Rigid endoscope provided with image transmitting rod
BACKGROUND OF THE INVENTION
The invention relates to rigid endoscopes for viewing into generally inaccessible areas, such as various body cavities or industrial components. Endoscopes for remotely viewing into body cavities or industrial components are well-known. Such endoscopes can be divided into two categories, rigid and flexible. Most flexible endoscopes utilize fiber optic image transfer bundles to carry the image from the distal tip to the proximal eyepiece. Other flexible endoscopes employ a small CCD chip at the distal tip and use fiber optics only for illumination and not for direct transfer of the image.
Most modern rigid endoscopes are of the "rod-lens" type, which utilize a train of rod-like lenses to relay the image of an object from a distal end to a proximal eyepiece or other viewing means, such as a CCD camera. Such a device is taught in U.S.P. No. 4,168,882 to Hopkins, whose entire disclosure is incorporated herein by reference. In that device, the image of an object area is formed by a first distal lens. A second lens reimages the first image to a third lens, which reimages the second image to a fourth lens, and so on, until the image is relayed to the viewing means. Rigid endoscopes employing a train of lenses for image
transfer require many lenses in order to transfer the image through a slender tube while retaining good resolving capabilities and a wide field of view. It is necessary that endoscope probe lengths reach as high as 30-40 centimeters, and such lengths require as many as 20-30 lenses in order to transmit a clear, bright image. Each lens requires grinding, polishing, and coating to obtain high optical quality, and must be aligned and mounted in a rigid encasement with great precision. As a result, the cost of producing such rigid endoscopes is very high. Further, such expensive rod-lens construction precludes the feasibility of removal and disposal of the whole shaft after a single use, which would be a preferred option, especially for cleanliness in medical applications. Removable, disposable sheaths which cover the length of the shaft have been proposed. However, such sheaths do not provide adequate protection against bacterial contamination, are cumbersome to work with, and are susceptible to breakage. Stereo versions of rod-lens type endoscopes are also known in the prior art. For example, U.S. Patent No. 5,122,650 to McKinley, the entire disclosure of which is incorporated herein by reference, teaches such an endoscope. However, substantial modifications to the basic rod-lens design must be made to obtain independent optical paths in the shaft portion in order to yield two images containing parallax data, such images being essential for production of a stereo image. These modifications require
much duplication of optical elements, especially in the shaft portion, which results in an endoscope which is costly and is even less suitable for disposability of the shaft.
SUMMARY OF THE INVENTION It is an object of the present invention to provide an improved rigid endoscope. This invention provides such an endoscope which can be constructed at a lower cost relative to prior art devices with comparable lengths and resolving capabilities. Moreover, the rigid endoscope of the invention comprises a shaft which is constructed in such a manner, and from such materials, as to allow it to be removed and disposed of at a low cost. The present invention provides a rigid endoscope utilizing a solid transparent high refractive index (HRI) tunnel rod, preferably made of glass, in place of the conventional train of lenses discussed above, for conducting image light from a distal end to a proximal end of the device, the outer surface of such rod being modified so that a minimum of light is scattered and/or reflected within the rod, thus minimizing veiling glare and contrast reduction of the image which is formed by the proximal optics near the HRI tunnel rod's proximal end. Relatively simple lenses are incorporated at the ends of the HRI tunnel rod for image formation so as to cover a wide object field and to relay the image to a receiving device, such as a video camera.
In one aspect, this invention provides a rigid endoscope device useful for remotely examining a cavity, comprising distal optics for forming an image of an object area to be examined, an HRI tunnel rod of transparent material having an index of refraction greater than 1 for conducting image light from a distal end to a proximal end of said endoscope, the HRI tunnel rod having an outer surface which is blackened effectively to inhibit internal scattering of light, proximal optics located at a proximal end of the HRI tunnel rod, the proximal optics serving to relay an image of an object area to be examined, and a means for receiving and displaying the image relayed from the proximal optics.
