Self-tuning microelectromechanical impedance matching circuits and methods of fabrication

US 10,491,159 B2
Filed: 08/31/2017
Issued: 11/26/2019
Est. Priority Date: 09/07/2016
Status: Active Grant

First Claim

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1. A self-tuning impedance-matching microelectromechanical circuit, comprisinga) a self-tuning inductor element connected to a first mechanical spring and having a tunable reactance;

b) a tunable or fixed capacitor;

c) one or more electrical connections between the self-tuning inductor element and the tunable or fixed capacitor; and

d) an AC signal source configured to (i) provide an AC signal to the self-tuning inductor element and the tunable or fixed capacitor, the AC signal having a frequency, and (ii) create an electromagnetic force on the self-tuning inductor element that moves the self-tuning inductor element and tunes the self-tuning impedance-matching circuit toward resonance with the AC signal.

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Abstract

A self-tuning impedance-matching microelectromechanical (MEMS) circuit, methods for making and using the same, and circuits including the same are disclosed. The MEMS circuit includes a tunable reactance element connected to a first mechanical spring, a separate tunable or fixed reactance element, and an AC signal source configured to provide an AC signal to the tunable reactance element(s). The reactance elements comprise a capacitor and an inductor. The AC signal source creates an electromagnetically energy favorable state for the tunable reactance element(s) at resonance with the AC signal. The method of making generally includes forming a first MEMS structure and a second mechanical or MEMS structure in/on a mechanical layer above an insulating substrate, and coating the first and second structures with a conductor to form a first tunable reactance element and a second tunable or fixed reactance element, as in the MEMS circuit.

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20 Claims

1. A self-tuning impedance-matching microelectromechanical circuit, comprisinga) a self-tuning inductor element connected to a first mechanical spring and having a tunable reactance;
- b) a tunable or fixed capacitor;
  
  c) one or more electrical connections between the self-tuning inductor element and the tunable or fixed capacitor; and
  
  d) an AC signal source configured to (i) provide an AC signal to the self-tuning inductor element and the tunable or fixed capacitor, the AC signal having a frequency, and (ii) create an electromagnetic force on the self-tuning inductor element that moves the self-tuning inductor element and tunes the self-tuning impedance-matching circuit toward resonance with the AC signal.
- View Dependent Claims (2, 3, 4, 5, 6)
- - 2. The self-tuning impedance-matching circuit of claim 1, wherein the tunable or fixed capacitor comprises a self-tuning capacitor, and the self-tuning impedance-matching circuit further comprises an electrical connection between the self-tuning inductor element and the self-tuning capacitor.
  - 3. The self-tuning impedance-matching circuit of claim 1, wherein the self-tuning inductor element is connected in series with the tunable or fixed capacitor.
  - 4. The self-tuning impedance-matching circuit of claim 1, wherein the self-tuning inductor element is connected in parallel with the tunable or fixed capacitor.
  - 5. A circuit comprising:
    - at least one device selected from an antenna, an energy storage device, a piezoelectric energy harvester, a piezoelectric resonator, a MEMS resonator, and an inductively coupled circuit; and
      
      at least one self-tuning circuit of claim 1, directly or indirectly electromagnetically coupled to the at least one device.
  - 6. The circuit of claim 5, wherein the at least one device comprises the inductively coupled circuit, the at least one self-tuning circuit comprises at least one self-tuning microelectromechanical impedance-matching circuit, and the circuit further comprises an electrical load receiving inductive power from the inductively coupled circuit and the at least one self-tuning microelectromechanical impedance-matching circuit.

7. A self-tuning impedance-matching microelectromechanical circuit, comprisinga) a self-tuning capacitor element connected to a first mechanical spring and having a tunable reactance;
- b) an inductor;
  
  c) one or more electrical connections between the self-tuning capacitor element and the inductor; and
  
  d) an AC signal source configured to (i) provide an AC signal to the self-tuning capacitor element and the inductor, the AC signal having a frequency, and (ii) create an electromagnetic force on the self-tuning capacitor element that moves the self-tuning capacitor element and tunes the self-tuning impedance-matching circuit toward resonance with the AC signal.
- View Dependent Claims (8, 9)
- - 8. The self-tuning impedance-matching circuit of claim 7, wherein the self-tuning capacitor element is connected in series with the inductor.
  - 9. The self-tuning impedance-matching circuit of claim 7, wherein the self-tuning capacitor element is connected in parallel with the inductor.

