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Claims  |
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What is claimed is:
1. A measuring endoscope for measuring an object, comprising:
an endoscope body having a foremost end portion;
illumination light supply means housed within said body of said endoscope
and having a number of regularly arranged fine light-emitting sectors, for
supplying illumination, said illumination light supply means comprising a
light guide including a bundle of a plurality of optical fibers, said
bundle having two light-incidence end portions, said plurality of optical
fibers being arranged at a light-emission end of said light guide to form
a plurality of alternate rows of fibers in such a manner that those
optical fibers included within one of the two light-incidence end portions
and those optical fibers included within the other light-incidence end
portion are arranged in alternate rows relative to each other at the
light-emission end portion of the light guide;
image focusing means, housed in said foremost end portions of said
endoscope body, for forming an image of said object from illumination
reflected from said object;
image pickup means, housed within said endoscope body and having a number
of picture elements disposed regularly at a position at which said image
of the object is formed by said image focusing optical means, for picking
up said object image;
controlling means, associated with said illumination light supply means,
for controlling the illumination supplied to said fine light-emitting
sectors to cause said illumination light supply means to emit light in
lattice form;
image processing means, connected to said image pickup means, for
performing a three-dimensional measurement of said object; and
display means, connected to said image processing means, for displaying
information corresponding to the said three-dimensional measurement.
2. A measuring endoscope according to claim 1, further comprising a
magnetic disc memory connected to said image processing means to store
information regarding said three-dimensional measurement.
3. A measuring endoscope according to claim 1, further comprising an X-Y
plotter connected to said image processing means.
4. A measuring endoscope according to claim 1, wherein said illumination
light supply includes an incandescent light supply, and an infrared light
cutting filter disposed adjacent one of said two light-incidence end
portions, and wherein said image pickup means comprises a solid-state
image sensor and a color-separating stripe filter disposed adjacent said
solid-state image sensor.
5. A measuring endoscope according to claim 1 wherein said image pickup
means comprises a solid-state image sensor constructed so that, at a time
of observation using an infrared light as said illumination, signals are
read out from every other row or column of said picture elements.
6. A measuring endoscope according to claim 1, wherein
said image pick-up means comprises a solid-state image sensor and a
color-separating stripe filter disposed adjacent said solid-state image
sensor, and wherein said controlling means comprises a rotary filter
facing the light-incidence end faces of said light guide and has a red
light transmitting sector, a green light transmitting sector, a blue light
transmitting sector and an infrared light transmitting sector, and wherein
said infrared light transmitting sector is constructed to cause an
infrared light to impinge onto only one of the two light-incidence end
portions of said light guide.
7. A measuring endoscope according to claim 6, further comprising driving
means coupled to said image focussing means for moving said image
focussing means to focus illumination emitted from said bundle on said
object only during a period in which said infrared light transmitting
sector is inserted in a path of light from said light supply means in
synchronism with a rotation of said rotary filter.
8. A measuring endoscope according to claim 6 wherein said light supply
means comprises an LED array having successibly arranged roads of LEDs
emitting a red light, a green light, a blue light, and an infrared light,
respectively, and wherein said controlling means comprises a driving
circuit for repetitively causing said rows of LEDs of said LED array to
emit a red light, a green light, a blue light, and an infrared light,
respectively, in a predetermined order.
9. Endoscope apparatus for forming a three-dimensional image of an object,
comprising:
illumination supply means for providing a plurality of distinct
illuminations including infrared illumination;
illumination transmission means, having an illumination input end and an
illumination output end, for receiving and transmitting said plurality of
illuminations, said illumination transmission means having a first group
of light channels separated from a second group of light channels at said
illumination input end, said light channels being arranged in alternating
rows of said first and second groups, respectively, at said illumination
output end, said first group of light channels transmitting said infrared
illumination;
projecting means adapted for projecting illumination from said illumination
output end onto said object;
objective means for focusing illumination reflected from said object;
image sensor means for receiving the focused illumination reflected from
said object and providing electrical signals corresponding thereto; and
processing means for receiving said electrical signals and providing output
signals having information corresponding to said three-dimensional image
of said object.
