Ultrasound imaging apparatus and method

Claims

What is claimed and desired to be secured by United States Letters Patent is:

1. An ultrasound imaging apparatus for reconstructing images of reflection from synthetically focused ultrasound energy, said apparatus comprising:

means for transmitting ultrasound energy signals;

means for receiving ultrasound energy signals that have been either reflected by or transmitted through an object being scanned by said apparatus;

means, electronically connected to said receiving means, for electronically storing said received ultrasound signals;

means for developing a particular type of waveform for each said stored signal such that when said stored signals are combined so as to reconstruct therefrom an image of reflection, regions of both constructive and destructive interference will occur, said regions improving the point response of said combined signals so as to enhance the resolution of said reconstructed image of reflection;

means, electronically connected to said storage means, for combining said stored signals so as to reconstruct therefrom said image of reflection corresponding to said scanned object; and

means for displaying said reconstructed image of reflection.

2. The apparatus of claim 1 wherein said means for developing said particular type of waveform comprises means, electronically connected to said transmitting means, for periodically generating said waveform and thereafter communicating said periodically generated waveforms to said transmitting means so that each ultrasound signal transmitted has the shape of said waveform.

3. The apparatus of claim 2 wherein said waveform generating means comprise:

means for electronically storing a plurality of digital signals, each said digital signal corresponding to a discrete value on said particular waveform;

means, electronically connected to said digital storage means, for retrieving and converting each said digital signal into a corresponding analog signal; and

means for shaping said analog signals so as to develop therefrom said particular waveform.

4. An apparatus for ultrasound imaging as defined in claim 3 further comprising means, electronically connected between said receiving means and said means for combining said received signals, for converting each said received signal to a series of corresponding digital signals.

5. The apparatus of claim 1 wherein said means for developing said particular type of waveform comprises means, electronically connected between said receiving means and said combining means, for transforming each said received ultrasound signal into one or more signals corresponding to said waveform.

6. The apparatus of claim 5 wherein said transforming means comprise:

means, electronically connected to said receiving means, for converting each said received signal into a series of digital signals;

means, electronically connected to said converting means, for storing said digital signals;

means, electronically connected to said digital storage means, for retrieving and multiplying each said digital signal by a predetermined value corresponding to a discrete value on said waveform; and

means for electronically summing each said retrieved and multiplied digital signal so as to develop therefrom a series of digital signals corresponding to said particular waveform.

7. The apparatus of claim 5 wherein said transforming means comprise:

means, electronically connected to said receiving means, for converting each said received signal into a series of digital signals;

means, electronically connected to said converting means, for storing said digital signals;

means, electronically connected to said converting means, for simultaneously (1) retrieving each said digital signal, (2) multiplying said retrieved digital signal by a predetermined value corresponding to a discrete value on said waveform and (3) converting said multiplied signals back to analog signals;

means for electronically summing each said analog signal so as to develop therefrom said particular waveform;

means, electronically connected to said summing means, for converting each said particular waveform to a series of corresponding digital signals.

8. The apparatus of claim 5 wherein said transforming means comprise:

means, electronically connected to said receiving means, for developing a series of time delays for each said received signal;

means, electronically connected to said delay means, for accessing portions of the received signal during each said time delay;

means, electronically connected to said accessing means, for multiplying each accessed portion of the received signal by a predetermined value corresponding to a discrete value on said particular waveform;

means for summing said multiplied portions of the received signal so as to develop therefrom said particular waveform; and

means, electronically connected to said summing means, for converting said waveform to a series of corresponding digital signals.

9. An ultrasound imaging apparatus as defined in claim 1 wherein said transmitting and receiving means comprise:

a ring of transducer arrays adapted to circumscribe the object being scanned, said ring of transducer arrays comprising a plurality of transmitter arrays and receiver arrays, said transmitter arrays being located at different points around said ring of arrays;

means, electronically connected to said transducer arrays, for sequentially triggering said transmitter arrays, thereby propagating semicircular wave fronts of ultrasound energy through said object at said different points around said ring of transducer arrays; and

means, connected to said ring of transducer arrays, for commutating said transmitter arrays so as to transmit ultrasound energy from each possible position around said object.