10. A self-tuning impedance-matching microelectromechanical circuit, comprisinga) a first tunable reactance element connected to a first mechanical spring and having a tunable reactance;
- b) a second tunable or fixed reactance element;
  
  c) one or more electrical connections between the first tunable reactance element and the second tunable or fixed reactance element, wherein all or part of the at least one electrical connection comprises a superconducting material; and
  
  d) an AC signal source configured to (i) provide an AC signal to the first tunable reactance element and the second tunable or fixed reactance element, the AC signal having a frequency, and (ii) create an electromagnetic force on the first tunable reactance element that moves the first tunable reactance element and tunes the self-tuning impedance-matching circuit toward resonance with the AC signal,wherein one of the first tunable reactance element and the second tunable or fixed reactance element comprises a capacitor and the other of the first tunable reactance element and the second tunable or fixed reactance element comprises an inductor.
- View Dependent Claims (11, 12)
- - 11. The self-tuning impedance-matching circuit of claim 10, wherein the superconducting material comprises niobium-titanium, niobium-tin, YBaCuO, BiCaSrCuO, TlBaCuO, TlCaBaCuO, or HgCaBaCuO.
  - 12. The self-tuning impedance-matching circuit of claim 10, comprising a series RLC circuit having a Q factor, wherein the superconducting material is cooled to increase the Q factor.

13. A self-tuning impedance-matching microelectromechanical circuit, comprisinga) a first tunable reactance element connected to a first mechanical spring and having a tunable reactance;
- b) a second tunable or fixed reactance element;
  
  c) one or more electrical connections between the first tunable reactance element and the second tunable or fixed reactance element;
  
  d) an AC signal source configured to (i) provide an AC signal to the first tunable reactance element and the second tunable or fixed reactance element, the AC signal having a frequency, and (ii) create an electromagnetic force on the first tunable reactance element that moves the first tunable reactance element and tunes the self-tuning impedance-matching circuit toward resonance with the AC signal; and
  
  e) a plurality of actuator electrodes electrically coupled to the first tunable reactance element, configured to fine tune or de-tune the resonance of the self-tuning impedance-matching circuit,wherein one of the first tunable reactance element and the second tunable or fixed reactance element comprises a capacitor and the other of the first tunable reactance element and the second tunable or fixed reactance element comprises an inductor.
- View Dependent Claims (14)
- - 14. The self-tuning impedance-matching circuit of claim 13, wherein the plurality of actuator electrodes comprises first and second comb actuators coupled to the first tunable reactance element.

15. A circuit comprising:
- an antenna;
  
  a plurality of channels connected to the antenna, each having a different frequency;
  
  a first self-tuning circuit in series with at least one of the plurality of channels; and
  
  a second self-tuning parallel circuit connected between adjacent ones of the plurality of channels,wherein at least one of the first and second self-tuning circuits is directly or indirectly electromagnetically coupled to the antenna, and comprisesa first tunable reactance element connected to a first mechanical spring and having a tunable reactance;
  
  a second tunable or fixed reactance element;
  
  one or more electrical connections between the first tunable reactance element and the second reactance elements; and
  
  an AC signal source configured to (i) provide an AC signal to the first tunable reactance element and second reactance elements, the AC signal having a frequency, and (ii) create an electromagnetic force on the first tunable reactance element that moves the first tunable reactance element and tunes the self-tuning impedance-matching circuit toward resonance with the AC signal, wherein one of the first tunable reactance element and second reactance elements comprises a capacitor and the other of the first tunable reactance element and second reactance elements comprises an inductor.
- View Dependent Claims (16)
- - 16. The circuit of claim 15, comprising a plurality of the first self-tuning circuits, each in series with a unique one of the plurality of channels, and a plurality of the second self-tuning parallel circuits connected between first and second adjacent ones of the plurality of channels, wherein each of the first and second self-tuning circuits comprises the first tunable reactance element, the second tunable or fixed reactance element, the one or more electrical connections, and the AC signal source.

