Circular polarization illumination based analyzer system
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01N-021/00
G01J-004/00
출원번호
UP-0554878
(2006-10-31)
등록번호
US-7630075
(2009-12-16)
발명자
/ 주소
Fritz, Bernard S.
출원인 / 주소
Honeywell International Inc.
대리인 / 주소
Fredrick, Kris T.
인용정보
피인용 횟수 :
1인용 특허 :
100
초록▼
A particle discriminator using circularly polarized light projected through a channel having target particles. Light may be propagated through the channel, with some light scattered separated into forward angle scattered light, small angle scattered light and unscattered light. The forward angle sca
A particle discriminator using circularly polarized light projected through a channel having target particles. Light may be propagated through the channel, with some light scattered separated into forward angle scattered light, small angle scattered light and unscattered light. The forward angle scattered light may be linearly polarized and detected. The small angle scattered light may be linearly polarized in a direction orthogonal to the direction of the polarization of the forward angle scattered light, and at least both these kinds of light may be detected. Data from these detected kinds of light may be analyzed to discriminate particles from one another.
대표청구항▼
What is claimed is: 1. A polarization based analyzer system comprising: a light source; a first polarizer situated at an output of the light source; a channel; a first optical mechanism for focusing light from the polarizer to the channel; a second optical mechanism for collimating light from the c
What is claimed is: 1. A polarization based analyzer system comprising: a light source; a first polarizer situated at an output of the light source; a channel; a first optical mechanism for focusing light from the polarizer to the channel; a second optical mechanism for collimating light from the channel; a structure for directing a first light from the second optical mechanism in a first direction and a second light from the second optical mechanism in a second direction; a first detector for detecting the first light; a second detector for detecting second light; a second polarizer situated between the structure and the first detector; and a third polarizer situated between the structure and the second detector. 2. The system of claim 1, wherein: the light source is for emanating linearly polarized light; the first polarizer is a circular polarizer; the second polarizer is a first linear polarizer; and the third polarizer is a second linear polarizer. 3. The system of claim 2, wherein a polarization state of the second linear polarizer is approximately orthogonal to a polarization state of the second linear polarizer. 4. The system of claim 3, wherein: the first light comprises forward angle scattered light; and the second light comprises small angle scattered light. 5. The system of claim 4, further comprising: a computer connected to the first and second detectors; and wherein: the forward angle scattered light is some of the first light scattered by particles in the channel; the small angle scattered light is some of the second light scattered by particles in the channel; the computer processes data from the first and second detectors into small angle scatter light versus forward angle scatter light graphs; and the graphs provide groupings of the particles according to at least one feature that distinguish particles from one another. 6. The system of claim 4, wherein: the structure comprises a first portion, a second portion and a third portion; wherein: the first portion is transmissive; the second portion is reflective; and the third portion is reflective; the first portion is for transmitting the first light; and the second portion is for reflecting the second light; and the third portion is for reflecting a third light in a third direction. 7. The system of claim 1, wherein the channel is of a cytometer. 8. A method for discriminating particles, comprising: projecting circularly polarized light through a receptacle for particles; collimating the light that has been projected through the receptacle; separating the light into small angle scattered light and forward angle scattered light; linearly polarizing the forward angle scattered light; linearly polarizing the small angle scattered light orthogonally relative to the polarized forward angle scattered light; and analyzing the polarized forward angle scattered light and the polarized small angle scattered light to discriminate particles that being in the receptacle. 9. The method of claim 8, further comprising: converting the polarized forward angle scattered light into a first type of electronic signals; converting the polarized small angle scattered light into a second type of electronic signals; and processing the first and second types of electronic signals into data representing various particles that being in the receptacle. 10. The method of claim 8, wherein the receptacle is a flow channel of a cytometer. 11. A circularly polarized illumination-based analyzer comprising: a circularly polarized light source; a first light splitter; a channel situated between the light source and the first light splitter; and a first linear polarizer proximate to the light splitter; a second linear polarizer proximate to the first light splitter and having a polarization direction approximately orthogonal to a polarization direction of the first linear polarizer; a first detector proximate to the first linear polarizer; a second detector proximate to the second linear polarizer; the first light splitter for separating light from the channel into small angle scattered light, forward angle scattered light, and unscattered light; the first linear polarizer for polarizing forward angle scattered light; and the second linear polarizer is for polarizing small angle scattered light. 12. The analyzer of claim 11, further comprising: a third detector proximate to the channel; and wherein the third detector is for detecting unscattered light. 13. The analyzer of claim 11, further comprising: a second light splitter situated between the first light splitter and the first polarizer; a third detector proximate to the second light splitter; a third linear polarizer situated between the second light splitter and the third detector; a third light splitter situated between the first light splitter and the second linear polarizer; a fourth detector proximate to the third light splitter; and a fourth linear polarizer situated between the third light splitter and the fourth detector; and wherein: the third linear polarizer is orthogonal relative to the first linear polarizer; and the fourth linear polarizer is orthogonal relative to the second linear polarizer. 