Abstract: Differing metallic electrodes having the same or differing thickness are formed at different locations on a support structure and/or on a single thickness film of piezoelectric material in order to form a multiple frequency resonator device having greatly separated acoustic resonance frequencies. A plurality of multiple frequency resonators can be combined to form a blank of frequency selective devices in order to handle the many different RF bands, at widely varying frequencies, that wireless communication technologies demand today.

Abstract: A process for configuring a thin film resonator to advantageously shape a desired acoustic mode of the resonator such that the electrical and acoustic performance of the resonator is enhanced. As a result of the contouring or shaping, a minimum amount of acoustic energy occurs near the edge of the resonator, from which energy may leak or at which undesired waves may be created by a desired mode. The process is used during batch-fabrication of thin-film resonators which are used in high frequency RF filtering or frequency control applications. Utilizing photolithography, the shaping can be achieved in a manner derived from the known methods used to manufacture lens arrays. Using the process, the lateral motion of acoustic waves within the resonator may be controlled and the acoustic energy of the sound wave positioned at a desired location within the resonator.

Abstract: A process for configuring a thin film resonator to advantageously shape a desired acoustic mode of the resonator such that the electrical and acoustic performance of the resonator is enhanced. As a result of the contouring or shaping, a minimum amount of acoustic energy occurs near the edge of the resonator, from which energy may leak or at which undesired waves may be created by a desired mode. The process is used during batch-fabrication of thin-film resonators which are used in high frequency RF filtering or frequency control applications. Utilizing photolithography, the shaping can be achieved in a manner derived from the known methods used to manufacture lens arrays. Using the process, the lateral motion of acoustic waves within the resonator may be controlled and the acoustic energy of the sound wave positioned at a desired location within the resonator.

Abstract: This invention relates to a method and apparatus for imaging acoustic fields in high-frequency acoustic resonators. More particularly, the invention is directed to a scanning RF mode microscope system that detects and monitors vibration of high frequency resonators that vibrate in the frequency range of approximately 1 MHz to 20 GHz. The system then maps with sub-Angstrom resolution vibration modes of such devices and obtains quantitative measurements of the piezoelectric properties of the materials.

Abstract: First and second wafers are micromachined by standard integrated-circuit fabrication techniques to respectively make first and second component parts of a variable capacitor. A thin flexible membrane in the first wafer is integral with and mechanically supported by the first wafer. A metal pattern on the first wafer includes a first capacitor plate on the membrane. In the second wafer, a well is formed. A metal pattern on the second wafer includes a second capacitor plate in the well. By bonding the two parts together face-to-face, the capacitor plates are positioned in spaced-apart alignment with each other. External electrical connections to the plates are made via bonding-pad portions of the metal patterns on the wafers. In response to electrical control signals, the metal plate on the membrane can be moved toward the other plate, thereby selectively changing the capacitance of the assembly.

Abstract: A switching element according to this invention comprises a photostrictive member. Exposing the member to control light results in a dimensional change in the material. This change is utilized for changing the relative position between an optical fiber and another element, exemplarily a further fiber, a corrugated member, or a mirror, such that signal radiation is directed to a predetermined output port. A variety of exemplary switching elements are disclosed, including interferometric, beam-steering, evanescent field and mode conversion switching elements. Disclosed are also optical communication systems that utilize such switching elements, including passive optical networks.

Abstract: There is disclosed a number of rare-earth chelitte compounds which are useful for fluorescent thermal imaging applications over a wide temperature range. Several of these materials are ideal for particular imaging applications. Between EuTFC and EuHFC films, the entire temperature range of 30-300.degree. K. can be covered. The temperature sensitivity and other film properties may be tailored by varying the polymer in which the film is dissolved or changing from a dissolved film to a vacuum sublimated film.

Abstract: The specification describes a refractive lens for focusing cold neutrons. It comprises a plurality of concave lens elements made from materials with low neutron absorption.