Apparatus and method for remote, noninvasive characterization of structures and fluids inside containers

US 6,186,004 B1
Filed: 05/27/1999
Issued: 02/13/2001
Est. Priority Date: 05/27/1999
Status: Expired due to Term

First Claim

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1. An apparatus for remote, noninvasive characterization of an object which comprises in combination:

(a) at least one air-coupled transducer for generating a directed, ultrasonic sound wave having a chosen frequency, wherein the ultrasonic sound wave is directed toward the object to be characterized;

(b) modulation means for amplitude modulating the ultrasonic sound wave at a chosen modulation frequency, whereby the interaction of the amplitude modulated sound wave with the air medium between the object to be characterized and said at least one transducer generates a sound wave having as its frequency the chosen modulation frequency, the sound wave produced thereby generating vibrational excitation in the object to be characterized; and

(c) remote means for measuring the vibrational excitation in the structure under investigation, whereby the object is remotely characterized.

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Abstract

An apparatus and method for the remote, noncontact evaluation of structures and containers at large distances (on the order of several meters) in air is described. The invention utilizes an air-coupled, parametric acoustic array to excite resonance vibrations of elastic, fluid-filled vessels and structural members. A nonlinear mixing process in the air medium transforms highly directional, narrow beamwidth higher acoustic frequencies into lower acoustic frequencies suitable for vibrational excitation of common structures. The parametric array also has an advantage for nondestructive evaluation applications in that it is capable of producing a broader bandwidth than typical linear devices, such as speakers and ultrasonic transducers. Typical carrier frequencies are in the 200 kHz range, and the sound field 3 m from the array has been demonstrated to have a bandwidth of greater than 25 kHz at a center frequency of 15 kHz. Vibrations have been excited in a fluid-filled, steel container at distances greater than 3 m from the array which are readily detected using a laser vibrometer in a fixed position relative to the acoustic array. It is demonstrated that the fluid contained within the steel vessel may be classified by analyzing the change in the response of the generated lowest-order, antisymmetric Lamb wave to changes in the interior fluid loading.

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20 Claims

1. An apparatus for remote, noninvasive characterization of an object which comprises in combination:
- (a) at least one air-coupled transducer for generating a directed, ultrasonic sound wave having a chosen frequency, wherein the ultrasonic sound wave is directed toward the object to be characterized;
  
  (b) modulation means for amplitude modulating the ultrasonic sound wave at a chosen modulation frequency, whereby the interaction of the amplitude modulated sound wave with the air medium between the object to be characterized and said at least one transducer generates a sound wave having as its frequency the chosen modulation frequency, the sound wave produced thereby generating vibrational excitation in the object to be characterized; and
  
  (c) remote means for measuring the vibrational excitation in the structure under investigation, whereby the object is remotely characterized.
- View Dependent Claims (2, 3, 4, 5, 6)
- - 2. The apparatus for remote, noninvasive characterization of an object as described in claim 1, wherein said remote means for measuring the vibrational excitation includes a laser vibrometer.
  - 3. The apparatus for remote, noninvasive characterization of an object as described in claim 1, wherein said at least one air-coupled transducer is disposed at a sufficient distance from the object to be characterized such that a substantial portion of the directed ultrasonic sound wave is absorbed by the air therebetween.
  - 4. The apparatus for remote, noninvasive characterization of an object as described in claim 1, wherein the chosen frequency for the ultrasonic sound wave is between 40 kHz and 1 MHz and the chosen modulation frequency is between 1 and 30 kHz.
  - 5. The apparatus for remote, noninvasive characterization of an object as described in claim 1, wherein the object includes fluid-filled containers and pipes.
  - 6. The apparatus for remote, noninvasive characterization of an object as described in claim 1, wherein said at least one air-coupled transducer is formed into an array having a geometry which focuses the ultrasonic sound wave onto the object to be characterized.

7. An apparatus for remote, noninvasive characterization of an object which comprises in combination:
- (a) at least one first air-coupled transducer for generating a first directed, ultrasonic sound wave having a chosen first frequency and directed toward the object to be characterized;
  
  (b) at least one second air-coupled transducer for generating a second directed, ultrasonic sound wave having a chosen second frequency, and directed toward the object to be characterized, whereby the first sound wave and the second sound wave are caused to intersect in a region in the air between said at least one first transducer and said at least one second transducer and the object to be characterized, such that the difference frequency therebetween is generated and impinges on the object to be characterized, thereby producing vibrational excitation in the object to be characterized; and
  
