NONLINEAR DYNAMIC FOCUSING CONTROL METHOD

Abstract

A nonlinear dynamic focusing control method includes: (1) using a minimum length in a scan line having the minimum length and a maximum length as an initial location and assigning a focal point on the scan line; (2) calculating half depth of focus of the focal point, and the initial location plus the half depth of focus of the focal point being the location of this focal point on the scan line; (3) determining an initial calculation location of the next focal point by adding the half depth of focus of the focal point from the location of this focal point on the scan line in the direction of the maximum length; and (4) determining if the initial calculation location of the next focal point is greater than the maximum length.

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5G	18/10/2022	ISLD-202209-082	INDUSTRIAL TECHNOLOGY RESEARCH INSTITUTE	S1 TS Number: TS 138 211 v16.3.0 Version No: v16.3.0 Illustrative part: ---- Release: 16 S2 TS Number: TS 138 212 v16.3.0 Version No: v16.3.0 Illustrative part: ---- Release: 16 S3 TS Number: TS 138 211 Version No: Illustrative part: ---- Release: S4 TS Number: TS 138 212 Version No: Illustrative part: ---- Release: +3 -3				Yes	Basis Patent

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Publication No	Technology	Declaration Date	Declaration Reference	Declaring Company	Specification Number	Explicitly Disclosed	Patent Type
CN104142608A	5G	18/10/2022	ISLD-202209-082	INDUSTRIAL TECHNOLOGY RESEARCH INSTITUTE	S1 TS Number: TS 138 211 v16.3.0 Version No: v16.3.0 Section No: Release : 16 S2 TS Number: TS 138 212 v16.3.0 Version No: v16.3.0 Section No: Release : 16 S3 TS Number: TS 138 211 Version No: ---- Section No: Release : ---- S4 TS Number: TS 138 212 Version No: ---- Section No: Release : ---- +3 -3	Yes	Family Member
CN104142608B	5G	18/10/2022	ISLD-202209-082	INDUSTRIAL TECHNOLOGY RESEARCH INSTITUTE	S1 TS Number: TS 138 211 v16.3.0 Version No: v16.3.0 Section No: Release : 16 S2 TS Number: TS 138 212 v16.3.0 Version No: v16.3.0 Section No: Release : 16 S3 TS Number: TS 138 211 Version No: ---- Section No: Release : ---- S4 TS Number: TS 138 212 Version No: ---- Section No: Release : ---- +3 -3	Yes	Family Member
TW201443466A	5G	18/10/2022	ISLD-202209-082	INDUSTRIAL TECHNOLOGY RESEARCH INSTITUTE	S1 TS Number: TS 138 211 v16.3.0 Version No: v16.3.0 Section No: Release : 16 S2 TS Number: TS 138 212 v16.3.0 Version No: v16.3.0 Section No: Release : 16 S3 TS Number: TS 138 211 Version No: ---- Section No: Release : ---- S4 TS Number: TS 138 212 Version No: ---- Section No: Release : ---- +3 -3	Yes	Family Member
TWI470258B	5G	18/10/2022	ISLD-202209-082	INDUSTRIAL TECHNOLOGY RESEARCH INSTITUTE	S1 TS Number: TS 138 211 v16.3.0 Version No: v16.3.0 Section No: Release : 16 S2 TS Number: TS 138 212 v16.3.0 Version No: v16.3.0 Section No: Release : 16 S3 TS Number: TS 138 211 Version No: ---- Section No: Release : ---- S4 TS Number: TS 138 212 Version No: ---- Section No: Release : ---- +3 -3	Yes	Family Member
US2014334267A1	5G	18/10/2022	ISLD-202209-082	INDUSTRIAL TECHNOLOGY RESEARCH INSTITUTE	S1 TS Number: TS 138 211 v16.3.0 Version No: v16.3.0 Section No: Release : 16 S2 TS Number: TS 138 212 v16.3.0 Version No: v16.3.0 Section No: Release : 16 S3 TS Number: TS 138 211 Version No: ---- Section No: Release : ---- S4 TS Number: TS 138 212 Version No: ---- Section No: Release : ---- +3 -3	Yes	Basis Patent

Publication No	Technology	Declaration Information			Specification Information				Explicitly Disclosed	Patent Type	Status	National Phase Entries
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Claim

