A memory controller instantiated on a semiconductor IC device comprises a timing circuit to transfer a timing signal, the timing circuit being configured to receive a first test signal and to effect a delay in the timing signal in response to the first test signal, the first test signal including a first timing event. The memory controller further comprises an interface circuit configured to transfer the data signal in response to the timing signal, the interface circuit being further configured to receive a second test signal and to effect a delay in the data signal in response to the second test signal, the second test signal including a second timing event that is related to the first timing event according to a test criterion.

Herein disclosed are an electronic component testing system and a time certification method. The electronic component testing system comprising a testing device and an interface device. The testing device comprises a backboard, and the backboard electrically connected to at least one test board and comprising a time certification component. The interface device, electrically connected to the testing device, provides a test instruction. Wherein the time certification component stores an authorization start time and an authorization end time. Wherein the testing device starts a test procedure according to the test instruction, the time certification component updates the authorization start time to a first stop time of the test procedure after the test procedure is completed.

The timing margin of various signal paths in an integrated circuit is monitored by components on the integrated circuit itself. Path margin monitor (PMM) circuits on the integrated circuit receive (a) functional signals propagating along signal paths in the integrated circuit, and (b) corresponding clock signals that are used to clock the functional signals. The PMM circuits output signals (PMM signals) which are indicative of the actual timing margins for the signal paths. For convenience, these will be referred to as path margins. A controller is also integrated on the integrated circuit. The controller controls the PMM circuits. It also receives and analyzes the PMM signals to monitor the path margins across the integrated circuit. Automated software is used to automatically insert instances of the PMM circuits into the design of the integrated circuit. The controller may also be automatically configured and inserted into the design.

A testing system includes a signal generator circuit, a jitter modulation circuit, and an oscilloscope circuit. The signal generator circuit is configured to generate a clock pattern signal with a single clock pattern frequency. The jitter modulation circuit is configured to generate a jitter signal. A device-under-test is configured to receive an input signal. The input signal is a combination signal of the clock pattern signal and the jitter signal. The device-under-test includes a clock data recovery circuit and is further configured to generate an output signal according to the input signal. The oscilloscope circuit is configured to receive the output signal for determining performance of the clock data recovery circuit.

An in-circuit emulator device includes a CPU that generates a first address signal by executing a program in synchronization with a first clock signal, a real-time capture circuit that generates a second address signal in synchronization with a second clock signal having a higher frequency than the first clock signal, and a selector circuit that supplies the second address signal to a storage device during a first period of one cycle of the first clock signal, and supplies the first address signal to the storage device during the remaining second period. The storage device reads data from a storage location of an address identified by the second address signal while the second address signal is supplied, and writes data from the CPU to a storage location of an address identified by the first address signal or reads data from said storage location while the first address signal is supplied.

A semiconductor IC device comprises a timing circuit to transfer a timing signal, the timing circuit being configured to receive a first test signal and to effect a delay in the timing signal in response to the first test signal, the first test signal including a first timing event. The semiconductor IC device further comprises an interface circuit configured to transfer the data signal in response to the timing signal, the interface circuit being further configured to receive a second test signal and to effect a delay in the data signal in response to the second test signal, the second test signal including a second timing event that is related to the first timing event according to a test criterion.

A synchronization circuit includes a first synchronizer, a second synchronizer, and selection circuitry. The first synchronizer is configured to synchronize a received signal to a clock signal. The second synchronizer is disposed in parallel with the first synchronizer and configured to synchronize the received signal to the clock signal. The selection circuitry is coupled to the first synchronizer and the second synchronizer. The selection circuitry is configured to provide an output value generated by the first synchronizer at an output terminal of the synchronization circuit based on the output value generated by the first synchronizer being the same as an output value generated by the second synchronizer.

A testing circuitry includes an on-chip clock controller circuit and a first clock adjustment circuit. The on-chip clock controller circuit is configured to generate an internal clock signal in response to a reference clock signal, a scan enable signal, a plurality of enable bits, and a scan mode signal, and generate a first control signal in response to the scan enable signal, a plurality of first bits, and the reference clock signal. The first clock adjustment circuit is configured to generate a first test clock signal according to the first control signal and the internal clock signal, in order to test a multicycle path circuit. The plurality of first bits are to set a first pulse of the first test clock signal, in order to prevent the multicycle path circuit from occurring a timing violation.

[Problem] To monitor a frequency difference between an input clock and a synchronous clock synchronized with the input clock. [Solution] A clock frequency monitoring apparatus that monitors the frequency of an input clock 18a includes a phase comparator 12 that compares a phase of a synchronous clock 18e phase-synchronized with the input clock 18a or a first frequency-divided clock 18f obtained by frequency-dividing the synchronous clock 18e with the phase of the input clock 18a, a filter 13 that low-pass filters an output signal of the phase comparator 12, an oscillator 14 that generates the synchronous clock 18e having a frequency corresponding to a control value from the filter 13, and a determiner 19 that determines that the frequency of the input clock 18a is abnormal when the variation amplitude of the output signal of the filter 13 is equal to or more than a predetermined range.

A semiconductor IC device comprises a timing circuit to transfer a timing signal, the timing circuit being configured to receive a first test signal and to effect a delay in the timing signal in response to the first test signal, the first test signal including a first timing event. The semiconductor IC device further comprises an interface circuit configured to transfer the data signal in response to the timing signal, the interface circuit being further configured to receive a second test signal and to effect a delay in the data signal in response to the second test signal, the second test signal including a second timing event that is related to the first timing event according to a test criterion.