10. An ultrasound imaging apparatus as defined in claim 9 wherein said receiver arrays comprise one or more arrays having a first arcuate length and one or more arrays having a second arcuate length different from said first length so as to enable all sound holes between said receiver arrays to be covered by rotating said ring of arrays to at least a second position, said ultrasound imaging apparatus further comprising means for rotating said ring of arrays to at least a second position.

11. An ultrasound imaging apparatus as defined in claim 1 further comprising:

means, electronically connected to said detecting means, for determining the refractive index for said object and the attenuation coefficient for said object; and

means for correcting said reconstructed image of reflection so as to eliminate distortions arising from refraction and attenuation of ultrasound energy through said object, thereby enhancing the resolution for said reconstructed image.

12. An ultrasound imaging apparatus for reconstructing images of reflection from synthetically focused ultrasound energy, said apparatus comprising:

a plurality of transducer arrays for transmitting and receiving ultrasound energy signals;

means, electronically connected to said transducer arrays, for triggering a plurality of said arrays, thereby propagating a series of wave fronts of ultrasound energy through an object being scanned;

an electronic memory circuit for storing said received ultrasound signals;

means for electronically combining said stored signals so as to reconstruct therefrom an image of reflection corresponding to said scanned object;

means for developing a particular type of waveform for each said stored signal such that when said stored signals are combined so as to reconstruct therefrom an image of reflection, all signals corresponding to a given scattering point within said object will (1) constructively interfere within a first region to produce an extreme value for a point in said image of reflection corresponding to said scattering point, and (2) destructively interfere within a second region to produce a value near or at zero for closely situated adjacent points in said image of reflection that do not correspond to said scattering point, thereby enhancing the resolution of said reconstructed image of reflection; and

a display screen electronically connected to said combining means for displaying said reconstructed image of reflection.

13. The ultrasound imaging apparatus of claim 12 wherein said transducer arrays comprise:

a plurality of transmitter and receiver arrays configurated as a ring which circumscribes said object, said transmitter arrays being spaced around said ring at a plurality of locations;

means for sequentially triggering said transmitter arrays; and

means, connected to said ring of transducer arrays, for commutating said transmitter arrays so as to transmit said ultrasound signals from each possible position around said object.

14. The apparatus of claim 13 wherein said receiver arrays comprise one or more arrays having a first length and one or more arrays having a second length different from said first length so as to enable all sound holes between said receiver arrays to be covered by rotating said ring of arrays to at least a second position, said ultrasound imaging apparatus further comprising means for rotating said ring of arrays to at least a second position.

15. The apparatus of claim 14 further comprising means for vertically displacing said ring of transducer arrays.

16. An ultrasound imaging apparatus as defined in claim 12 further comprising:

means for detecting data from which the refractive index and attenuation coefficient of said object may be determined;

a computer connected to said data detection means, said computer being programmed to (1) determine the refractive index and attenuation coefficient for said object from said data, and (2) correct said reconstructed image of reflection in accordance with the determined refractice index and attenuation coefficient so as to eliminate distortions arising from refraction and attenuation of said transmitted ultrasound signals through said object.

17. The ultrasound imaging apparatus of claim 12 wherein said means for developing said particular type of waveform comprises a waveform generator circuit connected to said transducer arrays for transmitting said ultrasound signals.

18. An ultrasound imaging apparatus as defined in claim 17 wherein said waveform generator circuit comprises:

a memory circuit for storing a plurality of digital signals, each said digital signal corresponding to a discrete value on said waveform;

a digital-to-analog (D/A) converter circuit connected to said memory circuit, said D/A converter circuit transforming said digital signals into analog pulses;

a sample and hold circuit connected to said D/A circuit, said sample and hold circuit holding each analog signal for a selected increment of time;

a low pass filter circuit connected to said sample and hold circuit for filtering out distortions in said waveform; and

a counter circuit for generating pulses, said counter circuit being connected to said memory and said sample and hold circuits so as to synchronize said circuits.

