Abstract: A method includes forming a dummy gate over a semiconductor fin; forming a source/drain epitaxial structure over the semiconductor fin and adjacent to the dummy gate; depositing an interlayer dielectric (ILD) layer to cover the source/drain epitaxial structure; replacing the dummy gate with a gate structure; forming a dielectric structure to cut the gate structure, wherein a portion of the dielectric structure is embedded in the ILD layer; recessing the portion of the dielectric structure embedded in the ILD layer; after recessing the portion of the dielectric structure, removing a portion of the ILD layer over the source/drain epitaxial structure; and forming a source/drain contact in the ILD layer and in contact with the portion of the dielectric structure.

Abstract: A method of generating a first performance-data-library (for a standard-cell-library) includes: for each standard cell that includes multiple gates, sorting the gates into groups including searching for matched ones amongst the gates (matched gates), grouping corresponding matched gates into corresponding multiple member-gates, and (for unmatched ones of the gates having no other matched gate (unmatched gates)), grouping the unmatched gates into corresponding single-member groups; for each standard cell, generating a corresponding first volume of performance data including, for each group, discretely calculating the first volume of performance data, mapping the volume of performance data to the subject gate in the group, and, for each multimember group, mapping the volume of performance data to non-subject gates; and basing the first performance-data-library at least in part on the first volumes of performance data.

Abstract: An in-car temperature-controlling device for a car in its parked state uses a wireless remote control to remotely control a power-activating unit, an engine-starting unit, a window-activating unit and an AC-activating unit of the car, so as to adjust the car's in-car temperature. Its installation is easy and needs no structural changes to the car, so the car using the device can, in its parked state, have its in-car temperature prevented from being too high or too low. The in-car temperature-controlling device is characterized in contributing to convenience, safety, comfort and low costs, and is applicable to all existing and newly built cars.

Abstract: An in-car temperature-controlling device for a car in its parked state uses a wireless remote control to remotely control a power-activating unit, an engine-starting unit, a window-activating unit and an AC-activating unit of the car, so as to adjust the car's in-car temperature. Its installation is easy and needs no structural changes to the car, so the car using the device can, in its parked state, have its in-car temperature prevented from being too high or too low. The in-car temperature-controlling device is characterized in contributing to convenience, safety, comfort and low costs, and is applicable to all existing and newly built cars.

Abstract: An in-car temperature-controlling device for a car in its parked state uses a wireless remote control to remotely control a power-activating unit, an engine-starting unit, a window-activating unit and an AC-activating unit of the car, so as to adjust the car's in-car temperature. Its installation is easy and needs no structural changes to the car, so the car using the device can, in its parked state, have its in-car temperature prevented from being too high or too low. The in-car temperature-controlling device is characterized in contributing to convenience, safety, comfort and low costs, and is applicable to all existing and newly built cars.

Abstract: An AMOLED display device includes a substrate, a device layer, a flat layer, a first, a second, and a third color filter layers, a first, a second, and a third pixel electrodes, a first, a second and a third organic light emitting layers. The device layer on the substrate includes active devices. The flat layer on the device layer includes contact window openings. The first color filter layer on the flat layer has a first pixel area and a first opening configured above a part of the contact window openings. The second color filter layer on the flat layer has a second pixel area and a second opening configured above a part of the contact window openings. The third color filter layer on the flat layer has a third pixel area and a third opening configured above a part of the contact window openings.

Abstract: An AMOLED display device includes a substrate, a device layer, a flat layer, a first, a second, and a third color filter layers, a first, a second, and a third pixel electrodes, a first, a second and a third organic light emitting layers. The device layer on the substrate includes active devices. The flat layer on the device layer includes contact window openings. The first color filter layer on the flat layer has a first pixel area and a first opening configured above a part of the contact window openings. The second color filter layer on the flat layer has a second pixel area and a second opening configured above a part of the contact window openings. The third color filter layer on the flat layer has a third pixel area and a third opening configured above a part of the contact window openings.

Abstract: A method for fabricating an AMOLED display device is provided. A substrate is provided. A device layer having multiple active devices is formed on the substrate. A flat layer is configured on the device layer. A first, a second and a third color photoresistant layers are respectively configured on the flat layer and are patterned to form a first, a second and a third color filter layers. The first, the second and the third color filter layers respectively define a first, a second and a third pixel areas and are used for etching masks to etch the flat layer for exposing parts of the active devices. A first, a second and a third pixel electrode are respectively configured in the mentioned pixel areas and are electrically connected with the active devices. A first, a second and a third organic light emitting layers are respectively configured on the mentioned pixel electrodes.

Abstract: A manufacturing method of a thin film transistor is provided. A buffer layer is formed on a substrate, and then a first and a second poly-silicon island are formed thereon. A gate-insulating layer is formed on the substrate, and a first and a second gate are formed thereon. A sacrificed layer is formed on the substrate and a photo-resist layer is formed thereon. The sacrificed layer above the first poly-silicon island is removed by using the photo-resist layer as a mask. A first ion implantation process is performed to form a first source/drain. The photo-resist layer is removed and a second ion implantation process is performed to form a second source/drain. At the same time, the second ion implantation process is used to implant ions into the buffer layer below the two sides of the second gate. A lightly-doped ion implantation process is performed after removing the sacrificed layer.

Abstract: A method for fabricating an AMOLED display device is provided. A substrate is provided. A device layer having multiple active devices is formed on the substrate. A flat layer is configured on the device layer. A first, a second and a third color photoresistant layers are respectively configured on the flat layer and are patterned to form a first, a second and a third color filter layers. The first, the second and the third color filter layers respectively define a first, a second and a third pixel areas and are used for etching masks to etch the flat layer for exposing parts of the active devices. A first, a second and a third pixel electrode are respectively configured in the mentioned pixel areas and are electrically connected with the active devices. A first, a second and a third organic light emitting layers are respectively configured on the mentioned pixel electrodes.

Abstract: A manufacturing method of a thin film transistor is provided. A buffer layer is formed on a substrate, and then a first and a second poly-silicon island are formed thereon. A gate-insulating layer is formed on the substrate, and a first and a second gate are formed thereon. A sacrificed layer is formed on the substrate and a photo-resist layer is formed thereon. The sacrificed layer above the first poly-silicon island is removed by using the photo-resist layer as a mask. A first ion implantation process is performed to form a first source/drain. The photo-resist layer is removed and a second ion implantation process is performed to form a second source/drain. At the same time, the second ion implantation process is used to implant ions into the buffer layer below the two sides of the second gate. A lightly-doped ion implantation process is performed after removing the sacrificed layer.