Abstract: A liposome including a neutral lipid membrane, a positively charged polymer, and a surface active polymer is provided. The neutral lipid membrane is formed as a hollow sphere, the positively charged polymer is dispersed on the neutral lipid membrane by non-covalent bonding, and the surface active polymer is dispersed on the neutral lipid membrane by non-covalent bonding. The liposome can stably adsorb various amounts of biomaterials by non-covalent bonding.

Abstract: The present disclosure provides an integrated circuit. The integrated circuit includes a substrate having a surface that is defined by a first axis and a second axis perpendicular to the first axis; and a capacitor structure disposed on the substrate. The capacitor structure includes a first conductive component; a second conductive component and a third conductive component symmetrically configured on opposite sides of the first conductive component. The first, second and third conductive components are separated from each other by respective dielectric material.

Abstract: An integrated circuit device includes a semiconductor body, active components formed over the semiconductor body, one or more seal rings surrounding the active components, and a signal line. One or more of the seal rings are configured to provide the primary return path for current flowing through the signal line.

Abstract: A method includes providing on a substrate having at least two through substrate vias (“TSVs”) a plurality of test structures for de-embedding the measurement of the intrinsic characteristics of a device under test (DUT) including at least two of the TSVs; measuring the intrinsic characteristics [L] for a first and a second test structure on the substrate including two pads coupled with a transmission line of length L; using simultaneous solutions of ABCD matrix or T matrix form equations, and the measured intrinsic characteristics, solving for the intrinsic characteristics of the pads and the transmission lines; de-embedding the measurements of the third and fourth test structures using the intrinsic characteristics of the pads and the transmission lines; and using simultaneous solutions of ABCD matrix or T matrix form equations for BM_L and BM_LX, and the measured intrinsic characteristics, solving for the intrinsic characteristics of the TSVs.

Abstract: Methods and apparatus for forming a semiconductor device package with inductors and transformers using a micro-bump layer are disclosed. The micro-bump layer may comprise micro-bumps and micro-bump lines, formed between a top die and a bottom die, or between a die and an interposer. An inductor can be formed by a redistribution layer within a bottom device and a micro-bump line above the bottom device connected to the RDL. The inductor may be a symmetric inductor, a spiral inductor, a helical inductor which is a vertical structure, or a meander inductor. A pair of inductors with micro-bump lines can form a transformer.

Abstract: Some embodiments relate to a semiconductor module comprising an integrated antenna structure configured to wirelessly transmit signals. The integrated antenna structure has a lower metal layer and an upper metal layer. The lower metal layer is disposed on a lower die and is connected to a ground terminal. The upper metal layer is disposed on an upper die and is connected to a signal generator configured to generate a signal to be wirelessly transmitted. The upper die is stacked on the lower die and is connected to the lower die by way of an adhesion layer having one or more micro-bumps. By connecting the lower and upper die together by way of the adhesion layer, the lower and upper metal layers are separated from each other by a large spacing that provides for a good performance of the integrated antenna structure.

Abstract: An antenna includes a substrate and a conductive top plate over the substrate. A feed line is connected to the top plate, and the feed line comprises a first through-silicon via (TSV) structure passing through the substrate. The feed line is arranged to carry a radio frequency signal. A method of designing an antenna includes selecting a shape of a top plate, determining a size of the top plate based on an intended signal frequency, and determining, based on the shape of the top plate, a location of each TSV of at least one TSV contacting the top plate. A method of implementing an antenna includes forming a first feed line through a substrate, the first feed line comprising a TSV, and forming a top plate over the substrate, the top plate being electrically conductive and connected to the first feed line.

Abstract: A differential MOS capacitor structure includes two capacitor sections coupled to different gates and operating using different signals. The respective signals may be 180° out of phase. The capacitor sections of the differential capacitor each include two or more upper capacitor plates disposed over a single common lower capacitor plate which serves as a common node thereby preventing parasitic capacitance. The upper capacitor plates of a first capacitor section are adjacent one another with no electrical components disposed between them. The upper capacitor plates of a second capacitor section are adjacent one another with no electrical components disposed between them. The upper capacitor plates are formed of a plurality of stacked conductive layers in some embodiments.

Abstract: The present disclosure provides a semiconductor device. The semiconductor device includes a first inductor formed on a first substrate; a second inductor formed on a second substrate and conductively coupled with the first inductor as a transformer; and a plurality of micro-bump features configured between the first and second substrates. The plurality of micro-bump features include a magnetic material having a relative permeability substantially greater than one and are configured to enhance coupling between the first and second inductors.