19. The apparatus of claim 18 further comprising an analog to digital converter circuit interposed between said transducers for receiving ultrasound signals and said memory circuit for storing said received ultrasound signals.

20. The apparatus of claim 12 wherein said means for developing said particular type of waveform comprises a waveshaping circuit interposed between said transducers for receiving ultrasound signals and said combining means.

21. An ultrasound imaging apparatus as defined in claim 20 wherein said waveshaping circuit comprises:

an analog-to-digital (A/D) converter circuit for transforming each received ultrasound signal to a plurality of digital signals;

a digital shift register connected to said A/D converter circuit for storing said digital signals;

a plurality of multiplier circuits connected to said register;

a plurality of latching circuits for gating said digital signals through said multiplier circuits, each latching circuit being connected to one of said multiplier circuits;

a multiplexer circuit connected to said latching circuits, said multiplexer selectively accessing each said latching circuit so as to gate said digital signals through said multiplier circuits; and

a digital adder circuit connected to said multiplier circuits for summing said digital signals after they have been multiplied, thereby developing a series of digital signals for said received ultrasound signal corresponding to said particular waveform.

22. An ultrasound imaging apparatus as defined in claim 20 wherein said waveshaping circuit comprises:

an analog-to-digital (A/D) converter circuit for transforming each received ultrasound signal to a plurality of digital signals;

a digital shift register connected to said A/D converter circuit for storing said digital signals;

a plurality of multiplying digital-to-analog (D/A) converting circuits connected to said register;

a plurality of latching circuits for gating said digital signals through said multiplying D/A circuits, each latching circuit being connected to one of said multiplying D/A circuits;

a multiplexer circuit connected to said latching circuits, said multiplexer selectively accessing each said latching circuit so as to gate said digital signals through said multiplying D/A circuits;

an analog adder circuit connected to said multiplying A/D circuits for summing said signals gated through said multiplying D/A circuits; and

an analog-to-digital converter circuit connected to said analog adder circuit for transforming the summation of signals by said analog adder circuit into a series of digital signals corresponding to said particular waveform.

23. An ultrasound imaging apparatus as defined in claim 20 wherein said waveshaping circuit comprises:

a tapped delay line for receiving said ultrasound signals from said receiver transducers;

a plurality of variable resistors connected to said tapped delay line;

an analog adder circuit connected to said resistors for summing each signal received by each resistor from said tapped delay line, thereby developing said particular waveform; and

an analog-to-digital converter connected to said analog adder for transforming said particular waveform into a series of digital signals.

24. An ultrasound imaging apparatus as defined in claim 20 wherein said waveshaping circuit comprises:

a tapped delay line for receiving said ultrasound signals from said receiver transducers;

a plurality of multiplying circuits connected to said tapped delay line;

a plurality of digital-to-analog (D/A) converter circuits, each D/A circuit being connected to one of said multiplying circuits;

a plurality of latching circuits, each latching circuit being connected to one of said D/A circuits;

a multiplexer circuit connected to said latching circuits, said multiplexer selectively accessing each said latching circuit so as to gate a portion of said received ultrasound signal through said multiplying circuit;

an analog adder circuit connected to said multiplying circuits for summing the signals gated through said multiplying circuits, thereby developing said particular waveform; and

an analog-to-digital converter connected to said analog adder for transforming said particular waveform into a series of digital signals.

