A method for reading data stored in a flash memory includes at least the following steps: controlling the flash memory to perform a plurality of read operations upon a plurality of memory cells included in the flash memory; obtaining a plurality of bit sequences read from the memory cells, respectively, wherein the read operations read bits of a predetermined bit order from the memory cells by utilizing different control gate voltage settings; and determining readout information of the memory cells according to binary digit distribution characteristics of the bit sequences.

When a control circuit has received a first erase command, the control circuit controls performing a first pre-write process to allow a first storage device and a second storage device to have threshold voltages, respectively, both increased, and the control circuit thereafter controls performing an erase process to allow the first storage device and the second storage device to have their respective threshold voltages both decreased to be smaller than a prescribed erase verify level. When the control circuit has received a second erase command, the control circuit controls performing a second pre-write process to allow one of the first storage device and the second storage device to have its threshold voltage increased, and control circuit subsequently controls performing the erase process.

A content addressable memory cell includes a first floating body transistor and a second floating body transistor. The first floating body transistor and the second floating body transistor are electrically connected in series through a common node. The first floating body transistor and the second floating body transistor store complementary data.

The improvement of the reliability of a semiconductor device having a split gate type MONOS memory is implemented. An ONO film and a second polysilicon film are sequentially formed so as to fill between a first polysilicon film and a dummy gate electrode. Then, the dummy gate electrode is removed. Then, the top surfaces of the first and second polysilicon films are polished, thereby to form a memory gate electrode formed of the second polysilicon film at the sidewall of a control gate electrode formed of the first polysilicon film via the ONO film. As a result, the memory gate electrode high in perpendicularity of the sidewall, and uniform in film thickness is formed.

Approaches for a memory including a cell array are provided. The memory includes a first device of the cell array which is connected to a bitline and a node and controlled by a word line, and a second device of the cell array which comprises a third device which is connected to a source line and the node and controlled by the word line and a fourth device which is connected between the word line and the node. In the memory, in response to another word line in the cell array being activated and the word line not being activated to keep the first device in an unprogrammed state, the third device isolates and floats the node such that a voltage level of a gate to source of the first device is clamped down by the fourth device to a voltage level around zero volts.

Approaches for a memory including a cell array are provided. The memory includes a first device of the cell array which is connected to a bitline and a node and controlled by a word line, and a second device of the cell array which comprises a third device which is connected to a source line and the node and controlled by the word line and a fourth device which is connected between the word line and the node. In the memory, in response to another word line in the cell array being activated and the word line not being activated to keep the first device in an unprogrammed state, the third device isolates and floats the node such that a voltage level of a gate to source of the first device is clamped down by the fourth device to a voltage level around zero volts.

A memory array includes a plurality of twin cells, each of the twin cells composed of a first storage element and a second storage element configured to hold binary data according to a difference in threshold voltage between them, the first storage element and the second storage element each being electrically rewritable. Upon receiving a request to read the twin cell, when the threshold voltage of the first storage element forming the twin cell is lower than an erasure determination level and the threshold voltage of the second storage element forming the twin cell is lower than the erasure determination level, an output circuit masks the data stored in the twin cell and outputs the masked data.

A TCAM comprises multiple first search lines, multiple second search lines, multiple memory cell strings, and one or more current sensing units coupled to the plurality of memory cell strings. Each memory cell string comprises multiple memory cells. Each memory cell string comprises at least four transistors serially connected as a NAND memory string, and two transistors of the at least four transistors form each memory cell. One, of the two transistors in each memory cell, coupled to one of the first search lines is a first transistor, and the other one, of the two transistors in each memory cell, coupled to one of the second search lines is a second transistor. The multiple first search lines are arranged consecutively, and the multiple second search lines are arranged consecutively.

According to one embodiment, a semiconductor memory device includes first and second memory cells, a first word line, first and second sense amplifiers, first and second bit lines, a controller. The first and second sense amplifiers each include first and second transistors. The first bit line is connected between the first memory cell and the first transistor. The second bit line is connected between the second memory cell and the second transistor. In the read operation, the controller is configured to apply a kick voltage to the first word line before applying the read voltage to the first word line, and to apply a first voltage to a gate of the first transistor and a second voltage to a gate of the second transistor while applying the kick voltage to the first word line.

According to one embodiment, a semiconductor memory device includes first and second memory cells, a first word line, first and second sense amplifiers, first and second bit lines, a controller. The first and second sense amplifiers each include first and second transistors. The first bit line is connected between the first memory cell and the first transistor. The second bit line is connected between the second memory cell and the second transistor. In the read operation, the controller is configured to apply a kick voltage to the first word line before applying the read voltage to the first word line, and to apply a first voltage to a gate of the first transistor and a second voltage to a gate of the second transistor while applying the kick voltage to the first word line.