Disclosed herein is an apparatus that includes a fuse array circuit including a plurality of fuse sets each assigned to a corresponding one of a plurality of fuse addresses and configured to operatively store a fuse data, and a first circuit configured to generate and sequentially update a fuse address to sequentially read the fuse data from the plurality of fuse sets. The first circuit is configured to change a frequency of updating the fuse address based on a first signal.

A method for testing a memory chip includes the following: test data is written into memory cells of a memory chip to be tested; stored data is read from memory cells; a test result of the memory chip to be tested is generated according to the test data and the stored data. A current voltage of bit line precharge (VBLP) of the memory chip to be tested is smaller than a standard VBLP of the memory chip to be tested, and/or a current sensing delay time (SDT) of the memory chip to be tested is smaller than a standard SDT of the memory chip to be tested.

Apparatuses, systems, and methods for self-test mode abort circuit. Memory devices may enter a self-test mode and perform testing operations on the memory array. During the self-test mode, the memory device may ignore external communications. The memory includes an abort circuit which may terminate the self-test mode if it fails to properly finish. For example, the abort circuit may count an amount of time since the self-test mode began and end the self-test mode if that amount of time meets or exceeds a threshold, which may be based off of the expected amount of time for the testing operations to complete.

A test circuit includes first integration circuit configured to receive first test signal and integrate first test signal to output first integrated signal; second integration circuit configured to receive second test signal and integrate second test signal to output second integrated signal, where first test signal and second test signal are signals inverted with respect to each other, value of first integrated signal is product of duty cycle of first test signal and a voltage amplitude of power supply, and value of second integrated signal is product of duty cycle of second test signal and voltage amplitude of power supply; and comparison circuit connected to first and second integration circuits. The comparison circuit is configured to output high-level signal in response to first integrated signal being greater than second integrated signal, and output low-level signal in response to second integrated signal being greater than first integrated signal.

An apparatus is provided, comprising a controller, a plurality of memory devices operably connected to the controller, circuitry configured to measure a performance metric for each of the plurality of memory devices, and circuitry configured to select, based upon the measured performance metric, a subset of the plurality of memory devices to disable in response to a recovery command. Information corresponding to the selected subset cam be stored in a mode register of the apparatus, and the apparatus can further comprise circuitry configured, in response to a recovery command, to disable the subset of the plurality of memory devices.

A memory device includes a data pad; a read circuit outputting read or test data to the data pad according to a read timing signal and a read command; a write circuit receiving write data through the data pad according to a write timing signal; a test register circuit performing a preset operation on data and storing the data, and transferring the stored data as the test data in response to the read command, during a first test mode; a data compression circuit generating a test output signal by compressing the test data and outputting the test output signal to a first test output pad, during the first test mode; and a timing control circuit generating, according to first to third output control signals, the read timing signal and generating the write timing signal by delaying the read timing signal, during the first test mode.

An apparatus includes a host and a memory device connected to the host through a bus. The bus is used to communicate a data clock controlling data write timing during a write operation executed by the memory device and a read clock controlling data read timing during a read operation executed by the memory device. The memory device performs first duty cycle monitoring that monitors a duty cycle of the data clock, generates a first result, and provides a timing-adjusted data clock, performs second duty cycle monitoring that monitors a duty cycle of the read clock, generates a second result, and provides a timing-adjusted read clock, calculates an offset of the read clock based on the timing-adjusted data clock, the result and the second result, and corrects a duty error of the read clock using a read clock offset code derived from the offset of the read clock.

A signal generation circuit includes: a clock circuit configured to receive a flag signal and generate a clock signal; a control circuit configured to generate a control circuit; and a generation circuit connected to both the clock circuit and control circuit and configured to receive the clock signal, the control signal, and the flag signal and generate a target signal, wherein when the flag signal changes from a first level to a second level, the target signal changes from a third level to a fourth level, and after the target signal is maintained at the fourth level for a target duration, the target signal changes from the fourth level to the third level; and the generation circuit is further configured to determine the target duration according to the clock signal and control signal.

A signal generation circuit includes: a clock module, configured to generate a clock signal based on a flag signal; a control module, configured to generate a control signal according to number of transitions of the clock signal within a fixed time; and a generation module, respectively connected to the clock module and the control module, and configured to receive the clock signal, the control signal, and the flag signal, and to generate a target signal. When the flag signal changes from a first level to a second level, the target signal changes from a third level to a fourth level. After being maintained at the fourth level for a target duration, the target signal changes from the fourth level to the third level. The generation module is further configured to determine the target duration according to the clock signal and the control signal.

An apparatus includes a first group of memory units and a second group of memory units coupled to a first data path and a second data path coupled to a controller, a first delay element on the first data path coupled to the second group of memory units and configured to send, from the controller to the second group of memory units, signals for write and read operations in a sequence of time cycles delayed by a time cycle with respect to the first group of memory units, and a second delay element on the second data path and coupled to the first group of memory units and configured to send, from the first group of memory units to the controller, test result signals delayed by a time cycle, the delayed test result signals having a matching delay to the delayed write and read operations.