Method and apparatus for flow imaging using coded excitation
First Claim
Patent Images
1. An imaging system comprising:
- a transducer array having a multiplicity of transducer elements for transmitting wave energy centered at a fundamental frequency in response to electrical activation and for transducing returned wave energy into electrical signals;
a transmitter coupled to said transducer array and programmed to activate a plurality of said transducer elements to transmit focused wave energy encoded with a transmit code during first and second transmit events;
a receiver programmed to respectively form first and second receive signals from electrical signals produced by said plurality of transducer elements subsequent to said first and second transmit events respectively;
a wall filter programmed with first and second sets of filter coefficients to compress and bandpass first and second fundamental signal components of said first and second receive signals respectively and selectively pass frequencies corresponding to wave energy reflectors moving at a velocity above a predetermined threshold, the wall filter forming a flow signal derived at least in part from the compressed and bandpassed first and second fundamental signal components and the selectively passed frequencies; and
a subsystem for displaying an image having an image portion which is a function of at least said flow signal.
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Abstract
In performing flow imaging using coded excitation and wall filtering, a coded sequence of broadband pulses (centered at a fundamental frequency) is transmitted multiple times to a particular transmit focal position, each coded sequence constituting one firing. On receive, the receive signals acquired for each firing are supplied to a finite impulse response filter which both compresses and bandpass filters the receive pulses, e.g., to isolate a compressed pulse centered at the fundamental frequency. The compressed and isolated signals are then high pass filtered across firings using a wall filter. The wall-filtered signals are used to image blood flow and contrast agents.
104 Citations
62 Claims
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1. An imaging system comprising:
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a transducer array having a multiplicity of transducer elements for transmitting wave energy centered at a fundamental frequency in response to electrical activation and for transducing returned wave energy into electrical signals;
a transmitter coupled to said transducer array and programmed to activate a plurality of said transducer elements to transmit focused wave energy encoded with a transmit code during first and second transmit events;
a receiver programmed to respectively form first and second receive signals from electrical signals produced by said plurality of transducer elements subsequent to said first and second transmit events respectively;
a wall filter programmed with first and second sets of filter coefficients to compress and bandpass first and second fundamental signal components of said first and second receive signals respectively and selectively pass frequencies corresponding to wave energy reflectors moving at a velocity above a predetermined threshold, the wall filter forming a flow signal derived at least in part from the compressed and bandpassed first and second fundamental signal components and the selectively passed frequencies; and
a subsystem for displaying an image having an image portion which is a function of at least said flow signal. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
a processing subsystem for forming a flow image signal from said flow signal; and
a display subsystem programmed to display said image portion as a function of said flow image signal.
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11. The system as recited in claim 1, wherein said transducer elements comprise piezoelectric elements for transmitting ultrasound waves in response to electrical activation and for transducing returned ultrasound waves into electrical signals.
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12. An imaging system comprising:
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a transducer array having a multiplicity of transducer elements for transmitting wave energy centered at a fundamental frequency in response to electrical activation and for transducing returned wave energy into electrical signals;
a transmitter coupled to said transducer array and programmed to activate a plurality of said transducer elements to transmit focused wave energy encoded with a first Golay code of a Golay code pair during first and third transmit events and transmit focused wave energy encoded with a second Golay code of said Golay code pair during second and fourth transmit events;
a receiver programmed to respectively form first through fourth receive signals from electrical signals produced by said plurality of transducer elements subsequent to said first through fourth transmit events respectively;
a wall filter programmed with first through fourth sets of filter coefficients to decode and bandpass first through fourth fundamental signal components of said first through fourth receive signals respectively and selectively pass frequencies corresponding to wave energy reflectors moving at a velocity above a predetermined threshold, said wall filter forming a flow signal derived at least in part from said decoded and bandpassed first through fourth fundamental signal components and the selectively passed frequencies; and
a subsystem for displaying an image having an image portion which is a function of at least said flow signal. - View Dependent Claims (13, 14, 15, 16, 17, 18, 19)
a processing subsystem for forming a flow image signal from said flow signal; and
a display subsystem programmed to display said image portion as a function of said flow image signal.
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19. The system as recited in claim 12, wherein said transducer elements comprise piezoelectric elements for transmitting ultrasound waves in response to electrical activation and for transducing returned ultrasound waves into electrical signals.