25. A method of reconstructing images of reflection from synthetically focused ultrasound energy comprising the steps of:

transmitting ultrasound energy signals;

receiving ultrasound energy signals that have been either reflected by or transmitted through an object being scanned;

electronically storing said received ultrasound signals;

developing a particular type of waveform for each said stored signal such that when said stored signals are combined so as to reconstruct therefrom an image of reflection of said object, regions of both constructive and destructive interference will occur, said regions improving the point response of said combined signals so as to enhance the resolution of said reconstructed image of reflection;

electronically combining said stored signals so as to reconstruct therefrom said image of reflection corresponding to said scanned object; and

visually displaying said reconstructed image of reflection.

26. The method of claim 25 wherein said step of developing said particular type of waveform comprises the steps of:

periodically generating signals having the shape of said waveform; and

transmitting said periodically generated waveforms so that each transmitted ultrasound signal has the shape of said waveform.

27. A method as defined in claim 26 wherein said step of periodically generating said waveform comprises the steps of:

electronically storing a plurality of digital signals, each said digital signal corresponding to a discrete value on said particular waveform;

retrieving from storage each said digital signal;

converting each said retrieved digital signal into a corresponding analog signal; and

shaping said analog signals so as to develop therefrom said particular waveform.

28. A method as defined in claim 27 further comprising the step of converting each said received ultrasound signal to a series of corresponding digital signals.

29. A method as defined in claim 25 wherein said step of developing said particular type of waveform comprises the step of transforming each said received ultrasound signal into one or more signals corresponding to said particular type of waveform.

30. The method of claim 29 wherein said transforming step comprises the steps of:

converting each said received ultrasound signal into a series of digital signals;

storing said digital signals;

retrieving each said stored digital signal;

multiplying each said digital signal by a predetermined value corresponding to a discrete value on said waveform; and

electronically summing each said retrieved and multiplied digital signal so as to develop therefrom a series of digital signals corresponding to said particular waveform.

31. The method of claim 29 wherein said transforming step comprises the steps of:

converting each said received signal into a series of digital signals;

storing said digital signals;

retrieving each said stored digital signal;

multiplying said retrieved digital signals by a predetermined value corresponding to a discrete value on said waveform;

converting said multiplied digital signals back to analog signals;

electronically summing said analog signals so as to develop therefrom said particular waveform; and

converting each said particular waveform to a series of corresponding digital signals.

32. The method of claim 29 wherein said transforming step comprises the steps of:

imposing a series of time delays on each said received ultrasound signal;

selectively accessing portions of the received ultrasound signal during each said time delay;

multiplying each accessed portion of the received ultrasound signal by a predetermined value corresponding to a discrete value on said particular waveform;

electronically summing said multiplied portions of the received ultrasound signal so as to develop therefrom said particular waveform; and

converting said waveform to a series of corresponding digital signals.

33. A method as defined in claim 25 further comprising the steps of:

detecting the transmission data from which the refractive index and attenuation coefficient for said object may be determined;

determining the refractive index and the attenuation coefficient for said object; and

electronically adjusting said reconstructed image of reflection in accordance with said determined refractive index and attenuation index so as to eliminate distortions arising from refraction and attenuation of ultrasound energy through said object, thereby enhancing the resolution for said reconstructed image.

34. The method defined in claim 25 wherein said transmitting step comprises the steps of:

encircling said object with a plurality of transmitter and receiver transducer arrays;

propagating semicircular wavefronts of ultrasound energy at different points around said object by sequentially triggering a plurality of said transmitter arrays; and

commutating said transmitter arrays to permit transmission of ultrasound energy waves at each point around said object.

35. In an improved ultrasound imaging apparatus for reconstructing images of reflection from synthetically focused ultrasound energy, the improvement comprising:

a plurality of transmitter and receiver transducer arrays for transmitting and receiving ultrasound energy signals, said receiver arrays comprising one or more receiver arrays having a first length and one or more receiver arrays having a second length different from said first length so as to enable all sound holes caused by the transmitter arrays located between said receiver arrays to be covered by moving said receiver arrays to at least a second position, said ultrasound imaging apparatus further comprising means for moving said receiver arrays to at least said second position.

