VIRTUAL, GRID IMAGING METHOD AND SYSTEM FOR ELIMINATING SCATTERED RADIATION EFFECT
원문보기
IPC분류정보
국가/구분
United States(US) Patent
공개
국제특허분류(IPC7판)
G06K-009/40
G06T-007/00
출원번호
US-0514541
(2007-06-08)
공개번호
US-0046822
(2010-02-25)
우선권정보
CN-200610114533.8(2006-11-14)
국제출원번호
PCT/CN2007/001817
(2007-06-08)
발명자
/ 주소
LI, Yunxiang
Cao, Hongguang
대리인 / 주소
BIRCH STEWART KOLASCH & BIRCH
인용정보
피인용 횟수 :
0인용 특허 :
0
초록▼
A virtual grid imaging method capable of eliminating scattered radiation effect and an imaging system thereof are provided. The method is mainly applicable for imaging with high energy rays, in which scattered rays reaching a surface of a detector are not filtered, and data of the scattered rays and
A virtual grid imaging method capable of eliminating scattered radiation effect and an imaging system thereof are provided. The method is mainly applicable for imaging with high energy rays, in which scattered rays reaching a surface of a detector are not filtered, and data of the scattered rays and straight rays are all sampled, and then, separation and inhibition of scattered ray component are performed for the sampled data, thereby eliminating the scattered ray component in the resulted image. The method particularly includes the following steps: (1) decomposing a digital image into multi-band images from high to low according to frequencies; (2) performing de-scattering process for low-frequency band images; (3) performing contrast enhancement process for high-frequency band images; and (4) merging the images of various frequency bands processed in the step (2) and the step (3), and forming an output image. Experiment shows that, in digital X-ray imaging, the present invention can obviously eliminate the scattered radiation effect, and meanwhile significantly reduce the dosage of the rays, in which only one third of the required dosage of a common grid is used to obtain the same image brightness.
대표청구항▼
1. A virtual grid imaging method for eliminating scattered radiation effect, applicable for imaging with high energy rays, wherein scattered rays reaching a surface of a detector are not filtered, data of scattered rays and straight rays are all sampled, and then separation and inhibition for the s
1. A virtual grid imaging method for eliminating scattered radiation effect, applicable for imaging with high energy rays, wherein scattered rays reaching a surface of a detector are not filtered, data of scattered rays and straight rays are all sampled, and then separation and inhibition for the scattered ray component are performed for the sampled data, comprising: (1) decomposing a digital image generated by high energy rays into multi-band images from high to low according to frequencies; (2) directly performing de-scattering process for low-frequency band images; (3) performing contrast enhancement process for high-frequency band images; (4) merging the images of various frequency bands processed in the step (2) and the step (3), and forming an output image. 2. The virtual grid imaging method for eliminating scattered radiation effect as claimed in claim 1, wherein: in the step (1), the digital image is decomposed by means of Laplacian Pyramid decomposition. 3. The virtual grid imaging method for eliminating scattered radiation effect as claimed in claim 1, wherein: in the step (1), the digital image is decomposed by means of Wavelet Transform. 4. The virtual grid imaging method for eliminating scattered radiation effect as claimed in claim 2, wherein: in the step (1), the number of layers n decomposed from the digital image meets the following equation: n=log(N)/log(2)−0.5 wherein N is the size of the digital image. 5. The virtual grid imaging method for eliminating scattered radiation effect as claimed in claim 1, wherein: in the step (2), the de-scattering process is performed for the low-frequency band images according to the following equation: Ck(x,y)=Gain(Lk(x,y),k)×Lk(x,y) wherein Gain (Lx(x,y),k) ∈ [0,1] is a function in positive correlation with image brightness and frequency band, Ck(x,y) is the low-frequency band images after being processed, Lk(x,y) is the low-frequency band images obtained from decomposition in the step (1), and K is a positive integer. 6. The virtual grid imaging method for eliminating scattered radiation effect as claimed in claim 1, wherein: in the step (3), the contrast enhancement process is performed for the high-frequency band images according to the following equation: Ek(x,y)=Sigm(Lk(x,y),k)×Lk(x,y) wherein Sigm(Lk(x,y),k) is an S-type nonlinear amplification function, in inverse correlation with contrast of pixel, Ek(x,y) is the high-frequency band images after being processed, Lk(x,y) is the high-frequency band images obtained from decomposition in the step (1), and K is a positive integer. 7. The virtual grid imaging method for eliminating scattered radiation effect as claimed in claim 1, wherein: in the step (4), an interpolation frequency up-conversion sampling is performed for the lowest frequency band image after being processed in the step (2), and then, the image is overlapped with an adjacent image of a higher frequency band through Gaussian convolution interpolation process, so as to generate a new image of a higher frequency band, and the same process is performed upwards layer by layer, until a processed image of a size identical to the original image is obtained. 8. The virtual grid imaging method for eliminating scattered radiation effect as claimed in claim 1, wherein: in the step (4) or after the step (4), de-noising process is performed for the image according to the following equation: fk(x,y)=(1−b)×Rk(x,y)+b×Tk+1(x,y) wherein b=Weight(Tk+1(x,y),k) is in positive correlation with image brightness and frequency band, Rk(x,y) is an image of the Kth frequency band, Tk+1(x,y) is an image of the (K+1)th frequency band after performing interpolation frequency up-conversion sampling process, and fk(x,y) is an image of the frequency band output after performing the de-noising process, and K is a positive integer. 9. The virtual grid imaging method for eliminating scattered radiation effect as claimed in claim 1, wherein: data required during the image processing is compiled in advance, and corresponding mapping curves are fitted, such that when performing image processing, the required data is obtained quickly by directly using a mapping process through a lookup table. 10. The virtual grid imaging method for eliminating scattered radiation effect as claimed in claim 1, wherein: the high energy rays comprise, but not limited to, X-rays or gamma rays. 11. A virtual grid imaging system for eliminating scattered radiation effect, wherein: the virtual grid imaging system comprises a high energy ray emitting unit, a high energy ray detecting unit, an imageacquiring, pre-processing and correcting unit, a virtual grid unit, an image post-processing unit, and an image displaying unit, wherein the high energy ray emitting unit emits high energy rays that penetrate through a to-be-detected object and then received by the high energy ray detecting unit to generate a digital image; the high energy ray detecting unit, the image acquiring, pre-processing and correcting unit, the virtual grid unit, the image post-processing unit, and the image displaying unit are connected in sequence; and after the virtual grid unit performs the process as claimed in claim 1, the image with scattered radiation effect being eliminated is sent to the image displaying unit to be displayed. 12. The virtual grid imaging system for eliminating scattered radiation effect as claimed in claim 11, wherein the high energy ray emitting unit is an X-ray tube, and the high energy ray detecting unit is an X-ray detector. 13. The virtual grid imaging method for eliminating scattered radiation effect as claimed in claim 3, wherein: in the step (1), the number of layers n decomposed from the digital image meets the following equation: n=log(N)/log(2)−0.5 wherein N is the size of the digital image.
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