Circuitry and methods of operating the same to strobe a DQ signal with a gated DQS signal are described. Some aspects are directed to a gating scheme to selectively pass a received strobe signal such as a DQS strobe signal based on a state of a drive enable (DE) signal in a drive circuit in the ATE, such that edges generated by the drive circuit are prevented from mistakenly strobing a received data signal such as a DQ signal.

A test apparatus includes a device under test (DUT) configured to exchange data using a serial interface protocol and a test controller configured to receive a binary vector corresponding to a physical layer of the serial interface protocol from an external device and to buffer and transmit the received binary vector to the DUT.

A semiconductor memory device included in each of a plurality of chips which are divided by a scribe lane and formed on an upper surface of a wafer, includes a memory core and a built-in self test (BIST) circuit. The memory core includes a memory cell array that stores data and a data input/output circuit connected to a data input/output pad. The BIST circuit is connected to a test pad that is separate from the data input/output pad. The BIST circuit generates test pattern data including first parallel bits based on commands and addresses received from an external automatic test equipment (ATE) during a wafer level test process performed on the semiconductor memory device. The BIST circuit tests the memory core by applying the test pattern data to the memory cell array through the data input/output circuit.

A refresh time detection circuit and a semiconductor device including the same may be provided. The refresh time detection circuit may include a code generator configured to generate a code signal for detecting a refresh time. The refresh time detection circuit may include a latch circuit configured to generate a latch signal by latching the code signal according to a fail signal, and generate a pre-code signal and a post-code signal by latching each latch signal according to a pre-enable signal and a post-enable signal. The refresh time detection circuit may include a subtractor configured to output a refresh detection signal by performing subtraction between the pre-code signal and the post-code signal. The refresh time detection circuit may include a comparator configured to generate a detection signal by comparing the refresh detection signal with an offset signal based on the post-enable signal.

A write tracking circuit includes a dummy memory cell coupled to a first dummy bit line, a second dummy bit line, and a dummy word line, a logic operation unit coupled to the dummy word line and to the first dummy bit line and configured to output a write feedback signal based on a logic operation of a signal on the dummy word line and a signal on the first dummy bit line, and a delay unit coupled to the dummy memory cell at a storage node. The write tracking circuit provides a correct feedback signal to the clock generation module to ensure normal operation of the peripheral circuit, when a data write operation to the dummy memory cell failed.

Circuitry and methods of operating the same to strobe a DQ signal with a gated DQS signal are described. Some aspects are directed to a gating scheme to selectively pass a received strobe signal such as a DQS strobe signal based on a state of a drive enable (DE) signal in a drive circuit in the ATE, such that edges generated by the drive circuit are prevented from mistakenly strobing a received data signal such as a DQ signal.

A test apparatus may be provided. The test apparatus may include a delay compensator configured to generate delayed read data by delaying read data according to a difference between an external turnaround delay value provided externally from the test apparatus and a turnaround delay detection value detected within the test apparatus. The test apparatus may include a determination circuit configured to perform a test result determination operation by comparing the delayed read data with reference data. The turnaround delay detection value may be generated by detecting a time of from a point of time when write data including a read command as the reference data is output to a point of time when the read data is received.

A semiconductor apparatus may include: a data storage group including first to eight data storage areas; a first channel select pad configured to transmit a first channel select signal to the first and third data storage areas; a second channel select pad configured to transmit a second channel select signal to the second and fourth data storage areas; a third channel select pad configured to transmit the first channel select signal to the sixth and eighth data storage areas; a fourth channel select pad configured to transmit the second channel select signal to the fifth and seventh data storage areas; a first clock enable pad configured to transmit a first clock enable signal to the first and third data storage areas; a second clock enable pad configured to transmit a second clock enable signal to the second and fourth data storage areas; a third clock enable pad configured to transmit the first clock enable signal to the fifth and seventh data storage areas; and a fourth clock enable pad configured to transmit the second clock enable signal to the sixth and eighth data storage areas.

The disclosure provides a method and apparatus of interleaved on-chip testing. The method merges a test setup for analog components with a test setup for digital components and then interleaves the execution of the digital components with the analog components. This provides concurrency via a unified mode of operation. The apparatus includes a system-on-chip test access port (SoC TAP) in communication with a memory test access port (MTAP). A built-in self-test (BIST) controller communicates with the MTAP, a physical layer, and a memory. A multiplexer is in communication with the memory and a phase locked loop (PLL) through an AND gate.

A storage device includes a memory, a write circuit, a read circuit, and a debug information register. The memory includes a data area and a redundant area that corresponds to the data area. The write circuit writes first data specified in a write command to the data area, and first information about a transmission source which has transmitted the write command, to the redundant area. The read circuit reads the first data as second data from the data area, and reads the first information as second information from the redundant area, in response to a read command. The debug information register stores the second information read by the read circuit.