FREQUENCY SYNTHESIZERS

Brand Owner (click to sort) Address Description
CHI-O CHI ORGANIZER Don Paris 1837 Cascade View Dr. Camano Island WA 98282 Frequency synthesizers;CHI O CHI ORGANIZER;CHI ORGANIZER;
DIGIPHASE DANA LABORATORIES, INCORPORATED 2401 CAMPUS DRIVE IRVINE CA 92664 FREQUENCY SYNTHESIZERS;
IMPINJ Impinj, Inc. 400 Fairview Ave N. Suite 1200 Seattle WA 98109 Frequency synthesizers, pulse shaping filters, intermediate frequency filters and high resolution high speed analog to digital converters, all embodied in integrated circuits;Coffee mugs;
PROGRAMMED TEST SOURCES Programmed Test Sources, Inc. 9 Beaver Brook Road Post Office Box 517 Littleton MA 01460 frequency synthesizers;PTS;
SELF-ADAPTIVE SILICON Impinj, Inc. 400 Fairview Ave N. Suite 1200 Seattle WA 98109 frequency synthesizers, pulse shaping filters, intermediate frequency filters and high resolution high speed analog to digital converters, all embodied in integrated circuits;SELF ADAPTIVE SILICON;
STUTTER EDIT BINARY ACOUSTICS, INC. 267 Kentlands Blvd #605 Gaithersburg MD 20878 Frequency synthesizers; disc jockey electronic controllers for electronic sound mixing, processing and synthesizing apparatus;Guitar pedals; music synthesizers;
VIRTUAL CRYSTAL Mixed-Signal Devices Inc. 18 Technology, Suite 163 Irvine CA 92618 Frequency synthesizers; clock generators for computers; clock generators for cell phones; analog to digital converter (ADCs); digital to analog converters (DACs);CRYSTAL;
 

Where the owner name is not linked, that owner no longer owns the brand

    
Technical Examples
  1. There are many inventions described and illustrated herein. In one aspect, the present invention is directed to a compensated microelectromechanical oscillator, having a microelectromechanical resonator that generates an output signal and frequency adjustment circuitry, coupled to the microelectromechanical resonator to receive the output signal of the microelectromechanical resonator and, in response to a set of values, to generate an output signal having second frequency. In one embodiment, the values may be determined using the frequency of the output signal of the microelectromechanical resonator, which depends on the operating temperature of the microelectromechanical resonator and/or manufacturing variations of the microelectromechanical resonator. In one embodiment, the frequency adjustment circuitry may include frequency multiplier circuitry, for example, PLLs, DLLs, digital/frequency synthesizers and/or FLLs, as well as any combinations and permutations thereof. The frequency adjustment circuitry, in addition or in lieu thereof, may include frequency divider circuitry, for example, DLLs, digital/frequency synthesizers (for example, DDS) and/or FLLs, as well as any combinations and permutations thereof.