WO2010120257A1 - Optical light modulator - Google Patents

Abstract

The invention is used for controlling light beams in optical logic elements, optical computers, optical fibre lines, Q-switches and integrated optics devices. The optical light modulator is in the form of an optical fibre consisting of a core and a cladding that contains photochromic substances. The technical advantages are high reliability, a simple design, low manufacturing costs and high immunity to interference during operation in an electrically conductive medium or in strong electric fields. The device can also be operated using natural sources of light.

Description

 OPTICAL LIGHT MODULATOR

FIELD OF THE INVENTION

The invention relates to devices for controlling the parameters of light coming from an independent light source, and can be used to create optical logic elements for controlling light fluxes in optical computers, fiber optic lines, laser shutters, integrated optics devices.

State of the art

Known electro-optical light modulator, the operation of which is based on a change in light intensity at the output of the waveguide channel implanted in lithium niobate, when the control voltage at its electrodes changes. In addition, each waveguide channel is an electro-optical system that uses the electro-optical effect in lithium niobate, i.e., the appearance of optical anisotropy in a transparent isotropic dielectric when it is placed in an external electric field. When a control voltage is applied between the contacts, voltage is applied to the corresponding electrodes, which leads to the fulfillment of the conditions of total internal reflection in the waveguide channel. In this case, at the output of the waveguide channel, we obtain a luminous flux proportional to the luminous flux at its input. The coefficient is proportional

ι depends on the value of the applied voltage between the control electrodes, [see application of Russia Ns 2109313, class G02F 1/035, published on 04/20/1998].

The disadvantage of this modulator is its high cost, determined by both the high cost of the lithium niobate crystal and the complexity of the technology for creating implanted layers.

Known optical modulator, consisting of two optical fibers, the end surfaces of which are located at a small distance from each other, and between the end surfaces there is a transparent material that changes the refractive index when exposed to vibration. Luminous flux from one optical fiber to another enters, passing through this transparent material. A change in the refractive index of a transparent material leads to a change in the length of the optical path that the light flux passes when passing from one optical fiber to another. When exposed to vibration, part of the light flux, reflected from the end surfaces of the optical fibers, is superimposed on the main light flux, as a result of which light interference occurs. At the output of the second optical fiber, a modulated luminous flux is formed proportional to the luminous flux in the first optical fiber, and the proportionality coefficient depends on the parameters of the acting vibration. To create vibration, it is proposed to cover one or both ends of the optical fibers with a dielectric material and use the electro-optical effect or the piezoelectric effect, [see US patent Ne 4307937, class G02F 1/01, published 29.12. 1981]. The disadvantage of such an optical modulator is the design complexity, the use of a device that provides vibration on the path of the light flux, as a result of which the light flux passes through additional obstacles, which are the connections of the surface of the optical fiber and the dielectric coating, the connection of the dielectric coating and transparent material, which is accompanied by optical losses.

The closest in nature and effect, which is achieved, and adopted as a prototype, is an optical fiber containing a core and a sheath [see Ukrainian patent Ns 32816 A, according to class G02B 6/02, published on 02.15. 2001].

The disadvantage of the prototype is that the optical fiber cannot be directly used to modulate the light passing through this optical fiber.

The basis of the invention is the task of creating an optical light modulator having a simple design and low manufacturing cost by changing the design of the optical fiber by introducing photosensitive substances into the optical fiber sheath.

SUMMARY OF THE INVENTION

The problem is solved in that in an optical light modulator, made in the form of an optical fiber containing a core and a shell, according to the proposal, the shell contains photochromic substances.

Due to the introduction of photochromic substances into the optical fiber cladding, it becomes possible by the action of electromagnetic radiation on photo- chromic substances translate them into a photo-induced state, which is characterized by a different absorption spectrum, and thereby, changing the transparency of the shell, violate the conditions of total internal reflection in the optical fiber, and provide direct modulation of the light passing through the optical fiber.

The list of figures illustrative materials

Figure 1 is a design diagram of an optical light modulator.