Abstract: An antenna includes a substrate and a top plate disposed over the substrate. At least one feed line is connected to the top plate, and each feed line comprises a first through-silicon via (TSV) structure passing through the substrate. At least one ground line is connected to the top plate, and each ground line comprises a second TSV structure passing through the substrate. The top plate is electrically conductive, and the at least one feed line is arranged to carry a radio frequency signal. The at least one ground line is arranged to be coupled to a ground.

Abstract: A semiconductor structure is provided. The semiconductor structure includes a floating substrate; and a capacitor grounded and connected to the floating substrate. A method of manufacturing a semiconductor structure is also provided.

Abstract: The present disclosure provides an Integrated Circuit (IC) device. The IC device includes a first die that contains an electronic component. The IC device includes second die that contains a ground shielding structure. The IC device includes a layer disposed between the first die and the second die. The layer couples the first die and the second die together. The present disclosure also involves a microelectronic device. The microelectronic device includes a first die that contains a plurality of first interconnect layers. An inductor coil structure is disposed in a subset of the first interconnect layers. The microelectronic device includes a second die that contains a plurality of second interconnect layers. A patterned ground shielding (PGS) structure is disposed in a subset of the second interconnect layers. The microelectronic device includes an underfill layer disposed between the first and second dies. The underfill layer contains one or more microbumps.

Abstract: An electronic device comprises first, second and third inductors connected in series and formed in a metal layer over a semiconductor substrate. The first and second inductors have a mutual inductance with each other. The second and third inductors having a mutual inductance with each other. A first capacitor has a first electrode connected to a first node. The first node is conductively coupled between the first and second inductors. A second capacitor has a second electrode connected to a second node. The second node is conductively coupled between the second and third inductors.

Abstract: Some embodiments relate to a semiconductor module comprising an integrated antenna structure configured to wirelessly transmit signals. The integrated antenna structure has a lower metal layer and an upper metal layer. The lower metal layer is disposed on a lower die and is connected to a ground terminal. The upper metal layer is disposed on an upper die and is connected to a signal generator configured to generate a signal to be wirelessly transmitted. The upper die is stacked on the lower die and is connected to the lower die by way of an adhesion layer having one or more micro-bumps. By connecting the lower and upper die together by way of the adhesion layer, the lower and upper metal layers are separated from each other by a large spacing that provides for a good performance of the integrated antenna structure.

Abstract: Interposer and semiconductor package embodiments provide for the isolation and suppression of electronic noise such as EM emissions in the semiconductor package. The interposer includes shield structures in various embodiments, the shield structures blocking the electrical noise from the noise source, from other electrical signals or devices. The shields include solid structures and some embodiments and decoupling capacitors in other embodiments. The coupling structures includes multiple rows of solder balls included in strips that couple the components and surround and contain the source of electrical noise.

Abstract: The present disclosure provides a semiconductor device. The semiconductor device includes a first inductor formed on a first substrate; a second inductor formed on a second substrate and conductively coupled with the first inductor as a transformer; and a plurality of micro-bump features configured between the first and second substrates. The plurality of micro-bump features include a magnetic material having a relative permeability substantially greater than one and are configured to enhance coupling between the first and second inductors.

Abstract: A light emitting module includes a substrate, two first LEDs (light emitting diode), two second LEDs (light emitting diode) and at least one first circular LED array. The substrate includes a first central line and a second central line. The first central line and the second central line are substantially perpendicularly crossed on the center of the substrate. The first LEDs are disposed oppositely on the first central line and spatially separated by the center of the substrate. The second LEDs are disposed oppositely on the second central line and spatially separated by the center of the substrate. The color temperature of the light emitted by the first LEDs is different from which by the second LEDs. The first circular LED array is disposed on the substrate.

Abstract: A device using an inductor with one or more through vias, and a method of manufacture is provided. In an embodiment, an inductor is formed in one or more of the metallization layers. One or more through vias are positioned directly below the inductor. The through vias may extend through one or more dielectric layers interposed between a substrate and the inductors. Additionally, the through vias may extend completely or partially through the substrate.

Abstract: A device includes a die including a main circuit and a first pad coupled to the main circuit. A work piece including a second pad is bonded to the die. A first plurality of micro-bumps is electrically coupled in series between the first and the second pads. Each of the plurality of micro-bumps includes a first end joining the die and a second end joining the work piece. A micro-bump is bonded to the die and the work piece. The second pad is electrically coupled to the micro-bump.

Abstract: An electronic device comprises first, second and third inductors connected in series and formed in a metal layer over a semiconductor substrate. The first and second inductors have a mutual inductance with each other. The second and third inductors having a mutual inductance with each other. A first capacitor has a first electrode connected to a first node. The first node is conductively coupled between the first and second inductors. A second capacitor has a second electrode connected to a second node. The second node is conductively coupled between the second and third inductors.