A body, comprising stacked substrates, wherein: a first substrate, an adhesion layer comprising a reaction product of a compound (A), which has a cationic functional group containing at least one of a primary nitrogen atom or a secondary nitrogen atom and which has a defined weight average molecular weight, and a crosslinking agent (B), which has three or more C(O)OX groups in a molecule, in which from one to six of the three or more C(O)OX groups are C(O)OH groups and which has a weight average molecular weight of from 200 to 600, X is a hydrogen atom or an alkyl group having from 1 to 6 carbon atoms, and a second substrate, are layered in this order, and the compound (A) comprises at least one selected from the group consisting of a defined aliphatic amine and a defined compound having a siloxane bond and an amino group.

A packaged module for use in a wireless communication device has a substrate supporting an integrated circuit die that includes at least a microprocessor and radio frequency receiver circuitry and a stacked filter assembly configured as a filter circuit that is in communication with the radio frequency receiver circuitry. The stacked filter assembly includes a plurality of passive components, where each passive component is packaged as a surface mount device. At least one passive component is in direct communication with the substrate and at least another passive component is supported above the substrate by the at least one passive component that is in the direct communication with the substrate.

A substrate structure includes a first portion, a second portion, and an intermedia portion disposed between the first and the second portion and the electrically connected business. The first portion includes a first fine redistribution layer (RDL) and a first coarse RDL. The first coarse RDL includes a first coarse conductive pattern, electrically connected to the first fine conductive pattern, where a, the first coarse RDL includes a first coarse conductive pattern Layout density of the first fine conductive pattern is denser than that of the first coarse conductive pattern. The second portion includes at least one of a second fine RDL and a second coarse RDL. An electronic device including a substrate structure is also provided.

An ultrasound device includes: ultrasonic transducer cavities; a membrane comprising a silicon layer that seals the ultrasonic transducer cavities; electrode regions configured to control vibration of the membrane; and a complementary metal-oxide-semiconductor (CMOS) substrate including integrated circuitry that is electrically coupled to the electrode regions. The ultrasonic transducer cavities are disposed between the membrane and the integrated circuitry along a vertical direction of the ultrasound device.

A packaged module for use in a wireless communication device has a substrate supporting a crystal assembly and a first die that implements at least a portion of a radio frequency baseband subsystem. The crystal assembly, positioned between the first die and the substrate, includes a crystal, an input terminal configured to receive a first signal, an output terminal configured to output a second signal, a conductive pillar, and an enclosure configured to enclose the crystal, where the conductive pillar is formed at least partially within a side of the enclosure and extends from a top surface to a bottom surface of the enclosure. The conductive pillar conducts a third signal distinct from the first and second signals.

A packaged module for use in a wireless communication device has a substrate supporting an integrated circuit die that includes at least a microprocessor and radio frequency receiver circuitry and a stacked filter assembly configured as a filter circuit that is in communication with the radio frequency receiver circuitry. The stacked filter assembly includes a plurality of passive components, where each passive component is packaged as a surface mount device. At least one passive component is in direct communication with the substrate and at least another passive component is supported above the substrate by the at least one passive component that is in the direct communication with the substrate.

A packaged module for use in a wireless communication device has a substrate supporting a crystal assembly and a first die that implements at least a portion of a radio frequency baseband subsystem. The crystal assembly, positioned between the first die and the substrate, includes a crystal, an input terminal configured to receive a first signal, an output terminal configured to output a second signal, a conductive pillar, and an enclosure configured to enclose the crystal, where the conductive pillar is formed at least partially within a side of the enclosure and extends from a top surface to a bottom surface of the enclosure. The conductive pillar conducts a third signal distinct from the first and second signals.

A substrate structure includes a first portion, a second portion, and an intermedia portion disposed between the first and the second portion and the electrically connected business. The first portion includes a first fine redistribution layer (RDL) and a first coarse RDL. The first coarse RDL includes a first coarse conductive pattern, electrically connected to the first fine conductive pattern, where a, the first coarse RDL includes a first coarse conductive pattern Layout density of the first fine conductive pattern is denser than that of the first coarse conductive pattern. The second portion includes at least one of a second fine RDL and a second coarse RDL. An electronic device including a substrate structure is also provided.

There is provided a semiconductor device including: a plurality of bumps on a first semiconductor substrate; and a lens material in a region other than the plurality of bumps on the first semiconductor substrate, wherein a distance between a side of a bump closest to the lens material and a side of the lens material closest to the bump is greater than twice a diameter of the bump closest to the lens material, and wherein the distance between the side of the bump closest to the lens material and the side of the lens material closest to the bump is greater a minimum pitch of the bumps.

Micromachined ultrasonic transducers integrated with complementary metal oxide semiconductor (CMOS) substrates are described, as well as methods of fabricating such devices. Fabrication may involve two separate wafer bonding steps. Wafer bonding may be used to fabricate sealed cavities in a substrate. Wafer bonding may also be used to bond the substrate to another substrate, such as a CMOS wafer. At least the second wafer bonding may be performed at a low temperature.