A test apparatus for performing a test on a device under test includes a data storage unit being configured to store sets of input data applied to the device under test during the test and to store the respective output data of the device under test, the output data being obtained from the device under test as a response to the input data including values of setting variables related to settings of the device under test and values of input variables including further information, each set of input data representing one test case; and a data processor configured to process the data stored in the data storage unit such that a best combination of setting variables of the device under test is determined for one or more combinations of the input variables to obtain an optimized setting of the device under test for the one or more combinations of the input variables.

An apparatus is provided that includes a control unit and a memory including computer program code. The apparatus is capable of applying a first signal having a first value and a second signal having a second value to an electronic component and receiving a first feedback signal. The apparatus is capable of determining a first parameter associated with the first feedback signal. The apparatus is capable of applying a third signal having a third value and the second signal to the electronic component and receiving a second feedback signal. The apparatus is capable of determining a second parameter associated with the second feedback signal. The apparatus is capable of applying a fourth signal having a fourth value and the second signal to the electronic component if the first parameter is different from the second parameter.

An electronic system test method, comprising: (a)inputting a victim test pattern to a victim signal path of a target electronic system and simultaneously inputting at least one aggressor test pattern to at least one aggressor signal path of the target electronic system, according to a major set of test patterns comprising a plurality of minor set of test patterns; (b)acquiring a output response corresponding to the step (a); and (c)after changing the victim test pattern or the aggressor test pattern, and after repeating the step (a) and the step (b) until all of the major test patterns set are used thereby acquiring a plurality of the output responses, determining a combination level according to the output responses. The victim test pattern is an X bit pattern and the aggressor test pattern is a Y bit pattern, X and Y are positive integers larger than or equal to 3.

In an embodiment a method for testing a digital electronic circuit includes coupling an external test equipment to a digital electronic circuit in order to apply an external voltage signal to the digital electronic circuit when an automatic test pattern generation (ATPG) procedure with a given test pattern is performed, wherein a value of the external voltage signal is controlled by the external test equipment and measuring, at the external test equipment, the digital supply voltage at an output of the voltage regulator and at an input of the internal digital circuitry, wherein the external voltage signal is applied to the differential inputs of the op-amp voltage regulator through an adaptation circuit to obtain determined values of the digital supply voltage.

One embodiment provides a method and a system for generating test vectors for testing a computational system. During operation, the system obtains a design of the computational system, the design comprising an original system. The system generates a design of a fault-augmented system block by adding a plurality of fault-emulating subsystems to the original system; generates a design of an equivalence-checking system based on the original system and the fault-augmented system block; encodes the design of the equivalence-checking system into a logic formula, with variables within the logic formula comprising inputs and outputs of the original system and inputs and outputs of the fault-augmented system block; and solves the logic formula to obtain a test vector used for testing at least one fault in the computational system.

A semiconductor device capable of monitoring a connection state of a terminal on a semiconductor chip includes a selector configured to acquire terminal levels of a plurality of respective terminals on the semiconductor chip to which an inspection pattern is inputted based on a detection signal, a memory configured to store latch data based on a chip address which identifies the semiconductor chip and a plurality of the terminal levels corresponding to the plurality of terminals based on the detection signal, an output circuit configured to read a plurality of pieces of latch data from the memory based on the detection signal and to output the plurality of pieces of latch data, and a timing control circuit configured to generate the detection signal by detecting an edge of a clock inputted during an inspection mode and configured to activate the selector, the memory, and the output circuit.

A device of a data testing environment including a node configured to connect the device to a tester; one or more processors configured to receive from the node an electrical signal alternating between at least a first state and a second state, the first state representing a data transmission trigger and the second state representing a data transmission opportunity; determine a timing of the data transmission opportunity based on the received electrical signal; and send data to the node during the data transmission opportunity in response to receiving the data transmission trigger.

A semiconductor device capable of monitoring a connection state of a terminal on a semiconductor chip includes a selector configured to acquire terminal levels of a plurality of respective terminals on the semiconductor chip to which an inspection pattern is inputted based on a detection signal, a memory configured to store latch data based on a chip address which identifies the semiconductor chip and a plurality of the terminal levels corresponding to the plurality of terminals based on the detection signal, an output circuit configured to read a plurality of pieces of latch data from the memory based on the detection signal and to output the plurality of pieces of latch data, and a timing control circuit configured to generate the detection signal by detecting an edge of a clock inputted during an inspection mode and configured to activate the selector, the memory, and the output circuit.

A semiconductor device comprises a central processing device, a first logical circuit, and a serial memory interface circuit. The first logical circuit has a first scan chain in which a first scan pattern is set, is configured to suppress a leakage current when the first scan pattern for power saving is set in the first scan chain. The serial memory interface circuit is configured to acquire the first scan pattern for power saving from an external storage device. The leakage current of the first logical circuit is suppressed by transferring the first scan pattern for power saving acquired by the serial memory interface circuit to the first logical circuit and setting the first scan pattern for power saving in the first scan chain under control of the central processing device.

A semiconductor device includes a scan input circuit, a master latch, a slave latch, a first inverter, and a scan output circuit. The scan input circuit is configured to receive a scan input signal, a first data signal, and a scan enable signal and select any one of the first data signal and the scan input signal in response to the scan enable signal to output a first select signal. The master latch is configured to latch the first select signal and output a first output signal. The slave latch is configured to latch the first output signal and output a second output signal. The first inverter is configured to invert the second output signal. The scan output circuit is configured to receive a signal output from the slave latch and an external signal and output a first scan output signal.