JPS63234940A - Colorimetric apparatus - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Field of Application) The present invention relates to a color measurement device that is used in combination with an endoscope, for example, to measure the color of a living body such as an organ.

(Prior Art) In recent years, research has been actively conducted on the unique colors of living organisms, such as organs, as observation materials.

In this type of conventional colorimeter, a bundle of optical fibers for transmitting light and a bundle of optical fibers for receiving light are integrally bundled so that these optical fibers are mixed at the tip side, and the transmitting/receiving surface of the end face is Some have a fiber probe with a flat surface.

Then, the transmitting/receiving surface of the fiber probe is pressed in close contact with a subject such as biological tissue, and the light is transmitted from the light transmitting optical fiber bundle to the subject, and the reflected light is received by the light receiving optical fiber bundle. The color of the object is measured from the reflected light.

In addition, since the development of electronic endoscopes equipped with a solid-state imaging device (V camera) at the tip of the scope, it has been possible to
Attempts have been made to measure the chromaticity of organs, etc. using the B signal.

(Problems to be Solved by the Invention) By the way, according to the JIS standard regarding color measurement methods, color measurement is performed using irradiated light in a 45° direction and reflected light in a 90° direction to the object to be measured; Or 45° direction + by the irradiation light in 90° direction? It is specified that colorimetry is performed using 11 reflected lights.

This is a method used to accurately measure the color of a measured object by using specularly reflected light from the surface of the measured object.

However, in a colorimeter equipped with a fiber probe with a flat transmitting and receiving surface, the transmitting optical fiber and the receiving optical fiber are bundled together in a parallel manner.・Because the end surface for receiving light was flat, it was difficult to receive reflected light at an angle close to the above JIS standard with respect to the incident angle of the irradiated light. Because the probe was pressed in close contact with the subject, the state of blood flow on the surface of the subject may change. For this reason, there is a problem in that it is difficult to accurately measure the color of a subject such as a biological tissue.

In addition, in electronic endoscopes that measure chromaticity using the R, G, and B signals of the television signal output obtained from the solid-state imaging device, the solid-state imaging device that is the TV camera is used to measure chromaticity. Since the signal passed through the chromaticity filter is used, there is a problem in that it is difficult to obtain accurate chromaticity values because it is greatly influenced by the characteristics of the device.

The present invention has been made based on the above-mentioned circumstances, and an object of the present invention is to provide a colorimetric device that can accurately and easily measure the color of a living body or the like.

[Structure 1 of the Invention (Means for Solving the Problems) In order to solve the above-mentioned problems, the present invention has a fiber probe equipped with an illumination optical fiber bundle and a light receiving optical fiber bundle. A device that guides the light through the illumination optical fiber bundle and irradiates it onto a subject such as a living body, receives the reflected light with the light-receiving optical fiber bundle, and measures the color of the subject from the reflected light. The illumination optical fiber bundle and the light-receiving optical fiber bundle are formed concentrically with the light-receiving optical fiber bundle at the center, and the irradiation end surface of the illumination optical fiber bundle is formed into a concave tapered surface. However, the light-receiving end face of the light-receiving optical fiber bundle is positioned on the bottom side of the conical recess formed by the concave tapered surface. .

(Function) The illumination optical fiber bundle and the light receiving/outputting optical fiber bundle that make up the fiber pub 1 group are formed concentrically with the light receiving optical fiber bundle on the center side and the illumination optical fiber bundle on the outer periphery. Since the irradiation end face of the optical fiber bundle is a concave tapered surface, most of the irradiation light from the illumination output fiber bundle is irradiated diagonally toward the center of the fiber probe, and the light receiving optical fiber bundle is irradiated diagonally. , a large amount of vertically reflected light from the subject is received. For this reason, the amount of specularly reflected light received by the light-receiving optical fiber bundle is extremely small, and the irradiation angle and reflection angle are approximately close to the JIS color measurement standard.

Furthermore, a space is formed at the tip of the fiber probe by a conical recess formed by a concave tapered surface. Therefore, even if the tip of the fiber probe is brought into close contact with a subject such as a living tissue, changes in the state of blood flow on the surface of the subject are extremely minimized.

Therefore, accurate color measurement can be performed by a relatively simple operation of bringing the fiber probe into close contact with a subject such as a living body.

(Example) Examples of the present invention will be described below with reference to FIGS. 1 to 5. In this embodiment, a fiber probe can be inserted into the forceps port of an endoscope and used in combination with an inner chain.

