A semiconductor device (1) is manufactured which includes a SiC epitaxial layer (28), a plurality of transistor cells (18) that are formed in the SiC epitaxial layer (28) and that are subjected to ON/OFF control by a predetermined control voltage, a gate electrode (19) that faces a channel region (32) of the transistor cells (18) in which a channel is formed when the semiconductor device (1) is in an ON state, a gate metal (44) that is exposed at the topmost surface for electrical connection with the outside and that is electrically connected to the gate electrode (19) while being physically separated from the gate electrode (19), and a built-in resistor (21) that is made of polysilicon and that is disposed below the gate metal (44) so as to electrically connect the gate metal (44) and the gate electrode (19) together.

Provided is a semiconductor integrated circuit device including a nanowire field effect transistor (FET) and having a layout configuration effective for making manufacturing the device easy. A standard cell having no logical function is disposed adjacent to a standard cell having a logical function. The standard cell includes nanowire FETs having nanowires and pads. The standard cell further includes dummy pads, which have no contribution to a logical function of a circuit.

The present disclosure attempts to provide a capacitor cell having a large capacitance value per unit area in a semiconductor integrated circuit device using a three-dimensional transistor device. A logic cell includes a three-dimensional transistor device. A capacitor cell includes a three-dimensional transistor device. A length of a portion, of a local interconnect, which protrudes from a three-dimensional diffusion layer in a direction away from a power supply interconnect in the capacitor cell is greater than a length of a portion, of a local interconnect, which protrudes from a three-dimensional diffusion layer in a direction away from a power supply interconnect in the logic cell.

Disclosed is a reconfigurable complementary metal oxide semiconductor (CMOS) device with multiple operating modes (e.g., frequency multiplication mode, etc.). The device includes an N-type field effect transistor (NFET) and a P-type field effect transistor (PFET), which are threshold voltage-programmable, which are connected in parallel, and which have electrically connected gates. The threshold voltages of the NFET and PFET can be concurrently programmed and the operating mode of the device can be set depending upon the specific combination of threshold voltages achieved in the NFET and PFET. Optionally, the threshold voltages of the NFET and PFET can be concurrently reprogrammed to switch the operating mode. Such a device is relatively small and achieves frequency multiplication and other functions with minimal power consumption. Also disclosed are methods for forming the device and for reconfiguring the device (i.e., for concurrently programming the NFET and PFET to set or switch operating modes).

Apparatuses including semiconductor layout to mitigate local layout effects arc disclosed. An example apparatus includes a plurality of standard cells each including an active region, an isolation region adjacent the active region, and a first gate structure disposed on the active region and the isolation region. The first gate structure includes a first gate portion disposed on the active region, and a first contact portion disposed on the isolation region. The apparatus further includes a second gate structure disposed on the active region and the isolation region. The second gate structure includes a second gate portion disposed on the active region, and a second contact portion disposed on the isolation region. In the apparatus, a distance between a first contact point and the first gate portion is substantially equal to a distance between a second contact point and the second gate portion.

A method for forming an integrated circuit (IC) is provided. The method includes obtaining an IC design; generating a layout according to the IC design; calculating a score of a region in the layout based on voltage levels in the region; and fabricating a semiconductor device according to the layout when the score of the region in the layout is equal to or less than a threshold value.

An integrated circuit includes a first pair of power rails and a second pair of power rails that are disposed in a first layer, conductive lines disposed in a second layer above the first layer, and a first active area disposed in a third layer above the second layer. The first active area is arranged to overlap the first pair of power rails. The first active area is coupled to the first pair of power rails through a first line of the conductive lines and a first group of vias, and the first active area is coupled to the second pair of power rails through at least one second line of the conductive lines and a second group of vias different from the first group of vias.

An integrated circuit includes a first standard cell including a first first-type transistor, a first second-type transistor, a third second-type transistor, and a third first-type transistor, a second standard cell including a second first-type transistor, a second second-type transistor, a fourth second-type transistor and a fourth first-type transistor, a plurality of wiring layers which are disposed on the first and second standard cells and includes a first wiring layer, a second wiring layer, and a third wiring layer sequentially stacked. A source contact of the first first-type transistor and a source contact of the second first-type transistor are electrically connected through a first power rail of the plurality of wiring layers, and a source contact of the third first-type transistor and a source contact of the fourth first-type transistor are electrically connected through a second power rail of the plurality of wiring layers.

An integrated circuit is disclosure. The integrated circuit includes a first pair of power rails, a set of conductive lines arranged in the first layer parallel to the first pair of power rails, a first set of active areas. The integrated circuit further includes a first gate arranged along the second direction, between the first pair of power rails, and crossing the first set of active areas in a layout view, wherein the first gate is configured to be shared by a first transistor of a first type and a second transistor of a second type; and a second gate and a third gate, in which the second gate is configured to be a control terminal of a third transistor, and the third gate is configured to be a control terminal of a fourth transistor which is coupled to the control terminal of the third transistor.

A semiconductor integrated circuit includes a first power line to which a first voltage is continuously applied, a second power line, a power switch cell connected to the first power line and configured to output a second voltage to the second power line according to a first signal, a logic circuit driven by the second voltage applied via the second power line, a first circuit driven by the second voltage applied via the second power line and configured to output a third voltage to logic circuit according to a second signal which is an inverted signal of the first signal, and a second circuit driven by the second voltage applied via the second power line and configured to output a fourth voltage to logic circuit according to a third signal which is an inverted signal of the second signal, the fourth voltage being lower than the third voltage.