JPH0789093B2 - Optical connector parameter measurement method - Google Patents

Description

The present invention relates to a method for measuring various parameters of an optical connector used in the field of optical communication using a single mode optical fiber.

(Prior Art) Loss factors of an optical connector are determined by a positional relationship between optical fibers in a pair of connector plugs that are constituent elements of the optical connector. (1) End face spacing z, (2) Tilt angle θ, (3) Axis The difference is d. Conventionally, the parameters of the optical connector have been individually measured by the measuring means as shown in FIGS. In each drawing, 1 is a connector plug, 2 is an optical fiber, 3 is a holder, 4 is a microscope, 5 is a television camera, and 6
Is a monitor TV, 7 is a He-Ne laser, 8 is a screen,
Reference numeral 9 is a light source, 10 is a lens, 11 is a sensor, 12 is an amplifier, and 13 is a digital voltmeter. All of these are premised on a cylindrical connector plug, and all measurements are made by rotating the connector plug 1 in the direction of the arrow as shown in the figure.
FIG. 2 shows a method of measuring the axis shift of the optical fiber 2 in the connector plug 1 by displaying an image of the optical fiber 2 on a monitor television 6 via a microscope 4 and a television camera 5 and measuring from this image. Further, in FIG. 3, laser light from the He—Ne laser 7 is incident on the optical fiber 2 and light emitted from the connector plug 1 is projected on the screen 8. By rotating the connector plug 1, the projection light draws a circle on the screen 8,
Let the radius be r. Connector plug 1 and screen 8
If the distance between and is 1, the angle θ can be calculated by θ = tan ⁻¹ (r / l). FIG. 4 shows a method in which the method shown in FIG. 3 is made electronic, and the sensor 11 instead of the screen 8 is used for detection, and the measurement principle is the same. That is, the light from the light source 9 is incident on the optical fiber 2 via the lens 10, the light emitted from the connector plug 1 is projected on the sensor 11, and the output signal at the circumferential portion of the sensor 11 is supplied to the digital voltage via the amplifier 12. It is sent to the meter 13 and the angle θ is indexed using the indicated value of the digital voltmeter 3.

(Problems to be Solved by the Invention) These methods are useful as methods for measuring the axis deviation and angle of the optical fiber in the connector plug, but (i) rotation is required for measurement, and non-circular cross section is required. Difficult to apply to connector plugs of (ii) axis deviation and angle deviation in the actual connection state,
Furthermore, the distance between the end faces cannot be measured. There was a drawback. For example, an example of a connector plug having a non-circular cross section is shown in FIG. This is a multi-fiber optical connector. 14 is an optical fiber ribbon core wire that accommodates optical fibers of a plurality of cores,
15 is a protective sleeve, 16 is a clamp, 17 is a guide pin, 18
Is the optical fiber to which the connector plug 1 is attached.
With such an optical connector, it is difficult to measure by a conventional method that assumes a cylindrical shape. By measuring the optical connector parameters in the connected state and analyzing the loss factors,
It is possible to reduce the loss of the optical connector. 6 (a) (b)
Shows an example of a state in which the cylindrical connector plugs 1 are connected to each other. 19 is a sleeve. FIG. 6 (a) shows the case where the connector plug 1 has an axis deviation and the end face spacing, and FIG. 6 (b) shows the case where the connector plug 1 has a "C" shape and has an angle deviation. Even if the connection loss is the same in the examples of FIGS. 6A and 6B, the measures for reducing the loss are different. Therefore, separate measurement of the parameters of the optical connector in the connected state is very useful for improving the housing and the connector plug. However, there has been no means for measuring these parameters in the past.

In view of the above problems, an object of the present invention is to provide a simple method for separately measuring the loss factor of a single mode optical connector in a connected state.

(Means for Solving the Problems) In order to solve the above problems, the present invention provides a method for measuring a parameter of an optical connector for connecting a single mode optical fiber, in which a refractive index matching agent is inserted between the end faces of the optical connector. Without the condition, the wavelength characteristic α (λ) of the splice loss is measured, and the wavelength characteristic α ₂ (λ) of the splice loss is measured with the refractive index matching agent inserted between the end faces of the optical connector. The wavelength characteristic ω (λ) of the mode field radius of the used optical fiber is measured to measure the end surface spacing Z, the tilt angle θ, and the axis deviation d of the optical connector.

(Operation) In the present invention, the connection is made by measuring the wavelength characteristic of the splice loss in two states, with and without the refractive index matching agent between the end faces of the optical connector, and the wavelength characteristic of the mode field radius of the used optical fiber. The end surface spacing Z, the inclination angle θ, and the axis deviation d in the state are indirectly measured separately.