10. Apparatus according to claim 9 wherein said image sensor means includes
a plurality of light sensor elements arranged in a matrix-like structure
having columns and rows, and wherein said image sensor means provides said
electrical signals from every other row or every other column.
11. Apparatus according to claim 9 wherein said image sensor means includes
a plurality of light sensor elements arranged in a matrix-like structure
having columns and rows, and wherein said processing means includes memory
means for storing said electrical signals column-by-column or row-by-row,
and wherein said processing means processes the stored electrical signals
from every other row or every other column.
12. Apparatus according to claim 9 wherein said illumination supply means
includes:
an illumination source means for supplying a single illumination; and
illumination variation means, interposed between said illumination source
means and said illumination transmission means for causing said single
illumination to be transposed into said plurality of distinct
illuminations in a time dependent manner.
13. Apparatus according to claim 12 wherein said illumination variation
means includes a rotary filter having an infrared transmitting sector
adapted to allow said infrared illumination to enter said first group of
light channels while preventing said infrared illumination from entering
said second group of light channels.
14. A measuring endoscope for measuring an object, comprising:
a main body for holding said endoscope, said main body having proximal and
distal end portions;
light supply means for supplying a plurality of distinct illuminations;
illumination light emitting means, arranged within said distal end portion
of said main body and including a plurality of fine light emitting
sections, for emitting said plurality of distinct illuminations, only one
part of said light emitting sections emitting one of said distinct
illuminations to form a lattice-shaped light emitting pattern;
image forming means arranged within said distal end portion of said main
body, for forming an image of said lattice-shaped light emitting pattern
on said object when said illumination light emitting means forms said
lattice-shaped light emitting pattern;
objective means arranged within said distal end portion of said main body,
for forming an image of said object from illumination reflected from said
object, said image being formed at an image forming position of said
objective means;
image pickup means disposed at said image forming position of said
objective means and having a light receiving surface comprising a
plurality of picture elements arranged in columns and rows, for receiving
said image from said objective means and converting it into electrical
signals;
image processing means, connected to said image pickup means, for
processing selected electrical signals from among said electrical signals
provided by said image pickup means, said selected electrical signals
being obtained from picture elements corresponding to a position where
said image of said lattice-shaped light emitting pattern is formed on said
light receiving surface, said image processing means forming a
three-dimensional measurement of said object;
control means disposed adjacent said light supply means, for controlling
said distinct illuminations provided to said fine light emitting section
so that said illumination light emitting means emits a lattice-shaped
light pattern; and
display means coupled to said image processing means, for displaying
information corresponding to said three-dimensional measurement.
15. A measuring endoscope according to claim 14, wherein said light supply
means comprises an LED array having successively arranged rows of LEDs
emitting a red light, a green light, a blue light and an infrared light,
respectively, and wherein said control means comprises a driving circuit
for repetitively causing said rows of LEDs of said LED array to emit a red
light, a green light, a blue light and an infrared light, respectively, in
a predetermined order.
16. A measuring endoscope according to claim 15, wherein said image pickup
means comprises a solid-state image sensor constructed so that, at a time
of observation using an infrared light as one of said distinct
illuminations, signals are read out from every other row or every other
column of the picture elements.
17. A measuring endoscope according to claim 15, wherein said image pickup
means comprises a solid-state image sensor having picture elements
arranged in lattice form.
18. A measuring endoscope according to claim 14, wherein said illumination
light emitting means comprises an optical fiber bundle formed of a
plurality of optical fibers and has first and second bifurcated portions
at a light incidence end of said fiber bundle, a light emission end face
of said bundle being arranged so that respective fibers of said bifurcated
portions are alternatedly disposed in rows, said bundle being arranged so
that said light emission end face is provided within said distal end
portion of said main body, and wherein said light supply means projects
light upon respective bifurcated portions of said light incidence end
face, and wherein said control means comprises a light cutting means
provided between said light incidence end face and said light supply
means, for making at least a part of said distinct illuminations incident
upon only one of said bifurcated portions.
