Abstract: The present invention relates to methods for identifying optical materials, and more specifically to methods employed to identify glass and other optical materials used in medical devices. The method includes the steps of (1) selecting refractive index liquids matching a given optical sample; (2) determining the matching points for the refractive index liquids; and (3) calculating the refractive indices and selecting best fit optical materials. The invention also relates to a system for identifying optical materials. The system is under the control and operation of a computing device which documents, displays and stores all the data.

Abstract: Optical systems for flexible and rigid endoscopes that have a low diffraction limit and small geometrical optical aberrations, the systems including an aperture stop where the diameter can be adjusted to select either higher resolution or higher depth of field. The optical systems can include a lens group either to focus on different object distances or on a fixed average object distance. The aperture stop can be adjusted to increase either depth of field or resolution dependent on the endoscopic and surgical situation. Simple symbols help the surgeon to adjust the aperture stop to these situations. The surgeon can either look around the body cavity with large depth of field but moderate overall resolution or focus on a small area with less depth of field but greater resolution. The balance between resolution and depth of field can be adjusted by an automatic image control. Fields in the image field are defined and software used in the camera controller analyzes the sharpness of the different fields.

Abstract: An optical system for endoscopes for which the corrections of the geometrical optical aberrations for multiple wavelengths meet the diffraction limit of the optical system. The optical system is categorized by lens groups. The glass selection for each of these lens groups uses the Hartmann Dispersion Formula. For the glasses in each lens group, limited ranges for the ?o value of the Hartmann Dispersion Formula are set. These ranges are set based on the contribution of the individual lens groups to the overall chromatic aberrations.

Abstract: Disclosed is a stereo endoscope system comprising stereo endoscopes of varying working lengths, working diameters and directions of view. Each stereo endoscope comprises two identical optical systems where every pair of corresponding components is permanently couple in a sideways orientation. The system is capable of withstanding harsh conditions associated with medical equipment cleaning and sterilization, particularly, the high temperatures and pressures associated with autoclaving. Each of the corresponding components of the two identical optical systems is paired and moved relative to each other to adjust focus and then affixed to create a new singular optical component. The system includes a prism block that extends the distance between the optical axes on the stereo endoscope to the position of two video chips.

Abstract: A stereo comparator configured for use with a stereo endoscope for adjusting and aligning an optical assembly of the stereo endoscope, for example, in connection with the repair of the endoscope. The comparator includes a housing containing a plurality of optical components, namely, a first deflecting component, a second deflecting component, a third deflecting component and a beam splitter. The optical components are arranged so that the first deflecting component deflects a first beam from a right image channel of a stereo endoscope to the beam splitter, the second deflecting component deflects a second beam from a left image channel of the stereo endoscope to the third deflecting component, the third deflecting component deflects the second beam to the beam splitter and the beam splitter combines the first beam with the second beam to form a first combined beam that extends along an optical axis of the stereo endoscope.

Abstract: Optical systems for flexible and rigid endoscopes that have a low diffraction limit and small geometrical optical aberrations, the systems including an aperture stop where the diameter can be adjusted to select either higher resolution or higher depth of field. The optical systems can include a lens group either to focus on different object distances or on a fixed average object distance. The aperture stop can be adjusted to increase either depth of field or resolution dependent on the endoscopic and surgical situation. Simple symbols help the surgeon to adjust the aperture stop to these situations. The surgeon can either look around the body cavity with large depth of field but moderate overall resolution or focus on a small area with less depth of field but greater resolution. The balance between resolution and depth of field can be adjusted by an automatic image control. Fields in the image field are defined and software used in the camera controller analyzes the sharpness of the different fields.

Abstract: Disclosed are stereo endoscopes where the optical train of one optical system is separated in a left and right optical train. The separation in a left and right optical train is achieved by splitting the entrance pupil in a left and right pupil half. To additionally achieve a significant stereoscopic disparity the distance between the left and right pupil half is expanded. The separation of the entrance pupil and the expansion of the left and right pupil half is achieved by a distally located prism block. This prism block consists of a pair of rhomboidal prisms which are located exactly at the entrance pupil inside the endoscope objective. The front lens group is replaced by an identical pair of front lens groups each assembled in front of one of the two rhomboidal prisms. Such stereo endoscopes with expanded pupil halves enable to build stereo endoscopes with very small diameter or stereo endoscopes for special surgical applications.

Abstract: An objective assembly for use with small endoscopes like uretheroscopes, the objective assembly including a lens having an optical surface that includes a partial wedge. The partial wedge directly faces an aperture stop thereby limiting the F-number of the objective.

Abstract: Disclosed is a stereo endoscope system comprising stereo endoscopes of varying working lengths, working diameters and directions of view. Each stereo endoscope comprises two identical optical systems where every pair of corresponding components is permanently couple in a sideways orientation. The system is capable of withstanding harsh conditions associated with medical equipment cleaning and sterilization, particularly, the high temperatures and pressures associated with autoclaving. Each of the corresponding components of the two identical optical systems is paired and moved relative to each other to adjust focus and then affixed to create a new singular optical component. The system includes a prism block that extends the distance between the optical axes on the stereo endoscope to the position of two video chips.

Abstract: The present invention relates to methods for identifying optical materials, and more specifically to methods employed to identify glass and other optical materials used in medical devices. The method includes the steps of (1) selecting refractive index liquids matching a given optical sample; (2) determining the matching points for the refractive index liquids; and (3) calculating the refractive indices and selecting best fit optical materials. The invention also relates to a system for identifying optical materials. The system is under the control and operation of a computing device which documents, displays and stores all the data.

