An electronic component including a pad electrode provided on a wiring electrode and a Au bump provided on the pad electrode, wherein the uppermost layer of the wiring electrode is a first Ti layer, the uppermost layer of the pad electrode is a Au layer, and the thickness of the first Ti layer in at least a portion on which the Au bump is superposed in plan view is greater than the thickness of at least a portion of the first Ti layer in a portion on which the Au bump is not superposed in plan view.

An elastic wave filter apparatus includes at least one excitation electrode, a first electrode land, and second electrode lands provided on a first main surface of a device substrate including a piezoelectric layer. A signal terminal and metal members are provided on a second main surface of the device substrate. The first electrode land and the signal terminal are connected to a signal potential, and the second electrode lands and the metal members are connected to a ground potential. A first connection electrode connects the first electrode land and the signal terminal, and a second connection electrode connects at least one of the second electrode lands and at least one of the metal members. The at least one metal member connected to the second connection electrode overlaps at least a portion of the at least one excitation electrode across the device substrate.

An electronic component including a pad electrode provided on a wiring electrode and a Au bump provided on the pad electrode, wherein the uppermost layer of the wiring electrode is a first Ti layer, the uppermost layer of the pad electrode is a Au layer, and the thickness of the first Ti layer in at least a portion on which the Au bump is superposed in plan view is greater than the thickness of at least a portion of the first Ti layer in a portion on which the Au bump is not superposed in plan view.

An elastic wave device includes a piezoelectric substrate, an IDT electrode on the piezoelectric substrate and including first and second busbars and first and second electrode fingers connected to the first and second busbars, a bump electrode electrically connected to the IDT electrode, a protective film covering the IDT electrode, and a heat-conductive material layer that has an insulating property and that is provided only in a region excluding an excitation region of any IDT electrode and a region located above the bump electrode.

In an elastic wave filter apparatus, IDT electrodes and first and second electrode lands are provided on a first main surface of a piezoelectric substrate. The piezoelectric substrate, a supporting layer, and a covering member define a hollow portion. A signal terminal, a ground terminal, and a heat diffusion layer are provided on a second main surface of the piezoelectric substrate. The first and second electrode lands are electrically connected by first and second connection electrodes to the signal terminal and the ground terminal, respectively. The heat diffusion layer is provided at a position where the heat diffusion layer overlaps at least a portion of the IDT electrodes across the piezoelectric substrate.

An elastic wave device includes a piezoelectric substrate, an IDT electrode on the piezoelectric substrate, and a silicon oxide film arranged on the piezoelectric substrate to cover the IDT electrode. The IDT electrode includes first and second electrode layers laminated on each other, the first electrode layer is made of metal or an alloy with a density higher than a density of metal of the second electrode layer and a density of silicon oxide of the silicon oxide film, the piezoelectric substrate is made of LiNbO.sub.3 and is in a range of equal to or greater than about 8 and equal to or less than about 32 with Euler Angles (05, , 010) of the piezoelectric substrate, and the silicon oxide film contains hydrogen atoms, hydroxyl groups, or silanol groups.

Methods and apparatus for reducing electric loss in an elastic wave element. In one example such a method includes forming an IDT electrode on a piezoelectric body, and forming the connection wiring on the piezoelectric body and electrically connecting the connection wiring to the IDT electrode. Forming the connection wiring includes sequentially forming a lower connection wiring on an upper surface of the piezoelectric body and forming an upper connection wiring over the lower connection wiring. The method further includes forming a reinforcement electrode over the connection wiring that divides the upper connection wiring into first and second upper connection wirings electrically connected to one another by the reinforcement electrode. The reinforcement electrode is formed abutting an upper surface of the lower connection wiring between the first and second upper connection wirings and electrically connected to the lower connection wiring and to the first and second upper connection wirings.

An improved DMS filter with electrode structures between a first port and a second port is provided. Wiring junctions are realized in multilayer crossing with dielectric material in between. There are insulating patches (L2) between crossing conductor layers (L1,L3). Signal wirings may be realized with multiple conductor layers (L1, L3) to reduce wiring resistance and the upper conductor layer (L3) of the signal wiring may partly overlap the insulating patches (L2). The insulating patches (L2) may extend over the acoustic path to achieve temperature compensation.

An acoustic wave resonator includes: a piezoelectric substrate; and a pair of grating electrodes that is formed on the piezoelectric substrate, one of the pair of grating electrodes including a plurality of first electrode fingers having electric potentials equal to each other, another of the pair of grating electrodes including a plurality of second electrode fingers having electric potentials that differ from the electric potentials of the plurality of first electrode fingers and are equal to each other, two second electrode fingers of the plurality of second electrode fingers being located between at least a pair of adjacent first electrode fingers of the plurality of first electrode fingers, Pg differing from /4 where represents a wavelength of an acoustic wave excited by the plurality of first electrode fingers and the plurality of second electrode fingers and Pg represents a distance between centers of the two second electrode fingers.

Methods and apparatus for reducing electric loss in an elastic wave element. In one example such a method includes forming an IDT electrode on a piezoelectric body, and forming the connection wiring on the piezoelectric body and electrically connecting the connection wiring to the IDT electrode. Forming the connection wiring includes sequentially forming a lower connection wiring on an upper surface of the piezoelectric body and forming an upper connection wiring over the lower connection wiring. The method further includes forming a reinforcement electrode over the connection wiring that divides the upper connection wiring into first and second upper connection wirings electrically connected to one another by the reinforcement electrode. The reinforcement electrode is formed abutting an upper surface of the lower connection wiring between the first and second upper connection wirings and electrically connected to the lower connection wiring and to the first and second upper connection wirings.