RU98102160A - OPTICAL SYSTEM FOR BEAM FORMATION (OPTIONS) AND OPTICAL SENSOR - Google Patents

Claims (30)

1. An optical system for forming a beam containing a light source, multiple plates and a cylindrical lens located between the light source and multiple plates, characterized in that the system is configured to generate a light beam emerging from the light source, with the desired shape in cross section of the light beam, respectively.  2. The optical system according to claim 1, characterized in that the generated output light beam is a beam with a long axis diameter and a short axis diameter, which has an elliptical cross section and the same diameter as the output light beam in the case when light having a circular beam cross-section is output from the light source.  3. The optical system according to claim 1, characterized in that the diameter of the generated light beam emerging from the light source with an elliptical beam cross-section is equal to the diameter of the light beam emerging from the light source in the case when the light beam having a circular beam cross-section is output from a light source.  4. The optical system according to claim 1, characterized in that the multiple plates have a divergence of the light beam on the first control plane less than on the second control plane, and the first basal plane parallel to the large diameter of the beam emerging from the light source, and the second the basal plane is parallel to the small diameter of the beam emerging from the light source.  5. The optical system according to claim 4, characterized in that each multiple plate is a plane-parallel plate made with the ability to refract incident light.  6. The optical system according to claim 5, characterized in that the multiple plates contain two plates, which have a plane-symmetric relation with respect to a plane perpendicular to the optical axis of the light source and are configured to transmit incident light.  7. The optical system according to claim 4, characterized in that the cylindrical lens has a cylindrical surface, the long axis of which is an axis parallel to the second base plane and facing the numerous plates, and the cylindrical surface has a positive optical power.  8. The optical system according to claim 4, characterized in that the cylindrical lens has a cylindrical surface, the long axis of which is an axis parallel to the second reference plane and facing the light source, and the cylindrical surface has a negative optical power.  9. The optical system of claim 8, wherein the negative optical power has a relatively accurate increase compared to the positive optical power.  10. An optical sensor for optical storage medium, comprising a laser light source for outputting a light beam having an elliptical cross section in the form of a diverging beam, multiple plates, a cylindrical lens located between the laser source and multiple plates, and an objective lens for focusing light incident from multiple plates into an optical storage medium, characterized in that said optical system is configured to output a light beam from a light source a shaped beam that has a substantially circular shape in the cross section of the light beam.  11. The optical sensor of claim 10, wherein the multiple plates and a cylindrical lens form a light beam with an elliptical cross section, which has the same beam diameter as the axis of the elliptical light beam short on the axis.  12. The optical sensor according to claim 11, characterized in that the plurality of plates are made with the possibility of less divergence of the light beam on the first basal plane than on the second basal plane, while the first basal plane is parallel to the large diameter of the light beam exiting from the light source, and the second base plane is parallel to the small diameter of the light beam emerging from the light source.  13. The optical sensor according to claim 12, characterized in that the plurality of plates have plane-parallel plates that are capable of refracting incident light.  14. The optical sensor according to claim 13, characterized in that the multiple plates contain two plates that have a symmetrical plane ratio with respect to a plane perpendicular to the optical axis of the light source and transmit incident light.  15. The optical sensor according to 14, characterized in that it contains a photodetector and a first plate located next to the photodetector, is configured to reflect the incident light coming from the second plate, which is located away from the photodetector, towards the photodetector.  16. The optical sensor according to clause 15, wherein the photodetector has a structure adapted to detect light, according to the astigmatic method.  17. The optical sensor according to clause 16, characterized in that the surface of the first plate located next to the photodetector is configured to reflect light that falls from the second plate towards the photodetector.  18. The optical sensor according to 17, characterized in that the optical axis of the laser source is located in a direction different from the parallel optical axis of the objective lens, and the optical sensor further comprises a reflective mirror configured to reflect light incident from the second plate towards the lens of the lens.  19. The optical sensor according to claim 18, wherein the optical axis of the laser source is perpendicular to the optical axis of the objective lens.  20. The optical sensor according to item 12, wherein the cylindrical lens has a cylindrical surface, the long axis of which is an axis parallel to the second base plane and facing the numerous plates, and the cylindrical surface has a positive optical power.  21. The optical sensor according to p. 20, characterized in that the cylindrical lens has a cylindrical surface, the long axis of which is an axis parallel to the second reference plane and facing the light source, and the cylindrical surface has a negative optical power.  22. The optical sensor according to item 21, wherein the negative optical power has an increase compared with the positive optical power.  23. The optical sensor of claim 10, characterized in that it further comprises a collimating lens for collimating light incident through multiple plates, and for transmitting light to said objective lens.  24. An optical system for generating a beam that is output from a light source and has an elliptical beam cross section in a circular cross section of a light beam, characterized in that it comprises a cylindrical lens for receiving a light beam having an elliptical cross section and outputting a light beam in the form of such a beam whose diameter in the long axial direction decreases, and the diameter of the beam in which the axial direction essentially remains unchanged and numerous plates for correcting astigmatism are light Vågå beam which is output from the cylindrical lens has a circular cross section of the beam.  25. The optical system according to paragraph 24, wherein the cylindrical lens has a cylindrical surface, the long axis of which is the axis parallel to the direction of the short axis of the elliptical light beam, and faces numerous plates in which the cylindrical surface has a positive optical power.  26. The optical system according A.25, characterized in that the cylindrical lens has a cylindrical surface, the long axis of which is the axis parallel to the direction of the short axis of the elliptical light beam facing the light source, and the fact that the cylindrical surface has a negative optical power.  27. The optical system according to p, characterized in that the negative optical power has a precise increase relative to the positive optical power.  28. The optical system according to paragraph 24, wherein the multiple plates are configured to ensure the divergence of a light beam located in a plane parallel to the large diameter of the light beam emerging from the light source, to a lesser extent than that of a light beam located in the plane which is parallel to the small diameter of the light beam emerging from the light source.  29. The optical system of claim 28, wherein each multiple plate is a plane-parallel plate with an optical feature to reflect incident light.  30. The optical system according to clause 29, wherein the multiple plates contain two plates that have a plane-symmetric relationship with respect to a plane perpendicular to the optical axis of the light source, and configured to transmit incident light.