CN214407975U

CN214407975U - Measuring device of lateral optical fiber lens

Info

Publication number: CN214407975U
Application number: CN202120607820.2U
Authority: CN
Inventors: 王正义; 魏鲁明; 侯利平; 吴振英; 张林涛
Original assignee: Suzhou Argus Medical Technology Corp ltd
Current assignee: Suzhou Minimally Invasive Argus Medical Technology Co ltd
Priority date: 2021-03-25
Filing date: 2021-03-25
Publication date: 2021-10-15
Anticipated expiration: 2031-03-25

Abstract

The application discloses measuring device of side direction light fiber lens, including XZ moving platform and XY moving platform, be provided with on the XZ moving platform and rotatably hold the pipe fitting, be provided with the optical detection card on the XY moving platform, the below of optical detection card is provided with the optical power probe, and the height that highly is less than and holds the pipe fitting of optical detection card. The application provides a measuring device of side direction light fiber lens, can measure side direction light fiber lens's light-emitting angle and divergence angle, can rotate fiber lens through holding the pipe fitting, and can adjust fiber lens's position and height through XZ moving platform, thereby change fiber lens light-emitting direction, then utilize characteristics such as high monochromaticity, high directionality of laser, and through optical detection card and optical power probe, fix a position the facula projection placement, measure light-emitting angle, divergence angle.

Description

Measuring device of lateral optical fiber lens

Technical Field

The application relates to the technical field of optical fibers, in particular to a measuring device of a lateral optical fiber lens.

Background

The Optical Coherence Tomography (OCT) is a new Tomography technology with the greatest development prospect in recent years, especially has an attractive application prospect in the aspects of biological tissue biopsy and imaging, has been tried to be applied to clinical diagnosis in the department of cardiology, ophthalmology, dentistry and dermatology, is a great technical breakthrough following X-CT and MRI technologies, and has been rapidly developed in recent years, and an Optical interference Tomography system based on the technology can enable people to obtain ultra-high-definition images with micron-scale spatial resolution. The imaging catheter for scanning of the optical interference tomography system is often based on a side light fiber lens, and meanwhile, the measurement of key indexes such as the light-emitting angle and the divergence angle of the side light fiber lens becomes an important subject in the technical field.

At present, in the prior art, there is no unified measuring device and measuring method related to the light-emitting angle and the divergence angle of the lateral optical fiber lens, so that it is one of the problems to be solved urgently in the field to research a convenient, easy and high-accuracy measuring method and device.

SUMMERY OF THE UTILITY MODEL

The measuring device comprises a light source, a measuring device, a special light detection card, a light source and a light source.

The present application provides the following technical solutions.

The application provides a measuring device of side direction light fiber lens, including XZ moving platform and XY moving platform, be provided with the rotatable pipe fitting that holds on the XZ moving platform, be provided with the optical detection card on the XY moving platform, the below of optical detection card is provided with the optical power probe, just the height of optical detection card is less than hold the height of pipe fitting.

Furthermore, a fixed base is arranged between the XZ moving platform and the XY moving platform, a clamping groove is formed in the fixed base, and the optical power probe is arranged in the clamping groove.

Further, a first end of the optical detection card is fixed on the XY moving platform, and a second end of the optical detection card is positioned above the card slot;

and the XY moving platform is provided with a knob with scales and used for recording the relative distance of the optical detection card moving along the X-axis direction and/or the Y-axis direction.

Further, the optical detection card is a rectangular sheet, a square identification area is arranged at the second end of the optical detection card, and the square identification area is positioned above the card slot; the area of the square identification area is not less than the area of the detection surface of the optical power probe.

Further, the XZ moving platform comprises a fixing portion, a control portion and a lifting portion, the control portion is fixedly arranged on the fixing portion, and the lifting portion is arranged on the control portion in a retractable manner.

Furthermore, the lifting part is provided with scales along the Z axis and used for recording the lifting height of the lifting part.

