Abstract: A connector assembly includes a guiding shield cage, a receptacle connector, a partitioning bracket and a movable heat sink. The receptacle connector is provided to a rear segment of an interior of the guiding shield cage, the receptacle connector has an upper receptacle and a lower receptacle. The partitioning bracket is provided in the guiding shield cage, the partitioning bracket and the guiding shield cage together define an upper receiving space which corresponds to the upper receptacle and a lower receiving space which corresponds to the lower receptacle. The movable heat sink is assembled to the partitioning bracket, the movable heat sink is capable of moving relative to the partitioning bracket between a front position where the movable heat sink is positioned in front of a front end of the upper receptacle a front end of the lower receptacle and a rearward position where the movable heat sink at least partially enters into between the upper receptacle and the lower receptacle.

Abstract: A method of fabricating an integrated circuit includes fabricating a set of transistors in a front-side of a substrate, fabricating a first set of vias in a back-side of the substrate, depositing a first set of conductive structures on the back-side on a first level, depositing a second set of conductive structures on the back-side on a second level thereby forming a set of power rails, fabricating a second set of vias in the back-side, and depositing a third set of conductive structures on the back-side on a third level. The first set of vias is electrically coupled to the set of transistors. The second set of vias is electrically coupled to the first and third set of conductive structures. A first structure of the first set of conductive structures is electrically coupled to a first via of the first set of vias.

Abstract: The present invention provides a transceiver circuit including a transmitter circuit, a frequency synthesizer and control circuit. The transmitter circuit is configured to generate a transmission signal, wherein the transmission signal is transmitted through an antenna. The frequency synthesizer is configured to generate a clock signal for the transmitter circuit to generate the transmission signal. The control circuit is configured to generate a first control signal to control the frequency synthesizer to determine a loop bandwidth of the frequency synthesizer; wherein when the transceiver circuit operates in a standby mode, the control circuit generates the first control signal to make the frequency synthesizer have a first loop bandwidth; and after a period of time after the transceiver circuit is switched from the standby mode to a transmission mode, the control circuit generates the first control signal to make the frequency synthesizer have a second loop bandwidth.

Abstract: An asymmetric fused aromatic ring derivative containing sulfonyl group, which includes a structure represented by formula (I). Formula (I) is defined as in the specification. A use of the asymmetric fused aromatic ring derivative containing sulfonyl group, which is used as a photocatalyst. A hydrogen production device, which includes the asymmetric fused aromatic ring derivative containing sulfonyl group. An optoelectronic component, which includes the asymmetric fused aromatic ring derivative containing sulfonyl group.

Abstract: A data protection method includes the following steps. Input data is split into a plurality of data groups. The original start-address of each data group and the data length of each data group are recorded. The data groups are reordered randomly. The reordered data groups constitute random data. The new start-address of each reordered data group is recorded. The original start-addresses, the data lengths, and the new start-addresses are collected to form a look-up table. The look-up table records the original start-addresses of the data groups and the new start-addresses of the reordered data groups. Each original start-address corresponds to one new start-address. The random data is stored in the storage memory. The look-up table is stored in the memory controller.

Abstract: The present disclosure relates to a semiconductor device and a manufacturing method, and more particularly to forming via rail and deep via structures to reduce parasitic capacitances in standard cell structures. Via rail structures are formed in a level different from the conductive lines. The via rail structure can reduce the number of conductive lines and provide larger separations between conductive lines that are on the same interconnect level and thus reduce parasitic capacitance between conductive lines.

Abstract: A semiconductor structure includes a first transistor having a first source/drain (S/D) feature and a first gate; a second transistor having a second S/D feature and a second gate; a multi-layer interconnection disposed over the first and the second transistors; a signal interconnection under the first and the second transistors; and a power rail under the signal interconnection and electrically isolated from the signal interconnection, wherein the signal interconnection electrically connects one of the first S/D feature and the first gate to one of the second S/D feature and the second gate.

Abstract: A method of making a semiconductor structure includes defining a first recess in an insulation layer. The method further includes forming a protection layer along a sidewall of the first recess. The method further includes forming a first conductive line in the first recess and in direct contact with the protection layer. The method further includes depositing a first insulation material over the first conductive line. The method further includes defining a second recess in the first insulation material. The method further includes forming a second conductive line in the second recess. The method further includes forming a via extending from the second conductive line, wherein the via directly contacts a sidewall of the protection layer.

Abstract: An integrated circuit includes a strip structure having a front side and a back side. A gate structure is on the front side of the strip structure. The integrated circuit includes a plurality of channel layers above the front side of the strip structure, wherein each of the plurality of channel layers is enclosed within the gate structure. An isolation structure surrounds the strip structure. The integrated circuit includes a backside via in the isolation structure. An epitaxy structure is on the front side of the strip structure. The integrated circuit includes a contact over the epitaxy structure. The contact has a first portion on a first side of the epitaxy structure. The first portion of the contact extends into the isolation structure and contacts the backside via. The integrated circuit includes a backside power rail on the back side of the strip structure and contacting the backside via.

