A circuit for implementing a scan chain in an integrated circuit having a clock domain crossing is described. The circuit comprises a first dual-edge storage circuit configured to receive an input signal at a scan input and to receive a first clock signal in a first clock domain at a clock input; a storage element having a data input configured to receive an output of the first dual-edge storage circuit; a second dual-edge storage circuit configured to receive an output of the storage element at a scan input and to receive a second clock signal in a second clock domain at a clock input; and a pulse generator configured to provide, to a clock input of the storage element, a pulse signal having a pulse width selected to enable the second dual-edge storage element to store the output of the first dual-edge storage element.

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 digital circuit robustness verification method is provided that includes the following steps. An internal storage circuit and an external storage circuit corresponding to a circuit under test are set to store a plurality of random values and a configuration of the circuit under test for performing a predetermined function is set by a processing circuit. A driving signal corresponding to the predetermined function is transmitted to the circuit under test by a previous stage circuit, such that the circuit under test executes the predetermined function to further generate an output signal. The determination as to whether the output signal is correct or not is made by a next stage circuit, and the circuit under test is determined to pass a robustness verification when the output signal is correct.

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.

Systems, integrated circuits and methods for synchronizing testing a Device under test (DUT) with an automated test equipment (ATE) is provided. In one example, a method includes transmitting a test packet from an ATE to a first Device Under Test DUT; receiving, at the ATE from the DUT, a result packet; and in response to receiving a Start of Packet (SOP) indicator from the DUT at the ATE, evaluating the first DUT by comparing the result packet to an expected packet associated with the test packet.

A method and apparatus for determining jitter, a storage medium and an electronic device are disclosed. The method for determining jitter includes: determining a plurality of measurement time points for an output signal from an integrated circuit (IC); identifying one or more jitter points from the plurality of measurement time points by comparing the output signal with a predetermined signal at the plurality of measurement time points; and determining a jitter of the output signal of the IC based on the one or more jitter points. The jitter of the output signal of an IC chip can be determined without relying on any other additional equipment.

One embodiment of the present disclosure describes a memory system that may include one or more memory devices that may store data. The memory devices may receive command signals to access the stored data as a loopback signal. The memory devices may operate in a normal operational mode, a loopback operational mode, a retrieval operational mode, a non-inverting pass-through operational sub-mode, and an inverting pass-through operational sub-mode. The operational modes facilitate the transmission of the loopback signal for the purpose of monitoring of memory device operations. A selective inversion technique, which uses the operational modes, may protect the loopback signal integrity during transmission.

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.

An electric meter that is configured to regenerate meter state data after a power loss includes a memory with at least one volatile and non-volatile memory device and a processor connected to the memory. The processor is configured to retrieve a backup copy of meter state data and a plurality of meter input data samples that were generated after the backup copy of the meter state data and prior to the power loss from a nonvolatile memory device. The processor is configured to regenerate meter state data by updating the backup copy of meter state data with the plurality of meter input data samples to regenerate the meter state data at the time of a final meter input data sample prior to the power loss.

Disclosed is an auto-calibration circuit and method to generate the precise pulses that are required for energy savings achieved by using wide-band resonating cells for digital circuits. The calibration circuit performs a calibration technique by programming the number of PMOS devices and NMOS devices in parallel to an inverter, and these numbers are dynamically changed based on a target reference voltage that is defined by a resistance ratio or any PVT-independent reference voltages could also be set as a target voltage level.