Further, the top of portion of going up and down is provided with the through-hole, it runs through to hold the pipe fitting the through-hole, just hold the pipe fitting with the portion of going up and down sets up perpendicularly.

Further, the inner diameter of the through hole is larger than the outer diameter of the accommodating pipe fitting.

Furthermore, the lifting part is also provided with a locking piece for locking the accommodating pipe fitting.

Further, the device also comprises a bottom plate, and the XZ moving platform, the XY moving platform and the fixed base are all positioned on the bottom plate.

Furthermore, scales are arranged on the bottom plate and used for recording the relative distance between the XZ moving platform and the XY moving platform on the bottom plate.

The application provides a measuring device measures the measuring method of the light-emitting angle of side direction light fiber lens, including the following steps:

initializing a measuring device, wherein the initial position of the center of the fiber lens is A0(0, 0, Z0);

adjusting the XZ moving platform and/or accommodating pipe fitting to drive the fiber lens to move and/or rotate until the projection of the fiber lens on the optical detection card does not exceed the square identification area and the projection center of the light spot on the optical detection card is positioned at the center O of the square identification area, and stopping adjusting the XZ moving platform and/or accommodating pipe fitting, wherein the position A1 of the fiber lens is at the moment (X1, 0, Z1);

and calculating the light-emitting angle alpha of the fiber lens, namely | arctan (X1/Z1) |.

Further, the initialized measuring device is that an optical fiber is placed in the accommodating pipe fitting, a fiber lens faces the XY moving platform, and the projection of the fiber lens on the optical detection card is located at the center O of the square identification area, and the coordinate of O is (0,0, 0).

The application provides a measuring device for measuring the divergence angle of a lateral optical fiber lens, which comprises the following steps:

adjusting the XZ moving platform and/or accommodating pipe fitting to drive the fiber lens to move and/or rotate until the projection of the fiber lens on the optical detection card does not exceed the square identification area and the projection center of the light spot on the optical detection card is positioned at the center O of the square identification area, and stopping adjusting the XZ moving platform and/or accommodating pipe fitting, wherein the position A1(X1, 0, Z1) of the fiber lens is at the moment;

adjusting the XY moving platform to drive the optical detection card to move along the first direction of the X axis, observing the change of the index P of the optical power probe, and recording the coordinate (X2,0,0) of O at the moment when P reaches the maximum value P1;

adjusting the XY moving platform to drive the optical detection card to move along a second direction of the X axis, observing the change of the index P of the optical power probe, and recording the coordinate (X3,0,0) of O at the moment when P reaches 0.5P 1;

initializing a measuring device;

adjusting the XY moving platform to drive the optical detection card to move along the first direction of the Y axis, observing the change of the index P of the optical power probe, and recording the coordinate (0, Y2,0) of O at the moment when P reaches the maximum value P1;

adjusting the XY moving platform to drive the optical detection card to move along a second direction of the Y axis, observing the change of the index P of the optical power probe, and recording the coordinate (0, Y3,0) of O at the moment when P reaches 0.5P 1;

calculating the divergence angle of the fiber lens:

divergence angle (OX) β ≈ 2 × arctan [ (δ x × cos α)/δ L ];

the divergence angle (OY) γ is 2 × arctan [ (δ y/δ L ];

wherein δ X ═ X2-X3|, δ Y ═ Y2-Y3|, α ═ arctan (X1/Z1) |, δ L ═ Z1/cos α.