Abstract: A method of manufacturing a semiconductor device, including: forming a plurality of gate strips, each gate strip is a gate terminal of a transistor; forming a plurality of first contact vias connected to a part of the gate strips; forming a plurality of first metal strips above the plurality of gate strips; connecting one of the first metal strips to one of the first contact vias; forming a plurality of second metal strips above the plurality of first metal strips, wherein the plurality of second metal strips are co-planar, each second metal strip and one of the first metal strips are crisscrossed from top view; a length between two adjacent gate strips is twice as a length between two adjacent second metal strips, and a length of said one of the first metal strips is smaller than two and a half times as the length between two adjacent gate strips.

Abstract: A method includes: disposing a first conductive segment; disposing a first conductive via above the first conductive segment; disposing a first conductive line above the first conductive via; and disposing a second conductive segment electrically coupled to the first conductive line through a third conductive segment, the first conductive segment, and the first conductive via.

Abstract: An integrated circuit includes a first, second and third active region and a first, second and third conductive line. The first, second and third active regions extend in a first direction, and are on a first level of a front-side of a substrate. The second active region is between the first active region and the third active region. The first and second conductive line extend in the first direction, and are on a second level of a back-side of the substrate. The first conductive line is between the first and second active region. The second conductive line is between the second and third active region. The third conductive line extends in the second direction, is on a third level of the back-side of the substrate, overlaps the first and second conductive line, and electrically couples the first and second active regions.

Abstract: A semiconductor structure includes a first conductive line, a first conductive segment, a second conductive segment, and a third conductive segment. The first conductive segment is electrically coupled to the first conductive line. The second conductive segment is electrically coupled the first conductive segment. The second conductive segment is disposed between the first conductive segment and the third conductive segment. A top surface of the first conductive segment is aligned with a top surface of the second conductive segment in a same layer.

Abstract: An integrated circuit structure is disclosed, including a gate, a first conductive line and a pair of second conductive lines, and a first feed-through via. The gate is disposed on a front side of the integrated circuit structure and extends in a first direction on a first side of a dielectric layer. The first conductive line and a pair of second conductive lines are disposed on a second side, opposite of the first side, of the dielectric layer and on a back side, opposite of the front side, of the integrated circuit structure. The first conductive line is interposed between the pair of second conductive lines in a layout view. The first feed-through via extends through the dielectric layer in a second direction different from the first direction. The first feed-through via couples the gate to the first conductive line.

Abstract: An integrated circuit includes multiple backside conductive layers disposed over a backside of a substrate. The multiple backside conductive layers each includes conductive segments. The conductive segments in at least one of the backside conductive layers are configured to transmit one or more power signals. The conductive segments of the multiple backside conductive layers cover select areas of the backside of the substrate, thereby leaving other areas of the backside of the substrate exposed.

Abstract: An integrated circuit includes a first power rail, a second power rail, and a power tap cell. The first power rail is at a first side of the integrated circuit. The second power rail is at a second side of the integrated circuit. The first and second sides are on opposite sides of at least a complementary field effect transistor. The power tap cell is coupled to the first power rail and the second power rail and configured to provide power from the first power rail to the second power rail.

Abstract: A device including first nanosheet structures each including a first number of nanosheets, second nanosheet structures each including a second number of nanosheets that is different than the first number of nanosheets, and a plurality of rows including first rows and second rows. Where each of the first nanosheet structures is in a respective one of the first rows, each of the second nanosheet structures is in a respective one of the second rows, at least two of the first rows are adjacent one another, and at least two of the second rows are adjacent one another.

Abstract: An integrated circuit includes a first-voltage power rail and a second-voltage power rail in a first connection layer, and includes a first-voltage underlayer power rail and a second-voltage underlayer power rail below the first connection layer. Each of the first-voltage and second-voltage power rails extends in a second direction that is perpendicular to a first direction. Each of the first-voltage and second-voltage underlayer power rails extends in the first direction. The integrated circuit includes a first via-connector connecting the first-voltage power rail with the first-voltage underlayer power rail, and a second via-connector connecting the second-voltage power rail with the second-voltage underlayer power rail.

Abstract: In some embodiments, an integrated circuit device includes a substrate having a frontside and a backside; one or more active semiconductor devices formed on the frontside of the substrate; conductive paths formed on the frontside of the substrate; and conductive paths formed on the backside of the substrate. At least some of the conductive paths formed on the backside of the substrate, and as least some of the conductive paths formed on the front side of the substrate, are signal paths among the active semiconductor devices. In in some embodiments, other conductive paths formed on the backside of the substrate are power grid lines for powering at least some of the active semiconductor devices.

Abstract: A method of manufacturing a semiconductor device including: arranging a first and a second gate strip separating in a first distance, wherein each of the first and the second gate strip is a gate terminal of a transistor; depositing a first contact via on the first gate strip; forming a first conductive strip on the first contact via, wherein the first conductive strip and the first gate strip are crisscrossed from top view; arranging a second and a third conductive strip, above the first conductive strip, separating in a second distance, wherein each of the second and the third conductive strip is free from connecting to the first conductive strip, the first and the second conductive strip are crisscrossed from top view. The first distance is twice as the second distance. A length of the first conductive strip is smaller than two and a half times as the first distance.