Claims
- 1. A sparse array structure for transmitting and receiving energy having a center axis, comprising:
a transmit array comprising transmit elements, a centerline of the transmit array being substantially coaxial with the center axis, an area containing the transmit array defined by a space within an annular space between radius R(T inner) and radius R(T outer) taken with respect to the center axis; and a receive array comprising receive elements substantially coaxial with the center axis comprising, the area of the receive array defined by the space within the annular space between radius R(R inner) and radius R(R outer) taken with respect to the center axis where R(T outer) is greater than R(T inner), R(R inner) is greater than R(T outer) and R(R outer is greater than R(R inner) such that the receive array is within an annular region outside of the area containing the transmit array.
- 2. The sparse array structure of claim 1 wherein R(T inner) is zero such that the area containing the transmit array is defined by a circular space within radius R(T outer).
- 3. The sparse array structure of claim 1 wherein:
the transmit elements have a typical interelement spacing in an azimuth direction and a typical interelement spacing in an elevation direction to form a spacing grid; and the transmit array has at least one gap in the spacing grid where there is a gap between adjacent connected transmit elements that is at least approximately twice the interelement spacing in the azimuth direction and there is a gap between adjacent connected transmit elements that is at least approximately twice the interelement spacing in the elevation direction.
- 4. The sparse array structure of claim 1 wherein the transmit array is surrounded by a dead band region lacking either connected transmit elements or connected receive elements, the dead band region contained in an annular area around center axis defined by R(DB inner) and R(DB outer) where R(DB inner is not less than R(T outer) and R(DB outer) is not greater than R(R inner).
- 5. The sparse array structure of claim 1 wherein the transmit array is surrounded by a TR region comprised of elements that are used as transmit elements and as receive elements, the TR region contained in the annular area around center axis defined by R(TR inner) and R(TR outer) where R(TR inner) is not less than R(T outer) and R(TR outer) is not greater than R(R inner).
- 6. The sparse array of claim 1 wherein for a given mode of operation, none of the active receive elements are used as transmit elements and none of the active transmit elements are used as receive elements.
- 7. The sparse array of claim 1 wherein the transmit elements are designed to have a resonant frequency of f and the receive elements are designed to have a resonant frequency of other than f.
- 8. The sparse array of claim 7 wherein the transmit elements are designed to have the resonant frequency of f and the receive elements are designed to have a resonant frequency of approximately a harmonic of f.
- 9. The sparse array of claim 7 wherein the transmit elements are designed to have the resonant frequency of f and the receive elements are designed to have a resonant frequency of approximately a sub-harmonic of f.
- 10. The sparse array of claim 7 wherein the transmit elements are designed to have the resonant frequency of f and the receive elements are designed to have a resonant frequency of approximately a fractional harmonic of f.
- 11. The sparse array of claim I wherein:
the transmit and receive elements are located in a scanning head; the scanning head is connected by a cable to a scanning device; the scanning head contains a set of pre-amps for the receive elements, the pre-amps operating to produce a first voltage; the scanning head contains a set of transmitters for the transmit elements operating at a second voltage; and the second voltage is at least an order of magnitude greater than the first voltage.
- 12. A sparse array structure for transmitting and receiving energy having a center axis, comprising:
a transmit array comprising transmit elements, the center of the transmit array being substantially coaxial with the center axis, an area of the transmit array defined by a space within a polygon defined by a set of n vertices located at approximately distance V(To) from the center axis; and a receive array comprising receive elements, a region containing the receive array defined by an annular polygonal space defined by an inner polygon and an outer polygon wherein:
the inner polygon is defined by a set of n vertices located at approximately distance V(Ri) from the center axis; the outer polygon is defined by a set of nnn vertices located at approximately distance V(Ro) from the center axis; V(To) is less than V(Ri); and V(Ri) is less than V(Ro).
- 13. The sparse array structure of claim 12 wherein:
the transmit elements have a typical interelement spacing in an azimuth direction and a typical interelement spacing in an elevation direction to form a spacing grid; and the transmit array has at least one gap in the spacing grid where there is a gap between adjacent connected transmit elements that is at least approximately twice the typical interelement spacing in the azimuth direction and there is a gap between adjacent connected transmit elements that is at least approximately twice the typical interelement spacing in the elevation direction.
- 14. The sparse array structure of claim 12 wherein:
the transmit array is surrounded by a dead band region lacking either connected transmit elements or connected receive elements, the dead band region contained in an annular polygonal space defined by an inner polygon and an outer polygon wherein:
the inner polygon is defined by a set of n vertices located at approximately distance V(To) from the center axis; and the outer polygon is defined by a set of n vertices located at approximately distance V(Ri).
- 15. The sparse array structure of claim 12 wherein:
the transmit array is surrounded by TR region comprised of elements that are used as transmit elements and as receive elements, the TR region contained in the annular polygonal space defined by an inner polygon and an outer polygon wherein:
the inner polygon is defined by a set of m vertices located at approximately distance V(TR inner); the outer polygon is defined by a set of mm vertices located at approximately distance V(TR outer); V(TR inner) is greater than V(To); and V(TR outer) is less than V(Ri).
- 16. The sparse array of claim 12 wherein none of the receive elements for a particular scanning function are used during the same scanning function as transmit elements and none of the transmit elements for that particular scanning function are used during that same scanning function as receive elements.
- 17. The sparse array of claim 12 wherein the transmit elements are designed to have a resonant frequency of f and, the receive elements are designed to have a resonant frequency other than f.
- 18. The sparse array of claim 17 wherein the transmit elements are designed to have the resonant frequency of f and, the receive elements are designed to have a resonant frequency of approximately a harmonic of f.
- 19. The sparse array of claim 17 wherein the transmit elements are designed to have the resonant frequency of f and the receive elements are designed to have a resonant frequency of approximately a sub-harmonic of f.
- 20. The sparse array of claim 17 wherein the transmit elements are designed to have the resonant frequency of f and the receive elements are designed to have a resonant frequency of approximately a fractional harmonic of f.
- 21. The sparse array of claim 12 wherein:
the transmit and the receive elements are located in a scanning head; the scanning head is connected by a cable to a scanning device; the scanning head contains a set of pre-amps for the receive elements operating at a first voltage; the scanning head contains a set of transmitters for the transmit elements operating at a second voltage; and the second voltage is at least an order of magnitude greater than the first voltage.
- 22. A method of acquiring information for medical imaging comprising:
transmitting energy from an inner array of transmit elements to electronically illuminate a target area within a body; then using a set of receive elements located in a band of receive elements outside the inner array of transmit elements to receive reflected energy from a fraction of the illuminated target area; and using parallel processing to combine information from reflected energy from several sets of data collected by various transmit elements to form a three-dimensional image of the target area within the body.
- 23. The method of claim 22 wherein:
the transmit elements are optimized to operate at a transmit frequency; the receive elements are optimized to operate at a receive frequency which is different than the transmit frequency; and the information for medical imaging is acquired using harmonic imaging techniques.
Government Interests
[0001] This invention was made with government support under grant number R44 HL57111 awarded by National Institute of Health (“NIH”). The Government has certain rights in the invention.