The present invention relates to an illuminating optical system mounted to an endoscope apparatus for illuminating an observed region, particularly to an illuminating optical system for an endoscope (hereinafter sometimes referred to as “endoscope illuminating optical system”), having a gradient index lens (GRIN lens) constituted such that a refractive index is increased as being proximate to a center portion from a peripheral portion in a radius direction.
In a background art, according to an illuminating optical system mounted to an endoscope apparatus, there is frequently used a light guide constituted by an optical fiber in which a refractive index of a core is constant regardless of a portion thereof, however, a light guide of this type poses a problem that a luminous intensity distribution characteristic thereof cannot be adapted to an endoscope having a wide angle object lens, that is, an intensity of a light ray emitted to a peripheral portion having a large angle from an optical axis is more attenuated than an intensity of a light ray emitted to a center portion.
For example,
The object lens used in an endoscope is frequently provided with a wide angle in which an angle of view (viewing angle) exceeds 100 degrees (semi angle of view is 50 degrees), in a case of illumination by the above-described luminous intensity distribution, an image at a peripheral field of view region becomes dark and therefore, it is difficult to carry out sufficient observation. Further, although there is also known an illuminating optical system widening an illuminating angle by arranging a concave lens at a front end portion of a light guide, only a light amount at a peripheral portion which is inherently liable to be insufficient is scattered and it is not improved that the light amount of the peripheral portion is smaller than that of a center portion thereof.
On the other hand, there is proposed an endoscope illuminating optical system having a wider angle having a refractive indexes distribution type lens in which a refractive index is increased as being proximate to a center portion from a peripheral portion (refer to JP-A-10-54945).
An object of an illustrative, non-limiting embodiment of the invention is to provide an endoscope illuminating optical system having a gradient index lens capable of illuminating by a sufficient light amount and by a wider angle.
The inventor(s) found that by simply using the gradient index lens, a luminous intensity distribution suitable for an endoscope cannot be achieved such that although a wide range can be illuminated, a light amount at a peripheral portion cannot sufficiently be achieved and in order to achieve a preferable luminous intensity distribution, it is necessary to pertinently set a refractive index distribution, a length in an optical axis direction and the like of the gradient index lens.
According to an illustrative, non-limiting embodiment of an endoscope illuminating optical system of the invention, a refracting index distribution of a gradient index lens, a length in a direction of an optical axis and the like are set to pertinent ranges.
That is, an exemplary endoscope illuminating optical system according to the invention is characterized in an endoscope illuminating optical system including: a light guide; and a gradient index lens having a refractive index distribution n(r) approximately expressed by Condition Equation (1), wherein the gradient index lens illuminates an observed region by light guided by the light guide, and wherein the gradient index lens satisfies Condition Equations (2) and (3):
n(r)=N0(1−(A2r2/2)) (1)
(AR)2≦0.6 (2)
0.5k+0.35≦AL/π≦0.5k+0.65 (3)
wherein N0 designates a refractive index on an optical axis of the gradient index lens; r designates a distance from the optical axis along a radial direction of the gradient index lens; R designates an effective radius of the gradient index lens; L designates a length of the gradient index lens in a direction of the optical axis; A designates a constant coefficient; and k designates a nonnegative integer.
Further, all of units of r, R, L stay the same (for example, when a unit of r is mm, also units of R, L is mm), a unit of A is an inverse of the unit of r, R, L (for example, when the units of r, R, L are mm, the unit of A is mm−1).
According to an endoscope illuminating optical system of the invention, by constituting the gradient index lens to satisfy Condition Equations (2) and (3), a luminous intensity distribution suitable for an endoscope, that is, a luminous intensity distribution capable of illuminating by a sufficient light amount and by a wider angle can be provided.
Therefore, by mounting the system to the endoscope, it is easy to provide a bright image even at a peripheral portion of a field of view region and excellent observation, diagnosis can be carried out.
Reference numerals and signs are set forth below.
1: light guide
2: gradient index lens
2π/A: radius of light ray incident on gradient index lens in parallel with optical axis
θmax: angle relative to optical axis of light ray emitted by widest angle
L: length (in optical axis direction of gradient index lens)
R: effective radius (of gradient index lens)
X: optical axis
An exemplary embodiment of the invention will be explained in details in reference to the drawings as follows.
