Abstract: The present invention relates to an input and output port circuit. The input and output port circuit comprises a signal register for storing output signals, an input/output register at which an input/output control signal for determining an input/output direction is stored, a plurality of control registers, a power supply switch circuit for selectively supplying a low voltage or a high voltage depending on a power mode control signal, a signal direction control circuit for determining the direction of the signal depending on a value of the signal register and a value of the input/output register, an output control circuit driven depending on the value of the control register and an output of the signal direction control circuit, and an output driving circuit for outputting the low voltage, the high voltage or the ground value depending on an output of the signal direction control circuit and an output of the output control circuit.

Abstract: The present invention provides an EDMOS (extended drain MOS) device having a lattice type drift region and a method of manufacturing the same. In the case of n channel EDMOS(nEDMOS), the drift region has a lattice structure in which an n lattice having a high concentration and a p lattice having a low concentration are alternately arranged. As a drain voltage is applied, a depletion layer is abruptly extended by a pn junction of the n lattice and the p lattice, so that the entire drift region is easily depleted. Therefore, a breakdown voltage of the device is increased, and an on resistance of the device is decreased due to the n lattice with high concentration.

Abstract: Provided is a semiconductor fabrication technology; and, more particularly, to a semiconductor device having a heat release structure that uses a silicon-on-insulator (SOI) substrate, and a method for fabricating the semiconductor device. The device and method of the present research provides a semiconductor device having a high heat-release structure and high heat-release structure, and a fabrication method thereof. In the research, the heat and high-frequency noises that are generated in the integrated circuit are released outside of the substrate through the tunneling region quickly by forming an integrated circuit on a silicon-on-insulator (SOI) substrate, aiid removing a buried insulation layer under the integrated circuit to form a tunneling region. The heat-release efficiency can be enhanced much more, when unevenness is formed on the surfaces of the upper and lower parts of the tunneling region, or when the air or other gases having excellent heat conductivity is flown into the tunneling region.

Abstract: The present invention relates to structures of a high voltage device and a low voltage device formed on a SOI substrate and a method for manufacturing the same, and it is characterized in which the low voltage device region of silicon device regions in a SOI substrate is higher than the high voltage device region by steps, and a thickness of the silicon device region, where the high voltage device is formed, is equal to a junction depth of impurities of a source and drain in the low voltage device. Accordingly, silicon device regions in the SOI substrate are divided into the high voltage region and the low voltage region and steps are formed there between by oxidation growth method, so that the high voltage device having low junction capacitance can be made, and the low voltage device compatible with the conventional CMOS process and device characteristics can also be made at the same time.

Abstract: The MOS transistor of the present invention is manufactured by a conventional complementary MOS transistor technology. In the manufacturing method of the MOS transistor having nanometer dimensions, a gate having dimensions at a nanometer scale can be formed through control of the width of spacers instead of with a specific lithography technology. The doped spacers are used for forming source/drain extension regions having an ultra-shallow junction, thereby avoiding damage on the substrate caused by ion implantation. In addition, a dopant is diffused from the doped space into a semiconductor substrate through annealing to form the source/drain extension regions having an ultra-shallow junction.

Abstract: Provided is a semiconductor fabrication technology; and, more particularly, to a semiconductor device having a heat release structure that uses a silicon-on-insulator (SOI) substrate, and a method for fabricating the semiconductor device. The device and method of the present research provides a semiconductor device having a high heat-release structure and high heat-release structure, and a fabrication method thereof. In the research, the heat and high-frequency noises that are generated in the integrated circuit are released outside of the substrate through the tunneling region quickly by forming an integrated circuit on a silicon-on-insulator (SOI) substrate, and removing a buried insulation layer under the integrated circuit to form a tunneling region. The heat-release efficiency can be enhanced much more, when unevenness is formed on the surfaces of the upper and lower parts of the tunneling region, or when the air or other gases having excellent heat conductivity is flown into the tunneling region.

Abstract: The present invention relates to an input and output port circuit. The input and output port circuit comprises a signal register for storing output signals, an input/output register at which an input/output control signal for determining an input/output direction is stored, a plurality of control registers, a power supply switch circuit for selectively supplying a low voltage or a high voltage depending on a power mode control signal, a signal direction control circuit for determining the direction of the signal depending on a value of the signal register and a value of the input/output register, an output control circuit driven depending on the value of the control register and an output of the signal direction control circuit, and an output driving circuit for outputting the low voltage, the high voltage or the ground value depending on an output of the signal direction control circuit and an output of the output control circuit.

Abstract: The present invention provides an EDMOS (extended drain MOS) device having a lattice type drift region and a method of manufacturing the same. In the case of n channel EDMOS(nEDMOS), the drift region has a lattice structure in which an n lattice having a high concentration and a p lattice having a low concentration are alternately arranged. As a drain voltage is applied, a depletion layer is abruptly extended by a pn junction of the n lattice and the p lattice, so that the entire drift region is easily depleted. Therefore, a breakdown voltage of the device is increased, and an on resistance of the device is decreased due to the n lattice with high concentration.

Abstract: The present invention relates to a ferroelectric memory cell array formed of a single transistor, and method of storing data using the same. The ferroelectric memory cell array includes a plurality of word lines connected to gates of the memory cells located at respective rows, a plurality of bit lines connected to drains of the memory cells located at respective columns, a common source line commonly connecting sources of the memory cells, and a plurality of well lines each connected to wells in which the memory cells are each formed, wherein a bias voltage of an unit pulse shape is applied to a gate of a selected memory cell and a bias voltage of a pulse shape is applied to a well line. Therefore, the present invention allows a random access without a disturbance since data can be written by means of the polarity characteristic of the ferroelectric.