Abstract: A stereo comparator configured for use with a stereo endoscope for adjusting and aligning an optical assembly of the stereo endoscope, for example, in connection with the repair of the endoscope. The comparator includes a housing containing a plurality of optical components, namely, a first deflecting component, a second deflecting component, a third deflecting component and a beam splitter. The optical components are arranged so that the first deflecting component deflects a first beam from a right image channel of a stereo endoscope to the beam splitter, the second deflecting component deflects a second beam from a left image channel of the stereo endoscope to the third deflecting component, the third deflecting component deflects the second beam to the beam splitter and the beam splitter combines the first beam with the second beam to form a first combined beam that extends along an optical axis of the stereo endoscope.

Abstract: A wide field video endoscope objective and method of assembly the objective including four groups with five lenses, a mechanical housing containing the entire image forming elements, a aperture stop, a centering member and a retainer sleeve. The centering member is at first centered over the photo sensitive area of the chip and bonded to the surface of the cover glass. The retainer sleeve slides over said centering member and is glued to the centering member and the housing of the video chip. The objective housing with the optical elements is screwed on the centering member to adjust for focusing.

Abstract: A video endoscope for diagnostic and therapeutic usage including a rigid or flexible tube defining an axis and a compact video module arranged at a distal end of the tube along the axis, the video unit being configured to pivot off the axis for providing improved access of medical instruments through the distal end of the tube.

Abstract: The invention relates to test equipment for rigid endoscopes, but also for flexible endoscopes and video endoscopes. The equipment includes an enclosure having a cover hingedly coupled to a base, an optical test target coupled to the cover, an endoscope support stand pivotably coupled to the enclosure and a bed contained within the base including a plurality of indentations shaped for receiving individual pieces of endoscope testing equipment. The testing equipment can include magnification loupes, light post adapters, battery powered light sources, cleansing tissues and a ruler. A support bracket is coupled between the cover and the endoscope support stand wherein the endoscope support stand is pivotably coupled to the support bracket.

Abstract: A wide field video endoscope objective and method of assembly the objective including four groups with five lenses, a mechanical housing containing the entire image forming elements, a aperture stop, a centering member and a retainer sleeve. The centering member is at first centered over the photo sensitive area of the chip and bonded to the surface of the cover glass. The retainer sleeve slides over said centering member and is glued to the centering member and the housing of the video chip. The objective housing with the optical elements is screwed on the centering member to adjust for focusing.

Abstract: A wide field video endoscope objective and method of assembly the objective including four groups with five lenses, a mechanical housing containing the entire image forming elements, a aperture stop, a centering member and a retainer sleeve. The centering member is at first centered over the photo sensitive area of the chip and bonded to the surface of the cover glass. The retainer sleeve slides over said centering member and is glued to the centering member and the housing of the video chip. The objective housing with the optical elements is screwed on the centering member to adjust for focusing.

Abstract: A symmetric relay system for endoscopes includes an optically-aligned pair of elongated concavo-convex rod-type lenses formed from crown glass, to the convex end surface of each of which a meniscus-shaped flint lens is cemented. The concave ends of the rod lenses are disposed to face the intermediate images of the relay system, and the convex ends to face the aperture of the relay system. A pair of achromatic lenses, each formed of a pair of lens elements x, y, are disposed adjacent and in optical alignment with the respective concave ends of the rod lenses between the concave rod ends and the intermediate images. Each achromatic lens fulfills the condition n x/ny=vx/vy. Apochromatic glass combinations may be used in the rod lenses to significantly reduce the secondary spectrum.

Abstract: A stereo endoscope has a shaft containing two optical systems which extend through the shaft and are arranged in close proximity to each other and a housing on the proximal end of the shaft for containing an interior holding assembly for a stereo optical device which provides a stereo view into the optical systems. The stereo optical device has on each side a duplicate, mirror-image arrangement having a first deviating prism aligned coaxially with its the associated optical system, a second deviating prism which follows the first prism and again aligns the optical axis of the associated optical system parallel to the direction of observation, and a transparent protective element in the direction of observation. The holding assembly includes a first holding part, which extends transverse to the optical axis of the two optical systems of the endoscope shaft.

Abstract: The endoscope optical system has an objective with an object-side negative lens cluster, the constructional design of which should minimise or exclude image scale defects, such as distortion and field curvature. The object-side negative lens cluster comprises two menisci each having negative refractive power. The individual defects of distortion occurring at the surfaces are reduced as a result of the meniscus-like design, and a flattened image field, that is prevention of field curvature, is achieved as a result of splitting the lens cluster into two menisci. The object-side meniscus may be designed as a single lens or as a cemented component comprising an outer lens and an inner lens. Since the distortion defect at the cement surface has a negative sign, the defects are thus partially compensated at the outer surfaces of the meniscus.

Abstract: A wide-angle objective for endoscopes, in particular for video endoscopes comprises fibre image conductors or CCD image transducers, in which known instruments are taken as a basis, in which a distally positioned objective comprises a meniscus lens with its concave surface facing towards the object, as well as another optical component located on the image side. To secure an uncomplicated structure, adequate image quality, a wide object field angle and short structural length, the image-side optical component is also produced as a meniscus lens.