Abstract: A nonvolatile memory device using a variable resistive element is provided. The nonvolatile memory device includes first and second nonvolatile memory cells. Word lines are coupled to the first and second nonvolatile memory cells. First and second bit lines are coupled to the first and second nonvolatile memory cells, respectively. A read circuit reads resistance levels of the first and second nonvolatile memory cells by providing first and second read bias currents of different levels to the first and second bit lines, respectively.

Abstract: Disclosed is a method of preventing coupling noises for a non-volatile semiconductor memory device. According to the method, if an edge of a write operation signal overlaps an activated period of a read operation signal a check result is generated. The write operation signal is modified based on the check result.

Abstract: A semiconductor device includes phase-change memory cells and an access circuit. The access circuit generates a plurality of bitwise comparison signals indicating different comparison events for respective write and read bit groups. At least a portion of the write data is then written to the phase-change memory cells according to a number of activated comparison signals for each comparison event, as well as according to a ratio of a set current pulse width and a reset current pulse width as applied to the of phase-change memory cells.

Abstract: A nonvolatile memory using a resistance material includes first and second memory-cell blocks having different block address information and each including a plurality of nonvolatile memory cells; a global bitline common to the first and second memory-cell blocks; first and second local bitlines corresponding to the first and second memory-cell blocks, respectively, and coupled to each other; and a common bitline selection circuit interposed between the first and second memory-cell blocks and coupled between the first and second local bitlines and the global bitline.

Abstract: Disclosed is a method of preventing coupling noises for a non-volatile semiconductor memory device. According to the method, if an edge of a write operation signal overlaps an activated period of a read operation signal a check result is generated. The write operation signal is modified based on the check result.

Abstract: Provided is a nonvolatile memory using a resistance material. In embodiments of the invention, a PRAM is configured to apply a step-down voltage to wordlines during a standby mode. Aspects of the present invention thus provide a nonvolatile memory with reduced standby current. Additionally, embodiments of the invention allow for faster transition from a standby state to an active state.

Abstract: A nonvolatile memory device includes global selection lines, local selection lines, a first selection circuit, and a second selection circuit. The local lines correspond respectively to the global selection lines. The first selection circuit is configured to connect to the global selection lines to select the global selection lines. The second selection circuit is connected between the global selection lines and the local selection lines and is configured to select the local selection lines. The first selection circuit is configured to select at least one global selection line, and the second selection circuit is configured to select the local selection lines corresponding to the selected global selection line while the at least one global selection line is continuously activated.

Abstract: A nonvolatile memory device using a variable resistive element is provided. The nonvolatile memory device includes first and second nonvolatile memory cells. Word lines are coupled to the first and second nonvolatile memory cells. First and second bit lines are coupled to the first and second nonvolatile memory cells, respectively. A read circuit reads resistance levels of the first and second nonvolatile memory cells by providing first and second read bias currents of different levels to the first and second bit lines, respectively.

Abstract: A non-volatile semiconductor memory device may include a memory cell array that may include a plurality of memory transistors; a input circuit that may control a voltage level of an internal reference voltage and a delay time of an internal clock signal in response to an MRS trim code or an electric fuse trim code, and that may generate a first buffered input signal; a column gate that may gate the first buffered input signal in response to a decoded column address signal; and a sense amplifier that may amplify an output signal of the memory cell array to output to the column gate, and that may receive an output signal of the column gate to output to the memory cell array. The non-volatile semiconductor memory device may properly buffer an input signal of a small swing range.

Abstract: The present invention relates to a resistance variable memory device, and more particularly, to a resistance variable memory device capable of preventing an effect of coupling noise. The resistance variable memory device includes: a memory cell connected to a bit line; a precharge circuit precharging the bit line in response to a precharge signal; a bias circuit providing a bias voltage to the bit line in response to,a bias signal; and a control logic controlling the precharge signal and the bias signal. The control logic provides the bias signal to the bias circuit at a precharge interval. Accordingly, the resistance variable memory device according to the present invention can prevent an effect coupling noise.

