RU173159U1 - Optical attenuator - Google Patents

Abstract

The utility model is intended to create the necessary optical signal attenuation in optical channels for adjusting the multi-channel optical information transmission system. The adjustable optical attenuator contains a transmitting monofilament fiber, a collimating gradient cylindrical lens (GTL), a receiving (focusing) GTL, a receiving monofilament fiber, a round opaque screen, a worm, and a worm wheel. The technical result is an increase in reliability, smoothness of attenuation control in the range of transmission coefficients from 0 to 1. 1 ill.

Description

An adjustable optical attenuator is designed to create the necessary optical attenuation of signals in the optical channels for adjusting the multi-channel optical information transmission system. The closest in technical essence to a utility model is an optical attenuator [Butusov MM, Galkin SL, Orobinsky SP, Pal B.P .; Under the total. Ed. M.M. Butusov. L .: Mechanical engineering. Leningra. Separation, 1987, p. 328, (p. 278)] containing a transmitting monofilament fiber, a collimating gradient cylindrical lens (GTL), a filter focusing the GTL, a receiving monofilament fiber. The disadvantage of this optical attenuator is the inability to smoothly adjust the transmission coefficient.

The technical result is an increase in reliability, smoothness of attenuation control in the range of transmission coefficients from 0 to 1.

To achieve this technical result, an optical attenuator comprising a transmitting monofilament fiber, a collimating gradient cylindrical lens (HLC), a focusing HLC, a receiving monofilament fiber, the transmitting monofilament fiber is located in the focus of the collimating HLC, the focusing HLC is aligned with the focusing HLC in the end face of the receiving monofilament fiber is located, characterized in that an additional round opaque screen, a worm wheel are introduced therein, a worm, and in the gap between the collimating and focusing GTsL, there is a circular opaque screen connected in plane with the worm wheel, which is driven by the worm, and the geometric center of the screen is offset from the center of rotation of the wheel by the amount of eccentricity ε.

The utility model is characterized by the following drawing: a functional diagram of an optical attenuator is shown.

The optical attenuator includes a transmitting monofilament optical fiber 1 located at the focus of the collimating GCR 2, the focusing GTsL 3 is located coaxially with the collimating GTsL 2, the focus of the focusing GTsL 3 has the end face of the receiving monofilament optical fiber 4, and a round non-transparent screen is located in the gap between the collimating and focusing GTsL 5, connected in a plane with the worm wheel 6, which is driven by the worm 7, the geometric center of the screen being offset from the center of rotation of the wheel by eccentricity ε.

Optical attenuator works as follows.

When the worm rotates through the angle ϕ, the worm wheel rotates through the angle α = ϕ / k, where k is the gear ratio of the worm pair. Simultaneously with the wheel, the screen 5 is rotated, which leads to the screening of part of the light flux passing from the GTL 1 to the GTsL 2. With an appropriate choice of the eccentricity value, the degree of overlap depends on the angular position of the screen and can vary from 0 to 1.

Claims (1)

An optical attenuator containing a transmitting monofilament waveguide, a collimating gradient cylindrical lens (GTL) focusing an HLC, a receiving monofilament waveguide, the transmitting monofilament waveguide is located in the focus of the collimating GTsL, the focusing GTsL is aligned with the collimating GTsL, in the focus focusing receiver characterized in that an additional round opaque screen, a worm wheel, a worm are introduced into it, moreover, in the gap between the collimating and the focusing GCR is a circular opaque screen connected in plane with a worm wheel mounted for rotation by means of a worm, and the geometric center of the screen is offset from the center of rotation of the wheel by the amount of eccentricity ε.

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