14. A polarization based analyzer system comprising: a light source; a first polarizer situated at an output of the light source; a channel; a first optical mechanism for focusing light from the polarizer to the channel; a second optical mechanism for collimating light from the channel; a structure for directing a first light from the second optical mechanism in a first direction and a second light from the second optical mechanism in a second direction; a first detector for detecting the first light; a second detector for detecting second light; a second polarizer situated between the structure and the first detector; and a third polarizer situated between the structure and the second detector; and wherein: the light source is for emanating linearly polarized light; the first polarizer is a circular polarizer; the second polarizer is a first linear polarizer; the third polarizer is a second linear polarizer; a polarization state of the second linear polarizer is approximately orthogonal to a polarization state of the second linear polarizer; the first light comprises forward angle scattered light; the second light comprises small angle scattered light; the structure comprises a first portion, a second portion and a third portion; the first portion is transmissive; the second portion is reflective; the third portion is reflective; the first portion is for transmitting the first light; the second portion is for reflecting the second light; and the third portion is for reflecting a third light in a third direction. 15. The system of claim 14, further comprising: a third detector for detecting the third light; and wherein the third light is unscattered light. 16. The system of claim 14, wherein: the second portion is a ring-like band having borders that are different sized concentric circles; the first portion is situated within the smaller concentric circle; and the third portion is situated within the first portion. 17. A polarization based analyzer system comprising: a light source; a first polarizer situated at an output of the light source; a channel; a first optical mechanism for focusing light from the polarizer to the channel; a second optical mechanism for collimating light from the channel; a structure for directing a first light from the second optical mechanism in a first direction and a second light from the second optical mechanism in a second direction; a first detector for detecting the first light; a second detector for detecting second light; a second polarizer situated between the structure and the first detector; and a third polarizer situated between the structure and the second detector; and wherein the channel is of a cytometer. 18. A method for discriminating particles, comprising: projecting circularly polarized light through a receptacle for particles; collimating the light that has been projected through the receptacle; separating the light into small angle scattered light and forward angle scattered light; linearly polarizing the forward angle scattered light; linearly polarizing the small angle scattered light orthogonally relative to the polarized forward angle scattered light; analyzing the polarized forward angle scattered light and the polarized small angle scattered light to discriminate particles that being in the receptacle; converting the polarized forward angle scattered light into a first type of electronic signals; converting the polarized small angle scattered light into a second type of electronic signals; and processing the first and second types of electronic signals into data representing various particles that being in the receptacle. 19. The method of claim 18, further comprising: plotting the data representing the signals into plots; and analyzing the plots to classify the particles into several groups. 20. A method for discriminating particles, comprising: projecting circularly polarized light through a receptacle for particles; collimating the light that has been projected through the receptacle; separating the light into small angle scattered light and forward angle scattered light; linearly polarizing the forward angle scattered light; linearly polarizing the small angle scattered light orthogonally relative to the polarized forward angle scattered light; and analyzing the polarized forward angle scattered light and the polarized small angle scattered light to discriminate particles that being in the receptacle; and wherein the receptacle is a flow channel of a cytometer. 21. A circularly polarized illumination-based analyzer comprising: a circularly polarized light source; a first light splitter; a channel situated between the light source and the first light splitter; and a first linear polarizer proximate to the light splitter; a second linear polarizer proximate to the first light splitter and having a polarization direction approximately orthogonal to a polarization direction of the first linear polarizer; a first detector proximate to the first linear polarizer; and a second detector proximate to the second linear polarizer; and wherein: the first light splitter is for separating light from the channel into small angle scattered light, forward angle scattered light, and unscattered light; the first linear polarizer is for polarizing forward angle scattered light; and the second linear polarizer is for polarizing small angle scattered light; and further comprising: a second light splitter situated between the first light splitter and the first polarizer; a third detector proximate to the second light splitter; a third linear polarizer situated between the second light splitter and the third detector; a third light splitter situated between the first light splitter and the second linear polarizer; a fourth detector proximate to the third light splitter; and a fourth linear polarizer situated between the third light splitter and the fourth detector; and wherein: the third linear polarizer is orthogonal relative to the first linear polarizer; and the fourth linear polarizer is orthogonal relative to the second linear polarizer. 22. The analyzer of claim 21, further comprising: a fifth detector proximate to the first light splitter; a fifth linear polarizer situated between the fifth detector and the first light splitter; a fourth light splitter situated between the fifth linear polarizer and the first detector; a sixth detector proximate to the fourth light splitter; and a sixth linear polarizer situated between the sixth detector and the fourth light splitter; and wherein: the fifth detector is for detecting unscattered light; the sixth detector is for detecting unscattered light; and the sixth linear polarizer is orthogonal relative to the fifth linear polarizer. 23. The analyzer of claim 22, further comprising: a processor connected to the first, second, third, fourth, fifth and sixth detectors; and the processor processes signals from the first, second, third, fourth, fifth and sixth detectors into data for discriminating particles in the channel.
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