Abstract: The present invention relates to polymer patterns of various shapes formed using modifications of means and methods used in the prior lithography process, and the metal film patterns, metal patterns and plastic molds using the polymer patterns, as well as methods of forming these patterns and molds. The method of forming the polymer patterns comprises the steps of: (a) depositing a photosensitive polymer on the substrate to form a polymer film; (b) placing a photomask on the polymer film; and (c) irradiating the polymer film with a light moving in random direction through the photomask, so as to form at least one pattern which is concave from the surface of the polymer film in a direction perpendicular to the substrate and extends in a direction parallel to the substrate. The inventive polymer patterns have at least one pattern which is concave from the surface of the polymer film in a direction perpendicular to the substrate and extends in a direction parallel to the substrate.

Abstract: A semiconductor memory device includes a memory cell array and the memory cell array includes: a plurality of memory blocks and at least one setting unit. The at least one setting unit stores a location and a size of a boot data storage region within the plurality of memory blocks that stores boot data. The at least one setting units may include a register for setting usage of each memory block as a boot block. The semiconductor device may be a phase-change memory.

Abstract: A projection display apparatus using a microlens array and a micromirror array comprises a substrate, multiple micromirror arrays and multiple microlens arrays. The substrate is disposed apart with a predetermined distance from a light source. The multiple micromirror arrays are disposed over the substrate to be assembled together to have a predetermined incidence angle with respect to the incident rays. The multiple microlens arrays are configured to correspond to the micromirror arrays. More specifically, a first microlens array is disposed in a predetermined region between the light source and the substrate and comprises multiple microlenses. A second microlens array is disposed in a light path of reflection rays reflected from the micromirrors.

Abstract: A nonvolatile memory using a resistance material includes first and second memory-cell blocks having different block address information and each including a plurality of nonvolatile memory cells; a global bitline common to the first and second memory-cell blocks; first and second local bitlines corresponding to the first and second memory-cell blocks, respectively, and coupled to each other; and a common bitline selection circuit interposed between the first and second memory-cell blocks and coupled between the first and second local bitlines and the global bitline.

Abstract: Provided is a nonvolatile memory using a resistance material. In embodiments of the invention, a PRAM is configured to apply a step-down voltage to wordlines during a standby mode. Aspects of the present invention thus provide a nonvolatile memory with reduced standby current. Additionally, embodiments of the invention allow for faster transition from a standby state to an active state.

Abstract: Provided are a phase-change memory device and method that maintains a resistance of a phase-change material in a set state within a constant resistance range. In the method, data is provided to a first phase-change memory cell and then it is first determined whether data stored in the first phase-change memory cell and the data provided to the first phase-change memory cell are identical. If the data stored in the first phase-change memory cell and the data provided to the first phase-change memory cell are not identical, a complementary write current is provided to the first phase-change memory cell and it is second determined whether the data stored in the first phase-change memory cell and the data provided to the first phase-change memory cell are identical. If the data stored in the first phase-change memory cell and the data provided to the first phase-change memory cell are identical, data is provided to a second phase-change memory cell.

Abstract: A phase change memory device is disclosed. It includes a memory cell array including a plurality of memory cells programmed in relation to a phase change material, and a write driver circuit configured to provide a set current and a reset current to a selected memory cell. The write driver circuit includes a set current driver configured to provide the set current and a reset current driver configured to provide the reset current.

Abstract: A non-volatile semiconductor memory device may include a memory cell array that may include a plurality of memory transistors; a input circuit that may control a voltage level of an internal reference voltage and a delay time of an internal clock signal in response to an MRS trim code or an electric fuse trim code, and that may generate a first buffered input signal; a column gate that may gate the first buffered input signal in response to a decoded column address signal; and a sense amplifier that may amplify an output signal of the memory cell array to output to the column gate, and that may receive an output signal of the column gate to output to the memory cell array. The non-volatile semiconductor memory device may properly buffer an input signal of a small swing range.

Abstract: Provided are a phase-change memory device and method that maintains a resistance of a phase-change material in a set state within a constant resistance range; In the method, data is provided to a first phase-change memory cell and then it is first determined whether data stored in the first phase-change memory cell and the data provided to the first phase-change memory cell are identical.

Abstract: A phase change memory device is disclosed. It includes a memory cell array including a plurality of memory cells programmed in relation to a phase change material, and a write driver circuit configured to provide a set current and a reset current to a selected memory cell. The write driver circuit includes a set current driver configured to provide the set current and a reset current driver configured to provide the reset current.