Description of a preferred embodiment of the invention

The optical light modulator consists of a core 1, a shell 2, particles of a photochromic substance 3, a light source 4, a source of modulating electromagnetic radiation 5. An optical light modulator works as follows.

In the mode when the source of modulating electromagnetic radiation 5 is turned off, the modulating electromagnetic radiation does not act on particles of photochromic substance 3 that are distributed in the shell 2. Particles of photochromic substance 3 do not transform into a photoinduced state and remain unpainted. The transparency of the shell 2 does not change. The light waves from the light source 4, which propagate through the core 1, with full internal reflection penetrate into the shell 2 to a depth of the order of the wavelength. [Physical Encyclopedic Dictionary - M .: Soviet Encyclopedia, 1984. - p. 446, 562]. Light waves from the light source 4 penetrating into the shell 2 to a depth of the order of the wavelength interact with the atoms and molecules of the shell 2, after As a result, at all points inside the transparent shell 2 in the layer of penetration of light waves from the light source 4, secondary light waves are generated. As a result of superposition (superposition) of secondary light waves, a light wave arises, perceived as an unchanged reflected light wave. [P. Feynman. Feynman Lectures in Physics / Per. from English - M .: URSS editorial, 2004. T. 3, chapter 31]. Thus, the conditions of total internal reflection at the boundary of the shell 2 and the core 1 are not violated, and the light from the light source 4 propagates through the core 1 without changing.

In modulation mode, the source of modulating electromagnetic radiation 5 is turned on. Particles of photochromic substance 3, uniformly distributed in the shell 2, under the influence of modulating electromagnetic radiation from the source 5 go into a photoinduced state, characterized by a different absorption spectrum, which is visually perceived as the appearance of a color. [Physical Encyclopedic Dictionary - M .: Soviet Encyclopedia, 1984. - p. 828]. In this case, the transparency of the shell 2 decreases throughout the thickness. The light waves from the light source 4, which propagate in the core 1, with full internal reflection penetrate into the shell 2 to a depth of the order of the wavelength. Light waves from the light source 4, penetrating into the shell 2 to a depth of the order of the wavelength, interact with the atoms and molecules of the shell 2, as a result of which secondary light waves are generated at all points inside the transparent shell 2 in the layer of penetration of light waves from the light source 4. Part of the electromagnetic energy of light waves penetrating the shell 2 is absorbed by particles of photochromic substance 3. As a result of superposition (superposition) of secondary light waves, a light wave arises, perceived as an altered reflected light wave.

Thus, the conditions of total internal reflection at the boundary of the shell 2 and the core 1 are violated, and the light from the light source 4 propagates through the core 1 altered. Depending on the type of photochromic substance, both the intensity and the frequency spectrum of the light from the light source 4 can change. At the output of the optical light modulator, we obtain a luminous flux proportional to the luminous flux at its input. The proportionality coefficient depends on the intensity and other parameters of electromagnetic radiation from a source of modulating electromagnetic radiation 5.

A significant difference of the proposed optical light modulator, made in the form of an optical fiber, is that photochromic substances are introduced into the optical fiber sheath, which makes it possible to use the optical fiber directly to modulate the light passing through this optical fiber.

None of the known light modulators has these properties, since they do not implement the principle of exposure to conditions of total internal reflection in an optical fiber by electromagnetic radiation.

Technical Advantages of the Invention

The technical advantages of the proposed optical light modulator, in which electromagnetic waves are used to simulate light, in comparison with the known light modulators, include simplicity of design and high reliability due to the use of a simple design of optical local. A significant technical advantage is the ability of the proposed optical light modulator to operate in the absence of an electric power source through the use of natural sources of electromagnetic radiation.

The advantages of the proposed optical light modulator also include an extended scope due to the possibility of functioning in an electrically conductive medium, in strong electric fields, in a wide temperature range.

Claims

CLAIM

An optical light modulator made in the form of an optical fiber consisting of a core and a shell, which means that the shell contains photochromic substances.