initializing a measuring device;

adjusting an XZ moving platform and/or accommodating pipe fittings to drive the fiber lens to move and/or rotate until the projection of the fiber lens on the optical detection card does not exceed the square identification area and the projection center of a light spot on the optical detection card is positioned at the center O of the square identification area, and stopping adjusting the XZ moving platform and/or accommodating pipe fittings, wherein the position A4(X4, 0, Z4) of the fiber lens is at the moment;

adjusting the XY moving platform to drive the optical detection card to move along the first direction of the X axis, observing the change of the index P of the optical power probe, and recording the coordinate (X5,0,0) of O at the moment when P reaches the maximum value P1;

adjusting the XY moving platform to drive the optical detection card to move along a second direction of the X axis, observing the change of the index P of the optical power probe, and recording the coordinate (X6,0,0) of O at the moment when P reaches 0.5P 1;

initializing a measuring device;

adjusting the XY moving platform to drive the optical detection card to move along the first direction of the Y axis, observing the change of the index P of the optical power probe, and recording the coordinate (0, Y5,0) of O at the moment when P reaches the maximum value P1;

adjusting the XY moving platform to drive the optical detection card to move along a second direction of the Y axis, observing the change of the index P of the optical power probe, and recording the coordinate (0, Y6,0) of O at the moment when P reaches 0.5P 1;

calculating the divergence angle of the fiber lens:

the divergence angle (ox) β ≈ 2 × arctan [ (| δ x- Δ x | × cos α)/Δ d ];

divergence angle (oy) γ is 2 × arctan [ (| δ y- Δ y |/Δ d ];

wherein, δ X ═ X1-X2|, δ Y ═ Y1-Y2|, Δ X ═ X5-X6|, Δ Y ═ Y5-Y6|,

Δz＝|Z1-Z4|，Δd＝Δz/cosα，α＝|arctan(X4/Z4)|。

further, the initialization measuring device is to place an optical fiber in the accommodating tube, and a fiber lens faces the XY moving platform, and a projection of the fiber lens on the optical detection card is located at the center O of the square identification area.

Further, the first direction of the X axis is a direction away from the XZ moving platform, that is, the first direction of the X axis is an X axis negative direction; the second direction of the X axis is opposite to the first direction, namely the second direction of the X axis is the positive direction of the X axis;

the first direction of Y axle is the negative direction of Y axle, the second direction of Y axle is the positive direction of Y axle.

The application provides a measuring device of side direction light fiber lens can measure side direction light fiber lens's light-emitting angle and divergence angle, through it can rotate to hold the pipe fitting fiber lens, through XZ moving platform can adjust fiber lens's position and height to change fiber lens light-emitting direction, then utilize characteristics such as high monochromaticity, high directionality of laser, and through optical detection card and optical power probe, fix a position the facula projection placement, measure light-emitting angle, divergence angle.

According to the measuring device and the measuring method of the lateral light fiber lens, the light-emitting angle of the fiber lens does not change along with the side length, and the side length at a far position is measured, so that the influence of measurement errors on measurement results is reduced, and the measurement accuracy of the light-emitting angle and the divergence angle of the lateral light fiber lens is further improved; the light power probe is used, the XZ moving platform and the XY moving platform are matched to measure the size of the light spot, the measurement precision is further improved according to the characteristics of Gaussian beams and the geometric optics correlation principle, the size of the light spot projection on a target detection surface is obtained, and the divergence angle is further calculated.

The measuring device is simple in structure, the measuring method is simple and easy to implement, and the light-emitting angle and the divergence angle of the lateral optical fiber lens can be measured quickly; and the low-cost components are used for replacing high-cost instruments and equipment, and good measurement repeatability is ensured within a certain allowable error range.

Drawings

The drawings are included to provide a further understanding of the application and are not to be construed as limiting the application. Wherein:

fig. 1 is a schematic structural diagram of a measurement apparatus for a side-view optical fiber lens provided in the present application.

Fig. 2 is a top view of the measurement apparatus for a side-view optical fiber lens provided in the present application after initialization.

Fig. 3 is a front view of the measurement device of the lateral optical fiber lens provided by the present application after initialization.

Fig. 4 is a schematic structural diagram of a measurement apparatus of a side-view optical fiber lens provided in the present application in use.

Description of the reference numerals

The optical fiber detection device comprises a 1-optical fiber lens, a 2-accommodating tube body, a 3-optical fiber, a 4-lifting part, a 5-control part, a 6-optical detection card, a 7-fixed base, an 8-XY moving platform, a 9-bottom plate, a 10-clamping groove and an 11-square identification area.

