Abstract: A semiconductor IC device includes a base substrate comprising P?-type silicon, a first P+-type silicon layer is provided on the base substrate, and an N+-type silicon layer and a second P+-type silicon layer are provided in the same layer thereon. The impurity concentration of the first P+-type silicon layer and the N+-type silicon layer is higher than that of the base substrate. Also, a buried oxide layer and an SOI layer are provided on the entire upper surface of the N+-type silicon layer and the second P+-type silicon layer. The first P+-type silicon layer is connected to ground potential wiring GND, and the N+-type silicon layer is connected to power-supply potential wiring VDD. Accordingly, a decoupling capacitor, which is connected in parallel to the power supply, is formed between the P+-type silicon layer and the N+-type silicon layer.

Abstract: The bottom side of an N type silicon substrate is connected to a power supply terminal, a second P type epitaxial layer is formed on all sides of the N type silicon substrate, and a device forming portion is provided on the second P type epitaxial layer. A first P type epitaxial layer and an interlayer insulating film are provided on the device forming portion and an N well and a P well are formed on the top surface of the first P type epitaxial layer. The second P type epitaxial layer is connected to a ground terminal via the first P type epitaxial layer, the P well, a p+ diffusion region, a via and a wire. Accordingly, a pn junction is formed at the interface between the second P type epitaxial layer and the N type silicon substrate.

Abstract: An image sensor is disclosed that prevents a photoelectrically-converted signal from being corrupted during a readout operation. The image sensor includes a line-selection line located on an upper side of a pixel relative to a top to bottom scan direction and disposed across the pixel in a direction substantially perpendicular to the top to bottom scanning direction. A signal reset line is located on a lower side of the pixel relative to a top to bottom scan direction and is disposed across the pixel in a direction substantially perpendicular to the top to bottom scanning direction. The line-selection line and the signal-reset line are disposed above and below a photoelectric conversion portion of the pixel.

Abstract: A semiconductor IC device includes a base substrate comprising P?-type silicon, a first P+-type silicon layer is provided on the base substrate, and an N+-type silicon layer and a second P+-type silicon layer are provided in the same layer thereon. The impurity concentration of the first P+-type silicon layer and the N+-type silicon layer is higher than that of the base substrate. Also, a buried oxide layer and an SOI layer are provided on the entire upper surface of the N+-type silicon layer and the second P+-type silicon layer. The first P+-type silicon layer is connected to ground potential wiring GND, and the N+-type silicon layer is connected to power-supply potential wiring VDD. Accordingly, a decoupling capacitor, which is connected in parallel to the power supply, is formed between the P+-type silicon layer and the N+-type silicon layer.

Abstract: In a temperature sensor section of a semiconductor integrated circuit device, first vias of tungsten are formed at the topmost layer of a multi-layer wiring layer and pads of titanium are provided on regions of the multi-layer wiring layer which covers the vias. An insulating layer is provided in such a way as to cover the multi-layer wiring layer and the pads, second vias are so formed as to reach the pads. Vanadium oxide is buried in the second vias by reactive sputtering, and a temperature monitor part of vanadium oxide is provided in such a way as to connect the second vias each other. Accordingly, the temperature monitor part is connected between the two wires.

Abstract: In a conventional solid state imaging device, there is a room for improvement in sensitivity. In order to solve the problem, a solid state imaging device includes a semiconductor substrate and a light receiving portion. The light receiving portion is provided adjacent to a surface layer on the surface (a first surface) side of the semiconductor substrate. The surface of the light receiving portion is silicided. The solid state imaging device is one in which light from an object to be imaged incident on the back side (a second surface) of the semiconductor substrate is photoelectric-converted inside the semiconductor substrate, the light receiving portion receives electric charge generated by the photoelectric conversion, and the above mentioned object to be imaged is imaged.

Abstract: Conventional capacitors constituted of a FET incur degradation in frequency response. A semiconductor integrated circuit includes a semiconductor substrate, an N-type FET, a P-type FET, and capacitors. The N-type FET includes N-type impurity diffusion layers, a P-type impurity-implanted region, a gate insulating layer, and a gate electrode. The P-type FET includes P-type impurity diffusion layers, an N-type impurity-implanted region, a gate insulating layer, and a gate electrode. The capacitor includes N-type impurity diffusion layers, an N-type impurity-implanted region, a capacitance insulating layer, and an upper electrode. The capacitor includes P-type impurity diffusion layers, a P-type impurity-implanted region, a capacitance insulating layer, and an upper electrode.