19. A measuring endoscope according to claim 18, wherein said control means
further comprises an infrared cutting filter arranged between said light
supply means and one of said bifurcated portions, and wherein said image
pickup means comprises a solid-state image sensor and a color-separating
stripe filter disposed adjacent said solid-state image sensor, said image
pickup means having a lattice-shaped stripe which transmits only infrared
light.
20. A measuring endoscope according to claim 18, wherein said control means
further comprises a rotary filter facing the light incidence end face of
said optical fiber bundle and has a red light transmitting sector, a green
light transmitting sector, a blue light transmitting sector, and an
infrared light transmitting sector.
21. A measuring endoscope according to claim 20, wherein said image pickup
means comprises a solid-state image sensor having picture elements
arranged in lattice form.
22. A measuring endoscope according to claim 20, wherein said image pickup
means comprises a solid-state image sensor constructed so that, at a time
of observation using an infrared light as one of said distinct
illuminations, signals are read out from every other row or every other
column of the picture elements.
23. A measuring endoscope according to claim 22, further comprising driving
means coupled to said image forming means to move said image forming means
to focus light emitted from said bundle on said object only during a
period in which the infrared light transmitting sector is inserted in a
path of light from said light supply means in synchronism with a rotation
of said rotary filter. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
(A) Field of the Invention
The present invention relates to an endoscope arranged to be able to
perform a three-dimensional measurement by utilizing Moire topography.
(B) Description of the Prior Art
In case Moire topography is performed, it is in general necessary to
provide a lattice for both the illumination optical system and the
observation optical system. When it is intended to make an ordinary
topographic observation by using these same optical systems, such a
lattice hinders the observation. Especially, in case of a small-sized
optical instrument such as endoscope, it is practically impossible to
detachably mount a lattice within the foremost end portion of the
instrument, and thus the prior known endoscope have the drawback that, for
performing a Moire topography and an ordinary endoscopic observation, two
separate endoscopic instruments (each being designed for a different
specific purpose) have to be used. Also, there has been placed on the
market an endoscopic instrument in which the lattice for observation
optical system is omitted because the image of an object is scanned by
using a photomultiplier. In such an instrument, it has been impossible to
house a photomultiplier within the small space at the foremost end portion
of the instrument because the size thereof is too large.
SUMMARY OF THE INVENTION
It is, therefore, the primary object of the present invention to provide an
endoscope which allows measurements including three-dimensional
measurement by Moire topography without the use of a special lattice and
without affecting ordinary endoscopic observation in any way.
This object is achieved according to the present invention by the
arrangement comprising: an illumination light supply consisting of a
plurality of fine illuminating members which are disposed regularly;
illumination optical system for projecting the beam of light of said light
supply onto an object under study; a focusing optical system for forming
the image of the object; image pickup means consisting of a plurality of
picture elements regularly disposed at the position of the object image
formed by the focusing optical system; and controlling means for
controlling the illumination of the respective fine illuminating members
to insure that the illumination light supply will illuminate in the form
of lattice so that, by this lattice-form illumination given by the
illumination light supply, there are performed measurements of the object
including a three-dimensional measurement thereof.
According to a preferred formation of the present invention, the
illumination light supply comprises a light guide which is formed by
placing together a large number of optical fibers into a bundle and whose
light-incidence end is bifurcated into two portions. It should be noted
that those optical fibers in these two light-incidence end portions are
arranged, at the single light-emission end of this light guide, in such a
pattern that the optical fibers in one of the incidence end portion and
those in the other incidence end portion Between the light supply and the
light-incidence ends of the light guide, there is provided a rotary filter
having a red light transmitting sector, a green light transmitting sector,
a blue light transmitting sector and an infrared light transmitting
sector. The infrared light transmitting sector is constructed so as to
insure that the infrared light beam impinges onto only one of the two
light-incidence ends of the light guide whereby allowing the illumination
light supply to emit light with a lattice pattern.
