Ultrasonic detection method and apparatus and ultrasonic diagnostic apparatus
First Claim
1. An ultrasonic detection method comprising the steps of:
- (a) introducing a light beam into an ultrasonic-optical transducer including a first optical layer and a second optical layer which define a gap having a predetermined length therebetween from a side of said first optical layer such that the light beam is totally reflected at an interface between said first optical layer and said gap to obtain the reflected light beam, said introduced light beam having a wavelength larger than the predetermined length of said gap;
(b) applying ultrasonic waves onto said ultrasonic-optical transducer from a side of said second optical layer such that said second optical layer resiliently deforms to thereby vary intensity of light leaking from said first optical layer via said gap into said second optical layer;
(c) two-dimensionally detecting distribution of intensity of the reflected light beam which varies depending on variation of the intensity of the light leaking from said first optical layer via said gap into said second optical layer; and
(d) two-dimensionally obtaining distribution of sound pressure of the ultrasonic waves applied on said second optical layer on the basis of the distribution of intensity of the reflected light beam detected at step (c).
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Abstract
An ultrasonic detection method and apparatus are suited for real-time collection of three-dimensional ultrasonic data. The ultrasonic detection apparatus has an ultrasonic-optical transducer including a first optical layer and a second optical layer which define a gap having a predetermined length therebetween, the second optical layer being resiliently deformed such that the length of the gap varies when ultrasonic waves are applied from a second optical layer side; a light source for introducing a light beam having a wavelength longer than the gap length from a first optical layer side such that the light beam is totally reflected at an interface between the first optical layer and the gap; a detecting unit for two-dimensionally detecting distribution of intensity of the reflected light beam which varies depending on variation of intensity of light leaking from the first optical layer via the gap into the second optical layer; and a signal processing unit for two-dimensionally obtaining distribution of sound pressure of the ultrasonic waves applied on the second optical layer on the basis of the distribution of intensity of the reflected light beam detected by the detecting unit.
10 Citations
21 Claims
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1. An ultrasonic detection method comprising the steps of:
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(a) introducing a light beam into an ultrasonic-optical transducer including a first optical layer and a second optical layer which define a gap having a predetermined length therebetween from a side of said first optical layer such that the light beam is totally reflected at an interface between said first optical layer and said gap to obtain the reflected light beam, said introduced light beam having a wavelength larger than the predetermined length of said gap;
(b) applying ultrasonic waves onto said ultrasonic-optical transducer from a side of said second optical layer such that said second optical layer resiliently deforms to thereby vary intensity of light leaking from said first optical layer via said gap into said second optical layer;
(c) two-dimensionally detecting distribution of intensity of the reflected light beam which varies depending on variation of the intensity of the light leaking from said first optical layer via said gap into said second optical layer; and
(d) two-dimensionally obtaining distribution of sound pressure of the ultrasonic waves applied on said second optical layer on the basis of the distribution of intensity of the reflected light beam detected at step (c). - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9)
step (c) includes two-dimensionally detecting distribution of intensity of the reflected light beam by using an area sensor.
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3. An ultrasonic detection method according to claim 2, wherein:
step (d) includes reading, in parallel, the distribution of intensity of the reflected light beam detected by said area sensor.
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4. An ultrasonic detection method according to claim 2, wherein:
step (d) includes reading, in time-sharing, the distribution of intensity of the reflected light beam detected by said area sensor.
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5. An ultrasonic detection method according to claim 1, wherein:
step (d) includes subtracting the intensity of the reflected light beam detected at step (c) from the intensity of the light beam introduced into said ultrasonic-optical transducer, to thereby obtain the distribution of sound pressure of ultrasonic waves applied on said second optical layer.
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6. An ultrasonic detection method according to claim 1, further comprising a step of:
adjusting unevenness of the interface between-said gap and said second optical layer.
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7. An ultrasonic detection method according to claim 1, further comprising a step of:
(e) varying the length of said gap as a function of the intensity of sound pressure of the ultrasonic waves.
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8. An ultrasonic detection method according to claim 7, wherein:
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said ultrasonic waves include ultrasonic echoes reflected by an echo source within an object; and
step (e) includes reducing the length of said gap as a function of a depth of the echo source within the object.
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9. An ultrasonic detection method according to claim 1, wherein:
step (a) includes introducing a light beam having form of a P-polarized wave into said ultrasonic-optical transducer.
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10. An ultrasonic detection method comprising the steps of:
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(a) introducing a plurality of light beams into a plurality of ultrasonic-optical transducers each including a first optical layer and a second optical layer which define a gap having a predetermined length therebetween from a side of said first optical layer such that the plurality of light beams are totally reflected at respective interfaces between said first optical layer and said gap to obtain a plurality of reflected light beams, each of said introduced plurality of light beams having a wavelength larger than said predetermined length of said gap;
(b) applying ultrasonic waves onto said plurality of ultrasonic-optical transducers from a side of said second optical layer such that said second optical layer of each ultrasonic-optical transducer resiliently deforms to thereby vary intensity of light leaking from said first optical layer via said gap into said second optical layer;
(c) individually detecting intensity of the plurality of reflected light beams each varies depending on variation of the intensity of the light leaking from said first optical layer via said gap into said second optical layer; and
(d) two-dimensionally obtaining distribution of sound pressure of the ultrasonic waves applied on said second optical layer on the basis of the distribution of intensity of the reflected light beams detected at step (c).