Abstract: It is concerned in conventional semiconductor devices that a presence of a heat sink promotes propagating noise through the semiconductor chip. A semiconductor device includes a substrate, interconnects (first interconnects), interconnects (second interconnect), a semiconductor chip and a heat sink (electroconductive member). The interconnect is the interconnect that is electrically coupled to an internal interconnect of the semiconductor chip. On the contrary, the interconnect is the interconnect that is electrically coupled to a back surface (first surface) of the semiconductor chip. The interconnects are electrically insulated from the interconnects in the substrate. The semiconductor chip is provided on the substrate. A predetermined fixed potential is presented at the back surface of such semiconductor chip through the interconnect.

Abstract: A semiconductor device capable of integrally controlling thresholds of gate electrodes of transistors present in a region of one-conductivity-type and transistors present in a region of an reverse-conductivity-type while suppressing noise propagation is provided. A digital circuit region 123 and an analog circuit region 121 are provided on a P—Si substrate 101. P-wells 103 and 193 and N-wells 105 and 195 are provided in the analog circuit region 121. P-wells 107 and 197 and N-wells 109 and 199 are provided in the digital circuit region 123. A mesh-like deep N-well 111 is provided to contact with lower surfaces of the P-well 103 and the N-well 105. A mesh-like deep N-well 113 is provided to contact with lower surfaces of the P-well 107 and the N-well 109.

Abstract: A voltage-controlled oscillator operates stably over a narrow variation range of a control voltage, including a variable capacitance circuit 12 controllable by voltage, an inductor circuit 11 having inductors, a negative resistance circuit 13, and a capacitance control circuit 14 that outputs a correction voltage. An oscillator circuit is constituted by the variable capacitance circuit 12, the inductor circuit 11, and the negative resistance circuit 13 connected in parallel. The capacitance control circuit 14 controls to correct the capacitance of the variable capacitance circuit 12 with the correction voltage outputted in response to a temperature fluctuation and/or power supply voltage fluctuation in the oscillator circuit.

Abstract: A semiconductor device includes a signal output unit, and a decision unit. The signal output unit includes m (?2) pieces of fuses, a NAND gate, resistance elements, and an output terminal. The decision unit decides whether n or more pieces (m?n?2) of fuses are disconnected out of the m pieces of fuses included in the signal output unit, and outputs the result of a decision. When m=n=2, the decision unit is constituted of a NOR gate having two input terminals connected to a respective end of the fuses. Thus, a H-level potential signal is output at an output terminal of the NOR gate when the decision result is affirmative. On the other hand, when the decision result is negative, a L-level potential signal is output at the output terminal.

Abstract: A semiconductor device includes a semiconductor substrate, and an electrical fuse provided on the semiconductor substrate. The electrical fuse includes a first fuse link and a second fuse link mutually connected in series, a first current inlet/outlet terminal (first terminal) and a second current inlet/outlet terminal (second terminal) respectively provided at an end and the other end of the first fuse link, and a third current inlet/outlet terminal (second terminal) and a fourth current inlet/outlet terminal (third terminal) provided at an end and the other end of the second fuse link.

Abstract: A semiconductor device, in which four pieces of strip-shaped electrodes, whose longitudinal directions are the same, are formed in each layer of a plurality of wiring layers that are provided by a same design rule with each other, simultaneously with regular wirings. In each wiring layer, two pieces each of first electrode and second electrode are formed parallelly with each other, alternately, and remote from each other. Then, the first electrodes formed in each layer are connected to each other by a first via, the second electrodes formed in each layer are connected to each other by a second via, a first structure body formed by connecting the first electrodes and the first via to each other is connected to a ground wiring, and a second structure body formed by connecting the second electrodes and the second via to each other is connected to a power source wiring.