(Embodiment) An embodiment of the present invention will be described with reference to FIGS. 1, 7 to 11. FIG. 1 shows an example of a wavelength characteristic measuring system for connection loss. In the figure, the same components as those of the conventional example are designated by the same reference numerals. That is, 1 is a connector plug, 2 is an optical fiber, 9 is a light source, 10 is a lens, 20 is a spectroscope, 21 is a chopper, 22 is a photodetector, and 23 is a lock-in amplifier. The lock-in amplifier 23 is synchronized by the synchronization signal from the chopper 21 and detects the output of the photodetector 22.

In the present invention, as shown in FIG. 7, the wavelength characteristic of the connection loss is divided into the case where the refractive index matching agent 24 is interposed and the case where the refractive index matching agent 24 is not interposed in the end surface distance Z of the pair of connector plugs 1 of the optical connector. taking measurement. The mode field radius ω of the used optical fiber can be conventionally measured by various methods such as a field method and a near field method. FIG. 8 shows an example of the near field method. Reference numeral 25 is a light source, 26 is a vidicon, and 27 is an arithmetic processing circuit.
The wavelength characteristic ω (λ) of the mode field radius can be measured by changing the wavelength of the light.

The measurement principle of the present invention will be described below. If the wavelength characteristic of the connection loss of the optical connector is α (λ), these can be expressed as follows due to each loss factor.

α (λ) = α _d (λ) + α _θ (λ) + α _z (λ)
(1) Each loss is expressed as follows in the analysis of Mr. D. Marcuse described in BSTJ vo156, No.5, P.703 to 718, 1977.

α _d (λ) = 4.343 (d / ω / (λ)) ² (dB) ......
(2) α _θ (λ) = 4.343 (nπθω (λ) / d) ² (dB) ……
(3) However, P = Zλ / (n · 2π · ω ² (λ)),
n is the refractive index of the optical fiber. From these expressions,
It is impossible to separate each factor. The present invention separates each factor based on the following facts. First, the equation (4) is an equation in the case where the refractive index matching is made between the optical fibers, and when air is interposed between the optical fibers, α (λ) = α _d (λ) + α _θ (λ) + α _zp It was noted that (λ) + α _z (λ) (6). Here, except α _zp (λ),
It is the same as the expression (1). α _zp (λ) represents a phenomenon in which periodic peaks and valleys occur in the connection loss due to multiple reflection caused by a slight difference in refractive index at each boundary of the optical fiber-air-optical fiber. Analyzing multiple reflections by approximating normal incidence of plane waves, Becomes R is the reflectance at the boundary, and in this case R = 0.035. Except for α _zp (λ), it does not show periodic _splice loss. _Therefore , from (7), measure the wavelengths that show peaks (or troughs) of splice loss, and let these be λ ₁ and λ ₂ , Interval Z
Is Becomes If there is no periodic splice loss in the measurement range λ _{1 to} λ ₂ , Becomes FIG. 9 shows the measured values of the loss wavelength characteristic of the 5-fiber batch optical connector shown in FIG. 5 in the absence of the index matching agent. From this result, Z is about 3.5 μm according to the equation (8).

From the expression of the equation (6), Z is known. (In the case of the unknown formula (9), it will be described later.) Next, the same loss wavelength characteristic is measured by interposing the index matching agent in the end surface spacing Z. In this case, the loss is expressed by equation (1). If Z is known in the above measurement and ω (λ) is measured in advance, α _z (λ) is known from the equation (4). Therefore,
It is necessary to separate α _d (λ) and α _θ (λ).

Using equations (2) and (3) and using the measured values of ω (λ) and d, θ, Was found to hold. Here, d / dλ represents the derivative with respect to the wavelength.

From this, the connection loss difference Δα between the two wavelengths can be approximated as follows.

Δα≡α (λ ₁ ) −α (λ ₂ ) [α _d (λ ₁ ) −α _d (λ ₂ )] + [α _z (λ ₁ ) −α _z (λ ₂ )] …… (11) α _{Since z} (λ ₁ ) −α _z (λ ₂ ) is known, Δα−
From the value of [α _z (λ ₁ ) −α _z (λ ₂ )], d can be obtained.

FIG. 10 shows the relationship between Δα and d when Z = 3 μm.