Detailed Description

The following description of the exemplary embodiments of the present application, including various details of the embodiments of the present application to assist in understanding, should be taken as exemplary only. Accordingly, those of ordinary skill in the art will recognize that various changes and modifications of the embodiments described herein can be made without departing from the scope and spirit of the present application. Also, descriptions of well-known functions and constructions are omitted in the following description for clarity and conciseness.

As shown in fig. 1-4, the present application provides a measuring apparatus for a lateral optical fiber lens, which includes an XZ moving platform and an XY moving platform 8, wherein the XZ moving platform is provided with a rotatably accommodating tube 2, the XY moving platform 8 is provided with an optical probe card 6, an optical power probe is provided below the optical probe card 6, the thickness of the optical probe card 6 is not greater than 1mm, and the distance from the lower surface of the optical probe card to the detection surface of the optical power probe is not greater than 0.5mm, so as to improve the measurement accuracy of the spot size, the height of the optical probe card 6 is smaller than the height of the accommodating tube 2, and a limited height difference range is used to ensure that the projection size of the light spot projected by the optical fiber lens 1 on the optical probe card is greater than the step accuracy of the XZ moving platform and the XY moving platform and does not exceed the square area on the probe card. For example, the height difference may be 10mm to 200 mm.

The optical fiber accommodating pipe is characterized in that an optical fiber 3 to be detected can be placed in the accommodating pipe 2, a lateral optical fiber lens 1 is arranged at the end part of the optical fiber 3, the optical fiber 3 penetrates through the accommodating pipe 2, the optical fiber lens 1 extends out of the end part of the accommodating pipe 2, and the optical fiber lens 1 is close to the XY moving platform 8.

In the present application, the X axis is on a straight line (the longitudinal direction of the base plate in fig. 1) where the XZ moving stage, the optical probe card, and the XY moving stage are located, the Y axis is on a straight line (the width direction of the base plate in fig. 1) perpendicular to the X axis on a horizontal plane where the XZ moving stage and the XY moving stage are located, and the Z axis is on a straight line (the height direction of the XZ moving stage) perpendicular to a plane formed by the X axis and the Y axis.

The XZ moving platform can drive the fiber lens 1 to move towards the direction of the X axis or the Z axis.

The XY moving platform 8 can drive the optical detection card 6 to move in the direction of the X axis or the Y axis. And the XY moving platform is provided with a knob with scales and used for recording the relative distance of the optical detection card moving along the X-axis direction and/or the Y-axis direction.

The accommodating pipe 2 can be a hollow cylindrical, prismatic, truncated cone or truncated pyramid pipe.

The fiber lenses 1 in the present application are all lateral optical fiber lenses.

The XZ moving platform and the XY moving platform 8 are both the prior art as long as the functions in the present application can be realized.

A fixed base 7 is further arranged between the XZ moving platform and the XY moving platform 8, a clamping groove 10 is formed in the fixed base 7, and the optical power probe is arranged in the clamping groove 10. The first end of the optical detection card 6 is fixed on the XY moving platform 8, and the second end of the optical detection card 6 is located above the card slot 10. The optical detection card 6 is a rectangular sheet (the thickness is also negligible), a square identification area 11 is arranged at the second end of the optical detection card 6, and the square identification area 11 is positioned above the card slot 10; the area of the square identification area 11 is not less than the area of the detection surface of the optical power probe. The design can ensure that the optical detection card fully shields light from the probe of the power meter, so that the indicated value of the power meter starts from the minimum random value, and the accuracy of the test of the projection size of the light spot is improved.