36. An improved ultrasound imaging apparatus as defined in claim 35 wherein said transmitter and receiver arrays are connected so as to encircle the object to be scanned, and wherein said receiver arrays comprise one or more arrays having a first arcuate length and one or more arrays having a second arcuate length different from said first length so as to enable all sound holes between said receiver arrays to be covered by rotating said ring of arrays to at least a second position, said ultrasound imaging apparatus further comprising means for rotating said ring of arrays to at least a second position, means for sequentially triggering said transmitter arrays so as to propagate a series of ultrasound signals through said object, and means, connected to said transducer arrays, for commutating said transmitter arrays so as to transmit said ultrasound signals from each possible position around said object.

37. An improved ultrasound imaging apparatus as defined in claim 36 further comprising means for vertically displacing said transducer arrays.

38. An ultrasound imaging apparatus for reconstructing images of reflection from synthetically focused ultrasound energy, said apparatus comprising:

means for transmitting ultrasound energy signals;

means for receiving ultrasound energy signals that have been either reflected by or transmitted through an object being scanned by said apparatus;

means, electronically connected to said receiving means, for electronically storing said received ultrasound signals;

means, electronically connected to said receiving means, for detecting transmission data from which the refractive index and attenuation coefficient for said object may be determined;

means, electronically connected to said storage means, for combining said stored signals so as to reconstruct therefrom an image of reflection corresponding to said scanned object;

means, electronically connected to said detecting means, for determining the refractive index and attenuation coefficient for each point in said object;

means for correcting each corresponding point of said reconstructed image of reflection in accordance with the determined point-dependant refractive index and attenuation coefficient for said object so as to eliminate distortions arising from refraction and attenuation of ultrasound energy through said object, thereby enhancing the resolution for said reconstructed image of reflection; and

means for visually displaying said reconstructed image of reflection.

39. An ultrasound imaging apparatus as defined in claim 38 further comprising means for developing a particular type of waveform for each said stored signal such that when said stored signals are combined so as to reconstruct therefrom an image of reflection, regions of both constructive and destructive interference will occur, said regions improving the point response of said combined signals so as to enhance the resolution of said reconstructed image of reflection.

40. An improved method of reconstructing images of reflection from synthetically focused ultrasound energy comprising the steps of:

transmitting ultrasound energy signals;

receiving ultrasound energy signals that have been either reflected by or transmitted through an object being scanned;

electronically storing said receiver ultrasound signals;

detecting transmission data from which the refractive index and attenuation coefficient for said object may be determined;

determining the refractive index and attenuation coefficient for each point in said object;

electronically combing said stored signals so as to reconstruct therefrom an image of reflection corresponding to said scanned object;

correcting each corresponding point of said reconstructed image of reflection in accordance with the determined point-dependant refractive index and attenuation coefficient for said object so as to eliminate distortions in said reconstructed image arising from refraction and attenuation of ultrasound energy through said object, thereby enhancing the resolution for said reconstructed image; and visually displaying said corrected reconstructed image of reflection.

41. A method as defined in claim 40 further comprising the step of developing a particular type of waveform for each said stored signal such that when said stored signals are combined so as to reconstruct therefrom an image of reflection, regions of both constructive and destructive interference will occur, said regions improving the point response of said combined signals so as to enhance the resolution of said reconstructed image of reflection.

BACKGROUND

1. Field of the Invention

The present invention relates to an apparatus and method for ultrasound imaging of biological tissue according to the impulse-echo technique, and more particularly the present invention relates to a novel and unobvious apparatus and method for reconstructing images of reflection in biological tissue or other media using synthetically focused ultrasound energy.