According to another preferred formation of the present invention, the
illumination light supply is constructed as an array of successively
arranged LEDs emitting a red light, a green light, a blue light and an
infrared light, respectively.
According to still another preferred formation of the present invention,
one of the two light-incedince end portions of the light guide is covered
with an infrared light cutting filter, and an incandescent light is used
as the light supply. In this case, striped filters for separating colors
are provided in the foreground of the image pickup device.
According to the present invention, it will be noted that, at the time of
an ordinary endoscopic observation, it is possible to perform a
three-dimansional measurement of an object under observation by Moire
topography without providing any visually obstructive lattice. It is also
possible to indicate on a color display a compound image consisting of the
image of the object under examination and a contour image formed by Moire
fringes superposed on the image of the object. Thus, it is possible to
present, with an improved reality, the concavo-convex, i.e. uneven,
pattern of the surface of the object under observation. Moreover, the
system as a whole can be constructed in a compact size, so that the
resulting endoscopic instrument can be used very conveniently.
These and other objects of the present invention will become more apparent
during the course of the following description and appended claims.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a diagrammatic general illustration of an embodiment of the
endoscope according to the present invention.
FIG. 2 is a diagrammatic detailed illustration of a light guide employed in
the embodiment of FIG. 1.
FIG. 3 is a diagrammatic front view of a rotary filter of FIG. 1.
FIGS. 4 and 5 are illustrations for explaining the principle for allowing
the observer to know the unevenness of the surface of an object by
utilizing Moire fringes.
FIG. 6 is a diagrammatic illustration showing the unevenness of the surface
of an object which is to be shown on the display.
FIG. 7 is a diagrammatic illustration showing the signal readout section of
a solid-state image sensor.
FIG. 8 is a block diagram showing a signal readout circuit of the
solid-state image sensor.
FIG. 9 is a diagrammatic illustration showing the structure of an interline
transfer type solid-state image sensor.
FIGS. 10A and 10B are diagrammatic illustrations showing the entirety and a
part, respectively, of an illuminating lens moving mechanism.
FIGS. 11A and 11B are diagrammatic illustrations, respectively, for
explaining a second embodiment of the present invention.
FIGS. 12A, 12B and 12C are diagrammatic illustrations for explaining a
third embodiment of the present invention.
FIG. 13 is a block diagram of the electric circuit portion which is applied
to the third embodiment.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
The present invention will hereunder be described with respect to the
embodiments illustrated in the accompanying drawings.