The configuration of the 1111Q device 2 will be explained first with reference to FIG. 1, starting from the tip of the fiber probe. The fiber probe 1 includes an illumination optical fiber bundle 2 and a light receiving optical fiber bundle 3.
is provided. The illumination optical fiber bundle 2 and the light-receiving optical fiber bundle 3 are formed concentrically with the light-receiving optical fiber bundle 3 at the center, and the peripheral surface of the light-receiving optical fiber bundle 3, that is, both optical fiber bundles 2 A light-shielding coating 4 is provided at the boundary portion of .3, and the outer peripheral surface of the illumination optical fiber bundle 2 is coated with a protective coating 5 that also serves as a light-shielding coating.

The tip of the protective coating 5 protrudes from the end face of the illumination optical fiber bundle 2 by a required length to form a rigid cylindrical portion 5a.
The inner peripheral surface of this rigid cylindrical portion 5a is painted matte black.

The illumination end surface 2a of the illumination optical fiber bundle 2 is formed into a concave tapered surface with a predetermined angle, and the light receiving end surface 3a of the light receiving optical fiber bundle 3 is formed into a conical shape formed by the concave tapered surface. It is located a required distance deep from the bottom of the recess. A light-shielding chamber 6 is formed at the tip of the fiber probe 1 by the rigid cylindrical portion 5a, conical recess, and the like. The outer diameter of the fiber probe 1 is set to a thickness that allows it to be inserted into the forceps port of an endoscope. 7 is a subject such as an organ.・Figure 2 shows the overall configuration of fiber probe 1 and controller 1.
- This shows the appearance of the roller body 8. The fiber probe 1 is branched from the middle into an illumination optical fiber bundle 20 and a light receiving optical fiber bundle 30, and this illumination optical fiber bundle 20
The light-receiving optical fiber bundle 30 is connected to the controller body 8 by a connector, respectively. A display 9 for displaying measured chromaticity values, a chromaticity diagram, etc. is attached to the controller main body 8. Further, inside the controller main body 8, a spectrometer for received reflected light, a light source for illumination, and a data processing section are built in, as described below.

FIG. 3 schematically shows an example of the configuration of a spectrometer. The rear end of the light-receiving optical fiber bundle 30 is rearranged so that the optical fibers are aligned in a line in this spectrometer section.

11 is a lens, 12 is a concave mirror, 13 is a reflective diffraction grating,
14 is a one-dimensional optical sensor.

The reflected light emitted from the l+2'15 surface of the light-receiving optical fiber bundle 30 is converted into parallel light by the lens 11, and the concave mirror 1
After being reflected by 2, the light enters a reflective diffraction grating 13 and is separated into spectra. The separated light is detected by the one-dimensional optical sensor 14 and output as a signal of a spectral reflection spectrum.

FIG. 4 shows an example of the configuration of a light source for illumination.

In FIG. 4, 15 is a diffusion chamber, and the illumination optical fiber bundle 2
0, the light incident surface at the rear end faces the diffusion chamber 15.

Reference numeral 16 denotes a monitoring optical fiber for monitoring the intensity of the light source, and a monitoring photodiode, which will be described later, is disposed on the other end surface of the monitoring optical fiber 16, and the light intensity of the light source is converted into an electrical signal for monitoring. be done.

17 is a pulsed xenon lamp as a light source, and 18 is a light shielding plate. The light shielding plate 18 is provided to prevent the light from the pulsed xenon lamp 17 from directly entering the illumination optical fiber bundle 20. Pulsed xenon lamp 1
The light from 7 is reflected many times on the inner wall surface of the diffusion chamber 15, is diffused, and then enters the illumination optical fiber bundle 20.

FIG. 5 is a block diagram showing an example of the configuration of the data processing section. 19 is a monitor photodiode, 21 is a correction circuit, 22 is an A/D converter, 23 is a memory, 24 is an arithmetic processing unit, and 25 is a processor for controlling these circuit devices.

Data on the spectral reflection spectrum from the one-dimensional optical sensor 14 and a monitor signal from the monitor photodiode 19 are input to the correction circuit 21 . First, the influence on the data value of the spectral reflection spectrum due to fluctuations in the light intensity of the pulsed xenon lamp 17, which is the light source, is corrected. The output from the correction circuit 21 is recorded on a meter 23 via an A/D converter 22. Based on the output from the memory 23, the arithmetic processing unit 24 calculates the X, Y, Z triad values, x, , y chromaticity values, L
Colorimetric values such as 'a'b' chromaticity and l"u"v" chromaticity are measured, and these colorimetric data are displayed as numerical values or as a chromaticity diagram on the display 9 as appropriate. Furthermore, necessary information such as the spectral reflection spectrum is also displayed.

Next, the effect will be explained.

