A semiconductor memory device includes a memory block, and control logic. The memory block includes a plurality of memory cells. The control logic controls a peripheral circuit to perform a read operation on selected memory cells among the plurality of memory cells. The read operation includes a bit line precharge operation, an evaluation operation, and a sensing operation. The control logic is configured to control the peripheral circuit to float a common source line coupled to the memory block during at least a partial period of a period of the bit line precharge operation, in which a voltage of a plurality of bit lines coupled to the memory block increases.

A page buffer includes a bit line controller connected between a bit line and a sensing node, wherein the bit line controller is capable of adjusting a potential level of the sensing node, based on a cell current amount of the bit line, by performing an evaluation operation. The page buffer also includes a first latch unit connected to the sensing node, wherein the first latch unit is capable of adjusting an operation period of the evaluation operation. The page buffer further includes a second latch unit for latching verify data, based on the potential level of the sensing node.

A non-volatile memory device includes: one or more memory blocks including a plurality of memory cells connected to a plurality of word lines, and a plurality of memory cell strings; a page buffer unit; one or more pass units including a plurality of pass transistors that may supply operation voltages to the plurality of word lines; one or more monitoring units including one or more monitoring pass transistors connected to the plurality of pass transistors; a voltage generator that may supply activation voltages to a first pass transistor, in which a leakage current is to be measured, and to the one or more monitoring pass transistors; and a control logic that may control the voltage generator to generate the activation voltages by using a voltage control signal and detect the leakage current based on monitoring voltages output from the one or more monitoring pass transistors.

A memory device according to the present technology includes a memory cell array configured to include planes having a plurality of memory cells, a page buffer connected to at least one memory cell among the memory cells through a bit line and configured to perform a sensing operation of reading data stored in the at least one memory cell connected to the bit line, a common reference voltage generator configured to generate a common reference voltage, a plurality of merged buffers configured to generate a reference signal using the common reference voltage, and control logic configured to control an operation of the common reference voltage generator and the merged buffers so that page buffer control signals generated based on the reference signal are supplied to the page buffer.

Countermeasure method for programming a non-defective plane of a non-volatile memory experiencing a neighbor plane disturb, comprising, once a first plane is determined to have completed programming of a current state but where not all planes have completed the programming, a loop count is incremented and a determination is made as to whether the loop count exceeds a threshold. If so, programming of the incomplete plane(s) is ceased and programming of the completed plane(s) is resumed by suspending the loop count and bit scan mode, and, on a next program pulse, applying a pre-determined rollback voltage to decrement a program voltage bias. The loop count and bit scan mode are resumed once a threshold voltage level equals a program voltage bias when the loop count was last incremented. BSPF criterion is applied for each programmed state. Advancement to the next loop only occurs if a programmed state is determined incomplete.

A method of programming a nonvolatile memory device includes: receiving a programming command, data for a plurality of pages, and an address corresponding to a selected word-line; programming the data for one of the pages to an unselected word-line; reading data of a previously programmed page from the selected word-line; and programming the data for the remaining pages and the data of the previously programmed page to the selected word-line.

Technology for sensing non-volatile memory cells in which one or more sense nodes are charged to a sense voltage having a magnitude that improves sensing accuracy. One sense node may be charged to different sense voltages when sensing different memory cells at different times. Multiple sense nodes may be charged to a corresponding multiple different sense voltages when sensing different memory cells at the same time. The one or more sense nodes are allowed to discharge based on respective currents of memory cells for a pre-determined time while applying a reference voltage to the memory cells. The Vts of the selected memory cells are assessed based on respective voltages on the one or more of sense nodes after the pre-determined time. Different sensing voltages may be used based on bit line voltage, bit line resistance, distance of memory cells from the sense node, or other factors.

A memory device having an improved operation speed includes: a memory cell; a page buffer connected to the memory cell through a bit line; and a program operation controller for controlling an operation of the page buffer. The page buffer includes: a bit line voltage supply for providing a precharge voltage to the bit line; a sensing node voltage supply for providing a sensing node precharge voltage to a sensing node connected to the bit line; a first latch for storing first verify data; a sensing node connector for releasing connection between the bit line and the sensing node, after the first verify data is stored; and a second latch for storing second verify data determined according to the voltage of the sensing node, after the connection between the bit line and the sensing node is released.

Apparatuses and techniques are described for programming data in memory cells while concurrently storing backup data. One or more initial pages of data are programmed into both a primary block and a first backup block in a first program pass. A power loss then occurs which can corrupt the data or otherwise prevent reading of the one or more initial pages of data from the primary block. The one or more initial pages of data are read from the first backup block and used to perform a second program pass in which one or more additional pages of data are programmed into the primary block. Single bit per cell data can be stored in a second backup block to decode the one or more initial pages of data as read from the first backup block.

A page buffer circuit includes an intermediate circuit, a data storage circuit and an enhancive circuit. The intermediate circuit is coupled to a bit line coupled to a memory region and configured to form apply a voltage having a voltage level, corresponding to a status of the memory region, to a sensing node. The data storage circuit is configured to store, therein, a value that corresponds to the status of the memory region in response to the voltage level. The enhancive circuit is coupled to the sensing node and configured to increase a capacitance of the sensing node in an enhancive interval during a selected operation.