  (c) remote means for measuring the vibrational excitation in the object to be characterized, whereby the object is remotely characterized.
- View Dependent Claims (8, 9, 10, 11, 12)
- - 8. The apparatus for remote, noninvasive characterization of an object as described in claim 7, wherein said remote means for measuring the vibrational excitation includes a laser vibrometer.
  - 9. The apparatus for remote, noninvasive characterization of an object as described in claim 7, wherein said at least one first air-coupled transducer and said at least one second air-coupled transducer are disposed at a sufficient distance from the object to be characterized such that a substantial portion of the first ultrasonic sound wave and the second ultrasonic sound wave are absorbed by the air therebetween after the difference frequency sound wave is generated.
  - 10. The apparatus for remote, noninvasive characterization of an object as described in claim 7, wherein the chosen first frequency for the first ultrasonic sound wave is between 40 kHz and 1 MHz and the chosen second frequency for the second ultrasonic sound wave is between 40 kHz and 1 MHz, and the difference frequency is between 1 and 30 kHz.
  - 11. The apparatus for remote, noninvasive characterization of an object as described in claim 7, wherein the object includes fluid-filled containers and pipes.
  - 12. The apparatus for remote, noninvasive characterization of an object as described in claim 7, wherein said at least one first air-coupled transducer is formed into an array having a geometry which focuses the first directed, ultrasonic sound wave into the region of intersection of the first directed, ultrasonic sound wave and the second directed, ultrasonic sound wave, and wherein said at least one second air-coupled transducer is formed into an array having a geometry which focuses the second directed, ultrasonic sound wave into the region of intersection of the first directed, ultrasonic sound wave and the second directed, ultrasonic sound wave.

13. A method for remote, noninvasive characterization of an object which comprises the steps of:
- (a) generating a directed, ultrasonic sound wave having a chosen frequency, wherein the ultrasonic sound wave is directed toward the object to be characterized;
  
  (b) amplitude modulating the ultrasonic sound wave at a chosen modulation frequency, whereby the interaction of the amplitude modulated sound wave with the air medium generates a sound wave having as its frequency the chosen modulation frequency which produces vibrational excitation in the object to be characterized; and
  
  (c) remotely measuring the vibrational excitation in the object to be characterized, whereby the structure is remotely characterized.
- View Dependent Claims (14, 15, 16)
- - 14. The method for remote, noninvasive characterization of an object as described in claim 13, wherein the object includes fluid-filled containers and pipes.
  - 15. The method for remote, noninvasive characterization of an object as described in claim 13, wherein the chosen frequency for the ultrasonic sound wave is between 40 kHz and 1 MHz and the chosen modulation frequency is between 1 and 30 kHz.
  - 16. The method for remote, noninvasive characterization of an object as described in claim 13, wherein said step of generating a directed, ultrasonic sound wave having a chosen frequency is caused to occur at a sufficient distance from the object to be characterized that a substantial portion of the directed ultrasonic sound wave is absorbed by the air.

17. A method for remote, noninvasive characterization of an object which comprises the steps of:
- (a) generating a first directed, ultrasonic sound wave having a chosen first frequency and directed toward the object to be characterized;
  
  (b) generating a second directed, ultrasonic sound wave having a chosen second frequency, and directed toward the object to be characterized, whereby the first sound wave and the second sound wave are caused to intersect in the air such that the difference frequency therebetween is generated and impinges on the object to be characterized, thereby producing vibrational excitation in the object; and
  
  (c) measuring the vibrational excitation in the object to be characterized, whereby the object is remotely characterized.
- View Dependent Claims (18, 19, 20)
- - 18. The method for remote, noninvasive characterization of an object as described in claim 17, wherein the object includes fluid-filled containers and pipes.
  - 19. The method for remote, noninvasive characterization of an object as described in claim 17, wherein the chosen first frequency for the first ultrasonic sound wave is between 40 kHz and 1 MHz and the chosen second frequency for the second ultrasonic sound wave is between 40 kHz and 1 MHz, and the difference frequency is between 1 and 30 kHz.
  - 20. The method for remote, noninvasive characterization of an object as described in claim 17, wherein said step of generating a first directed, ultrasonic sound wave having a chosen first frequency and said step of generating a second directed, ultrasonic sound wave having a chosen second frequency are caused to occur at a sufficient distance from the object to be characterized that a substantial portion of the first ultrasonic sound wave and the second ultrasonic sound wave are absorbed by the air after the difference frequency sound wave is generated.

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Current Assignee
TRIAD National Security, LLC
Original Assignee
Regents of the University of California (University of California)
Inventors
Kaduchak, Gregory, Sinha, Dipen N.
Primary Examiner(s)
Moller, Richard A.

Application Number

US09/323,175
Time in Patent Office

628 Days
Field of Search

735/96, 736/49, 736/55, 736/57, 736/45, 736/46, 736/27, 736/28, 367/87, 367/92
US Class Current

73/596
CPC Class Codes

G01N 2291/014   Resonance or resonant frequ...

G01N 2291/02836   Flow rate, liquid level

G01N 2291/0423   Surface waves, e.g. Rayleig...

G01N 2291/0427   Flexural waves, plate waves...

G01N 2291/106   one or more transducer arrays

G01N 2291/2634   cylindrical from outside

G01N 29/036   by measuring frequency or r...

G01N 29/2418   using optoacoustic interact...

G01N 29/346   with amplitude characterist...

G01N 29/348   with frequency characterist...

Apparatus and method for remote, noninvasive characterization of structures and fluids inside containers

First Claim

4 Assignments

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Abstract

Citations

20 Claims

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Apparatus and method for remote, noninvasive characterization of structures and fluids inside containers

First Claim

4 Assignments

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0 Petitions

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Accused Products

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Abstract

Citations

20 Claims

Specification

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Solutions

Use Cases

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