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 apparatus for de-embedding through substrate vias is provided. The apparatus may include pads on a first side of a substrate are coupled to through vias extending through a substrate, wherein pairs of the through vias are interconnected by transmission lines of varying lengths along a second side of the substrate. The apparatus may further include pairs of pads coupled together by transmission lines of the same varying lengths. Apparatuses may include through vias surrounding a through via device under test. The surrounding through vias are connected to the through via device under test by a backside metal layer. The apparatus may further include a dummy structure having an area equal to an area of the backside metal layer.

Abstract: A transmission line is provided. In one embodiment, the transmission line comprises a substrate, a well within the substrate, a shielding layer over the well, and a plurality of intermediate metal layers over the shielding layer, the plurality of intermediate metal layers coupled by a plurality of vias. The transmission line further includes a top metal layer over the plurality of intermediate metal layers. A test structure for de-embedding an on-wafer device, and a wafer are also disclosed.

Abstract: The present disclosure provides a semiconductor device. The semiconductor device includes a semiconductor substrate having an integrated circuit (IC) device; an interconnect structure disposed on the semiconductor substrate and coupled with the IC device; and a transformer disposed on the semiconductor substrate and integrated in the interconnect structure. The transformer includes a first conductive feature; a second conductive feature inductively coupled with the first conductive feature; a third conductive feature electrically connected to the first conductive feature; and a fourth conductive feature electrically connected to the second conductive feature. The third and fourth conductive features are designed and configured to be capacitively coupled to increase a coupling coefficient of the transformer.

Abstract: A strip-line includes a ground plane extending through a plurality of dielectric layers over a substrate; a signal line over the substrate and on a side of the ground plane; a first plurality of metal strips under the signal line and in a first metal layer, wherein the first plurality of metal strips is parallel to each other, and is spaced apart from each other by spaces; and a second plurality of metal strips under the signal line and in a second metal layer over the first metal layer. The second plurality of metal strips vertically overlaps the spaces. The first plurality of metal strips is electrically coupled to the second plurality of metal strips through the ground plane, and no via physically contacts the first plurality of metal strips and the second plurality of metal strips.

Abstract: An adjustable meander line resistor comprises a plurality of series circuits. Each series circuit comprises a first resistor formed on a first doped region of a transistor, a second resistor formed on a second doped region of the transistor and a connector coupled between the first resistor and the second resistor. A control circuit is employed to control the on and off of the transistor so as to achieve the adjustable meander line resistor.

Abstract: A cathode material structure and a method for preparing the same are described. The cathode material structure includes a material body and a composite film coated thereon. The material body has a particle size of 0.1-50 ?m. The composite film has a porous structure and electrical conductivity.

Abstract: A differential MOS capacitor includes a first plurality of upper capacitor plates, a second plurality of upper capacitor plates, and a conductive plate. At least two of the second plurality of upper capacitor plates are spaced laterally from each other and are disposed laterally between at least two of the first plurality of upper capacitor plates. The conductive plate is configured to serve as a common bottom capacitor plate such that a first capacitor is formed by the first plurality of upper capacitor plates and the conductive plate and a second capacitor is formed by the second plurality of upper capacitor plates and the conductive plate.

Abstract: A system and method for persistent ID flag for RFID applications includes a method for operating an RFID tag. The method includes measuring a voltage potential of a supply voltage for the RFID tag, and turning on a pass gate that couples a memory cell to a data line used for reading or writing data, if the voltage potential is greater than a first threshold. An accumulated charge on the memory cell is also measured, and both the voltage potential and the accumulated charge are used to generate a control signal to set a state of the pass gate. The pass gate is turned off if the control signal is a true value.

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 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: A system comprises a first transistor comprising a first active region and a second active region, a first resistor comprising a plurality of first vias connected in series, wherein the first resistor is over the first active region, a second resistor comprising a plurality of second vias connected in series, wherein the second resistor is over the second active region, a second transistor comprising a third active region and a fourth active region, a capacitor having a terminal electrically coupled to the fourth active region and a bit line electrically coupled to the third active region.

Abstract: A method comprises implanting ions in a substrate to form a first active region and a second active region, depositing a first dielectric layer over the substrate, forming a first via and a second via in the first dielectric layer, wherein the first via is over the first active region and the second via is over the second active region, depositing a second dielectric layer over the first dielectric layer, forming a third via and a fourth via in the second dielectric layer, wherein the third via is over the first via and the fourth via is over the second via and forming a connector in a metallization layer over the second dielectric layer, wherein the connector is electrically connected to the third via and the fourth via.

Abstract: A method of manufacturing a package may include: providing a first device having a first redistribution layer (RDL) and an insulator layer disposed over the first RDL; and forming a first micro-bump line over the insulator layer of the first device. The first micro-bump line may extend laterally over a surface of the insulator layer facing away from the first RDL, and a first inductor of the package comprises the first RDL and the first micro-bump line.

Abstract: A transmission line structure for semiconductor RF and wireless circuits, and method for forming the same. The transmission line structure includes embodiments having a first die including a first substrate, a first insulating layer, and a ground plane, and a second die including a second substrate, a second insulating layer, and a signal transmission line. The second die may be positioned above and spaced apart from the first die. An underfill is disposed between the ground plane of the first die and the signal transmission line of the second die. Collectively, the ground plane and transmission line of the first and second die and underfill forms a compact transmission line structure. In some embodiments, the transmission line structure may be used for microwave applications.

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 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: 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: A meander line resistor structure comprises a first resistor formed on a first active region, wherein the first resistor is formed by a plurality of first vias connected in series, a second resistor formed on a second active region, wherein the second resistor is formed by a plurality of second vias connected in series and a third resistor formed on the second active region, wherein the third resistor is formed by a plurality of third vias connected in series. The meander line resistor further comprises a first connector coupled between the first resistor and the second resistor.

Abstract: An apparatus for de-embedding through substrate vias is provided. The apparatus may include pads on a first side of a substrate are coupled to through vias extending through a substrate, wherein pairs of the through vias are interconnected by transmission lines of varying lengths along a second side of the substrate. The apparatus may further include pairs of pads coupled together by transmission lines of the same varying lengths. Apparatuses may include through vias surrounding a through via device under test. The surrounding through vias are connected to the through via device under test by a backside metal layer. The apparatus may further include a dummy structure having an area equal to an area of the backside metal layer.