The XZ mobile platform comprises a fixed part, a control part 5 and a lifting part 4, wherein the control part 5 is fixedly arranged on the fixed part, and the lifting part 4 can be arranged on the control part 5 in a retractable manner. The lifting part 4 is provided with scales along the Z axis and used for recording the lifting height of the lifting part 4. The top of lift portion 4 is provided with the through-hole, it runs through to hold pipe fitting 2 the through-hole, just hold pipe fitting 2 with lift portion 4 sets up perpendicularly. The inner diameter of the through hole is larger than the outer diameter of the receiving pipe 2. The accommodating pipe 2 can rotate in the through hole, so that the optical fiber 3 can be driven to rotate, and the light emitting direction of the optical fiber lens 1 can be changed.

Still be provided with on the lift portion 4 and be used for the closure the card latch fitting that holds pipe fitting 2, when adjusting behind the light-emitting direction of fiber lens 1, can pass through the card latch fitting will hold pipe fitting 2 and pin, thereby it is fixed the light-emitting direction of fiber lens 1.

The measuring device further comprises a bottom plate 9, and the XZ moving platform, the XY moving platform 8 and the fixed base 7 are all located on the bottom plate 9. Scales are arranged on the bottom plate 9 and used for recording the moving distance of the XZ moving platform and the XY moving platform 8 on the bottom plate 9. The bottom plate 9 can be a rectangular plate, and scales are arranged on four edges of the rectangular plate, so that the moving distance can be recorded conveniently.

When the measuring device of the lateral optical fiber lens is used, the measuring device is initialized firstly, and the initialization state of the device is as follows: placing an optical fiber 3 in the accommodating pipe fitting 2, wherein the optical fiber lens 1 faces the XY moving platform 8, the projection of the optical fiber 3 on the optical detection card 6 is coincident with the axial direction of the optical detection card 6, and the projection of the optical fiber lens 1 on the optical detection card 6 is located at the center O of the square identification area 11. Then, the accommodating pipe fitting 2 is rotated to drive the optical fiber lens 1 to rotate, the position and the height of the optical fiber lens 1 can be adjusted by adjusting the XZ moving platform, so that the light emitting direction of the optical fiber lens 1 is changed, and the XY moving platform 8 is adjusted to drive the optical detection card 6 to move towards the direction of the X axis or the Y axis. And then, by utilizing the characteristics of high monochromaticity, high directivity and the like of the laser, positioning a light spot projection falling point and measuring a light-emitting angle and a divergence angle through the optical detection card 6 and the optical power probe.

According to the measuring device of the lateral optical fiber lens, the light-emitting angle of the optical fiber lens 1 does not change along with the side length, and the side length at a far position is measured, so that the influence of measurement errors on measurement results can be reduced, and the measurement accuracy of the light-emitting angle and the divergence angle of the lateral optical fiber lens is further improved; the light power probe is used, the XZ moving platform and the XY moving platform 8 are matched to measure the size of the light spot, the measurement precision is further improved according to the characteristics of Gaussian beams and the geometric optics correlation principle, the size of the light spot projection on the target detection surface is obtained, and the divergence angle is further calculated.

The application provides a first measurement method for measuring the light-emitting angle of a lateral optical fiber lens, which comprises the following steps:

the method comprises the following steps: initializing the measuring device (as shown in fig. 2 and 3), wherein the initial position of the center of the fiber lens is A₀(0，0，Z₀)；

Step (ii) ofII, secondly: adjusting the XZ moving platform and/or accommodating the pipe fitting to drive the fiber lens to move and/or rotate until the projection of the fiber lens on the optical detection card does not exceed the square identification area and the projection center of the light spot on the optical detection card is positioned at the center O of the square identification area (as shown in fig. 4), stopping adjusting the XZ moving platform and/or accommodating the pipe fitting, and at the moment, the position A of the fiber lens₁(X₁，0，Z₁)；

Step three: calculating the light-emitting angle alpha of the fiber lens as | arctan (X)₁/Z₁)|。

In this application, the initialization measuring device is to place the optical fiber in the accommodating tube, and the fiber lens faces the XY moving platform, and the projection of the fiber lens on the optical detection card is located at the center O (0,0,0) of the square identification area.

