A memory device and a glitch prevention method thereof are provided. The memory device includes a data strobe signal input circuitry, a transfer signal generating circuitry, a data alignment circuitry, and a blocking circuitry. The data strobe signal input circuitry is configured to input a data strobe signal. The transfer signal generating circuitry is configured to generate a transfer signal with pulses in synchronization with rising edges or falling edges of the data strobe signal in response to a transfer command. The data alignment circuitry is configured to align a data signal to be transferred in response to the generated transfer signal. The blocking circuitry is configured to block an input of the data strobe signal over a postamble timing of the data strobe signal according to a number of bursts counted in each time of data transfer.

The present disclosure includes apparatuses and methods for cache operations. An example apparatus includes a memory device including a plurality of subarrays of memory cells, where the plurality of subarrays includes a first subset of the respective plurality of subarrays and a second subset of the respective plurality of subarrays. The memory device includes sensing circuitry coupled to the first subset, the sensing circuitry including a sense amplifier and a compute component. The first subset is configured as a cache to perform operations on data moved from the second subset. The apparatus also includes a cache controller configured to direct a first movement of a data value from a subarray in the second subset to a subarray in the first subset.

A readout circuit structure is provided, which includes: a first sense amplification circuit and a second sense amplification circuit, disposed adjacent to each other along an extension direction of a bit line, here the first sense amplification circuit is coupled to one memory array in the adjacent memory arrays by a first bit line, and is coupled to the other memory array by a first complementary bit line, and the second sense amplification circuit is coupled to one memory array in the adjacent memory arrays by a second bit line, and is coupled to the other memory array by a second complementary bit line; a first equalization pipe, connected to the first bit line; a second equalization pipe, connected to the first complementary bit line; a third equalization pipe, connected to the second bit line; and a fourth equalization pipe, connected to the second complementary bit line.

A control circuit, a method for reading and writing and a memory are provided. The control circuit includes a pre-charge circuit, an amplification circuit and an equalization circuit. The pre-charge circuit is directly electrically connected to at least one of a bit line or a complementary bit line. The amplification circuit has a first node and a second node. The equalization circuit is connected between the first node and the bit line and between the second node and the complementary bit line.

A sense amplifier of a memory device that includes sense amplifier circuits and a reference sharing circuit is introduced. The sense amplifier circuits are configured to sense the plurality of bit lines according to an enable signal. The reference sharing circuit includes first switches and second switches that are coupled to the reference nodes and second reference nodes of the sense amplifier circuits, respectively. The first switches and second switches are controlled according to a control signal to control a first electrical connection among the first reference nodes, and to control a second electrical connection among the second reference nodes. An operation method of the sense amplifier and a memory device including the sense amplifier are also introduced.

Apparatuses and techniques are described for reducing the number of latches used in sense circuits for a memory device. The number of internal user data latches in a sense circuit is reduced by using an external data transfer latch to store a bit of user data, in place of an internal user data latch. The user data in the data transfer latches identifies a subset of the data states which are not prohibited from having a verify test. The subset is shifted as the program operation proceeds, at specified program loops, to encompass higher data states. The completion of programming by a memory cell is indicated by the user data latches and another internal latch of the sense circuit in place of the external data transfer latch.

The present invention provides a pseudo dual-port memory. The pseudo dual-port memory includes a single-port memory, a multiplexer, a timing control circuit and an output circuit. The multiplexer is configured to sequentially output a first address and a second address to the single-port memory. The output circuit is configured to receive output data from the single-port memory to generate a first reading result corresponding to the first address and a second reading result corresponding to the second address. The output circuit includes a first sense amplifier and a second sense amplifier, wherein the first sense amplifier receives the output data to generate first data serving as the first reading result according to a first control signal, and the second sense amplifier receives the output data to generate second data serving as the second reading result according to a second control signal.

A memory includes S storage blocks, N global bitlines, and a signal amplification circuit. Each of the S storage blocks is connected to the N global bitlines, the N global bitlines are connected to the signal amplification circuit, the signal amplification circuit is configured to amplify electrical signals on the N global bitlines, and each storage block includes N columns of storage units, N local bitlines, and N bitline switches. In each storage block, storage units in an i.sup.th column are connected to an i.sup.th local bitline, the i.sup.th local bitline is connected to an i.sup.th global bitline by using an i.sup.th bitline switch in the N bitline switches. A memory array is fine-grained, so that i.sup.th local bitlines in the S storage blocks can share one global bitline.

A sense amplifier control system includes a precharge control switch configured to receive a precharge signal. A reference cell is configured to receive a reference word line signal. In a precharge phase, the control switch is controlled in response to the precharge signal to precharge the reference input node to a predetermined precharge level. In a sensing phase subsequent to the pre-charge phase, the trigger circuit is configured to output a triggering signal at the output terminal in response to the reference input node reaching a triggering level.

A data storage includes a memory array including a plurality of memory cells, and peripheral circuitry disposed underneath the memory array. The peripheral circuitry includes an M-tier sense amplifier (SA) circuit including X stacks of SA latches, wherein each SA latch is respectively coupled to a bit line of a memory cell of the plurality of memory cells; and an N-tier memory cache data (XDL) circuit including Y stacks of XDL latches, wherein M is less than N, and X is greater than Y. The peripheral circuitry further includes data path circuitry coupling (i) each SA latch of the X stacks of SA latches to (ii) a respective XDL latch of the Y stacks of XDL latches.