1. A nonlinear dynamic focusing control method applicable to an imaging system with an array transducer, comprising:
(1) adding, by an adder, a minimum length of a scan line as an initial location of the scan line with a half depth of focus of a focal point on the scan line as the location of the focal point on the scan line;
(2) adding, by the adder, the half depth of focus of the focal point with the location of the focal point on the scan line in a direction of a maximum length of the scan line to form an initial calculation location of a next focal point;
(3) comparing, by a comparator, the initial calculation location of the next focal point with the maximum length; and
(4) replacing the initial location by the initial calculation location and repeating steps (2) to (3) when the initial calculation location of the next focal point is less than the maximum length,
wherein the locations of the focal points on the scan line are nonlinear distribution.', '(1) adding, by an adder, a minimum length of a scan line as an initial location of the scan line with a half depth of focus of a focal point on the scan line as the location of the focal point on the scan line;', '(2) adding, by the adder, the half depth of focus of the focal point with the location of the focal point on the scan line in a direction of a maximum length of the scan line to form an initial calculation location of a next focal point;', '(3) comparing, by a comparator, the initial calculation location of the next focal point with the maximum length; and', '(4) replacing the initial location by the initial calculation location and repeating steps (2) to (3) when the initial calculation location of the next focal point is less than the maximum length,', 'wherein the locations of the focal points on the scan line are nonlinear distribution.

2. The nonlinear dynamic focusing control method of claim 1, wherein an equation for calculating the location of the focal point on the scan line is', 'K
Â·

Î»

A
2

âx81¢

z

F
,
i

2

-

z

F
,
i

+

z
i

=
0

,

âx81¢

wherein
âx81¢

âx81¢

K
Â·

Î»

A
2

âx81¢

z

F
,
i

2', 'is the half depth of focus of the focal point, Î» is the wavelength of the ultrasound transmitted by the imaging system, A is the aperture of the ultrasound transmitted by the imaging system, zF,i is the location of the focal point on the scan line, zi is the initial location, and K is a coefficient for adjusting the total number of focal points on the scan line.

3. The nonlinear dynamic focusing control method of claim 1, wherein the nonlinear distribution is a second-order nonlinear distribution.

4. The nonlinear dynamic focusing control method of claim 1, wherein the location of the focal point on the scan line is greater than the initial location and less than the maximum length.

5. The nonlinear dynamic focusing control method of claim 1, wherein step (1) further includes comparing, by the comparator, the half depth of focus of the focal point with a preset sample duration of the imaging system, sample duration, then and replacing the half depth of focus of the focal point is replaced by the sample duration when the half depth of focus of the focal point is smaller than the preset sample duration.

6. The nonlinear dynamic focusing control method of claim 1, wherein the initial calculation location of the next focal point is smaller than the maximum length, the maximum length minus the initial calculation location of the next focal point is smaller than the half depth of focus of the next focal point, and step (3) further comprises setting the next focal point to be the maximum length.

7. The nonlinear dynamic focusing control method of claim 1, further comprising:
(5) receiving by the array transducer at least one sampling point along the scan line, and weighing the sampling point with a weight according to a weight block within which the sampling point is located, wherein the weighted block is formed by extending from each of the focal points at the locations on the scan line as the center half depth of focus corresponding to each focal point in directions towards the minimum length and the maximum length, wherein each sampling point in and sampling points within the same weighted block are given the same weight for beamforming.', '(5) receiving by the array transducer at least one sampling point along the scan line, and weighing the sampling point with a weight according to a weight block within which the sampling point is located, wherein the weighted block is formed by extending from each of the focal points at the locations on the scan line as the center half depth of focus corresponding to each focal point in directions towards the minimum length and the maximum length, wherein each sampling point in and sampling points within the same weighted block are given the same weight for beamforming.