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11. An ultrasonic detection apparatus comprising:
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an ultrasonic-optical transducer including a first optical layer and a second optical layer which define a gap having a predetermined length therebetween, said second optical layer being resiliently deformed such that the length of said gap varies when ultrasonic waves are applied from a side of said second optical layer;
means for introducing a light beam having a wavelength larger than the predetermined length of said gap into said ultrasonic-optical transducer from a side of said first optical layer such that the light beam is totally reflected at an interface between said first optical layer and said gap;
detecting means for two-dimensionally detecting distribution of intensity of the reflected light beam which varies depending on variation of intensity of light leaking from said first optical layer via said gap into said second optical layer; and
signal processing means for two-dimensionally obtaining distribution of sound pressure of the ultrasonic waves applied on said second optical layer on the basis of the distribution of intensity of the reflected light beam detected by said detecting means. - View Dependent Claims (12, 13, 14, 15, 16, 17, 18, 19)
said detecting means includes an area sensor for two-dimensionally detecting the distribution of intensity of the reflected light beam.
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13. An ultrasonic detection apparatus according to claim 12, wherein:
said signal processing means reads, in parallel, the distribution of intensity of the reflected light beam detected by said area sensor.
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14. An ultrasonic detection apparatus according to claim 12, wherein:
said signal processing means reads, in time-sharing, the distribution of intensity of the reflected light beam detected by said area sensor.
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15. An ultrasonic detection apparatus according to claim 11, wherein:
said signal processing means subtracts the intensity of the reflected light beam detected by said detecting means from the intensity of the light beam introduced into said ultrasonic-optical transducer, to thereby determine the distribution of sound pressure of ultrasonic waves applied on said second optical layer.
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16. An ultrasonic detection apparatus according to claim 11, further comprising:
means for adjusting unevenness of the interface between said gap and said second optical layer.
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17. An ultrasonic detection apparatus according to claim 11, further comprising:
adjustment means for varying the length of said gap as a function of the intensity of sound pressure of the ultrasonic waves.
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18. An ultrasonic detection apparatus according to claim 17, wherein:
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said ultrasonic waves include ultrasonic echoes reflected by an echo source within an object; and
said adjustment means varies the length of said gap as a function of a depth of the echo source within the object.
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19. An ultrasonic detection apparatus according to claim 11, wherein:
said light beam introduced into said ultrasonic-optical transducer includes a P-polarized wave.
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20. An ultrasonic detection apparatus comprising:
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a plurality of ultrasonic-optical transducers each including a first optical layer and a second optical layer which define a gap having a predetermined length therebetween, said second optical layer of each ultrasonic-optical transducer being resiliently deformed such that the length of said gap varies when ultrasonic waves are applied from a side of said second optical layer;
a plurality of means each for introducing a light beam having a wavelength larger than the predetermined length of said gap into respective one of said plurality of ultrasonic-optical transducers from a side of said first optical layer such that each light beam is totally reflected at an interface between said first optical layer and said gap;
a plurality of detecting means for detecting distribution of intensity of the reflected light beams each varies depending on variation of intensity of light leaking from said first optical layer via said gap into said second optical layer; and
signal processing means for two-dimensionally obtaining distribution of sound pressure of the ultrasonic waves applied on said second optical layer on the basis of the distribution of intensity of the reflected light beams detected by said plurality of detecting means.
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21. An ultrasonic diagnostic apparatus comprising:
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a transmission unit for transmitting ultrasonic waves to an object;
a detection unit having;
an ultrasonic-optical transducer including a first optical layer and a second optical layer which define a gap having a predetermined length therebetween, said second optical layer being resiliently deformed such that the length of said gap varies when ultrasonic waves are applied from a side of said second optical layer;
means for introducing a light beam having a wavelength larger than the predetermined length of said gap into said ultrasonic-optical transducer from a side of said first optical layer such that the light beam is totally reflected at an interface between said first optical layer and said gap; and
detecting means for two-dimensionally detecting distribution of intensity of the reflected light beam which varies depending on variation of intensity of light leaking from said first optical layer via said gap into said second optical layer;
a signal processing unit for two-dimensionally obtaining distribution of sound pressure of the ultrasonic waves applied on said second optical layer on the basis of the distribution of intensity of the reflected light beam detected by said detecting means; and
a display unit for displaying an image on the basis of a detection signal output from said signal processing unit.
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Specification