Embodiments of the invention relate generally to data storage and computer memory, and more particularly, to systems, integrated circuits and methods for accessing memory in multiple layers of memory implementing, for example, third dimension memory technology. In a specific embodiment, an integrated circuit is configured to implement write buffers to access multiple layers of memory. For example, the integrated circuit can include memory cells disposed in multiple layers of memory. In one embodiment, the memory cells can be third dimension memory cells. The integrated circuit can also include read buffers that can be sized differently than the write buffers. In at least one embodiment, write buffers can be sized as a function of a write cycle. Each layer of memory can include a plurality of two-terminal memory elements that retain stored data in the absence of power and store data as a plurality of conductivity profiles.

Embodiments of the invention are directed towards a memory device comprising a plurality of wordlines each coupled to a row of memory cells in a subtile of the memory device, a plurality of level one column select circuits coupled to each cell in a plurality of groups of cells in a subtile, a plurality of level two column select circuits coupled to each of the plurality of groups of cells in the subtile, a common bit line coupled to the plurality of level one column select circuits and the plurality of level two column select circuits, the common bit line also coupled to a sense and program circuit, wherein the sense and program circuit addresses each first cell in each of the groups of cells to form a single page of memory.

According to one embodiment, a semiconductor memory device includes: a first memory cell including a first variable resistance element; a first buffer coupled to the first memory cell; a second memory cell including a second variable resistance element; and a second buffer coupled to the second memory cell. In data write, first data is stored in the first buffer and is transferred to the first memory cell, and second data is stored in the second buffer and is transferred to the second memory cell, and a start of the transferring the first data and the second data is based on a first data transfer signal.

Embodiments of the invention relate generally to data storage and computer memory, and more particularly, to systems, integrated circuits and methods for accessing memory in multiple layers of memory implementing, for example, third dimension memory technology. In a specific embodiment, an integrated circuit is configured to implement write buffers to access multiple layers of memory. For example, the integrated circuit can include memory cells disposed in multiple layers of memory. In one embodiment, the memory cells can be third dimension memory cells. The integrated circuit can also include read buffers that can be sized differently than the write buffers. In at least one embodiment, write buffers can be sized as a function of a write cycle. Each layer of memory can include a plurality of two-terminal memory elements that retain stored data in the absence of power and store data as a plurality of conductivity profiles.

Embodiments of the invention are directed towards a memory device comprising a plurality of wordlines each coupled to a row of memory cells in a subtile of the memory device, a plurality of level one column select circuits coupled to each cell in a plurality of groups of cells in a subtile, a plurality of level two column select circuits coupled to each of the plurality of groups of cells in the subtile, a common bit line coupled to the plurality of level one column select circuits and the plurality of level two column select circuits, the common bit line also coupled to a sense and program circuit, wherein the sense and program circuit addresses each first cell in each of the groups of cells to form a single page of memory.

Apparatuses and methods are described, such as those involving driver circuits that are configured to provide reset and set voltages to different variable state material memory cells in an array at the same time. Additional apparatuses, and methods are described.

Apparatuses and methods are described, such as those involving driver circuits that are configured to provide reset and set voltages to different variable state material memory cells in an array at the same time. Additional apparatuses, and methods are described.

An operating method of a memory system including first and second one half pages includes acquiring first and second partial data from main data; performing a first program operation to the first one half page of a selected page with the first partial data; and performing a second program operation to the second one half page of the selected page with the second partial data. The first and second partial data may be programmed in the same first column region in the first and second one half pages, respectively.

A non-volatile storage system includes technology for skipping programming cycles while programming a page (or other unit) of data. While programming a current subset of the page (or other unit) of data, the system will evaluate whether the next subsets of the page (or other unit) of data should be programmed into non-volatile storage elements or skipped. Subsets of the page (or other unit) of data that should not be skipped are programmed into non-volatile storage elements. Some embodiments include transferring the appropriate data to temporary latches/registers, in preparation for programming, concurrently with the evaluation of whether to program or skip the programming.

The present description relates to a method of writing a first group of N data elements, N being an integer, into a second group of N memory cells of a phase-change memory, each data element of the first group comprising a metadata element, and at each writing of a data element of the first group into a memory cell of the second group, the value of the metadata element of the data element is modified.