit pattern to a test equipment component, applying a known/expected second bit pattern to a test equipment component, and performing a test equipment temperature control analysis based upon the results of applying the known/expected first bit pattern and known/expected second bit pattern. The first bit pattern and second bit pattern have known/expected respective thermal loads and corresponding respective first known/expected/expected temperature and second known/expected/expected temperature. In one embodiment, performing a test equipment temperature control analysis includes determining if temperature control components control a temperature of the test equipment component within acceptable tolerances. In one exemplary implementation, the test equipment component is a test control component (e.g., a field programmable gate array (FPGA), etc.).