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20. An imaging system comprising:
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a transducer array having a multiplicity of transducer elements for transmitting wave energy centered at a fundamental frequency in response to electrical activation and for transducing returned wave energy into electrical signals;
a display monitor for displaying an image having an image portion which is a function of a flow image signal; and
a computer programmed to perform the steps of;
(a) activating transducer elements of said array to transmit focused wave energy encoded with a transmit code during first and second transmit events;
(b) forming first and second receive signals from electrical signals produced by said transducer elements subsequent to said first and second transmit events respectively;
(c) compressing, bandpassing and wall filtering first and second fundamental signal components of said first and second receive signals respectively to form a flow signal;
(d) forming a flow image signal derived at least in part from said flow signal; and
(e) applying said flow image signal to said display monitor. - View Dependent Claims (21, 22)
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23. An imaging system comprising:
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a transducer array having a multiplicity of transducer elements for transmitting wave energy centered at a fundamental frequency in response to electrical activation and for transducing returned wave energy into electrical signals;
a display monitor for displaying an image having an image portion which is a function of a flow image signal; and
a computer programmed to perform the steps of;
(a) activating transducer elements of said array to transmit focused wave energy encoded with a first Golay code of a Golay code pair during first and third transmit events and to transmit focused wave energy encoded with a second Golay code of said Golay code pair during second and fourth transmit events;
(b) forming first through fourth receive signals from electrical signals produced by said transducer elements subsequent to said first through fourth transmit events respectively;
(c) decoding, bandpassing and wall filtering first through fourth fundamental signal components of said first through fourth receive signals respectively to form a flow signal;
(d) forming a flow image signal derived at least in part from said flow signal; and
(e) applying said flow image signal to said display monitor. - View Dependent Claims (24, 25)
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26. A method of operating an imaging system comprising a multiplicity of transducer elements for transmitting wave energy in response to electrical activation and transducing returned wave energy into electrical signals, and a display monitor for displaying an image having an image portion which is a function of a flow image signal, said method comprising the steps of:
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(a) activating transducer elements of said array to transmit focused wave energy encoded with a transmit code during first and second transmit events;
(b) forming first and second receive signals from electrical signals produced by said transducer elements subsequent to said first and second transmit events respectively;
(c) compressing, bandpassing and wall filtering first and second fundamental signal components of said first and second receive signals respectively to form a flow signal;
(d) forming a flow image signal derived at least in part from said flow signal; and
(e) applying said flow image signal to said display monitor. - View Dependent Claims (27, 28)
(f) activating transducer elements of said array to transmit uncoded focused wave energy during a third transmit event;
(g) forming a third receive signal from electrical signals produced by said transducer elements subsequent to said third transmit event;
(h) bandpassing a harmonic signal component of said third receive signal; and
(i) summing said harmonic signal component and said flow signal.
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28. The method as recited in claim 26, further comprising the steps of:
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(f) activating transducer elements of said array to transmit uncoded focused wave energy during third and fourth transmit events, said uncoded focused wave energy of said third transmit event being of opposite polarity to said uncoded focused wave energy of said fourth transmit event;
(g) forming third and fourth receive signals from electrical signals produced by said transducer elements subsequent to said third and fourth transmit events respectively;
(h) bandpassing respective harmonic signal components of said third and fourth receive signals while substantially canceling respective fundamental signal components of said third and fourth receive signals respectively to form a harmonic background signal; and
(i) summing said harmonic background signal with said flow signal.
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29. A method of operating an imaging system comprising a multiplicity of transducer elements for transmitting wave energy in response to electrical activation and transducing returned wave energy into electrical signals, and a display monitor for displaying an image having an image portion which is a function of a flow image signal, said method comprising the steps of:
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(a) activating transducer elements of said array to transmit focused wave energy encoded with a first Golay code of a Golay code pair during first and third transmit events and to transmit focused wave energy encoded with a second Golay code of said Golay code pair during second and fourth transmit events;
(b) forming first through fourth receive signals from electrical signals produced by said transducer elements subsequent to said first through fourth transmit events respectively;
(c) decoding, bandpassing and wall filtering first through fourth fundamental signal components of said first through fourth receive signals respectively to form a flow signal;
(d) forming a flow image signal derived at least in part from said flow signal; and
(e) applying said flow image signal to said display monitor. - View Dependent Claims (30, 31)
(f) activating transducer elements of said array to transmit focused wave energy which is uncoded during a fifth transmit event;
(g) forming a fifth receive signal from electrical signals produced by said transducer elements subsequent to said fifth transmit event;
(h) bandpassing a harmonic signal component of said fifth receive signal; and
(i) summing said harmonic signal component and said flow signal.