Abstract: The present invention provides an EDMOS (extended drain MOS) device having a lattice type drift region and a method of manufacturing the same. In the case of n channel EDMOS(nEDMOS), the drift region has a lattice structure in which an n lattice having a high concentration and a p lattice having a low concentration are alternately arranged. As a drain voltage is applied, a depletion layer is abruptly extended by a pn junction of the n lattice and the p lattice, so that the entire drift region is easily depleted. Therefore, a breakdown voltage of the device is increased, and an on resistance of the device is decreased due to the n lattice with high concentration.

Abstract: The present invention provides an EDMOS (extended drain MOS) device having a lattice type drift region and a method of manufacturing the same. In the case of n channel EDMOS(nEDMOS), the drift region has a lattice structure in which an n lattice having a high concentration and a p lattice having a low concentration are alternately arranged. As a drain voltage is applied, a depletion layer is abruptly extended by a pn junction of the n lattice and the p lattice, so that the entire drift region is easily depleted. Therefore, a breakdown voltage of the device is increased, and an on resistance of the device is decreased due to the n lattice with high concentration.

Abstract: The present invention relates to a method of fabricating a high-voltage high-power integrated circuit device using a substrate of a SOI structure in which an insulating film and a silicon layer are sequentially stacked on a silicon substrate.

Abstract: The present invention relates to a ferroelectric memory cell array formed of a single transistor, and method of storing data using the same. The ferroelectric memory cell array includes a plurality of word lines connected to gates of the memory cells located at respective rows, a plurality of bit lines connected to drains of the memory cells located at respective columns, a common source line commonly connecting sources of the memory cells, and a plurality of well lines each connected to wells in which the memory cells are each formed, wherein a bias voltage of an unit pulse shape is applied to a gate of a selected memory cell and a bias voltage of a pulse shape is applied to a well line. Therefore, the present invention allows a random access without a disturbance since data can be written by means of the polarity characteristic of the ferroelectric.

Abstract: A method of fabricating a vertical TDMOS power device using sidewall spacers and a self-align technique and a TDMOS power device of the same. The TDMOS is fabricated using only 3 masks and a source is formed using the self-align technique to embody a highly integrated trench formation. During the process, ion implantation of high concentration into the bottom of the trench makes a thick oxide film grow on the bottom and the corner of the gate, so that electrical characteristic, specifically leakage current and breakdown voltage of the device can be improved. Also, process steps can be much decreased to lower process cost, high integration is possible, and reliability of the device can be improved.

Abstract: A method for manufacturing a trench-gate type power semiconductor device is provided. A drift region having a low concentration of a first conductivity type and a body region of a second conductivity type are formed on a semiconductor substrate having a high concentration of the first conductivity type. A trench is formed using a nitride layer pattern and a sidewall oxide layer formed at sidewalls of the nitride layer pattern as a mask, and then the sidewall oxide layer is removed. The corners of the trench are rounded by performing a heat treatment in a hydrogen atmosphere. A source region having a high concentration of the first conductivity type is formed using the nitride layer pattern as a mask. The nitride layer pattern is removed, and an upper oxide layer pattern is formed to cover a predetermined portion of the source region and the gate conductive layer. A body contact region of the second conductivity type is formed using the upper oxide layer pattern as a mask.

Abstract: A method for manufacturing a trench-gate type power semiconductor device is provided A drift region having a low concentration of a first conductivity type and a body region of a second conductivity type are formed on a semiconductor substrate having a high concentration of the first conductivity type A trench is formed using a nitride layer pattern and a sidewall oxide layer formed at sidewalls of the nitride layer pattern as a mask, and then the sidewall oxide layer is removed The corners of the trench are rounded by performing a heat treatment in a hydrogen atmosphere A source region having a high concentration of the first conductivity type is formed using the nitride layer pattern as a mask. The nitride layer pattern is removed, and an upper oxide layer pattern is formed to cover a predetermined portion of the source region and the gate conductive layer.

Abstract: The present invention relates to a method of fabricating a vertical TI)MOS power device using sidewall spacers and a self-align technique and a TDMOS power device of the same. The TDMOS according to the present invention is fabricated using only 3 masks and a source is formed using the self-align technique to embody a highly integrated trench formation. During the process, ion implantation of high concentration into the bottom of the trench makes a thick oxide film grow on the bottom and the corner of the gate, so that electrical characteristic, specifically leakage current and breakdown voltage of the device can be improved. Also, process steps can be much decreased to lower process cost, high integration is possible, and reliability of the device can be improved.

Abstract: A semiconductor technique is disclosed. Particularly a low voltage high current power device for use in a lithium ion secondary battery protecting circuit, a DC-DC converter and a motor is disclosed. Further, a method for fabricating a high density trench gate type power device is disclosed. That is, in the present invention, a trench gate mask is used for forming the well and/or source, and for this purpose, a side wall spacer is introduced. In this manner, the well and/or source is defined by using the trench gate mask, and therefore, 1 or 2 masking processes are skipped unlike the conventional process in which the well mask and the source mask are separately used. The decrease in the use of the masking process decreases the mask align errors, and therefore, the realization of a high density is rendered possible. Consequently, the on-resistance which is an important factor for the power device can be lowered.