2. The Prior Art

It has long been known that ultrasonic or acoustic waves in the frequency range of 15,000 cycles per second and higher can be propagated through many solids and liquids. Ultrasound waves are usually considered to be those in the frequency range from approximately 50,000 cycles per second to 10,000,000 cycles per second and higher. Ultrasound energy waves may be partially reflected and partially transmitted at any interface between two media of different density. The product of material density and sonic wave velocity is known as the acoustic impedance, and the amount of reflection which occurs at the interface between two media is dependent upon the amount of change in the acoustic impedance between one medium as opposed to the other medium.

These principles have long been used for imaging reflecting bodies within an ultrasound propagation medium. For example, the organs of a human body as well as bones and sinew act as reflecting bodies within the soft tissue of the body. Likewise, any foreign inclusion will act as a reflecting body. Thus, noninvasive internal examination and medical diagnosis of the human body by ultrasound imaging has long been known in the art. For example, piston type transducers have been used for over 30 years to image some parts of the body.

The inherent advantages of noninvasive medical diagnosis by ultrasound imaging are readily apparent. Unlike exploratory surgery or x-rays, ultrasound imaging permits internal examination of an organ without damaging the surrounding tissue and organs of the body and with much less trauma to the patient.

However, despite the many advantages which may be derived from noninvasive examination by ultrasound imaging, in the past ultrasound imaging has been somewhat limited in its application. One of the primary problems encountered in this regard is the difficulty in providing reflection images of high quality resolution. These images may often be blurred or distorted to some degree, making accurate diagnosis difficult, particularly with respect to very small objects in the body.

Thus, recently much attention has been directed to improving the quality of resolution of ultrasound images. For example, linear phased (or so-called "beam steering") transducer arrays have demonstrated improved depth of focus and time resolution. See, for example, Somer, J. C., W . A. Oosterbaan and H. J. Freund: Ultrasonic Tomographic Imaging of the Brain with an Electronic Sector Scanning System, Proceedings of the 1973 IEEE Ultrasonic Symposium, Nov. 5-7, 1973; and Thurstone, F. L., and O. T. Van Ramm: A New Ultrasound Imaging System Employing Two-Dimensional Electronic Beam Steering, Heart Bulletin, Volume 4, p. 51 (1973). It has also been demonstrated that non-straight line transducer array configurations may be employed to enhance resolution quality in ultrasound images by increasing the aperture for transmitting and receiving ultrasound energy. See, for example, Maginness, M. G., J. D. Plummer and J. D. Meindl: A Cardiac Dynamics Visualization System, Proceedings of the 1973 IEEE Ultrasonic Symposium, Nov. 5-7, 1973; and Green, P. S., L. F. Schaefer, E. D. Jones and J. R. Suarez: A New High-Performance Ultrasonic Camera System, Fifth International Symposium on Acoustical Holography Imaging, July 18-20, 1973. These improvements in the resolution quality of ultrasound images increase the ability of a system to detect small, focal lesions such as cancer, abscesses, or infarcts of less than one centimeter in diameter.

However, often more fundamental than the focal lesion itself, regardless of its size, is the state of the tissue surrounding the lesion. The pattern of the adjacent tissue plays a crucial role in the identification of specific diseases by supplying the physician with information concerning the local context of the bodily processes which are resulting in the lesion.

Compared to tumor nodules and the like, the structures of the surrounding normal tissue are relatively delicate. The tissue structure is essentially determined by the dimensions of the fibrous and vascular framework of an organ and is responsive to the pathologic processes.

It would therefore be highly desirable to be able to image such delicate patterns as those associated with, for example, the interstitial spaces of parenchymal organs, or the tertiary branching of major arteries of the heart, brain, kidneys and lungs, or the biliary ducts of the liver and the ductular system of the breast and pancreas. However, ultrasound imaging of these delicate tissues requires a resolution capability not presently possible with commercially known ultrasound scanning systems.

Accordingly, what is needed is an improved ultrasound imaging apparatus and method capable of high quality resolution for images of reflection for highly delicate tissue and the like. Such a device would provide a significant advancement in the state of the art by providing noninvasive diagnostic techniques through ultrasound imaging which could be used for pathogenesis, prevention and early detection of disease rather than being limited to the diagnosis of gross advanced lesions. Such an invention is disclosed and claimed herein.

