An integrated circuit includes a standard cell including a first output pin and a second output pin configured to each output the same output signal, a first routing path connected to the first output pin, and a second routing path connected to the second output pin. The first routing path includes a first cell group including at least one load cell, the second routing path includes a second cell group including at least one load cell, and the first routing path and the second routing path are electrically disconnected from each other outside the standard cell.

An integrated circuit includes a standard cell including a first output pin and a second output pin configured to each output the same output signal, a first routing path connected to the first output pin, and a second routing path connected to the second output pin. The first routing path includes a first cell group including at least one load cell, the second routing path includes a second cell group including at least one load cell, and the first routing path and the second routing path are electrically disconnected from each other outside the standard cell.

Some embodiments provide a method for calculating parasitic parameters for a pattern to be manufactured on an integrated circuit (IC) substrate. The method receives a definition of a wire structure as input. The method rasterizes the wire structure (e.g., produces pixel-based definition of the wire structure) to produce several images. Before rasterizing the wire structure, the method in some embodiments decomposes the wire structure into several components (e.g., several wires, wire segments or wire structure portions), which it then individually rasterizes. The method then uses the images as inputs to a neural network, which then calculates parasitic parameters associated with the wire structure. In some embodiments, the parasitic parameters include unwanted parasitic capacitance effects exerted on the wire structure. Conjunctively, or alternatively, these parameters include unwanted parasitic resistance and/or inductance effects on the wire structure.

Some embodiments provide a method for calculating parasitic parameters for a pattern to be manufactured on an integrated circuit (IC) substrate. The method receives a definition of a wire structure as input. The method rasterizes the wire structure (e.g., produces pixel-based definition of the wire structure) to produce several images. Before rasterizing the wire structure, the method in some embodiments decomposes the wire structure into several components (e.g., several wires, wire segments or wire structure portions), which it then individually rasterizes. The method then uses the images as inputs to a neural network, which then calculates parasitic parameters associated with the wire structure. In some embodiments, the parasitic parameters include unwanted parasitic capacitance effects exerted on the wire structure. Conjunctively, or alternatively, these parameters include unwanted parasitic resistance and/or inductance effects on the wire structure.

A method of designing a device includes identifying a pin to be inserted into a first layer of the device, wherein the first layer has a plurality of first routing tracks, and each of the plurality of first routing tracks extend in a first direction. The method further includes identifying a blocking shape on a second layer different from the first layer, wherein the second layer has a plurality of second routing tracks, and each of the plurality of second routing tracks extends in a second direction different from the first direction. The method further includes determining at least one candidate location for the pin in the first layer based on the plurality of first routing tracks of the first layer. The method further includes setting a location for the pin in the first layer based on the determined at least one candidate location.

A method of designing a device includes identifying a pin to be inserted into a first layer of the device, wherein the first layer has a plurality of first routing tracks, and each of the plurality of first routing tracks extend in a first direction. The method further includes identifying a blocking shape on a second layer different from the first layer, wherein the second layer has a plurality of second routing tracks, and each of the plurality of second routing tracks extends in a second direction different from the first direction. The method further includes determining at least one candidate location for the pin in the first layer based on the plurality of first routing tracks of the first layer. The method further includes setting a location for the pin in the first layer based on the determined at least one candidate location.

A semiconductor cell structure includes four pairs of conductive segments, a first gate-strip, and a second gate-strip. A first conductive segment is configured to have a first supply voltage, and a second conductive segment is configured to have a second supply voltage. Each of the first gate-strip and the second gate-strip intersects an active zone over a channel region of a transistor. The first gate-strip is conductively connected to the second conductive segment. The semiconductor cell structure also includes a first dummy gate-strip and a second dummy gate-strip. The first dummy gate-strip separates from the first gate-strip by one CPP. The second dummy gate-strip separates from the second gate-strip by one CPP. The first gate-strip and the second gate-strip are separated from each other by two CPPs. The dummy gate-strip and the second dummy gate-strip are separated from each other by four CPPs.

A semiconductor cell structure includes four pairs of conductive segments, a first gate-strip, and a second gate-strip. A first conductive segment is configured to have a first supply voltage, and a second conductive segment is configured to have a second supply voltage. Each of the first gate-strip and the second gate-strip intersects an active zone over a channel region of a transistor. The first gate-strip is conductively connected to the second conductive segment. The semiconductor cell structure also includes a first dummy gate-strip and a second dummy gate-strip. The first dummy gate-strip separates from the first gate-strip by one CPP. The second dummy gate-strip separates from the second gate-strip by one CPP. The first gate-strip and the second gate-strip are separated from each other by two CPPs. The dummy gate-strip and the second dummy gate-strip are separated from each other by four CPPs.

An integrated circuit (IC) device includes a substrate having opposite first and second sides, an active region over the first side of the substrate, a first conductive pattern over the active region, and a second conductive pattern under the second side of the substrate. The active region includes a first portion and a second portion. The first conductive pattern is electrically coupled to the first portion and the second portion of the active region. The second conductive pattern is electrically coupled to the first portion and the second portion of the active region.

An integrated circuit (IC) device includes a substrate having opposite first and second sides, an active region over the first side of the substrate, a first conductive pattern over the active region, and a second conductive pattern under the second side of the substrate. The active region includes a first portion and a second portion. The first conductive pattern is electrically coupled to the first portion and the second portion of the active region. The second conductive pattern is electrically coupled to the first portion and the second portion of the active region.