There is provided a field-effect transistor including: a gate electrode; a semiconductor layer having a source region and a drain region with the gate electrode in between; contact plugs provided on the source region and the drain region; first metals stacked on the contact plugs; and a low-dielectric constant region provided in a region between the first metals along an in-plane direction of the semiconductor layer and provided at least in a first region below bottom surfaces of the first metals along a stacking direction.

A first interconnect on an interconnect level connects a first subset of PMOS drains together of a CMOS device. A second interconnect on the interconnect level connects a second subset of the PMOS drains together. The second subset of the PMOS drains is different than the first subset of the PMOS drains. The first interconnect and the second interconnect are disconnected on the interconnect level. A third interconnect on the interconnect level connects a first subset of NMOS drains together of the CMOS device. A fourth interconnect on the interconnect level connects a second subset of the NMOS drains together. The second subset of the NMOS drains is different than the first subset of the NMOS drains. The third interconnect and the fourth interconnect are disconnected on the interconnect level. The first, second, third, and fourth interconnects are coupled together though at least one other interconnect level.

A plurality of unit MISFET elements connected in parallel with each other to make up a power MISFET are formed in an LDMOSFET forming region on a main surface of a semiconductor substrate. A control circuit that controls a gate voltage of the power MISFET is formed in a driver circuit region on the main surface of the semiconductor substrate. A wiring structure having a plurality of wiring layers made of the same metal material is formed on the semiconductor substrate. The gate electrodes of the plurality of unit MISFET elements formed in the LDMOSFET forming region are electrically connected to each other via gate wirings formed in all of the plurality of wiring layers made of the same metal material.

Implementations of semiconductor devices may include: a first layer with a plurality of cells, each cell having a drain finger, a source finger and a gate ring; a second layer having a drain pad and a source pad, the drain pad having a width and a source pad having a width substantially the same as the drain pad; wherein a width of each drain finger of the first layer is wider than a width of each source finger of the first layer; and wherein each drain pad is coupled to each drain finger through a first contact and the source pad is coupled to each source finger through a second contact, where a width of the first contact is wider than a width of the second contact.

Disclosed is a semiconductor package. The semiconductor package may include a substrate a semiconductor chip mounted over a surface of the substrate such that an active surface of the semiconductor chip faces the surface of the substrate. The semiconductor chip and substrate may be configured for shielding or scattering electromagnetic waves.

Provided is a package structure including a substrate, a metal pad, a first polymer layer, a second polymer layer, a redistribution layer (RDL), and a third polymer layer. The metal pad is located on the substrate. The first polymer layer is located on the substrate. The first polymer layer has a first opening which exposes a portion of a top surface of the metal pad. The second polymer layer is located on the first polymer layer. The second polymer layer has a second opening which exposes the portion of the top surface of the metal pad and a first top surface of the first polymer layer. The RDL covers the portion of the top surface of the metal pad and extends onto a portion of the first top surface of the first polymer layer and the second polymer layer. The third polymer layer is located on the RDL.

A UV LED package disclosed herein includes a submount, a UV LED chip adapted to emit UV light at 200 nm to 400 nm, and a package body mounted with the submount. The submount includes a heat dissipating substrate, a first reflective electrode film and a second reflective electrode film separated from each other by an electrode separation gap on the heat dissipating substrate, a first flip-chip bonding pad and a first wire bonding pad disposed on the first reflective electrode film, and a second flip-chip bonding pad and a second wire bonding pad disposed on the second reflective electrode film. The UV LED chip includes a first conductive electrode pad corresponding to the first flip-chip bonding pad and a second conductive electrode pad corresponding to the second flip-chip bonding pad. The UV LED chip is flip-chip bonded to the submount through a first bonding bump interposed between the first flip-chip bonding pad and the first conductive electrode pad and a second bonding bump interposed between the second flip-chip bonding pad and the second conductive electrode pad. The package body includes a first metal body electrically connected to the first wire bonding pad through a first bonding wire and a second metal body separated from the first metal body by an insulating material and electrically connected to the second wire bonding pad through a second bonding wire.

A chip-on-film package includes a base substrate on which a first pad region, a second pad region, and a third region located between the first pad region and the second pad region are defined, a dummy pad disposed on the first pad region, input pads disposed on the first pad region, output pads disposed on the second region, a first detection line disposed on the base substrate, and a second detection line disposed on the base substrate. The first detection line is connected to a first input pad and a second input pad via the second pad region to form a first loop between the first input pad and the second input pad, and the second detection line is connected to the dummy pad and the first detection line via the third region to form a second loop between the dummy pad and the first input pad.

The present disclosure relates to an integrated chip packaging device. In some embodiments, the packaging device has a first package component. A metal trace is arranged on a surface of the first package component. The metal trace has an undercut. A molding material fills the undercut of the metal trace and has a sloped outermost sidewall with a height that monotonically decreases from a position below a top surface of the metal trace to the surface of the first package component. A solder region is arranged over the metal trace.

Stripe-shaped surface transistor structures of a power MOSFET are disposed over an array of parallel-extending P type Buried Stripe-Shaped Charge Compensation Regions (BSSCCRs). The power MOSFET has two and only two epitaxial semiconductor layers, and the BSSCCRs are disposed at the interface between these layers. Looping around the area occupied by these parallel-extending BSSCCRs is a P type ring-shaped BSSCCR. At the upper semiconductor surface are disposed three P type surface rings. The inner surface ring and outer surface ring are coupled together by a bridging metal member, but the center surface ring is floating. The bridging metal member is disposed at least in part over the ring-shaped BSSCCR. The MOSFET has a high breakdown voltage, a low R.sub.DS(ON), and is acceptable and suitable for manufacture at semiconductor fabrication plants that cannot or typically do not make superjunction MOSFETs.