The HRI tunnel rod serves two major purposes: 1) it shortens the apparent distance from the proximal to the distal end by virtue of its refractive index being greater than that of air, and 2) it provides a light tunnel which can transmit image light over a relatively long distance without veiling energy from wall scatter by virtue of its modified inside walls. A preferred method of modification is by exposing the HRI tunnel rod to a reducing atmosphere, thereby reducing metal oxides to metal around the outer surface of the HRI tunnel rod to create a thoroughly blackened outer surface whose inner-diameter surface is greatly non-reflective, even at grazing incidences. A preferred reducing .method is hydrogen firing, wherein the HRI tunnel rod is exposed to a heated atmosphere of hydrogen. Such methods are taught in detail in U.S. Patent
No. 4,760,307 to Howorth, 5,074,899 to Howorth, and U.S. Patent No. 5,078,773 to Thomas.
In a second aspect, the invention provides an improved stereo measuring endoscope which resolves bright, clear images, contains fewer optical components, is less costly to manufacture, and which provides a shaft that may be disposed of at a low cost.
In a third aspect, the invention provides a method of producing a shaft for a rigid endoscope which is capable of accurately transmitting image light of high resolution from a distal end of the endoscope to a proximal end thereof, comprising modifying a rod of high refractive index transparent material by blackening the outer surface of the HRI tunnel rod, thereby creating an inner surface which minimizes the amount of light scattered and reflected within the HRI tunnel rod to an extent that veiling glare and contrast reduction of an image transmitted by the HRI tunnel rod are reduced, and surrounding the HRI tunnel rod with a ring of light-conducting members, the light- conducting members being oriented so as to run generally parallel to the HRI tunnel rod.
The foregoing and other objects, features, and advantages of the invention will be apparent from the following more particular description of the preferred embodiments as illustrated in the accompanying drawings in which reference characters refer to the same parts throughout the various views. The drawings are not necessarily to scale, emphasis instead being placed upon
illustrating the principles of the invention.
Fig. 1 shows the basic elements of the endoscope according to a preferred embodiment of the present invention. Fig. 2 shows an embodiment of the present invention wherein a positive lens is used as the distal optics.
Fig. 3 shows an embodiment of the present invention wherein a negative lens is used as the distal optics.
Fig. 4 shows an embodiment of the present invention wherein a concave "dimple" is formed on the distal end of the HRI tunnel rod.
Fig. 5 shows an embodiment of the present invention wherein an eyepiece is used as a means of viewing the image produced. Fig. 6a and 6b show an embodiment of the present invention wherein the shaft is of an all-glass, integral construction.
Fig. 7 shows an embodiment of the present invention wherein the shaft of the device is rectangular in cross- section.
Figure 8 shows an embodiment of the present invention wherein the tunnel rod is surrounded by a solid light- conducting sleeve.
Figure 9 shows an embodiment wherein there is provided a twin-channel light shaft which produces a stereo image pair from a single object.
Figure 9a shows a cross-section of the shaft shown in the embodiment of Figure 9.
Figure 10 shows an embodiment wherein there is provided an arrangement of relay optics which produces a stereo image pair from light transferred by a single HRI tunnel rod and single set of distal optics. As shown in Fig. 1, a solid transparent HRI tunnel rod 1 serves as an optical tunnel to allow the image formed by a relatively simple lens 5 at the distal end to be viewed by the eye, via an image-recording device 3, which may be a CCD camera or the like. In a preferred embodiment, the HRI tunnel rod 1 is made of glass; however, other transparent materials, including conventional polymers such as lucite, or even water, can be used for the rod's composition. The HRI tunnel rod shortens the apparent distance from the proximal to the distal end by virtue of its refractive index being greater than that of air.
If the walls of the HRI tunnel rod are modified in order to reduce internal light scattered or reflected from them, the resultant images are vastly improved over images obtained in the absence of such modification. Various methods may be used to accomplish this. A preferable method is by grinding, etching, sandblasting, or otherwise roughening the surface of the rod and then firing it at an elevated temperature in a reducing atmosphere, such as a hydrogen atmosphere. The hydrogen reduces certain metallic oxides present in the glass, such as lead or arsenic, to metal and causes the surface of the HRI tunnel rod to create a thoroughly blackened surface 7. The rod may be composed of a conventional high-index, lead-
containing glass in order to aid in the hydrogen-firing process. Such a reducing treatment is disclosed in U.S. Patent No. 5,078,773 to Thomas.
