Method and apparatus for tuning and matching an NMR coil

US 5,036,426 A
Filed: 02/22/1990
Issued: 07/30/1991
Est. Priority Date: 02/22/1990
Status: Expired due to Fees

First Claim

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1. A differential capacitor, comprising:

first, second and third terminals;

means for varying a first capacitance across said first and second terminals, a second capacitance across said first and third terminals remaining substantially constant and independent of the value of said capacitance across said first and second terminals, a third capacitance defined across said second and third terminals;

said second capacitance being substantially equal to the inverse of the sum of (a) the inverse of said first capacitance and (b) the inverse of said third capacitance.

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Abstract

Apparatus for tuning an NMR probe coil (10) to a desired frequency (ω) and matching the coil (10) and the apparatus to a desired input impedance (20) comprises a differential capacitor (54, 70, 80, 120) having first, second and third terminals. The capacitance across the first and third terminals of the differential capacitor (54, 80, 120) is constant and is preselected to obtain the desired resonant frequency (ω). The capacitance across first and second terminals of the capacitor (54, 70, 80, 120) is variable and is adjusted to obtain the desired input impedance (Z₀) without affecting the capacitance across the first and third terminals thereof.

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25 Claims

1. A differential capacitor, comprising:
- first, second and third terminals;
  
  means for varying a first capacitance across said first and second terminals, a second capacitance across said first and third terminals remaining substantially constant and independent of the value of said capacitance across said first and second terminals, a third capacitance defined across said second and third terminals;
  
  said second capacitance being substantially equal to the inverse of the sum of (a) the inverse of said first capacitance and (b) the inverse of said third capacitance.

2. A differential capacitor, comprising:
- first, second and third terminals;
  
  a first conductive surface connected to said first terminal;
  
  a second conductive surface connected to said third terminal and disposed at a fixed, predetermined distance from said first conductive surface; and
  
  a tap conductive surface insulatively disposed between said first and second conductive surfaces and connected to said second terminal, said tap conductive surface operable to be moved toward or away from said first conductive surface to vary the capacitance between said first and second terminals.
- View Dependent Claims (3, 4)
- - 3. The differential capacitor of claim 2, wherein said first, second and tap surfaces are plates disposed substantially in parallel to each other.
  - 4. The differential capacitor of claim 2, wherein said conductive surfaces are substantially flat.

5. A differential capacitor, comprising:
- first, second and third terminals;
  
  a plurality of first conductive plates connected in parallel to said first terminal;
  
  a plurality of second conductive plates disposed in parallel to respective ones of said first conductive plates, said second conductive plates connected in parallel to said third terminal, each second conductive plate being fixed in relation to a respective one of said first conductive plates; and
  
  a plurality of tap conductive plates disposed in parallel between respective ones of said first and second conductive plates, said tap conductive plates insulated from said first and second conductive plates, said tap conductive plates connected in parallel to said second terminal, said tap conductive plates movable in unison toward or away from respective ones of said first conductive plates in order to vary the capacitance across said first and second terminals.
- View Dependent Claims (6)
- - 6. The differential capacitor of claim 5, wherein said conductive plates are substantially flat.

7. A differential capacitor, comprising:
- first, second and third terminals;
  
  a plurality of capacitors connected in series between said first and third terminals, each capacitor connected to an adjacent capacitor through an intercapacitor node; and
  
  a tap for connecting to a selected one of said intercapacitor nodes or to a selected one of said first and third terminals, said tap connected to said second terminal, means for varying the connection of the tap to said selected one of said nodes or terminals in order to vary the capacitance across said first and second terminals.

8. A circuit for tuning a coil to a predetermined resonant frequency and for matching an input impedance of the circuit to an impedance of an EMF source, comprising:
- a differential capacitor having first, second and third terminals, said first and third terminals connected to respective terminals of said coil, said first and second terminals connected to respective terminals of said EMF source; and
  
  means for varying a capacitance across said first and second terminals, a capacitance across said first and third terminals remaining substantially constant and independent of the value of said capacitance across said first and second terminals, said capacitance across said first and third terminals preselected to obtain said desired resonant frequency, said capacitance across said first and second terminals adjusted to obtain a match to said impedance of said EMF source.
- View Dependent Claims (9)
- - 9. The circuit of claim 8, wherein said differential capacitor comprises:
    - a first conductive surface connected to said first terminal;
      
      a second conductive surface connected to said third terminal and disposed at a fixed, predetermined distance from said first conductive surface; and
      
      a tap conductive surface insulatively disposed between said first and second conductive surfaces and connected to said second terminal, said tap conductive surface operable to be moved toward or away from said first conductive surface to vary the capacitance between said first and second terminals.

10. Apparatus for tuning a nuclear magnetic resonance (NMR) probe coil to a desired resonant frequency and for matching a combined input impedance of said coil and said apparatus to the output impedance of an EMF source, comprising:
- a differential capacitor having first, second and third terminals, terminals of said NMR coil connected to said first and third terminals of said differential capacitor, respective terminals of said EMF source connected to said second and third terminals of said differential capacitor; and
  
  means for varying a capacitance across said first and second terminals in order to achieve a match of said input impedance to said output impedance, a capacitance across said first and third terminals preselected to obtain said resonant frequency, said capacitance across said first and third terminals remaining substantially constant and independent of the value of said capacitance across said first and second terminals.
- View Dependent Claims (11, 12, 13, 14, 15)
- - 11. The apparatus of claim 10, and further comprising:
    - a first conductive plate connected to said first terminal;
      
