According to various aspects and embodiments, a method for forming a packaged electronic device is provided. In accordance with one embodiment, the method comprises depositing a layer of temporary adhesive material on at least a portion of a surface of a first substrate having a coefficient of thermal expansion, depositing a layer of dielectric material on at least a portion of the layer of temporary adhesive material, forming at least one seal ring on at least a portion of the layer of dielectric material, providing a second substrate having a coefficient of thermal expansion that is substantially the same as the coefficient of thermal expansion of the first substrate, the second substrate having at least one bonding structure attached to a surface of the second substrate, and aligning the at least one seal ring to the at least one bonding structure and bonding the first substrate to the second substrate.

An acoustic wave filter device includes a base having an acoustic wave filter part and a bonding part disposed thereon, the bonding part surrounding the acoustic wave filter part, and a cap having a bonding counterpart disposed thereon, the bonding counterpart being bonded to the bonding part of the base, and the bonding part includes a first bonding layer including gold, and the bonding counterpart includes a second bonding layer bonded to the first bonding layer and including tin.

A high-frequency module includes a propagation path that has a simple structure and improves filter characteristics by causing an inductor and a matching network to electromagnetic field couple with each other such that attenuation characteristics outside of a frequency band of a transmission signal are improved without increasing the size of the high-frequency module. In addition, unintended electromagnetic field coupling between a first filter and the inductor is significantly reduced or prevented by a shield electrode. Therefore, unintended propagation of a high-frequency signal is significantly reduced or prevented. Therefore, the attenuation characteristics outside of the frequency band of transmission signal input to the transmission terminal are improved more effectively.

Packaged RF front end systems including a hybrid filter and an active circuit in a single package are described. In an example, a package includes an active die comprising an acoustic wave resonator. A package substrate is electrically coupled to the active die. A seal frame surrounds the acoustic wave resonator and is attached to the active die and to the package substrate, the seal frame hermetically sealing the acoustic wave resonator in a cavity between the active die and the package substrate.

An electronic component device includes first and second mount boards, and first, second, and third electronic components. The first electronic component includes a first major surface and a second major surface, and is disposed on the first mount board. The first major surface is positioned closer to the first mount board than the second major surface. The second electronic component includes a third major surface and a fourth major surface, and is disposed on the second mount board. The third major surface is positioned closer to the second mount board than the fourth major surface. The third electronic component includes a fifth major surface and a sixth major surface, and is disposed on the second mount board. The fifth major surface is positioned closer to the second mount board than the sixth major surface. The second major surface directly contacts the fourth and sixth major surfaces, or indirectly contacts the fourth and sixth major surfaces with a bonding layer interposed therebetween.

An acoustic wave device includes a first acoustic wave element including a first substrate having piezoelectricity at least in a portion thereof, a first functional electrode provided on a first surface of the first substrate, and a first wiring conductor electrically connected to the first functional electrode. The first acoustic wave element further includes a relay electrode on the first surface of the first substrate and electrically connected to a second wiring conductor, and a ground electrode on the first surface of the first substrate and electrically connected to the first functional electrode. The ground electrode is between at least one of the first functional electrode and the first wiring conductor, and the relay electrode, and is electrically insulated from the relay electrode.

An electronic component includes an electronic component element including first and second main surfaces, a heat-dissipation accelerating member on the first main surface, a sealing resin layer sealing the electronic component element, and a shielding member provided on the sealing resin layer and electrically connected to the heat-dissipation accelerating member. The heat-dissipation accelerating member includes fourth and fifth main surfaces. The electronic component includes a connecting member disposed on the fifth main surface of the heat-dissipation accelerating member and electrically connecting at least one portion of the heat-dissipation accelerating member and the shielding member. The connecting member has a higher thermal conductivity than the sealing resin layer. The contact area between the heat-dissipation accelerating member and the connecting member is smaller than the area of the fifth main surface.

A SAW device includes a SAW element, a conductor connected to the SAW element, an LT substrate including the SAW element, and a case for housing the LT substrate including the SAW element. The case includes a cover part, a lateral part, and a bottom part. The bottom part is including a sapphire substrate, the LT substrate is positioned on a first surface of the sapphire substrate, the first surface serving as an inner surface of the case, and a second surface opposite to the first surface serves as an outer surface of the case. The conductor includes a via conductor provided in a through-hole continuously penetrating through the sapphire substrate and the LT substrate.

A protective cover for an acoustic wave device and a fabrication method thereof, for protecting an acoustic wave device having a resonant area on a surface of a substrate during a packaging operation so as to avoid molding compound flowing onto the resonant area of the acoustic wave device, wherein at least one electrical device is provided on the surface of the substrate and the at least one electrical device includes a temperature sensor. The acoustic wave device protection structure comprising: a metal covering layer, having a concave surface and a bottom rim, the bottom rim connected to the acoustic wave device and forming at least one opening between the bottom rim and the acoustic wave device, and the concave surface covering over the resonant area to form a cavity between the concave surface and the resonant area.

An acoustic wave device includes: a first substrate including a support substrate and a piezoelectric substrate bonded on an upper surface of the support substrate, and including a first acoustic wave element located on an upper surface of the piezoelectric substrate; a ring-shaped metal layer located in a region that surrounds the first acoustic wave element and in which the piezoelectric substrate is removed, a second substrate flip-chip mounted on an upper surface of the first substrate and including a functional element located on a lower surface of the second substrate; and a metallic member located on an upper surface of the ring-shaped metal layer, surrounding the second substrate in plan view, not located between the first substrate and the second substrate, and sealing the first acoustic wave element and the functional element so that the first acoustic wave element and the functional element are located across an air gap.