In FIG. 1, reference numeral 1 represents a light supply lamp; 2 a light
guide having bifurcated light-incidence ends 2a and 2b and having one
light-emission end 2c where respective optical fibers are regularly
arranged as shown in FIG. 2 in such a way that the optical fibers in the
two light-incidence end portions 2a and 2b are arranged at the
light-emission end in alternate rows of fibers relative to each other; 3 a
rotary filter disposed between the light supply lamp 1 and the
light-incidence ends of the light guide 2, and which is divided into four
sectors consisting of a red light transmitting sector 3a, a green light
transmitting sector 3b, a blue light transmitting sector 3c and an
infrared light transmitting sector 3d as shown in FIG. 3. Furthermore, the
infrared light transmitting sector 3d is constructed to have an opaque
region 3d' to face the sector 2b of the light incidence end of the light
guide 2 when the sector 3d is placed in a light path; 4 an illumination
lens for projecting onto the object 5 under observation the light-emission
end of the light guide 2 as being the illumination light supply which
consists of a plurality of fine light-emitting members; 6 an objective
lens of the observation optical system for forming the image of the object
5 under observation; and 7 a solid-state image sensor disposed at the
focusing position of the objective lens 6. Numeral 8 represents a
synchronizing circuit; 9 a motor driving circuit for driving a motor M
which rotates the rotary filter 3 in accordance with a control signal
delivered from the synchronous circuit 8; 10 a driving circuit for
actuating the solid-state image sensor 7 based on a control signal
delivered from the synchronous circuit 8; 11 a preamplifier for amplifying
an output signal delivered from the solid-state image sensor 7; 12 a
processing circuit; 13 an A/D converter circuit; 14 a multiplexer; 15 to
18 memories for being inputted with signals allotted, respectively, by the
multiplexer 14 to correspond to the illuminations of red light, green
light, blue light or infrared light emitting in synchronism with the
rotation of the rotary filter 3; 20, 21 and 22 D/A converter circuits,
respectively; 23 a color encoder; 24 a mixing circuit; 25 a color display;
26 a measuring and processing circuit for processing various data such as
determination or identification of the frequency of Moire fringes, removal
of unwanted fringes, and so forth, and for performing image processing; 27
a D/A converter circuit; 28 a projection image processing circuit for
converting that output of the measuring and processing circuit 26 which
has already been converted by the D/A converter circuit 27 to an analog
signal into a compound projection image signal; and 29 a color display for
indicating a contour image of the object 5 under observation as depicted
by Moire fringes in accordance with the signal coming from the projection
image processing circuit 28. The forward end portion of the light guide 2,
the illuminating lens 4, the objective lens 6 and the solid-state image
sensor 7 are housed especially in the foremost end portion of the main
body E of the endoscope.
The embodiment of the present invention is construction as described above.
Therefore, the beam of light emitting from the light supply lamp 1 is
successively converted to a red light, a green light, a blue light and an
infrared light along with the rotation of the rotary filter 3 driven by
the motor M, to illuminate the object 5 of observation via the light guide
2 and the illuminating lens 4. It should be noted. however, that the beam
of infrared light which is transmitted through the rotary filter 3 when
the infrared light transmitting sector 3d of the rotary filter 3 is
inserted in the path of light will enter into the light guide 2 only
through the light-incidence end 2a thereof. Therefore, the infrared light
beam will emit at the light-emission end of the light guide 2 through
every other row of optical fibers. Thus, the object 5 under survey will be
illuminated with stripes or fringes. On the other hand, when either one of
the other light-transmitting sectors of the rotary filter 3, i.e. either
the red light transmitting sector 3a, the green light transmitting sector
3b or the blue light transmitting sector 3c, is inserted in the path of
light beam, it will be noted that the red light, the green light or the
blue light which has transmitted through the rotary filter 3 will enter
the light guide 2 through both of the light-incidence ends 2a and 2b of
the light guide 2, and as a result the light beam will emit through the
entire output region of the light-emission end 2c of the light guide 2.