Another, less-effective method of modification is to grind, sandblast, or otherwise roughen the wall surface of the HRI tunnel rod and coat the so-treated surface with a black material, such as paint or resin, which preferably has a refractive index which closely matches that of the rod. The distal optics 5, which may be either a positive or a negative lens or lens system, forms an image of the object space, generally a volume of low accessibility, that image being of generally reduced size. The object space may be, for example, the inside of an abdominal cavity. However, rigid endoscopes are also used for viewing the inside of industrial components such as weldments or castings.
The HRI tunnel rod 1, by virtue of its blackened surface and zero-focussing power, will "transfer" the image light along the endoscope shaft with minimal stray light interfering with the image. A relay lens 17 is provided at the proximal end of the HRI tunnel rod 1 to focus the image formed by the distal objective lens 5 onto the image- recording device 3. A rigid, elongated tubular housing 37 comprises a sheath made of stainless steel or glass, or other material.
A ring of optical fibers 25 is formed around the tunnel rod 1 to provide illuminating light 2 to illuminate
the field of view 6. These fibers 25 terminate at the distal end of the shaft and have polished ends. The fibers 25 are routed in the handle 27 of the endoscope so as not to interfere with the optical path from the relay lens 17 to the imaging device 3, and are gathered together in a compact, generally circular bundle 29 and bonded into a tubular connector 31 mounted at the side or proximal end of the handle.
Light from a remote light source 33, which may be a Xenon arc lamp or other high intensity lamp, is transmitted to the connector 31 by means of a fiber optic cable 35. This cable may be separable or may be integral with the bundle 29.
A preferred embodiment of the endoscope has a separable shaft and handle to provide 1) disposability of the shaft, 2) interchangeable shafts of varying diameters or lengths, or 3) autoclavability of the shaft portion of the endoscope. In this embodiment, the shaft may consist of a glass HRI tunnel rod and a surrounding ring of light- conducting material, fibers or clad rods. A surrounding housing such as a stainless steel or glass tube may be provided, or the light-conducting material may serve also as a housing. For example, an aluminum-coated plastic tube may serve as both the housing and light-guide illuminator. A simple mechanical coupling 39, Figure 1, may be used to lock the shaft into the handle. Such coupling may be a ball detent, collet, threaded locking ring, or other means.
The handle may contain the relay lens placed just
behind the proximal end of the HRI tunnel rod 1, and may also contain a fiber bundle resembling a "cobra head" to form a ring of fibers 41 to optically couple to those in the shaft in very near contact (or actual contact) at a coupling point 43. A suitable light-tight ring seal 45 is used to prevent any of the light carried by the fibers 41 from entering the optical path of the image light in the space between the HRI tunnel rod 1 and the relay lens 17. Whereas the handle 27 may not be steam sterilizable, it may be gas sterilized in ethylene oxide gas or disinfected and/or sterilized by other appropriate means. The housing 37 may be made from metals or plastic or combinations thereof.
As shown in Fig. 2, if a positive objective lens 11 is used as the distal optics, a real image 9 is formed at or near the entrance face of the HRI tunnel rod 1.
As shown in Fig. 3, if a negative objective lens 13 is used, a virtual image 15 is formed in front of the negative lens 13. The distal and proximal optics in each of the embodiments may be simple plano-convex or plano-concave lenses, combinations of simple lenses, or more complex structures with aspheric surfaces for correction of image aberrations.
As shown in Figure 4, a simple form of objective lens may be utilized by incorporating a concave "dimple" 19 into the distal end of the HRI tunnel rod 1. The dimple 19 may be formed by grinding and polishing a concave surface directly into the end of the solid glass HRI tunnel rod 1,
or such may be accomplished by hot-pressing the end of the rod.