This figure shows the case of two types of optical fibers. Next, consider a case where the peaks and valleys are not shown in the wavelength measurement and expressed by the equation (9). In this case, for example, λ ₁ =
If 1.1 μm and λ ₂ = 1.7 μm, then Z <1.56 μm, and for λ _{1 to} λ ₂ , α _z (λ) is 1.8 × 10 ⁻⁴ dB to 4.3.
It is very small at × 10 ^-4 dB, and [α _z (λ ₁ )
Disregarding-[alpha] _z ([lambda] ₂ )] has no effect.

Next, when Z and d are obtained, θ can be obtained from the equations (1) and (3).

From the above measurement principle, in the measurement [corresponding to the equation (6)] when the refractive index matching agent is not used, a certain range (for example, λ ₁ to
It is necessary to measure the splice loss wavelength characteristic of λ ₂ ), but in the measurement using a refractive index matching agent [corresponding to formula (1)], it is understood that splice loss should be measured at least at two wavelengths. . However, the measurement error can be reduced by measuring even two wavelengths or more.

The results measured by the measuring method of the present invention will be described. The five-core collective optical connector shown in FIG. 5 and an ordinary cylindrical single-core optical connector are taken as examples. The optical fiber used is λ =
An optical fiber with zero dispersion at 1.3 μm. The end surface distance Z has already been described with reference to FIG. 9, and therefore the measurement results of the axis deviation d and the tilt angle θ are shown in FIG. 11 using the refractive index matching example. In this example, λ ₁ = 1.3 _μm , λ ₂ = 1.55 _μm
Was measured as Δα. As is clear from this result, each parameter of the optical connector, which could not be measured conventionally, can be measured separately, which can contribute to the improvement of the characteristics of the optical connector. In this measuring method, when Z is extremely small or when d is very small, the numerical value itself cannot be measured, but it can be measured that the values of Z and d are below a certain value. Therefore, it is possible to obtain useful data even if the measurement limit is reached.

(Effects of the Invention) As described above, the present invention has an advantage that the loss factor of a single-mode optical connector can be separately measured in a connected state. Therefore, not only the connector plug of the optical connector but also the housing of the optical connector can be used. It is useful for improvement. Further, the present invention is not limited to the cylindrical connector plug as in the conventional method, and has an advantage that it can be applied to a plug of any shape. Further, there is an advantage that it is simple because no special device is required for measurement.

[Brief description of drawings]

FIG. 1 is a conceptual diagram of a wavelength characteristic measuring system for connection loss according to the present invention, FIGS. 2 to 4 are diagrams showing a conventional method for measuring parameters of an optical connector, and FIG. 5 is a multicore collective optical connector. 6 and 6 are diagrams showing a connection state of a single-core connector, FIG. 7 is a diagram showing a connection state of an optical connector using a refractive index matching agent, and FIG. 8 is an example of a system for measuring a mode field radius. FIG. 9, FIG. 9 and FIG. 10 are diagrams for explaining the measurement principle of the present invention, and FIG. 11 is an explanatory diagram showing the results measured by the measuring method of the present invention. 1 ... Connector plug, 2 ... Optical fiber, 9 ... Light source, 10 ... Lens, 20 ... Spectrometer, 21 ... Chopper, 22
...... Photodetector, 23 ...... Lock-in amplifier, 24 ...... Refractive index matching agent, 25 ...... Light source, 26 ...... Vidicon, 27 ...... Arithmetic processing circuit.

Claims (2)

[Claims] 1. A method of measuring a parameter of an optical connector for connecting a single mode optical fiber, wherein a wavelength characteristic α (λ) of a splice loss is measured with a refractive index matching agent not inserted between the end faces of the optical connector. , Wavelength characteristics of splice loss with a refractive index matching agent between the end faces of the optical connector α
₂ (λ), and further, the wavelength characteristic ω (λ) of the mode field radius of the optical fiber used for the optical connector is measured to measure the end surface spacing Z, the tilt angle θ, and the axis deviation d of the optical connector. An optical connector parameter measuring method characterized by the above. 2. A wavelength characteristic of connection loss, a wavelength characteristic α ₁ (λ), in which a refractive index matching agent is not inserted between the end faces of the optical connector.
At a wavelength of at least two wavelengths λ ₁ and λ ₂ or more, and the connection loss α ₂ (λ ₁ ) and α ₂ (λ ₂ ) and the optical loss when the refractive index matching agent is inserted between the end faces of the optical connector. Mode field radius ω of the optical fiber used for the connector
The optical connector according to claim 1, wherein the end face distance Z, the tilt angle θ, and the axis deviation d of the optical connector are measured by measuring (λ ₁ ) and ω (λ ₂ ). Parameter measurement method.