Abstract: A digital filter for image processing which permits a reduction in the size of the circuit includes a plurality of bit shifters for multiplying each picture element data of a k.times.k matrix, each by a coefficient which corresponds to the respective picture element. A first adder circuit adds the output data of all of the bit shifters. A first multiplier circuit multiplies picture element data of a center picture element of the k.times.k matrix by a predetermined coefficient. A second multiplier circuit multiplies output data of the first adder circuit by a predetermined coefficient and a second adder circuit adds output data of the first multiplier circuit and that of the second multiplier circuit.

Abstract: An integrated circuit device has reduced stress concentration on the IC chip for prevention of package cracks in the device. Recessed portions are formed in the package at positions corresponding to at least the corner portions of the IC chip to reduce the stress concentration generated at the corner portions of the IC chip.

Abstract: The output of the first CMOS inverter, connected as an oscillator, is applied to the inputs of second and third CMOS inverters that have logic threshold voltages higher and lower than the logic threshold voltage of the first inverter. The outputs of the second and third CMOS inverters are connected to an output circuit via a logic output circuit. The output of the logic output circuit is shorted by an output control circuit, under the control of the outputs of the second and third CMOS inverters, when the output of the oscillator is between the logic threshold voltages of the second and third inverters.

Abstract: A semiconductor includes a conductor layer formed on one side thereof toward a first surface of a substrate, and a first interlayer insulation layer on the conductor layer. The first interlayer insulation layer has a first opening extending therethrough to the conductor layer. A first wiring layer is provided on the first interlayer insulation layer, and connected to the conductor layer via the first opening. A second interlayer insulation layer is formed on the first wiring layer and has a second opening extending through the first opening to the first wiring layer. A second wiring layer is formed on the second interlayer insulation layer and extends through the second interlayer to the first wiring layer and/or the conductor layer via the first opening and the second opening.

Abstract: A silicon thin film transistor array includes a plurality of silicon thin film transistors in an array-like form, each silicon thin film transistor including an insulating substrate, a gate electrode formed on the insulating substrate, a gate insulating layer formed on the insulating substrate containing the gate electrode, a pair of first impurity contained silicon layers formed on the gate insulating layer in such a manner as to transversely cross a terminal part of the gate electrode, an intrinsic silicon layer formed on the pair of first impurity contained silicon layers and on the gate insulating layer between the pair of first impurity contained silicon layers in such a manner as to connect the pair of first impurity contained silicon layers, a protective insulation layer formed on the intrinsic silicon layer, and a source electrode and a drain electrode formed at contact parts of the pair of first impurity contained silicon layers; gate wiring for connecting the gate electrodes of the silicon thin film

Abstract: A silicon thin film transistor array includes a plurality of silicon thin film transistors in an array-like form, each silicon thin film transistor including an insulating substrate, a gate electrode formed on the insulating substrate, a gate insulating layer formed on the insulating substrate containing the gate electrode, a pair of first impurity contained silicon layers formed on the gate insulating layer in such a manner as to transversely cross a terminal part of the gate electrode, an intrinsic silicon layer formed on the pair of first impurity contained silicon layers and on the gate insulating layer between the pair of first impurity contained silicon layers in such a manner as to connect the pair of first impurity contained silicon layers, a protective insulation layer formed on the intrinsic silicon layer, and a source electrode and a drain electrode formed at contact parts of the pair of first impurity contained silicon layers; gate wiring for connecting the gate electrodes of the silicon thin film

Abstract: A silicon thin film transistor array includes a plurality of silicon thin film transistors in an array-like form, each silicon thin film transistor including an insulating substrate, a gate electrode formed on the insulating substrate, a gate insulating layer formed on the insulating substrate containing the gate electrode, a pair of first impurity contained silicon layers formed on the gate insulating layer in such a manner as to transversely cross a terminal part of the gate electrode, an intrinsic silicon layer formed on the pair of first impurity contained silicon layers and on the gate insulating layer between the pair of first impurity contained silicon layers in such a manner as to connect the pair of first impurity contained silicon layers, a protective insulating layer formed on the intrinsic silicon layer, and a source electrode and a drain electrode formed at contact parts of the pair of first impurity contained silicon layers; gate wiring for connecting the gate electrodes of the silicon thin film