The application provides a first measurement method for measuring a divergence angle of a lateral optical fiber lens, which comprises the following steps:

the method comprises the following steps: initializing a measuring device, wherein the initial position of the center of the fiber lens is A₀(0，0， Z₀)；

Step two: adjusting the XZ moving platform and/or accommodating the pipe fitting to drive the optical fiber lens to move and/or rotate until the projection of the optical fiber lens on the optical detection card does not exceed the square identification area, and stopping adjusting the XZ moving platform and/or accommodating the pipe fitting when the projection center of a light spot on the optical detection card is positioned at the center O of the square identification area, wherein the position A of the optical fiber lens at the moment₁(X₁， 0，Z₁)；

Step three: adjusting the XY moving platform to drive the optical detection card to move along the first direction of the X axis, observing the change of the index P of the optical power probe, and when P reaches the maximum value P₁Then, the coordinates (X) of O at that time are recorded₂,0,0)；

Step four: adjusting the XY moving platform to drive the optical detection card to move along the second direction of the X axis, observing the change of the index P of the optical power probe, and when the P reaches 0.5P₁When the temperature of the water is higher than the set temperature,record the coordinate (X) of O at this time₃,0,0)；

Step five: initializing a measuring device;

step six: adjusting the XY moving platform to drive the optical detection card to move along the first direction of the Y axis, observing the change of the index P of the optical power probe, and when the index P reaches the maximum value P₁Then, the coordinates (0, Y) of O at that time are recorded₂,0)；

Step seven: adjusting the XY moving platform to drive the optical detection card to move along the second direction of the Y axis, observing the change of the index P of the optical power probe, and when the P reaches 0.5P₁Then, the coordinates (0, Y) of O at that time are recorded₃,0)；

Step eight: calculating the divergence angle of the fiber lens:

divergence angle (OX) beta ≈ 2 × arctan [ (delta)_x×cosα)/δ_L]；

Divergence angle (OY) γ ═ 2 × arctan [ (δ)_y/δ_L]；

Wherein δ X ═ X₂-X₃|，δy＝|Y₂-Y₃|，α＝|arctan(X₁/Z₁)|，δ_L＝Z₁/cosα。

The beam divergence is irregular in nature, and only two specific divergence angle components, ZOX normal vector direction and ZOX normal vector direction, are taken as the study objects.

The second measurement method for measuring the divergence angle of the lateral optical fiber lens provided by the application comprises the following steps:

Step four: adjusting the XY moving platform to drive the optical detection card to move along the second direction of the X axis, observing the change of the index P of the optical power probe, and when the P reaches 0.5P₁Then, the coordinates (X) of O at that time are recorded₃,0,0)；

Step five: initializing a measuring device;

Step eight: adjusting the XZ moving platform and/or accommodating the pipe fitting to drive the optical fiber lens to move and/or rotate until the projection of the optical fiber lens on the optical detection card does not exceed the square identification area, and stopping adjusting the XZ moving platform and/or accommodating the pipe fitting when the projection center of a light spot on the optical detection card is positioned at the center O of the square identification area, wherein the position A of the optical fiber lens at the moment₄(X₄， 0，Z₄)；

Step nine: adjusting the XY moving platform to drive the optical detection card to move along the first direction of the X axis, observing the change of the index P of the optical power probe, and when P reaches the maximum value P₁Then, the coordinates (X) of O at that time are recorded₅,0,0)；

Step ten: adjusting the XY moving platform to drive the optical detection card to move along the second direction of the X axis, observing the change of the index P of the optical power probe, and when the P reaches 0.5P₁Then, the coordinates (X) of O at that time are recorded₆,0,0)；

Step eleven: initializing a measuring device;

step twelve: adjusting the XY moving platform to drive the optical detection card to move along the first direction of the Y axis, observing the change of the index P of the optical power probe, and when the index P reaches the maximum value P₁Then, the coordinates (0, Y) of O at that time are recorded₅,0)；