Before the fiber probe 1 is inserted into the forceps port of an endoscope (not shown), it is brought into contact with a standard white plate outside the body, and its reflected light spectrum is recorded in advance on the dial 23 as a reference value. Next, the fiber probe 1 is inserted into the forceps opening and inserted into the test site in the body together with the endoscope.
It comes into contact with surface mucous membranes such as organ 1ia. This contact shields the light-shielding chamber 6 from the illumination light from the endoscope, and then the illumination light from the pulsed xenon lamp 17 is guided through the illumination optical fiber bundle 2 and irradiated onto the subject 7 .

At this time, since the irradiation end surface 2a of the illumination optical fiber bundle 2 is a concave tapered surface, much of the irradiation light is irradiated obliquely toward the center of the fiber probe 1. On the other hand, the light-receiving optical fiber bundle 3 that receives the reflected light from the subject 7 has its light-receiving end face 3a located at the back of the conical recess by a required distance of 7111 from the bottom of the conical recess. The light-shielding coating 4 in the area acts as a slit to produce a collimating effect, and the specularly reflected light from the surface of the object 7 is appropriately prevented from entering, so that the object 7 is on the light-receiving end surface 3a. Most of the light reflected in the vertical direction from the surface mucous membranes of organs etc. is received.

Therefore, the irradiation angle and reflection angle for the subject 7 are:
It is said to be in a state that is almost close to the JIS color measurement standard.

In addition, since the light-shielding chamber 6 space is formed at the tip of the fiber probe 1, changes in blood flow are extremely unlikely to affect the biological tissue ILs where reflected light occurs.
Reflected light from natural organ conditions is obtained.

The reflected light is sent to the spectrometer 6 via the receiving optical fiber bundle 3.
This is converted into a spectral reflection spectrum and input to the data processing section. In the data processing section, the influence on the data value of the spectral reflection spectrum due to fluctuations in the light intensity of the light source is corrected, and the reference value of the reflected light spectrum based on the standard white temporary is calculated from the data value of the spectral reflection spectrum that has been compensated. is subtracted, a required chromaticity value, etc. is calculated, and this is displayed on the display 9.

In this embodiment, the angle of illumination a3 and the angle of reflection with respect to the subject 7 are approximately close to the JIS color measurement standards, and the subject, such as the living body 111n, is color-measured in an extremely natural state. Therefore, accurate chromaticity data etc. can be obtained easily and quickly in parallel with observation using an endoscope.

Effects of the Invention] As explained above, according to the present invention, the illumination optical fiber bundle and the light receiving optical fiber bundle that make up the fiber probe are formed concentrically with the light receiving optical fiber bundle on the center side. However, since the irradiation end surface of the optical fiber bundle on the outer peripheral side is a concave tapered surface, the irradiation light from the illumination optical fiber bundle is irradiated diagonally toward the center of the fiber probe, and the light receiving optical fiber Eventually, a large amount of vertically reflected light from the subject is received, and the amount of specularly reflected light received becomes extremely small. Furthermore, due to the conical concave space formed at the tip of the fiber probe, even if the tip of the fiber probe is brought into close contact with a subject such as a biological tissue, there will be no change in the state of blood flow on the surface of the subject. It becomes extremely small. Therefore, there is an advantage that accurate color measurement can be performed with a relatively slow operation of bringing the fiber probe into close contact with a subject such as a living body.

[Brief explanation of drawings]

1 to 5 show an embodiment of the colorimetric device according to the present invention, in which FIG. 1 is an enlarged vertical sectional view of the tip of the fiber probe, FIG. 2 is an external perspective view of the entire configuration, and FIG. FIG. 3 is a block diagram of the spectrometer section, FIG. 4 is a block diagram of the light source, and FIG. 5 is a block diagram of the data processing section. 1: Fiber probe, 2: Optical fiber bundle for illumination, 2a = Irradiation end face, 3: Optical fiber bundle for light reception, 3a: Light reception end face, 6: Light shielding chamber, 1
3: Reflection type diffraction grating, 17: Pulsed xenon lamp (light source).

Claims (2)

[Claims] (1) It has a fiber probe equipped with an illumination optical fiber bundle and a light receiving optical fiber bundle, and the light from the light source is guided by the illumination optical fiber bundle and irradiated onto a subject such as a living body. An apparatus for receiving reflected light with the light-receiving optical fiber bundle and measuring the color of the object from the reflected light, wherein the illumination optical fiber bundle and the light-receiving optical fiber bundle are centered around the light-receiving optical fiber bundle. The illumination optical fiber bundle has a concentric concentric shape, and the illumination end face of the illumination optical fiber bundle is formed as a concave tapered face, and the light receiving end face of the light receiving optical fiber bundle has a conical recess formed by the concave tapered face. A color measuring device characterized in that it is located on the bottom side of the. (2) The color measurement device according to claim 1, wherein the light-receiving end face of the light-receiving optical fiber bundle is located a required distance deep from the bottom of the conical recess.