BRIEF DESCRIPTION AND OBJECTS OF THE INVENTION

The ultrasound imaging apparatus and method of the present invention provides high quality resolution real time images of reflection by synthetically focusing ultrasound energy. Novel structure and method are provided for sending and receiving ultrasound energy waves and for reconstructing the images of reflection from an arbitrary waveform selected to optimize the system's resolution capability. Structure and method are also provided for digitally sampling the ultrasound energy which is received and for thereafter further improving the resolution of the reconstructed image of reflection by computer aided correction for refraction and attenuation of the ultrasound energy. High speed computer aided analysis also provides quantitative determinations for various acoustic parameters associated with the scanned object.

It is therefore a primary object of the present invention to provide improved apparatus and method for ultrasound imaging.

Another primary object of the present invention is to provide an improved ultrasound imaging apparatus and method for reconstructing images of reflection by synthetically focusing ultrasound energy.

Another object of the present invention is to provide an ultrasound imaging apparatus and method for reconstructing an image of reflection from an arbitrary waveform selected so as to maximize the system's resolution capability.

Yet another object of the present invention is to improve the resolution of an image of reflection by correcting the image for distortions arising from attenuation and refraction of the ultrasound energy as it passes through the object being scanned.

Yet another object of the present invention is to provide an ultrasound imaging apparatus for improved transmission and reception of ultrasound energy waves.

Yet another object of the present invention is to provide an ultrasound imaging apparatus and method capable of providing spatial resolutions of approximately one-half wavelength in static media such as body tissues.

These and other objects and features of the present invention will become more fully apparent from the following description and appended claims taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side elevational view shown partially in cross section and schematically illustrates the ultrasound scanning apparatus of the present invention.

FIG. 2 is a perspective view illustrating one type of configuration which may be used for the transducer arrays employed in the ultrasound scanning apparatus of the present invention.

FIG. 3 is a plan view of the transducer arrays shown in FIG. 2.

FIG. 4 is a plan view illustrating a second type of configuration for the transducer arrays of the ultrasound scanning apparatus of FIG. 1.

FIG. 5 is a schematic diagram illustrating one embodiment of the electronic circuitry used for transmitting and receiving ultrasound energy signals and for thereafter processing the received signals to permit reconstruction of an image of reflection for an object being scanned.

FIG. 6 is a graph illustrating two alternative types of waveforms that may be employed by the ultrasound scanning apparatus of the present invention for purposes of reconstructing an image of reflection.

FIG. 7 is a graph illustrating the Fourier transforms for the waveforms of FIG. 6. FIG. 8 is a functional block diagram illustrating the components of the waveform generator of the circuit in FIG. 5.

FIGS. 9, 10 and 11 are graphs illustrating the method employed by the waveform generator illustrated in FIG. 8.

FIG. 12 is a schematic diagram illustrating a second embodiment of the electronic circuitry used for transmitting and receiving ultrasound energy signals and for thereafter processing the received signals to permit reconstruction of an image of reflection of a scanned object.

FIG. 13 is a schematic diagram illustrating one type of analog waveshaping circuit which may be employed with the electronic circuitry shown in FIG. 12.

FIG. 14 is a functional block diagram illustrating a second type of analog waveshaping circuit which may be employed with the electronic circuitry of FIG. 12.

FIG. 15 is a schematic diagram of a third embodiment of the electronic circuitry for transmitting and receiving ultrasound energy signals and for thereafter processing the received signals to enable reconstruction of an image of reflection.

FIG. 16 is a functional block diagram illustrating one type of digital waveshaping circuitry used in conjunction with the circuit of FIG. 15.

FIG. 17 is a functional block diagram illustrating a second type of digital waveshaping circuit which may be used with the circuitry of FIG. 15.