As shown in Figure 5, the real image produced by relay lens 17 can be viewed directly through an eyepiece 21. In this case, if a negative objective lens is used, a means for erecting the image is required. An aperture 23 placed between the relay lens 17 and the HRI tunnel rod 1 can be used to cut off rays which travel very close to the inner- diameter of the blackened surface 7 of HRI tunnel rod 1 and which may be distorted due to any slight inhomogeneities in the rod near these walls.
The entire shaft, including the HRI tunnel rod 1 and fibers 25, may be made of low cost materials, and hence be disposable after one use or after limited use. In one such embodiment, shown in Figure 6a and 6b, the shaft is made of an all-glass construction with a pre-blackened HRI tunnel rod 1 surrounded by glass-clad fibers 51a or keystone- shaped rods 51b, and surrounded by a glass housing 53 having a low coefficient of thermal expansion. This provides a mechanically very rugged construction for the shaft. Although both glass-clad fibers 51a and keystone- shaped rods 51b appear in FIG. 6a for purposes of illustration, an embodiment using a single light-conducting material may be preferable for purposes of design- simplification.
The outer glass housing 53 may also be blackened, such as by firing in hydrogen, to produce a glossy black finish. Such an integral shaft may be made by assembling the pre-
drawn and blackened glass rod along with a ring of light pipes into the glass housing and redrawing at a relatively low drawing ratio (such as 2:1) to thermally fuse all the glass elements into a sealed, void-free rod. To reduce internal reflection or scattering of light in this version, the surface of the HRI tunnel rod, which is oversized in diameter prior to the final draw to the desired diameter, may be modified by very coarse grinding and/or cutting of shallow, circular, or spiral grooves (by sandblasting through a mask, for example) so as to produce shallow baffles inside the HRI tunnel rod. The rod may then be fired in a reducing atmosphere to blacken the roughened and grooved exterior surface. This also causes the interior "surface" of the rod to appear very black.
When this rod is assembled with the light piping clad rods in a glass tube and redrawn, there will be some smoothing and flattening of the rough surface and the grooves, but the remaining roughness and modified grooved surface will still adequately serve to suppress the internal reflection and scattering of the HRI tunnel rod after final drawing.
In the embodiments shown in Figs. 1-6, the housing and HRI tunnel rod are formed so as to be circular in cross- section. However, as shown in Fig. 7, it is also foreseeable that an HRI tunnel rod la which is rectangular in cross-section could be used. Such an embodiment might be advantageous in order to conform the shape of the image
output to the shape of the detector used. For example, CCD detectors are generally available in rectangular form, and thus an endoscope which uses such a detector would benefit from a rod and housing which produce a rectangular image. Figure 8 illustrates an embodiment wherein a light- conducting sleeve 67 provides a cavity for transfer of illumination energy to the object. A typical illumination input point is shown at 78. Use of a plastic light- conducting sleeve is compatible with the concept of ultrasonically or chemically welding plastic distal optics 68 into the distal tip. The shaft depicted in Figure 8 is completed by inserting the HRI tunnel rod 1 via the opening at the proximal end 69. Flexible tabs 70 at the proximal end of the light-conducting sleeve could be used to retain the HRI tunnel rod. Examples of distal end configurations 71 and 72, providing different illumination fields, are also shown.
Figures 9 and 10 show configurations which generate "stereo images", such images being the source of parallax data which reveals the object distance from the distal tip. In Figure 9, the "stereo images" are generated by duplicating the basic optical system of Figure 1 within a single shaft. This embodiment comprises dual distal optics 5a and dual proximal optics 17a, and dual HRI tunnel rods lb and lc. In Figure 10, the shaft contains one set of distal optics 5b and one HRI tunnel rod 1. Two sets of relay optics 61, 62 interact with and are coupled to the shaft optics via beam splitter 60 to form images 63 and 64.
With properly-designed relay optics, the stereo base 65 in the embodiment of Figure 10 can approach or even exceed the HRI tunnel rod's diameter. The ability to increase the stereo base beyond the HRI tunnel rod's diameter provides an increased depth resolution.