Abstract: A method for producing a reverse staggered type silicon thin film transistor includes the steps of forming a gate insulating layer on a substrate having a gate electrode, the gate insulating layer having a transistor-forming portion; forming an intrinsic silicon film on the transistor-forming portion of the gate insulating layer; forming an n-type silicon layer on the intrinsic silicon layer; forming a source electrode on the n-type silicon layer; forming a drain electrode on the n-type silicon layer; forming a resist layer on the source electrode and drain electrode and having the same shape thereof; subsequently removing a portion of the n-type silicon layer by using the resist layer as a mask, such that there remains a predetermined thickness of the n-type silicon layer; and doping the predetermined thickness of the n-type silicon layer with p-type impurities by using the resist layer as a mask.

Abstract: A silicon thin film transistor array includes a plurality of silicon thin film transistors in an array-like form, each silicon thin film transistor including an insulating substrate, a gate electrode formed on the insulating substrate, a gate insulating layer formed on the insulating substrate containing the gate electrode, a pair of first impurity contained silicon layers formed on the gate insulating layer in such a manner as to transversely cross a terminal part of the gate electrode, an intrinsic silicon layer formed on the pair of first impurity contained silicon layers and on the gate insulating layer between the pair of first impurity contained silicon layers in such a manner as to connect the pair of first impurity contained silicon layers, a protective insulation layer formed on the intrinsic silicon layer, and a source electrode and a drain electrode formed at contact parts of the pair of first impurity contained silicon layers; gate wiring for connecting the gate electrodes of the silicon thin film

Abstract: A silicon thin film transistor array includes a plurality of silicon thin film transistors in an array-like form, each silicon thin film transistor including an insulating substrate, a gate electrode formed on the insulating substrate, a gate insulating layer formed on the insulating substrate containing the gate electrode, a pair of first impurity contained silicon layers formed on the gate insulating layer in such a manner as to transversely cross a terminal part of the gate electrode, an intrinsic silicon layer formed on the pair of first impurity contained silicon layers and on the gate insulating layer between the pair of first impurity contained silicon layers in such a manner as to connect the pair of first impurity contained silicon layers, a protective insulation layer formed on the intrinsic silicon layer, and a source electrode and a drain electrode formed at contact parts of the pair of first impurity contained silicon layers; gate wiring for connecting the gate electrodes of the silicon thin film

Abstract: A resistor for a semiconductor device includes a thin film resistor layer sandwiched between thin film silicon layers. A thin film silicon oxide layer formed on the upper silicon layer prevents oxidation of the upper silicon layer, so that the upper silicon layer serves as a stopper for subsequent etching of the device to provide contacts for the resistor.

Abstract: A silicon thin film transistor array includes a plurality of silicon thin film transistors in an array-like form, each silicon thin film transistor including an insulating substrate, a gate electrode formed on the insulating substrate, a gate insulating layer formed on the insulating substrate containing the gate electrode, a pair of first impurity contained silicon layers formed on the gate insulating layer in such a manner as to transversely cross a terminal part of the gate electrode, an intrinsic silicon layer formed on the pair of first impurity contained silicon layers and on the gate insulating layer between the pair of first impurity contained silicon layers in such a manner as to connect the pair of first impurity contained silicon layers, a protective insulation layer formed on the intrinsic silicon layer, and a source electrode and a drain electrode formed at contact parts of the pair of first impurity contained silicon layers; gate wiring for connecting the gate electrodes of the silicon thin film

Abstract: A reverse staggered type silicon thin film transistor includes a substrate having a gate electrode; a gate insulating layer on the substrate and the gate electrode, the gate insulating layer having a transistor-forming portion; a lower layer silicon film on the transistor-forming portion of the gate insulating layer and in contact therewith, the lower layer silicon film being formed at a first temperature and with a first thickness; an upper layer silicon film formed on the transistor-forming portion of the gate insulating layer at a second temperature which is lower than the first temperature and with a second thickness greater than the first thickness; an n-type silicon layer on the upper layer silicon film and in contact therewith; a source electrode on the n-type silicon layer; and a drain electrode on the n-type silicon layer.