Accordingly, the object 5 under observation is illuminated uniformly. The
light reflected from the illuminated object 5 under survey is thus focused
on the solid-state image sensor 7 by the focusing lens 6. This solid-state
image sensor 7 is actuated by the driving circuit 10 in synchronism with
the rotation of the rotary filter 3 based on a control signal delivered
from the synchronous circuit 8, and output signals of the image of the
object produced by the red light, the green light, the blue light and the
infrared light, successively. These signals which are outputted are
amplified by the preamplifier 11 and are processed by the processing
circuit 12, and they are converted to digital signals by the A/D converter
13, and these digital signals are allotted to respective memories 15 to
18, respectively, by the multiplexer 14. That is, the image signal
produced by the red light is inputted to the memory 15; the image signal
developed by the green light is inputted to the memory 16; the image
signal formed by the blue light is inputted to the memory 17; and the
image signal caused by the infrared light is inputted to the memory 18,
respectively. Those image signals due to the red light, the green light
and the blue light which have been stored in the memories 15, 16 and 17,
respectively, are read out simultaneously by the timing signal coming from
the synchronous circuit 8, and are converted to analog signals by the D/A
converter circuits 20, 21 and 22, respectively, and are supplied to the
color encoder 23, where video signals are produced. These video signals
are supplied further to the mixing circuit 24 where they are added with a
synchronous signal delivered from the synchronous circuit 8 to thereby
become a compound projection image signal to be displayed on the color
display 25. Also, the image signal due to the infrared light, which has
been stored in the memory 19, is first processed by the measuring and
processing circuit 26, and thereafter it is converted to an analog signal
by the D/A converter circuit 27, and is supplied to the projection image
processing circuit 28 where the signal is provided with a synchronous
signal coming from a synchronous circuit 8. It should be noted here that,
in case there is the need to superpose an ordinary image onto the image
which may, for example, be of a contour pattern obtained from the
measuring and processing circuit 26, said signal is made into a compound
projection image signal which is produced by mixing the image signal with
a signal coming from the color encoder 23, and this compound projection
image signal is displayed by the color display 29 such as CRT.
The method of obtaining a contour image by processing image data stored in
the memory 18 has already been put to practice and is known from, for
example, Yatagai et al's Opt. Eng. 21 (1982) 901, and 21 (1982) 432 of
same and also 23 (1984) 401 of same, and accordingly, its detailed
explanation is omitted.
Now a brief description will be provided of the principle that the
concavo-convex (i.e. uneven) surface of the object can be ascertained by
Moire fringes or stripes. The method employed in the present invention is
called the projection method. As shown in FIG. 4, lattice P.sub.1 is
projected onto an object O through a lens L.sub.1 to form the image of the
object O by a lens L.sub.2, so that this object image is observed through
a lattice P.sub.2. The image of the lattice P.sub.1 projected onto the
object O deforms in accordance with the concavo-convex (uneven) pattern of
the surface of the object O, and Moire fringes are formed between the
image of this deformed lattice P.sub.1 and the lattice P.sub.2. To make
the explanation simple, let us here suppose that the projection lens
L.sub.1 is the same as the focusing lens L.sub.2, and that the lattice
P.sub.1 is same as the lattice P.sub.2, respectively. Then, as shown in
FIG. 5, it is assumed that the distance between the lattice and the
principal point of the lens facing the lattice is assumed to be a, the
distance between the principal point of the lens and the reference point
(to be determined appropriately) at the surface of the object O to be l,
the distance between the principal points of the respective lenses to be
d, the focal distance of respective lenses to be f, the pitches of the
respective lattices to be S, and the frequency of Moire fringes to be N.
Then, the depth of the N-th Moire fringe as counted from the reference
point will be given by:
##EQU1##
In this way, it is possible to know the concavo-convex (uneven) appearance
of a given surface by utilizing Moire fringes. The above-mentioned
calculation is performed by the measuring and processing circuit 26.