As shown by
On the other hand, the gradient index lens 2 is constituted such that a refractive index is increased as being proximate to a center portion from a peripheral portion, in detail, a refractive index distribution n (r) thereof is approximately expressed by Condition Equation (1) below.
n(r)=N0(1−(A2r2/2)) (1)
Here, N0 designates a refractive index on an optical axis X, r designates a distance from the optical axis X along the radial direction, A designates a constant coefficient, respectively.
Further, as shown by
(AR)2≦0.6 (2)
0.5k+0.35≦AL/π≦0.5k+0.65 (3)
Here, k designates a nonnegative integer.
According to the gradient index lens 2, light guided by the light guide 1 can illuminate an observed region by a wide angle (an angle θmax (refer to
Further, as a gradient index lens in which a refractive index distribution approximately satisfies Condition Equation (1), for example, Selfoc (registered trade mark) made by Nippon Sheet Glass Co., Ltd. is known. According to a gradient index lens of this kind, as shown by
That is, a light ray incident on a peripheral portion of the gradient index lens in parallel with the optical axis X substantially crosses the optical axis X by ¼ period, passes a peripheral portion on an opposed side by ½ period and passes the original peripheral portion in parallel with the optical axis X after 1 period (2π/A).
According to the gradient index lens 2 of the above-described embodiment, a length L thereof is set to a length proximate to an amount of ¼ period, mentioned above. Thereby, a high intensity light ray incident on the peripheral portion of the gradient index lens 2 substantially in parallel with the optical axis X can be emitted from the light guide 1 having the luminous intensity distribution as shown by
The endoscope illuminating optical system of the invention will be explained further specifically by showing examples as follows. The constitution of the endoscope illuminating optical system according to respective examples shown below is as shown by
All of Examples 1 through 3 are provided with the gradient index lens 2 of the refractive index distribution n (r) in which the constant coefficient A=0.5 (mm−1), the refractive index N0 on the optical axis X=1.8 in Condition Equation (1). Further, the length of L of the gradient index lens 2 is set to a length of 3/16 period of the cosine curve in Example 1, a length of 4/16 period thereof in Example 2 and a length of 5/16 thereof in Example 3, respectively. Further, the effective radius R of the gradient index lens 2 is set to 1.0 (mm) in all the examples.
All of the gradient index lens 2 of Examples 1 through 3 satisfies Condition Equation (2) and (3) (in correspondence with a case of k=0, which stays the same in Examples 3 through 15 as follows).
Example 1: (AR)2=0.25, AL/π=0.375
Example 2: (AR)2=0.25, AL/π=0.5
Example 3: (AR)2=0.25, AL/π=0.625
Further, AL/π is a value calculated by constituting a length of one period by 2π/A. For example, in Example 1, L=( 3/16)×(2π/A) and therefore, AL/π=( 3/16)×2.
Further, as shown by
Further, an upper limit value 0.65 and a lower limit value 0.35 of Condition Equation (3) are set to include respective values 0.625 and 0.375 of AL/π of Examples 1, 3 centering on a value 0.5 of AL/π of Example 2.
Further,
Example 4 is provided with the gradient index lens 2 of the refractive index distribution n (r) in which the constant coefficient A=0.5 (mm−1), the refractive index on the optical axis X is set to be N0=1.5 in Condition Equation (1). Further, the length L is set to L=2.5 (mm) and the effective radius is set to R=1.0 (mm).
The gradient index lens 2 of Example 4 satisfies Condition Equations (2) and (3) as shown below. Further, calculation is carried out by setting π=3.14 (which stays the same in Examples 5 through 15).
Example 4: (AR)2=0.25, AL/π≈0.398
Example 5 is provided with the gradient index lens 2 of the refractive index distribution n (r) in which the constant coefficient is set to A=0.4 (mm−1), the refractive index on the optical axis X is set to N0=1.5 in Condition Equation (1). Further, the length is set to L=3.0 (mm), the effective radius is set to R=1.0 (mm).
Further, Example 6 is set to be the same as Example 5 except that the constant coefficient is set to A=0.5 (mm−1) in Condition Equation (1).
Examples 5, 6 satisfy all of Condition Equations (2) and (3) as follows.