The above embodiments are preferred for producing endoscopes which utilize an HRI rod having an aspect ratio of about 45:1 and an area of illuminating fibers approximately equal to the cross-sectional area of the rod. However, in certain circumstances where operating conditions are extreme, i.e., where a very wide field of view (90 degrees, for example) is required, and/or where a large object distance (over 100 millimeters, for example) and a high aspect ratio rod are required, the level of illumination at the CCD may be insufficient to reproduce satisfactory video images at the monitor. Since the rod aspect ratio is dictated by the endoscopic requirements, such as those for performing laparoscopy, the overall cross-section of the endoscope is similarly limited (typically 9-11 millimeters diameter) ; and, the light source (typically a Xenon arc lamp) cannot readily be made more intense. Thus, the preferred means for increasing the illumination on the CCD is to increase the refractive index of the HRI rod 1 (FIG. 1) to the highest practical level, e.g. , up to 1.95.
A refractive index increase of the HRI rod shifts the apparent position of the distal lens 5 (FIG. 1) toward the proximal relay lens 17 (FIG. 1) , thus shortening the
optical distance between the distal "window" (actually the distal lens) and relay lens 17. With a decreased optical distance between the "window" and relay lens 17, a shorter relay focal length is required to fill the CCD ship with an image of the "window." Illumination E at the CCD chip is proportional to the squared reciprocal of the relay f- number:
where f is the relay focal length and D is the HRI rod diameter. Other methods of increasing illumination at the CCD include 1) decreasing the field of view by means of longer focal length distal optics, and 2) decreasing the image size at the CCD by means of shorter focal length relay optics. Both of these methods may produce images which are less acceptable in some marketplaces.
If further illumination is required, additional optical means can be used. Figs. 11 and 12 illustrate "hybrid" embodiments wherein such additional optical means are used. Referring to FIG. 11, a tunnel rod having blackened walls is modified by "breaking" it into two (or more) segments 121, 123 and adding a relaying lens or lenses in the spaces between the rods. As shown in Fig. 11, the relay lens comprises modified ends 125, 127 of the tunnel rods 121, 123. Modification is performed, e.g., by contouring a convex surface onto an end portion of at least
one of the tunnel rods such that it forms an image 131 of the object 132 inside or near the end of the proximal rod, the image 131 preferably being of less than or equal diameter to the rod. This internal (relayed) image 131 is, 5 in turn, focused onto a CCD by a proximal relay lens 135. The image 131 and distal "window" image 137 are both now much nearer the proximal relay lens 135, which requires a correspondingly shorter focal length. The focal length of proximal relay lens 135 decreases to at least half of its 0 original value and increases the illumination on the CCD 133 by the inverse square of this ratio.
Certain variations on the hybrid embodiment may be made without departing from the spirit and scope of the invention. Examples of such variations include, e.g., 5 using a more complex objective lens 138, such as one or more negative, positive, or combinations of lenses, aspherizing both tunnel rods to relay the image, adding one or more lenses between the tunnel rods to improve the quality of the relayed images, 131, 137 (i.e., so as to 0 correct spherical and chromatic aberration) .
The embodiment shown in Fig. 11 is potentially the least costly version of the hybrid embodiments, and therefore may provide economically-practical disposability of the separable shaft. 5 Fig. 12 shows a "hybrid" tunnel scope with an intermediate relay lens to extend the length, e.g., from 8 inches to 16 inches. This embodiment preferably uses a 6- millimeter diameter rod 101 which is 200 millimeters long
with a concave tip (objective lens) 109. A second 8- millimeter diameter rod 103 which is 200 millimeters long with piano ends is further provided. A pair of 115- millimeter EFL achromatic doublets 105, 107 are placed face-to-face between the rods 101, 103. A 50-millimeter relay lens 111 and a 5X eye piece 113 are utilized. The 5X eyepiece is preferably made up of two achromatic lenses each having an focal length of about 80mm. The exit pupil is preferably approximately 1.5 millimeters in diameter with an apparent field of about 20 degrees. The apparent field can be varied by adjusting the position of the final relay lens 111.
For right-angle viewing, the above embodiment could be supplemented with a slip-on mirror tube. While the invention has been particularly described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.