Furthermore, by means of the microcomputer which is contained in this
measuring and processing circuit, there is performed the processing of the
signals necessary for the depiction, on the display 29, of such a diagram
pattern as shown in FIG. 6. As will be understood from the above
explanation, the light-emitting end face of the light guide 2 in, for
example, the embodiment of FIG. 1 corresponds to the lattice P.sub.1, and
the light-receiving face of the solid-state image sensor 7 corresponds to
the lattice P.sub.2. Also, an arrangement may be made so that the signals
delivered from the measuring and processing circuit 26 are outputted to
various data terminal devices such as a magnetic disc memory, or to an X-Y
plotter. It should be noted here that the arrangement is provided such
that, at the time of observation utilizing infrared light, there is read
out a signal from picture elements of every other row (see FIG. 7) or
every other column of the solid-state image sensor 7. Accordingly, there
is obtained a contour image formed by Moire fringes in the same way as
that obtained when the object 5 under survey is observed via the lattice
having a pitch representing the width or distance between the rows of
picture elements of the solid-state image sensor 7. For this reason,
either by providing a gating circuit 30 at the output portion of the
solid-state image sensor 7 as shown in FIG. 8, and by alternately
switching this circuit 30 to "on" and "off" in synchronism with the
driving pulses of the driving circuit 10 of the solid-state image sensor
7, or by reading out signals from the memory 18 in correspondence to the
outputs of the image elements of every other row or column of the
solid-state image sensor 7, or by performing image processing by the
measuring and processing circuit 26, there are read out signals delivered
from the picture elements of every other row or column of the solid-state
image sensor 7. Furthermore, in the case of the solid-state image sensor
of the interlacing type, it is possible to easily read out signals of
every other row or column by deriving signals of only the first field or
the second field. Also, from the fact that the picture elements themselves
of the solid-state image sensor are arranged in the form of a lattice, it
will be understood that especially in the case of an interline transfer
type solid-state image sensor (see FIG. 9) wherein vertical transfer
registers 32, 32', 32", . . . are arranged between light-sensitive
sections 31, 31', 31", . . . forming non-sensitive zones, it is also
possible to obtain a contour image due to Moire fringes by the output
signals from all the picture elements instead of by the signals from every
other row or column.
FIGS. 10A and 10B show a mechanism for moving an illuminating lens 4 in
such a way that, only when the infrared light transmitting sector 3d of
the rotary filter 3 is inserted in the path of light beam in synchronism
with the rotation of the rotary filter 3, the light-emission end of the
light guide 2 is focused on the object 5 under observation, and that when
the other light-transmitting sectors 3a, 3b or 3c of the rotary filter 3
are inserted in the path of light, the light-emission end of the light
guide 2 is projected as a blurred image onto the object 5 under
observation. Numeral 33 represents a lens frame for supporting the
illuminating lens 4 advanceably and retreatably in the direction of the
optical axis; 34 a spring having its one end fixed to the lens frame 33
for pulling the lens frame 33 in the direction of the arrow; 35 a cam
plate provided on a shaft 36 which is arranged to be brought, by such
means as a worm gear, into engagement with the shaft of the motor M which
is assigned to rotate the rotary filter 3 and which makes one revolution
during one rotation of the rotary filter 3. One end of a rod 37 having its
other end fixed to the lens frame 33 abuts, by means of the spring force
of a spring 34, a cam face 35a of the cam plate 35. The cam face 35a is
constructed to have a shape such that, when the infrared light
transmitting sector 3d of the rotary filter 3 is inserted in the path of
light, the rod 37 is brought into contact with the larger-diameter portion
35a' extending through about 90 degrees of the cam face 35a of the cam
plate 35, and that when the other light-transmitting sector 3a, 3b or 3c
is inserted in the path of light, said rod 37 is in contact with the
remainder smaller-diameter portion 35a" of the cam face 35a of the cam
plate 35. It should be understood that, when the rod 37 is in contact with
the larger-diameter portion 35a' of the cam face 35a, the illuminating
lens 4 is at a position of focusing the light-emission end of the light
guide 2 on the object 5 under observation. In case, however, the rod 37 is
abutting the smaller-diameter portion 35a" of the cam face 35a, the
illuminating lens 4 is located at a position closer to the light-emission
end of the light guide 2, so that the light-emission end of this light
guide 2 is projected, as a blurred image, onto the object 5 under
observation. Thus, in case of illumination by red light, green light or
blue light, it will be noted that, among the core and clad which
constitute the individual optical fibers of the light guide 2, only the
core will illuminate, so that the mesh-like illumination which can be
produced when the light-emission end of the light guide 2 is focused on
the object 5 under survey is eliminated due to blurring. In case of
illumination by infrared light, however, the light-emission end of the
light guide 2 is clearly focused in a stripe pattern on the object 5 under
examination.
FIGS. 11A and 11B show a second embodiment of the present invention.
