Abstract: A field effect transistor includes laterally spaced apart source and drain regions in a substrate, laterally spaced apart undoped regions in the substrate between the laterally spaced apart source and drain regions, a doped channel region in the substrate between the laterally spaced apart undoped regions, and a gate insulating layer on the substrate. A main gate is on the gate insulating layer opposite the channel, and first and second sub gates are on the gate insulating layer, a respective one of which is opposite a respective one of the spaced apart undoped regions. The first and second sub gates are laterally spaced apart from and electrically insulated from the main gate.

Abstract: A method for fabricating a MOS transistor having an offset resistance in a channel region controlled by a gate voltage and structure thereof is disclosed. A gate electrode is divided into three adjacent regions of respectively a second conductivity type, first conductivity type and second conductivity type connected laterally to one another on a channel region. A gate control voltage is applied to a central region of the first conductivity type, and a predetermined voltage between maximum and minimum values of the gate control voltage is applied to left and right adjacent regions of the second conductivity type. If a gate turn-on voltage is applied to the central region the gate turn-on voltage is forward biased to the adjacent left and right regions and is therefore also applied to the forwardly biased left and right regions. The effective length of the gate electrode then becomes the total length of the central region and the left and right adjacent regions.

Abstract: A field effect transistor includes laterally spaced apart source and drain regions in a substrate, laterally spaced apart undoped regions in the substrate between the laterally spaced apart source and drain regions, a doped channel region in the substrate between the laterally spaced apart undoped regions, and a gate insulating layer on the substrate. A main gate is on the gate insulating layer opposite the channel, and first and second sub gates are on the gate insulating layer, a respective one of which is opposite a respective one of the spaced apart undoped regions. The first and second sub gates are laterally spaced apart from and electrically insulated from the main gate.

Abstract: Methods of forming thin-film transistors include the steps of forming an amorphous silicon (a-Si) layer of predetermined conductivity type on a face of an electrically insulating substrate and then forming a first insulating layer on the amorphous silicon layer. The first insulating layer and amorphous silicon layer are then patterned to define spaced amorphous source and drain regions having exposed sidewalls. An amorphous silicon channel region is then deposited in the space between the source and drain regions and in contact with the sidewalls thereof. An annealing step is then performed to convert the amorphous source, drain and channel regions to polycrystalline silicon, prior to the step of forming an insulated gate electrode on the channel region.

Abstract: To accomplish the objects of the present invention, among others, the present invention provides a thin-film transistor that has a channel region operatively having an offset region only during turn-off. Source and drain regions self-aligned with different ends of the channel region. A gate region is formed on a gate insulating layer disposed over the channel region and has a main gate accepting a gate voltage, a subgate which comes into ohmic contact with the source region, and a junction gate for forming a rectifying junction between the main gate and subgate.

Abstract: A field effect transistor includes laterally spaced apart source and drain regions in a substrate, laterally spaced apart undoped regions in the substrate between the laterally spaced apart source and drain regions, a doped channel region in the substrate between the laterally spaced apart undoped regions, and a gate insulating layer on the substrate. A main gate is on the gate insulating layer opposite the channel, and first and second sub gates are on the gate insulating layer, a respective one of which is opposite a respective one of the spaced apart undoped regions. The first and second sub gates are laterally spaced apart from and electrically insulated from the main gate.

Abstract: A method for fabricating a MOS transistor having an offset resistance in a channel region controlled by a gate voltage and structure thereof is disclosed. A gate electrode is divided into three adjacent regions of respectively a second conductivity type, first conductivity type and second conductivity type connected laterally to one another on a channel region. A gate control voltage is applied to a central region of the first conductivity type, and a predetermined voltage between maximum and minimum values of the gate control voltage is applied to left and right adjacent regions of the second conductivity type. If a gate turn-on voltage is applied to the central region the gate turn-on voltage is forward biased to the adjacent left and right regions and is therefore also applied to the forwardly biased left and right regions. The effective length of the gate electrode then becomes the total length of the central region and the left and right adjacent regions.

Abstract: A process for manufacturing an offset gate structure thin film transistor which includes the steps of forming a first semiconductor layer, e.g., an active layer made of amorphous silicon or polysilicon, on a major surface of a substrate, e.g.

Abstract: A data transmission circuit capable of a high-speed data input/output operation and a large-scaled integration for use in a semiconductor memory device, is disclosed. The data transmission circuit has at least one memory cell 51, a word line 52, a pair of bit lines 65, 66, a sense amplifier 55, and a pair of isolation transistors 53, 54. Further, the circuit includes a pair of common input/output lines 67, 68 for transmitting input or output data with a complementary logic operation, a discharging transistor 56 receiving a control signal at its gate and having a channel connected with a ground voltage node, for transferring an electric potential applied to one end of the channel into the ground voltage level, and a pair of transmission transistors 59, 60 receiving the control signal at their respective gates and having each channel connected with the common input/output lines.