Example 5: (AR)2=0.16, AL/π≈0.382
Example 6: (AR)2=0.25, AL/π≈0.478
Example 7 is provided with the gradient index lens 2 of the refractive index distribution n (r) in which the constant coefficient is set to A=0.5 (mm−1), the refractive index on the optical axis X is set to N0=1.6 in Condition Equation (1). Further, the length is set to L=2.5 (mm), the effective radius is set to R=1.0 (mm).
Example 7 satisfies Condition Equations (2) and (3) as follows.
Example 7: (AR)2=0.25, AL/π≈0.398
Example 8 is provided with the gradient index lens 2 of the refractive index distribution n (r) in which the constant coefficient is set to A=0.4 (mm−1), the refractive index on the optical axis X is set to N0=1.6 in Condition Equation (1). Further, the length is set to L=3.0 (mm), the effective radius is set to R=1.0 (mm).
Further, Example 9 is set to be the same as Example 8 except that the constant coefficient is set to A=0.5 (mm−1) in Condition Equation (1).
Examples 8, 9 satisfy all of Condition Equations (2) and (3) as follows.
Example 8: (AR)2=0.16, AL/π≈0.382
Example 9: (AR)2=0.25, AL/π≈0.478
Example 10 is provided with the gradient index lens 2 of the refractive index distribution n (r) in which the constant coefficient is set to A=0.5 (mm−1), the refractive index on the optical axis X is set to N0=1.7 in Condition Equation (1). Further, the length is set to L=2.5 (mm), the effective radius is set to R=1.0 (mm).
Example 10 satisfies Condition Equations (2) and (3) as follows.
Example 10: (AR)2=0.25, AL/π≈0.398
Example 11 is provided with the gradient index lens 2 of the refractive index distribution n (r) in which the constant coefficient is set to A=0.4 (mm−1), the refractive index on the optical axis X is set to N0=1.7 in Condition Equation (1). Further, the length is set to L=3.0 (mm), the effective radius is set to R=1.0 (mm).
Further, Example 12 is set to be the same as Example 11 except that the constant coefficient is set to A=0.5 (mm−1) in Condition Equation (1).
Examples 11, 12 satisfy all of Condition Equations (2) and (3) as follows.
Example 11: (AR)2=0.16, AL/π≈0.382
Example 12: (AR)2=0.25, AL/π≈0.478
Example 13 is provided with the gradient index lens 2 of the refractive index distribution n (r) in which the constant coefficient is set to A=0.5 (mm−1), the refractive index on the optical axis X is set to N0=1.8 in Condition Equation (1). Further, the length is set to L=2.5 (mm), the effective radius is set to R=1.0 (mm).
Examples 13 satisfies Condition Equations (2) and (3) as follows.
Example 13: (AR)2=0.25, AL/π≈0.398
Example 14 is provided with the gradient index lens 2 of the refractive index distribution n (r) in which the constant coefficient is set to A=0.4 (mm−1), the refractive index on the optical axis X is set to N0=1.8 in Condition Equation (1). Further, the length of the gradient index lens 2 is set to L=3.0 (mm), the effective radius is set to R=1.0 (mm).
Further, Example 15 is set to be the same as Example 14 except that the constant coefficient is set to A=0.5 (mm−1) in Condition Equation (1).
Examples 14, 15 satisfy all of Condition Equations (2) and (3) as follows.
Example 14: (AR)2=0.16, AL/π≈0.382
Example 15: (AR)2=0.25, AL/π≈0.478
Further, although according to the above-described respective examples, the gradient index lens 2 corresponds to a case of k=0 in Condition Equation (3), the gradient index lens according to the invention is not limited to correspond to the case of k=0 in Condition Equation (3) but gradient index lenses respectively in correspondence with cases of arbitrary integers of k=1, 2, 3 . . . can be used.
It will be apparent to those skilled in the art that various modifications and variations can be made to the described embodiments of the invention without departing from the spirit or scope of the invention. Thus, it is intended that the invention cover all modifications and variations of this invention consistent with the scope of the appended claims and their equivalents.
The present application claims foreign priority based on Japanese Patent Application No. JP2005-54645, filed Feb. 28 of 2005, the contents of which is incorporated herein by reference.
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Number | Date | Country | |
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