Abstract: A semiconductor system includes a first semiconductor chip, a second semiconductor chip stacked above the first semiconductor chip, a controller configured to control the first and second semiconductor chips, a first wiring connected between the controller and each of the first and second semiconductor chips and by which a first signal is to be transmitted from the controller to each of the first and second semiconductor chips, a second wiring connected between the controller and the first semiconductor chip and by which a current of the first signal flowing through the first wiring to the first semiconductor chip is to be returned to the controller, and a third wiring connected between the controller and the second semiconductor chip and by which a current of the first signal flowing through the first wiring to the second semiconductor chip is to be returned to the controller.

Abstract: A third interconnection layer is disposed near a first interconnection layer and a second interconnection layer disposed above the first interconnection layer. The first interconnection layer and second interconnection layer are connected to each other by a regular via plug and a via plug for redundancy. The via plug for redundancy is disposed by the side of the regular via plug and between the regular via plug and the third interconnection layer. An extended portion of the second interconnection layer is extended from a portion connected to the via plug for redundancy on the second interconnection layer toward the third interconnection layer. The extended portion has a dimension smaller than the minimum dimension prescribed in the interconnection line design rule.

Abstract: A third interconnection layer is disposed near a first interconnection layer and a second interconnection layer disposed above the first interconnection layer. The first interconnection layer and second interconnection layer are connected to each other by a regular via plug and a via plug for redundancy. The via plug for redundancy is disposed by the side of the regular via plug and between the regular via plug and the third interconnection layer. An extended portion of the second interconnection layer is extended from a portion connected to the via plug for redundancy on the second interconnection layer toward the third interconnection layer. The extended portion has a dimension smaller than the minimum dimension prescribed in the interconnection line design rule.

Abstract: According to the embodiments, an impact ionization current is calculated based on a drain transverse electric field calculation formula in which a saturated source-drain voltage is given by a function of a source-gate voltage and a source-drain voltage.

Abstract: A semiconductor circuit deterioration simulation method for a circuit including MOSFETs includes inserting a dynamic voltage source associated with a fluctuation in voltage/current characteristics into each gate terminal of a plurality of MOSFETs in series, calculating dynamic deterioration amounts of the plurality of MOSFETs by performing circuit simulation and calculating a dynamic deterioration amount, and repeating the above processing to perform the circuit deterioration simulation over the long term.

Abstract: Semiconductor devices whose current characteristics can be prevented from varying even if a phase shift mask is used for patterning gate electrodes of MISFETs, and a manufacturing method thereof are disclosed. According to one aspect of the present invention, there is provided a semiconductor device comprising a first transistor including a first gate electrode provided above a semiconductor substrate, and a first source and a first drain provided in the semiconductor substrate, a second transistor arranged to be adjacent to the first transistor, and including a second gate electrode provided above the semiconductor substrate in parallel with the first gate electrode, and a second source and a second drain provided in the semiconductor substrate, and a third gate electrode provided between the first transistor and the second transistor and in parallel with the first and second gate electrodes.

Abstract: Semiconductor devices whose current characteristics can be prevented from varying even if a phase shift mask is used for patterning gate electrodes of MISFETs, and a manufacturing method thereof are disclosed. According to one aspect of the present invention, there is provided a semiconductor device comprising a first transistor including a first gate electrode provided above a semiconductor substrate, and a first source and a first drain provided in the semiconductor substrate, a second transistor arranged to be adjacent to the first transistor, and including a second gate electrode provided above the semiconductor substrate in parallel with the first gate electrode, and a second source and a second drain provided in the semiconductor substrate, and a third gate electrode provided between the first transistor and the second transistor and in parallel with the first and second gate electrodes.

Abstract: A third interconnection layer is disposed near a first interconnection layer and a second interconnection layer disposed above the first interconnection layer. The first interconnection layer and second interconnection layer are connected to each other by a regular via plug and a via plug for redundancy. The via plug for redundancy is disposed by the side of the regular via plug and between the regular via plug and the third interconnection layer. An extended portion of the second interconnection layer is extended from a portion connected to the via plug for redundancy on the second interconnection layer toward the third interconnection layer. The extended portion has a dimension smaller than the minimum dimension prescribed in the interconnection line design rule.

Abstract: A semiconductor device includes a monocrystalline silicon substrate, an insulating film consisting of a monocrystalline silicon oxide formed on the surface of the monocrystalline silicon substrate, and a conductive film formed on the insulating film. The monocrystalline silicon substrate has a (100) plane orientation, the insulating film essentially consists of .beta.-cristobalite having a unit structure in a P4.sub.1 2.sub.1 2 structural expression in such a manner that every other silicon atoms of four silicon atoms aligned about a C-axis are arranged on two adjacent silicon atoms aligned in a 110! direction on an Si (100) plane, and that a plane including the C-axis of the .beta.-cristobalite and the 110! direction is set perpendicular to the (100) plane.