Numeral 40 represents an LED array (see FIG. 11B) consisting of
successively arranged rows R, G, B and I of LEDs (which may be
semiconductor laser, for example) emitting red light, green light, blue
light and infrared light, respectively, at the position of the
light-emission end of the light guide 2, in place of the light supply lamp
1, the light guide 2 and the rotary filter 3 which are employed in the
embodiment of FIG. 1. The remains arrangement of this second embodiment is
similar to that of the embodiment of FIG. 1. According to this
arrangement, the rows of LED array are lighted up successively in the
order of R, G, B and I by a driving circuit 41 based on a control signal
delivered from the synchronizing circuit 8, whereby there can be performed
face-after-face type image-pickup operation. In this case also, if an
arrangement is provided so as to move the illuminating lens 4 in the same
way as in FIG. 10, it will be understood that, in case of illumination by
red light, green light or blue light, the object 5 under observation will
be illuminated substantially uniformly due to blurring. It should be noted
here that an arrangement may be provided so that the signals from the
solid-state image sensor are read out for example once every two rows or
three rows in accordance with the time intervals of emission of light from
the LEDs.
FIGS. 12A, 12B, 12C and 13 show a third embodiment of the present
invention. In place of the rotary filter 3 employed in the embodiment of
FIG. 1, there is disposed an infrared light cutting filter 50 (FIG. 12A)
in the foreground of the light-emission end 2b of the light guide 2. Also,
a color-separating stripe filter 51 (FIGS. 12B and 12C) is disposed in the
foreground of the solid-state image sensor 7, so that visible light
impinges onto the two light-incidence ends 2a and 2b of the light guide 2,
whereby the light emits through the entire region of the light-emission
end of the light guide 2 to illuminate the object 5 under survey. However,
infrared light enters only through the light-incidence end 2a of the light
guide 2 due to the function of the infrared light cutting filter 50, so
that the light emits through the light-emission end of the light guide 2
at every other row of optical fibers to illuminate the object 5 under
survey in a stripe pattern. The image of the object 5 under observation
thus illuminated is focused on the solid-state image sensor 7 by the
objective lens 6. The output signal of the solid-state image sensor 7 is
amplified by the preamplifier 11, and it is converted to a digital signal
by the A/D converter circuit 13, and thereafter it is distributed into
image signals produced by red light, green light, blue light and infrared
light, respectively, as allotted by the multiplexer 14, as shown in FIG.
13. After these respective signals are processed by the processing circuit
12', the image signals produced by red light, green light and blue light
are converted to analog signals by the D/A converter circuits 20, 21 and
22, respectively, and they are supplied to the color encoder 23 whereby a
video signal is formed. This video signal is supplied to the mixing
circuit 24 to become a compound image projection signal. By this image
projection signal, a color projection image is presented on the color
display 25. Also, the infrared light is processed by the measuring and
processing circuit 26, and thereafter it is converted to an analog signal
by the D/A converter circuit 27, and then it is converted further to a
compound image projection signal by the projection image processing
circuit 28 to present a contour image on the color display 29. It should
be understood here that the stripe filter 51 requires that the sector I
intended to transmit infrared light to be of lattice form. With respect to
the sectors R, G and B which transmit red light, green light and blue
light, respectively, they may be formed in mosaic pattern instead of
lattice form. In such a case, however, the color-separating circuit will
need some modification in its arrangement.
In the above-state description, in the first and second embodiments, the
observation by utilizing Moire fringes employs infrared light. It should
be understood, however, that in place of infrared light, there may be used
visible light such as red light, green light and blue light. Also, in the
respective embodiments stated above, it is also possible to use invisible
light such as ultraviolet light in place of infrared light.
In the above-mentioned description, the principle of the present invention
has been stated with respect to endoscope. It should be understood,
however, that this principle is not limited thereto, but it can be applied
also to optical instruments which perform Moire topography.
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