Abstract: Disclosed are an inductor for a semiconductor integrated circuit, which provides a wider cross-sectional area, significantly reduces the resistance to improve the Q value and has a highly uniform film thickness, and a method of fabricating the inductor. A spiral inductor is formed on a topmost interconnection layer of a multilayer interconnection layer formed by a damascene method. This inductor is formed by patterning a barrier metal layer on an insulation film, on which a topmost interconnection is formed, in such a way that the barrier metal layer contacts the topmost interconnection, then forming a protective insulation film on an entire surface of the barrier metal layer, forming an opening in that portion of the protective insulation film which lies over the barrier metal layer, forming a thick Cu film with the barrier metal layer serving as a plating electrode, and performing wet etching of the Cu film. This process can allow the inductor to be so formed as to be thick and have a wide line width.

Abstract: At an element formation surface side of a p-type Si substrate, a digital circuit and an analog circuit are provided. The analog circuit includes a p-type well and n-type wells formed at the element formation surface side of the p-type Si substrate. The analog circuit includes a deep n-type well located closer to the bottom side of the p-type Si substrate than the p-type well, so as to isolate the p-type well from a bottom-side region of the p-type Si substrate. The deep n-type well includes a first deep n-type well. The deep n-type well includes a second deep n-type well located closer to the bottom side of the p-type Si substrate than the first deep n-type well, and having an n-type impurity concentration, which is different from the first deep n-type well.

Abstract: A semiconductor device capable of integrally controlling thresholds of gate electrodes of transistors present in a region of one-conductivity-type and transistors present in a region of an reverse-conductivity-type while suppressing noise propagation is provided. A digital circuit region 123 and an analog circuit region 121 are provided on a P—Si substrate 101. P-wells 103 and 193 and N-wells 105 and 195 are provided in the analog circuit region 121. P-wells 107 and 197 and N-wells 109 and 199 are provided in the digital circuit region 123. A mesh-like deep N-well 111 is provided to contact with lower surfaces of the P-well 103 and the N-well 105. A mesh-like deep N-well 113 is provided to contact with lower surfaces of the P-well 107 and the N-well 109.

Abstract: The solid state image pick-up device comprises a chip wherein an object to be photographed is put directly on the back surface of the chip, a light incident on the object enters the inner portion of the chip, signal electric charges generated in the inner portion of the chip by the light, the signal electric charges are collected in a photo detective region and the photo detective region has a barrier diffusion layer adjacent thereto so as to collect the signal electric charges effectively. The above-mentioned structure of the solid state image pick-up device can provide superior features that the chip of the solid state image pick-up device is protected from the deterioration of elements included in the chip and the destruction of the elements by Electro Static Discharge, resulting in the reliability improvement of the chip.

Abstract: A capacity element with a simple configuration exhibits excellent production reliability. A semiconductor device 100 includes a capacity element consisting of a lower electrode 102, an SiCN film 107 and an upper electrode 113. In an insulating film 101 on a semiconductor substrate is formed a groove, in which the lower electrode 102 is buried. The lower electrode 102 includes two regions, that is, a first lower electrode 103 and a second lower electrode 105, which are separated from each other via the insulating film 101.

Abstract: The solid state image pick-up device comprises a chip wherein an object to be photographed is put directly on the back surface of the chip, a light incident on the object enters the inner portion of the chip, signal electric charges generated in the inner portion of the chip by the light, the signal electric charges are collected in a photo detective region and the photo detective region has a barrier diffusion layer adjacent thereto so as to collect the signal electric charges effectively. The above-mentioned structure of the solid state image pick-up device can provide superior features that the chip of the solid state image pick-up device is protected from the deterioration of elements included in the chip and the destruction of the elements by Electro Static Discharge, resulting in the reliability improvement of the chip.

Abstract: The present invention provides a semiconductor device comprising a capacitive element with a very uniform capacitive value as well as a method of manufacturing the semiconductor device. In a capacitive element formation region 20 of a semiconductor device 1, an N-type well 22 as a conductive layer is formed in a surface layer of a P-type semiconductor substrate 10. A capacitive film 24 is deposited on a front surface of the semiconductor substrate 10 on which the N-type well 22 is formed. The part of front surface of the semiconductor substrate 10 in which the capacitive film 24 is deposited is substantially flat. An upper electrode 26 is provided on the capacitive film 24. The upper electrode 26 constitutes a capacitive element (on-chip capacitor) together with the N-type well 22, located opposite the upper electrode 26 across the capacitive film 24.