17. A circuit comprising:
- an antenna;
  
  an energy storage device comprising a battery or a capacitor; and
  
  at least one self-tuning microelectromechanical impedance-matching circuit, directly or indirectly electromagnetically coupled to the antenna and/or the energy storage device, comprisinga first tunable reactance element connected to a first mechanical spring and having a tunable reactance;
  
  a second tunable or fixed reactance element;
  
  one or more electrical connections between the first tunable reactance element and the second reactance elements; and
  
  an AC signal source configured to (i) provide an AC signal to the first tunable reactance element and the second tunable or fixed reactance element, the AC signal having a frequency, and (ii) create an electromagnetic force on the first tunable reactance element that moves the first tunable reactance element and tunes the self-tuning impedance-matching circuit toward resonance with the AC signal,wherein one of the first tunable reactance element and the second tunable or fixed reactance element comprises a capacitor, the other of the first tunable reactance element and the second tunable or fixed reactance element comprises an inductor, and the energy storage device is configured to store electromagnetic energy from the antenna and the self-tuning microelectromechanical impedance-matching circuit.
- View Dependent Claims (18)
- - 18. The circuit of claim 17, wherein the at least one self-tuning microelectromechanical impedance-matching circuit comprises a first self-tuning microelectromechanical impedance-matching circuit in series with the energy storage device and a second self-tuning microelectromechanical impedance-matching circuit in parallel with the energy storage device, and each of the first and second self-tuning microelectromechanical impedance-matching circuits comprises the first tunable reactance element, the second tunable or fixed reactance element, the one or more electrical connections, and the AC signal source.

19. A circuit comprising:
- an energy storage device comprising a battery or a capacitor;
  
  a piezoelectric energy harvester; and
  
  at least one self-tuning microelectromechanical (MEMS) impedance-matching circuit, directly or indirectly electromagnetically coupled to the piezoelectric energy harvester and/or the energy storage device, comprisinga first tunable reactance element connected to a first mechanical spring and having a tunable reactance;
  
  a second reactance element, wherein the second reactance element is tunable or fixed;
  
  one or more electrical connections between the first tunable reactance element and the second reactance element; and
  
  an AC signal source configured to (i) provide an AC signal to the first and second reactance elements, the AC signal having a frequency, and (ii) create an electromagnetic force on the first tunable reactance element that moves the first tunable reactance element and tunes the self-tuning impedance-matching circuit toward resonance with the AC signal,wherein one of the first tunable reactance element and the second reactance element comprises a capacitor, the other of the first tunable reactance element and the second reactance element comprises an inductor, and the energy storage device is configured to store electromagnetic energy from the piezoelectric energy harvester and the self-tuning MEMS impedance-matching circuit.
- View Dependent Claims (20)
- - 20. The circuit of claim 19, wherein the at least one self-tuning MEMS impedance-matching circuit comprises a first self-tuning MEMS impedance-matching circuit in series with the energy storage device and a second self-tuning MEMS impedance-matching circuit in parallel with the energy storage device, and each of the first and second self-tuning MEMS impedance-matching circuits comprises the first tunable reactance element, the second tunable or fixed reactance element, the one or more electrical connections, and the AC signal source.

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Current Assignee
Michael J. Dueweke
Original Assignee
Michael J. Dueweke
Inventors
Dueweke, Michael J.
Primary Examiner(s)
Jones, Stephen E.

Application Number

US15/691,948
Publication Number

US 20180069507A1
Time in Patent Office

817 Days
Field of Search

333 173, 333 32
US Class Current
CPC Class Codes

B81B 3/0051   For defining the movement, ...

B81B 3/0086   Electrical characteristics,...

B81C 99/003   Characterising MEMS devices...

G01C 19/5755   the devices having a single...

H01L 23/642   Capacitive arrangements H01...

H01L 28/60   Electrodes

H03B 5/364   the amplifier comprising fi...

H03H 2001/0021   Constructional details

H03H 2007/008   the MEMS being trimmable

H03H 2007/386   Multiple band impedance mat...

H03H 2009/02165   Tuning

H03H 3/0077   by tuning of resonance freq...

H03H 7/0115   comprising only inductors a...

H03H 7/175   Series LC in series path H0...

H03H 7/1766   Parallel LC in series path ...

H03H 7/38   Impedance-matching networks

H03H 7/383   comprising distributed impe...

H03H 7/40   Automatic matching of load ...

H03H 7/46   Networks for connecting sev...

H03H 9/0004   Impedance-matching networks...

H03H 9/70 : Multiple-port networks for ...

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Self-tuning microelectromechanical impedance matching circuits and methods of fabrication

First Claim

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Abstract

42 Citations

20 Claims

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Self-tuning microelectromechanical impedance matching circuits and methods of fabrication

First Claim

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Accused Products

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Abstract

42 Citations

20 Claims

Specification

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Solutions

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