Step thirteen: adjusting the XY moving platform to drive the optical detection card to move along the second direction of the Y axis, observing the change of the index P of the optical power probe, and when the P reaches 0.5P₁Then, the coordinates (0, Y) of O at that time are recorded₆,0)；

Fourteen steps: calculating the divergence angle of the fiber lens:

divergence angle (ox) beta ≈ 2 × arctan [ (| δ)_x-Δx|×cosα)/Δd]；

Divergence angle (oy) γ ═ 2 × arctan [ (| δ) ]_y-Δy|/Δd]；

Wherein δ X ═ X₁-X₂|，δy＝|Y₁-Y₂|，Δx＝|X₅-X₆|，Δy＝|Y₅-Y₆|，

Δz＝|Z₁-Z₄|，Δd＝Δz/cosα，α＝|arctan(X₄/Z₄)|。

The initialization measuring device is that an optical fiber is placed in the accommodating pipe fitting, an optical fiber lens faces the XY moving platform, and the projection of the optical fiber lens on the optical detection card is positioned at the center O (0,0,0) of the square identification area.

The first direction of the X axis is a direction far away from the XZ moving platform, namely the first direction of the X axis is an X axis negative direction; the second direction of the X axis is opposite to the first direction, namely the second direction of the X axis is the positive direction of the X axis;

The first measurement method (a fiber lens position method) is used for measuring the divergence angle, the operation is simple, and the error of the test system during calculation is directly contained in test data.

The second measurement method (two fiber lens position method) tests the divergence angle, two independent repeated tests are carried out, and the error of the test system can be theoretically counteracted to a certain degree by calculating according to the difference value of test data.

While embodiments of the present application have been described above in connection with specific embodiments thereof, the present application is not limited to the above-described embodiments and fields of application, which are intended to be illustrative, instructive, and not restrictive. Those skilled in the art, having the benefit of this disclosure, may effect numerous modifications thereto and changes may be made without departing from the scope of the invention as defined by the appended claims.

Claims

1. The measuring device for the lateral optical fiber lens is characterized by comprising an XZ moving platform and an XY moving platform, wherein a rotatable accommodating pipe fitting is arranged on the XZ moving platform, an optical detection card is arranged on the XY moving platform, an optical power probe is arranged below the optical detection card, and the height of the optical detection card is smaller than that of the accommodating pipe fitting.

2. The measurement device according to claim 1, wherein a fixed base is further disposed between the XZ moving platform and the XY moving platform, and a slot is disposed on the fixed base, and the optical power probe is disposed in the slot.

3. The measurement apparatus according to claim 2, wherein a first end of the optical probe card is fixed on the XY moving stage, and a second end of the optical probe card is located above the card slot;

4. The measurement device according to claim 2, wherein the optical detection card is a rectangular sheet having a square identification area at a second end thereof, and the square identification area is located above the card slot; the area of the square identification area is not less than the area of the detection surface of the optical power probe.

5. The measurement device according to claim 1, wherein the XZ moving stage comprises a fixed part, a control part and a lifting part, the control part is fixed on the fixed part, and the lifting part is arranged on the control part in a manner of being capable of being lifted and retracted.

6. The measuring device as claimed in claim 5, wherein the lifting part is provided with a scale along the Z axis for recording the lifting height of the lifting part.

7. The measuring device as claimed in claim 5, wherein the lifting portion is provided at a top end thereof with a through hole through which the receiving pipe member extends, and the receiving pipe member is disposed perpendicular to the lifting portion.

8. A measuring device according to claim 7, wherein the through bore has an inner diameter larger than an outer diameter of the receiving tube.

9. The measuring device as claimed in claim 7, wherein a latch for locking the receiving tube is further provided on the lifting portion.

10. The measurement device according to any one of claims 2 to 9, further comprising a base plate on which the XZ moving stage, the XY moving stage, and the fixed base are located.

11. A measuring device according to claim 10, wherein the base plate is provided with graduations for recording the relative distances of the XZ and XY motion stages on the base plate.