Micromechanical resonator device and micromechanical device utilizing same
First Claim
1. A micromechanical resonator device having at least one mode shape, the device comprising:
- a substrate;
a disk-shaped resonator disposed above the substrate and having at least one nodal point; and
a support structure anchored to the substrate to support the resonator at the at least one nodal point above the substrate wherein both the resonator and the support structure are dimensioned and positioned relative to one another so that the resonator is substantially isolated during vibration thereof wherein energy losses to the substrate are substantially eliminated and wherein the resonator device is a high-Q resonator device.
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Abstract
A micromechanical resonator device and a micromechanical device utilizing same are disclosed based upon a radially or laterally vibrating disk structure and capable of vibrating at frequencies well past the GHz range. The center of the disk is a nodal point, so when the disk resonator is supported at its center, anchor dissipation to the substrate is minimized, allowing this design to retain high-Q at high frequency. In addition, this design retains high stiffness at high frequencies and so maximizes dynamic range. Furthermore, the sidewall surface area of this disk resonator is often larger than that attainable in previous flexural-mode resonator designs, allowing this disk design to achieve a smaller series motional resistance than its counterparts when using capacitive (or electrostatic) transduction at a given frequency. Capacitive detection is not required in this design, and piezoelectric, magnetostrictive, etc. detection are also possible. The frequency and dynamic range attainable by this resonator makes it applicable to high-Q RF filtering and oscillator applications in a wide variety of communication systems. Its size also makes it particularly suited for portable, wireless applications, where, if used in large numbers, such a resonator can greatly lower the power consumption, increase robustness, and extend the range of application of high performance wireless transceivers.
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Citations
11 Claims
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1. A micromechanical resonator device having at least one mode shape, the device comprising:
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a substrate;
a disk-shaped resonator disposed above the substrate and having at least one nodal point; and
a support structure anchored to the substrate to support the resonator at the at least one nodal point above the substrate wherein both the resonator and the support structure are dimensioned and positioned relative to one another so that the resonator is substantially isolated during vibration thereof wherein energy losses to the substrate are substantially eliminated and wherein the resonator device is a high-Q resonator device.
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2. A micromechanical resonator device having at least one mode shape, the device comprising:
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a substrate;
a disk-shaped resonator disposed above the substrate and having at least one nodal point; and
a drive electrode structure formed on the substrate at a position to allow electrostatic excitation of the resonator so that the resonator is driven in the at least one mode shape wherein the resonator and the drive electrode structure define a capacitive gap therebetween and wherein the capacitive gap is a sub-micron, lateral, capacitive gap.
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3. A micromechanical resonator device having at least one mode shape, the device comprising:
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a substrate;
a disk-shaped resonator disposed above the substrate and having at least one nodal point wherein the at least one nodal point corresponds to a center of the resonator; and
a support structure to support the resonator wherein the support structure is a single anchor positioned at the center of the resonator.
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4. A micromechanical resonator device having at least one mode shape, the device comprising:
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a substrate a disk-shaped resonator disposed above the substrate and having at least one nodal point; and
a drive electrode structure formed on the substrate at a position to allow electrostatic excitation of the resonator so that the resonator is driven in the at least one mode shape wherein the resonator and the drive electrode structure define a capacitive gap therebetween and wherein the drive electrode structure is positioned beneath the resonator and wherein the at least one mode shape includes a flexural mode shape.
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5. A micromechanical resonator device having at least one mode shape, the device comprising:
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a substrate; and
a disk-shaped resonator disposed above the substrate and having at least one nodal point wherein the device is diamond-based.
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6. A micromechanical device comprising:
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a substrate;
a disk-shaped input resonator disposed above the substrate and having at least one nodal point;
a disk-shaped output resonator disposed above the substrate and coupled to the input resonator and having at least one nodal point; and
a coupling spring for mechanically coupling the resonators together.
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7. A micromechanical device comprising:
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a substrate;
a disk-shaped input resonator disposed above the substrate and having at least one nodal point; and
a disk-shaped output resonator disposed above the substrate and coupled to the input resonator and having at least one nodal point, the device further comprising an intermediate resonator disposed above the substrate and coupled to the input and output resonators and having at least one nodal point, and further comprising a drive electrode structure formed on the substrate at a position to allow electrostatic excitation of the input resonator, a sense electrode structure formed on the substrate at a position to sense output current based on motion of the output resonator and an intermediate electrode structure formed on the substrate at a position for enhanced access to a response of the device.
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8. A micromechanical device comprising:
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a substrate;
a disk-shaped input resonator disposed above the substrate and having at least one nodal point; and
a disk-shaped output resonator disposed above the substrate and coupled to the input resonator and having at least one nodal point, wherein the device is a mixer.
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9. A micromechanical resonator device having at least one mode shape, the device comprising:
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a substrate; and
a disk-shaped resonator disposed above the substrate and having at least one nodal point, the resonator has at least one anti-nodal portion where the resonator experiences the most displacement when driven and wherein the device further comprises sensing means for sensing motion of the anti-nodal portion wherein the sensing means includes at least one projection projecting from the anti-nodal portion to move therewith and means coupled to the at least one projection to provide an output representation of motion of the anti-nodal portion. - View Dependent Claims (10)
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11. A micromechanical resonator device having at least one mode shape, the device comprising:
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a substrate; and
a disk-shaped resonator disposed above the substrate and having at least one nodal point further comprising a single electrode structure formed on the substrate at a position to allow electrostatic excitation of the resonator and to sense output current based on motion of the resonator.
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Specification