Abstract: An amorphous silicon thin film transistor includes a gate electrode, an amorphous silicon layer on the gate insulating layer, a drain electrode and a source electrode on the amorphous silicon layer such that a portion of the side of the amorphous silicon layer which faces away from the gate electrode is exposed, and an impurity layer for reducing an off current of the transistor, the impurity layer including an impurity forming an acceptor and which is formed on the exposed portion of the amorphous silicon layer, the amorphous silicon layer being of a first conduction type and the acceptor being of a second different conduction type.

Abstract: A semiconductor device has a fuse element formed on an insulating substrate, and a first insulating layer formed on the substrate and covering the fuse element. Further insulation on the first insulating layer nitride has an opening exposing the region of the first insulating layer above said fuse.

Abstract: A silicon thin film transistor array includes a plurality of silicon thin film transistors in an array-like form, each silicon thin film transistor including an insulating substrate, a gate electrode formed on the insulating substrate, a gate insulating layer formed on the insulating substrate containing the gate electrode, a pair of first impurity contained silicon layers formed on the gate insulating layer in such a manner as to transversely cross a terminal part of the gate electrode, an intrinsic silicon layer formed on the pair of first impurity contained silicon layers and on the gate insulating layer between the pair of first impurity contained silicon layers in such a manner as to connect the pair of first impurity contained silicon layers, a protective insulation layer formed on the intrinsic silicon layer, and a source electrode and a drain electrode formed at contact parts of the pair of first impurity contained silicon layers; gate wiring for connecting the gate electrodes of the silicon thin film

Abstract: A reverse staggered amorphous-silicon thin film transistor array substrate includes amorphous silicon thin film transistors in an array, gate wirings interconnecting the gate electrodes of the transistors, and source wirings of a transparent conductive layer connecting the source electrodes. An auxiliary source wiring of the material of the source electrodes of said transistors is provided under the source wiring.

Abstract: A reverse staggered type silicon thin film transistor includes a substrate having a gate electrode; a gate insulating layer on the substrate and the gate electrode, the gate insulating layer having a transistor-forming portion; a lower layer silicon film on the transistor-forming portion of the gate insulating layer and in contact therewith, the lower layer silicon film being formed at a first temperature and with a first thickness; an upper layer silicon film formed on the transistor-forming portion of the gate insulating layer at a second temperature which is lower than the first temperature and with a second thickness greater than the first thickness; and n-type silicon layer on the upper layer silicon film and in contact therewith; a source electrode on the n-type silicon layer; and a drain electrode on the n-type silicon layer.

Abstract: A digital-to-analog converter comprising: a distributing circuit (2, 3, 4, 5; 2, 13, 14-26) for distributing data pulses, which are bit-serially supplied at constant time intervals, into a plurality of routesand for providing them as pulses having a constant width; and a converting circuit (12) for adding together the pulses from the distributing circuit and thereby for converting them to an analog output. Such a circuit arrangement can provide pulses for conversion to analog form which all have an identical waveform and an identical area, and errors caused by the difference between the rise and fall times of the pulses can be eliminated and therefore D/A conversion characteristics can be improved.

Abstract: A method for manufacturing a amorphous silicon thin film transistor comprises exposing an morphous silicon layer situated between a source electrode and a drain electrode to a gas phase atmosphere having a gas containing an impurity forming an acceptor, then activating said impurity with an electric field or light energy and doping the activated impurity into said amorphous silicon layer. The gas may be a hydrogen compound and it may include an oxidizing gas.