8. A nonlinear dynamic focusing control method applicable to an imaging system with an array transducer, comprising:
(1) defining at least one knee point on a scan line that has a maximum length and a minimum length to segment the scan line into n scan segments, wherein n is not less than 2, and the n scan segments are arranged sequentially along the scan line from the minimum length to the maximum length, a first scan segment in the n scan segments has an initial location at the minimum length and an ending location at the knee point closest to the minimum length, a second scan segment in the n scan segments has an ending location at the maximum length and an initial location at the knee point closest to the maximum length, the rest of scan segments begin at knee points closest to the minimum length and have two adjacent knee points as the initial locations and the ending locations, and a focal point is assigned on each of the scan segments;
(2) adding, by an adder, the initial location of each scan segment with the half depth of focus of the focal point of the corresponding scan segment as the location of the focal point of this scan segment on the scan line;
(3) adding, by the adder, the half depth of focus of the respective focal points with the locations of the respective focal points on the respective scan segments in the direction of the maximum length, respectively, to form initial calculation locations of the next focal points of the respective scan segments;
(4) comparing, by a comparator, the initial calculation locations of the next focal points on the respective scan segments with the maximum length; and
(5) replacing the initial location of the scan segment by the initial calculation location of the scan segment and repeating steps (3) to (4) when the initial calculation locations of the next focal points on the respective scan segments are less than the maximum length,
wherein the locations of the focal points on the scan line are nonlinear distribution, and Îx94zi of at least one of the scan segments is different from the others.', '(1) defining at least one knee point on a scan line that has a maximum length and a minimum length to segment the scan line into n scan segments, wherein n is not less than 2, and the n scan segments are arranged sequentially along the scan line from the minimum length to the maximum length, a first scan segment in the n scan segments has an initial location at the minimum length and an ending location at the knee point closest to the minimum length, a second scan segment in the n scan segments has an ending location at the maximum length and an initial location at the knee point closest to the maximum length, the rest of scan segments begin at knee points closest to the minimum length and have two adjacent knee points as the initial locations and the ending locations, and a focal point is assigned on each of the scan segments;', '(2) adding, by an adder, the initial location of each scan segment with the half depth of focus of the focal point of the corresponding scan segment as the location of the focal point of this scan segment on the scan line;', '(3) adding, by the adder, the half depth of focus of the respective focal points with the locations of the respective focal points on the respective scan segments in the direction of the maximum length, respectively, to form initial calculation locations of the next focal points of the respective scan segments;', '(4) comparing, by a comparator, the initial calculation locations of the next focal points on the respective scan segments with the maximum length; and', '(5) replacing the initial location of the scan segment by the initial calculation location of the scan segment and repeating steps (3) to (4) when the initial calculation locations of the next focal points on the respective scan segments are less than the maximum length,', 'wherein the locations of the focal points on the scan line are nonlinear distribution, and Îx94zi of at least one of the scan segments is different from the others.', '9. The nonlinear dynamic focusing control method of claim 8, wherein an equation for calculating the location of the focal point on each scan segment is', 'K
Â·

Î»

A
2

âx81¢

z

F
,
i

2

-

z

F
,
i

+

z
i

+

Îx94
âx81¢

âx81¢

z
i

=
0

,

âx81¢

wherein
âx81¢

âx81¢

K
Â·

Î»

A
2

âx81¢

z

F
,
i

2', 'is the half depth of focus of the focal point, Î» is the wavelength of the ultrasound transmitted by the imaging system, A is the aperture of the ultrasound transmitted by the imaging system, zF,i is the location of the focal point on the scan line, zi is the initial location, Îx94zi is a correction term for adjusting the location of the focal point on the scan line, and K is a coefficient for adjusting the total number of focal points on the scan line.', '10. The nonlinear dynamic focusing control method of claim 8, wherein the focal points on the scan segments are distributed in a linear, second-order nonlinear, third-order nonlinear or higher-order nonlinear fashion by adjusting Îx94zi in the equation for calculating the location of the focal point on each scan segment.', '11. The nonlinear dynamic focusing control method of claim 8, wherein the location of the focal point on the respective scan segment is greater than the initial location and less than the ending location.', '12. The nonlinear dynamic focusing control method of claim 8, wherein step (2) further includes comparing, by the comparator, the half depth of focus of the focal point with a preset sample duration of the imaging system, and replacing the half depth of focus of the focal point by the sample duration when the half depth of focus of the focal point is smaller than the preset sample duration.', '13. The nonlinear dynamic focusing control method of claim 8, wherein the initial calculation location of the next focal point of the nth scan segment is smaller than the maximum length, the maximum length minus the initial calculation location of the next focal point of the nth scan segment is smaller than the half depth of focus of the next focal point of the nth scan segment, and step (4) further comprises setting the next focal point of the nth scan segment on the maximum length.', '14. The nonlinear dynamic focusing control method of claim 8, further comprising:
(6) receiving by the array transducer at least one sampling point along the scan line, and weighing the sampling point with a weight according to a weighted block within which the sampling point is located, wherein the weighted block is formed by extending from each of the focal points as the center half depth of focus corresponding to each focal point in directions towards the minimum length and the maximum length, and sampling points within the same weighted block are given the same weight for beamforming.', '(6) receiving by the array transducer at least one sampling point along the scan line, and weighing the sampling point with a weight according to a weighted block within which the sampling point is located, wherein the weighted block is formed by extending from each of the focal points as the center half depth of focus corresponding to each focal point in directions towards the minimum length and the maximum length, and sampling points within the same weighted block are given the same weight for beamforming.', '15. The nonlinear dynamic focusing control method of claim 8, wherein the knee point is a junction point of a near range and a far range or a transmit focus.']

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