A surface acoustic wave (SAW) device is disclosed. The SAW device includes a piezoelectric layer and a transducer having a plurality of electrodes. The electrodes are aligned with respective longitudinal axes parallel to each other and perpendicular to a wave propagation direction. Each electrode includes a conductive first layer having a first thickness and a first width in the wave propagation direction; and a conductive second layer having a second thickness that is negligible compared to the first thickness. The first layer and second layer are in electrical contact with each other to provide electrical conduction over a total width of the electrode in the wave propagation direction, the total width being greater than the first width of the first layer.

Multi-mode surface acoustic wave filters are disclosed. A multi-mode surface acoustic wave filter can include a plurality of interdigital transducer electrodes that are longitudinally coupled to each other and slanted acoustic reflectors on opposing sides of the plurality of interdigital transducer electrodes. The acoustic reflectors include acoustic reflector fingers with slanted pitches.

Multi-mode surface acoustic wave filters are disclosed. A multi-mode surface acoustic wave filter can include a plurality of interdigital transducer electrodes that are longitudinally coupled to each other and acoustic reflectors on opposing sides of the plurality of interdigital transducer electrodes. The acoustic reflectors include acoustic reflector fingers arranged to suppress a spurious response due to shear horizontal mode of the multi-mode surface acoustic wave filter. For example, the acoustic reflector fingers can include stepped lengths and/or slanted pitches to suppress the spurious response due to shear horizontal mode.

Multi-mode surface acoustic wave filters are disclosed. A multi-mode surface acoustic wave filter can include a plurality of interdigital transducer electrodes that are longitudinally coupled to each other and stepped acoustic reflectors on opposing sides of the plurality of interdigital transducer electrodes. The acoustic reflectors include acoustic reflector fingers with stepped lengths.

The present disclosure provides systems and methods for scalable and parallel computation of hierarchical cascading in finite element method (FEM) simulations of surface acoustic wave (SAW) devices. Different computing units of a cluster or cloud service may be assigned to independently model different core blocks or combinations of core blocks for iterative cascading to generate a model of the SAW devices. Similarly, frequency ranges may independently be assigned to computing units for modeling and analysis of devices, drastically speeding up computation.

Multi-mode surface acoustic wave filters are disclosed. A multi-mode surface acoustic wave filter can include a plurality of interdigital transducer electrodes that are longitudinally coupled to each other and stepped acoustic reflectors on opposing sides of the plurality of interdigital transducer electrodes. The acoustic reflectors include acoustic reflector fingers with stepped lengths.

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.

A reception filter includes a parallel arm resonator, a first longitudinally coupled resonance device including first acoustic wave resonators, and a second longitudinally coupled resonance device including second acoustic wave resonators, and cascade-connected to the first longitudinally coupled resonance device. Each of the first and second acoustic wave resonators include one end connected to a ground, the parallel arm resonator and the first and second longitudinally coupled resonance devices are provided on a piezoelectric substrate, and a ground to which the parallel arm resonator is connected, a ground to which at least one of the first acoustic wave resonators is connected, and a ground to which at least one of the second acoustic wave resonators is connected are commonly connected on the piezoelectric substrate.

A surface acoustic wave (SAW) device is disclosed. The SAW device includes a piezoelectric layer and a transducer having a plurality of electrodes. The electrodes are aligned with respective longitudinal axes parallel to each other and perpendicular to a wave propagation direction. Each electrode includes a conductive first layer having a first thickness and a first width in the wave propagation direction; and a conductive second layer having a second thickness that is negligible compared to the first thickness. The first layer and second layer are in electrical contact with each other to provide electrical conduction over a total width of the electrode in the wave propagation direction, the total width being greater than the first width of the first layer.

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.