Abstract: A method for forming a highly integrated semiconductor device having multiplayer conductive lines is presented. The method includes the operations of forming, etching, burying and forming. The first forming operation includes forming a line-type conductive layer on a semiconductor substrate including a buried gate to expose the gate. The etching operation includes etching the conductive layer to expose at least a region between one side of an active area defined in the semiconductor substrate and an opposite side of the neighboring active area, both the active areas being arranged next to each other in a major axis direction of the gate. The burying operation includes burying a first insulating film in the etched line-type conductive layer. The second forming operation includes forming a bit line passing through the center of the active area in a direction perpendicular to the major axis direction of the gate.

Abstract: A nonvolatile memory device comprises overwritable memory cells. In an overwrite operation, data is read from a selected region of the nonvolatile memory device and combined with overwrite data to produce combined data. An error correction code is then generated for the combined data and the overwrite data and the error correction code are stored in the selected region.

Abstract: A multi-port memory system includes a shared memory bank, and a refresh controller coupled to the shared memory bank, and configured to selectively apply refresh commands from multiple processors to the shared memory bank.

Abstract: A system having a memory device accessible by a plurality of processors is provided. The system includes a memory device, a first processor, and a second processor. The memory device has a first memory array part and a second memory array part. The first processor predominantly accesses the first memory array part of the memory device and selectively accesses the second memory array part of the memory device. The second processor predominantly accesses the second memory array part of the memory device and selectively accesses the first memory array part of the memory device.

Abstract: A nonvolatile memory device comprises overwritable memory cells. In an overwrite operation, data is read from a selected region of the nonvolatile memory device and combined with overwrite data to produce combined data. An error correction code is then generated for the combined data and the overwrite data and the error correction code are stored in the selected region.

Abstract: A multi-port volatile memory device can include a first port that is configured for data transfer to/from an external host system and the device. A volatile main memory core is configured to store data received thereat and read requested stored data thereform. A volatile sub memory core can be configured to store data received thereat and read requested stored data therefrom. A main interface circuit can be coupled to the first port and can be configured to provide data to/from the volatile main memory core and the first port in a master mode and can be configured to provide data to/from the volatile sub memory core and the first port in a slave mode. A second port can be configured for data transfer to/from an external non-volatile memory device and the device and a sub interface circuit can be coupled to the second port and configured to provide data to/from the volatile sub memory core and the second port in the slave mode.

Abstract: A method for forming a highly integrated semiconductor device having multiplayer conductive lines is presented. The method includes the operations of forming, etching, burying and forming. The first forming operation includes forming a line-type conductive layer on a semiconductor substrate including a buried gate to expose the gate. The etching operation includes etching the conductive layer to expose at least a region between one side of an active area defined in the semiconductor substrate and an opposite side of the neighboring active area, both the active areas being arranged next to each other in a major axis direction of the gate. The burying operation includes burying a first insulating film in the etched line-type conductive layer. The second forming operation includes forming a bit line passing through the center of the active area in a direction perpendicular to the major axis direction of the gate.

Abstract: A memory system includes a memory cell array having a plurality of memory sectors. Each memory sector includes a plurality of memory cells. The memory system further includes a controller configured to write data to the memory cell array in response to a writing signal. The controller is further configured to refresh a memory sector among the plurality of memory sectors each time a writing signal is provided. When N (N is a positive integer) memory cells are programmed, a programming current is less than or equal to about 0.75 mA*N.

Abstract: A multi-port volatile memory device can include a first port that is configured for data transfer to/from an external host system and the device. A volatile main memory core is configured to store data received thereat and read requested stored data thereform. A volatile sub memory core can be configured to store data received thereat and read requested stored data therefrom. A main interface circuit can be coupled to the first port and can be configured to provide data to/from the volatile main memory core and the first port in a master mode and can be configured to provide data to/from the volatile sub memory core and the first port in a slave mode. A second port can be configured for data transfer to/from an external non-volatile memory device and the device and a sub interface circuit can be coupled to the second port and configured to provide data to/from the volatile sub memory core and the second port in the slave mode.

Abstract: Example embodiments relate to a semiconductor memory system which may include a volatile memory and a non-volatile memory that share a common bus, and a method for controlling the operation of the non-volatile memory. The semiconductor memory system may include a non-volatile memory and a memory controller. The non-volatile memory may include a buffer memory that temporarily stores data to be read from or to be written to a memory cell array, and an internal controller. The memory controller may transmits a mode signal to the non-volatile memory in response to a control signal, the control signal corresponds to either a read mode or a write mode to be applied to the non-volatile memory. In response to the mode signal, the internal controller may control the data to be read to be stored in the buffer memory, if the read mode is to be applied, and the internal controller may control the buffer memory to stand-by until a write command is received, if the write mode is to be applied.