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31. The method as recited in claim 29, further comprising the steps of:
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(f) activating transducer elements of said array to transmit focused wave energy which is uncoded during fifth and sixth transmit events, said uncoded focused wave energy of said fifth transmit event being of opposite polarity to said uncoded focused wave energy of said sixth transmit event;
(g) forming fifth and sixth receive signals from electrical signals produced by said transducer elements subsequent to said fifth and sixth transmit events respectively;
(h) bandpassing respective harmonic signal components of said fifth and sixth receive signals while substantially canceling respective fundamental signal components of said fifth and sixth receive signals respectively to form a harmonic background signal; and
(i) summing said harmonic background signal with said flow signal.
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32. An ultrasound medical diagnostic system for imaging stationary and moving reflectors for an area of interest in a patient, comprising:
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a transmitter for transmitting a sequence of at least two B-mode pulses to a transmit focal position;
a receiver for receiving at least two B-mode echo signals associated with said sequence of at least two B-mode pulses, said B-mode echo signals containing a fundamental frequency component;
a filter for supplying a filtered signal containing flow image information for moving reflectors based on said at least two B-mode echo signals, said filtered signal containing B-mode information for stationary reflectors based on said at least two B-mode echo signals, said B-mode information for stationary reflectors including said fundamental frequency component; and
a display for displaying a B-mode flow image of moving reflectors and a B-mode image of stationary reflectors based on said filtered signal supplied by said filter. - View Dependent Claims (33, 34, 35, 36, 37, 38, 39, 40)
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41. An ultrasound medical diagnostic system for imaging stationary and moving reflectors for an area of interest in a patient, comprising:
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a transmitter for transmitting at least first and second pulses;
a receiver for receiving at least first and second echo signals associated with said first and second pulses, respectively;
a filter for providing a weighted sum of said first and second echo signals to pass moving reflectors and to pass, at an attenuated level, stationary reflectors including fundamental components of said first and second echo signals, said weighted sum including at least first and second weights; and
a display for imaging stationary components passed by said filter. - View Dependent Claims (42, 43, 44, 45, 46, 47, 48)
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49. A method for displaying B-flow ultrasound images, comprising;
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transmitting at least first and second broadband pulses to a common transmit focal position;
receiving at least first and second ultrasound reflections associated with said at least first and second broadband pulses;
forming a B-mode flow signal component based on said at least first and second ultrasound reflections;
forming a B-mode signal component based on said at least first and second ultrasound reflections; and
displaying a B-flow ultrasound image including a B-mode flow image component and a B-mode image component based on said B-mode flow signal component and said B-mode signal component. - View Dependent Claims (50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62)
forming an envelope of a signal including said B-mode flow signal component and said B-mode signal component.
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52. The method of claim 49, further comprising:
wall filtering across said first and second ultrasound reflections.
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53. The method of claim 52, further comprising:
passing fundamental frequency components of a signal including said B-mode flow signal component and said B-mode signal component.
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54. The method of claim 49, further comprising:
passing harmonic frequency components of a signal including said B-mode flow signal component and said B-mode signal component.
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55. The method of claim 49, further comprising:
passing subharmonic frequency components of a signal including said B-mode flow signal component and said B-mode signal component.
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56. The method of claim 49, further comprising:
summing ultrasound reflections to form said B-mode flow signal component and said B-mode signal component.
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57. The method of claim 49, wherein the transmitting step includes transmitting a sequence of identical broadband pulses, centered at a fundamental frequency, to a particular transmit focal position.
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58. The method of claim 49, further comprising:
bandpass filtering a fundamental frequency of said first and second ultrasound reflections substantially isolating a desired component of ultrasound reflections.
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59. The method of claim 49, wherein the transmitting step includes encoding said sequence of at least two B-mode pulses with transmit codes to form a packet of coded broadband pulses transmitted with a given pulse repetition interval to a transmit focal position, said packet including up to six pulses.
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60. The method of claim 49, wherein the transmitting step includes modulating each of said B-mode pulses with a predefined code sequence, each of said B-mode pulses having a predetermined transmit burst length.
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61. The method of claim 49, wherein the transmitting step includes modulating first and second B-mode pulses with first and second separate predefined code sequences, respectively.
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62. The method of claim 49, wherein the transmitting step includes modulating first through fourth B-mode pulses with first through fourth Golay code pair sequences, respectively.
Specification