      a second conductive plate connected to said third terminal and disposed in fixed relationship to said first conductive plate; and
      
      a tap conductive plate insulatively disposed between said first and second conductive plates and connected to said second terminal, said tap conductive plate disposed in parallel with said first and second conductive plates, and operable to be moved toward or away from said first conductive plate to vary the capacitance between said first and second terminals.
  - 12. The apparatus of claim 10, add further comprising:
    - a plurality of first conductive plates connected in parallel to said first terminal;
      
      a plurality of second conductive plates disposed in parallel to respective ones of said first conductive plates, said second conductive plates connected in parallel to said third terminal, each second conductive plate being fixed in relation to a respective one of said first conductive plates; and
      
      a plurality of tap conductive plates disposed in parallel between respective ones of said first and second conductive plates, said tap conductive plates insulated from said first and second conductive plates and connected in parallel to said second terminal, said tap conductive plates movable in unison toward or away from respective ones of said first conductive plate in order to vary the capacitance across said first and second terminals.
  - 13. The apparatus of claim 10, and further comprising:
    - a plurality of capacitors connected in series between said first and third terminals, each capacitor connected to an adjacent capacitor through an intercapacitor node; and
      
      a tap for connecting to a selected one of said intercapacitor nodes or to a selected one of said first and third terminals, said tap connected to said second terminal, means for varying the connection of the tap to said selected one of said nodes or terminals in order to vary the capacitance across the said first and second terminals.
  - 14. The apparatus of claim 10, and further comprising a variable capacitor connected across said first and third terminals for tuning said apparatus and said coil to said desired resonant frequency.
  - 15. The apparatus of claim 10, and further comprising a variable capacitor, a first terminal of said variable capacitor connected to said first terminal of said differential capacitor, a second terminal of said variable capacitor connected to a terminal of said NMR probe coil, said variable capacitor operable to have its capacitance varied for tuning said apparatus and said NMR probe coil to said desired resonant frequency.

16. A method for tuning a nuclear magnetic resonance probe coil to a desired resonant frequency and for matching the probe coil to an impedance of an EMF source, comprising the steps of:
- selecting a differential capacitor having a constant capacitance across first and third terminals thereof that, when placed across the probe coil, will cause the coil to resonate at the desired resonant frequency;
  
  coupling the first and third terminals of the differential capacitor across terminals of the probe coil;
  
  adjusting a tap of the differential capacitor to set an input impedance of the probe coil and capacitor to substantially equal the EMF source impedance; and
  
  connecting the EMF source between the tap and a preselected one of the probe coil terminals.
- View Dependent Claims (17, 18, 19)
- - 17. The method of claim 16, and further comprising the steps of:
    - connecting a variable capacitor across the terminals of the probe coil; and
      
      adjusting the capacitance of the variable capacitor in order to precisely tune to the resonant frequency.
  - 18. The method of claim 16, and further comprising the steps of:
    - connecting a first terminal of a variable capacitor to the first terminal of the differential capacitor;
      
      connecting a second, opposed terminal of the variable capacitor to a terminal of the probe coil; and
      
      varying the capacitance of the variable capacitor in order to precisely tune to the desired resonant frequency.
  - 19. The method of claim 16, wherein said step of adjusting comprises moving a tap conductive plate insulatively disposed between a first conductive plate connected to the first terminal and a second conductive plate connected to the third terminal toward or away from the first conductive plate in order to vary the capacitance across the first and second terminals.

20. A differential capacitor, comprising:
- a plurality of capacitive elements substantially solely providing all capacitances of said differential capacitor, said elements consisting of first, second and third integral conductors; and
  
  means for varying a capacitance between said first and second conductors, a capacitance between said first and third conductors remaining substantially constant and independent of said capacitance between said first and second conductors.
- View Dependent Claims (21, 22)
- - 21. The differential capacitor of claim 20, wherein said conductors are plates.
  - 22. The differential capacitor of claim 21, wherein said conductors are substantially flat.

23. A differential capacitor, comprising:
- a plurality of sets of capacitive elements substantially solely providing all capacitances of said differential capacitor, said sets consisting of first, second and third sets of integral conductors, each integral conductor within a set disposed in fixed relationship with each other integral conductor within the last said set;
  
  means for varying a capacitance between said first and second sets of conductors, a capacitance between said first and third sets of conductors remaining substantially constant and independent of said capacitance of said first and second sets of conductors.
- View Dependent Claims (24, 25)
- - 24. The differential capacitor of claim 23, wherein said conductors are plates.
  - 25. The differential capacitor of claim 24, wherein said conductors are substantially flat.

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Current Assignee
Board of Regents of the University of Texas System (University of Texas System)
Original Assignee
Board of Regents of the University of Texas System (University of Texas System)
Inventors
Shen, Gary G.
Primary Examiner(s)
Griffin, Donald A.

Application Number

US07/483,577
Time in Patent Office

523 Days
Field of Search

361/277, 361/299, 361/328, 361/329, 361/330, 334/78-83, 324/311, 324/318, 324/319, 324/322
US Class Current

361/329
CPC Class Codes

G01R 33/3628 Tuning/matching of the tran...

H01G 5/16 using variation of distance...

Method and apparatus for tuning and matching an NMR coil

First Claim

1 Assignment

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Abstract

21 Citations

25 Claims

Specification

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Method and apparatus for tuning and matching an NMR coil

First Claim

1 Assignment

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0 Petitions

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Accused Products

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Abstract

21 Citations

25 Claims

Specification

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Solutions

Use Cases

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