Abstract: A memory system includes a first external device, a second external device, and a multi-port memory device connected to the first and second external devices. The multi-port memory system includes: a first port and a second port connected to the first and second external devices, respectively, a first bank group having at least one memory bank, the first bank group configured to be accessed by the first external device through the first data port; a second bank group having at least one memory bank, the second bank group configured to be accessed by the second external device through the second data port; a third bank group having at least one memory bank, wherein the third bank group is configured to be selectively accessed by the first external device through the first data port or the second external device through the second data port. The multi-port memory system may prevent data collisions which occur when two ports simultaneously attempt to access the same memory bank.

Abstract: Circuits and methods for controlling data I/O operations in semiconductor memory devices to provide variable data I/O widths for read, write and active memory operations. Circuits and methods for selectively controlling a data width of a data I/O buffer “on the fly” to enable variable data I/O widths during memory access operations.

Abstract: Example embodiments relate to a semiconductor memory system which may include a volatile memory and a non-volatile memory that share a common bus, and a method for controlling the operation of the non-volatile memory. The semiconductor memory system may include a non-volatile memory and a memory controller. The non-volatile memory may include a buffer memory that temporarily stores data to be read from or to be written to a memory cell array, and an internal controller. The memory controller may transmits a mode signal to the non-volatile memory in response to a control signal, the control signal corresponds to either a read mode or a write mode to be applied to the non-volatile memory. In response to the mode signal, the internal controller may control the data to be read to be stored in the buffer memory, if the read mode is to be applied, and the internal controller may control the buffer memory to stand-by until a write command is received, if the write mode is to be applied.

Abstract: A multi-port volatile memory device can include a first port that is configured for data transfer to/from an external host system and the device. A volatile main memory core is configured to store data received thereat and read requested stored data thereform. A volatile sub memory core can be configured to store data received thereat and read requested stored data therefrom. A main interface circuit can be coupled to the first port and can be configured to provide data to/from the volatile main memory core and the first port in a master mode and can be configured to provide data to/from the volatile sub memory core and the first port in a slave mode. A second port can be configured for data transfer to/from an external non-volatile memory device and the device and a sub interface circuit can be coupled to the second port and configured to provide data to/from the volatile sub memory core and the second port in the slave mode.

Abstract: A multi-port volatile memory device can include a first port that is configured for data transfer to/from an external host system and the device. A volatile main memory core is configured to store data received thereat and read requested stored data thereform. A volatile sub memory core can be configured to store data received thereat and read requested stored data therefrom. A main interface circuit can be coupled to the first port and can be configured to provide data to/from the volatile main memory core and the first port in a master mode and can be configured to provide data to/from the volatile sub memory core and the first port in a slave mode. A second port can be configured for data transfer to/from an external non-volatile memory device and the device and a sub interface circuit can be coupled to the second port and configured to provide data to/from the volatile sub memory core and the second port in the slave mode.

Abstract: A multi-port volatile memory device includes a first port configured for data transfer to/from an external host system and the device. A volatile main memory core is configured to store data received thereat and read requested stored data thereform. A volatile sub memory core is configured to store data received thereat and read requested stored data therefrom. A main interface circuit is coupled to the first port and configured to provide data to/from the volatile main memory core and the first port in a master mode and configured to provide data to/from the volatile sub memory core and the first port in a slave mode. A second port is configured for data transfer to/from an external non-volatile memory device and the device. A sub interface circuit is coupled to the second port and configured to provide data to/from the volatile sub memory core and the second port in the slave mode.

Abstract: A semiconductor device is provided. The semiconductor device includes a storage part storing an address for weak cells in a nonvolatile state; and a dynamic semiconductor memory device including: a memory cell array having normal cells and the weak cells to be refreshed; and a refresh control part performing a refresh operation for the weak cells, wherein a refresh period for the weak cells is shorter than a refresh period for the normal cells when the address applied in a refresh operation mode coincides with the address stored in the storage part.

Abstract: A method for fabricating a semiconductor device includes: forming a pad oxide layer over a substrate; forming a hard mask pattern over the pad oxide layer; etching a predetermined portion of the pad oxide layer and the substrate using the hard mask pattern to form a first recess having sidewalls and a bottom portion; forming a spacer over the hard mask pattern and on the sidewalls and the bottom portion of the first recess; and etching the substrate beneath the first recess using the spacer as an etch barrier to form a second recess, the second recess being wider and more rounded than the first recess.

Abstract: A multi-port memory system includes a shared memory bank, multiple command decoders configured to receive refresh commands from multiple processors, and a refresh controller coupled to the shared memory bank and the command decoders, and configured to selectively apply refresh commands from the command decoders to the shared memory bank.

Abstract: A method for fabricating a semiconductor device includes forming a polysilicon layer, a silicide layer and a hard mask over a semiconductor substrate, etching the silicide layer using the hard mask as an etch barrier, shaping the silicide layer with a predetermined profile using a mixed gas, and etching the polysilicon layer using the hard mask as an etch barrier.