SU1670393A1 - Azimuth-indicating device - Google Patents

Abstract

The invention relates to a measurement technique and allows measuring the angle of rotation of an object. The purpose of the invention is to expand the range of measured angles and increase sensitivity. The radiation from the source 1 is passed through an angle sensor 2, made in the form of an anisotropic absorbing dye layer 3 deposited on the substrate 4 and intended for bonding with a controlled object. When the object is rotated, the angle of incidence of the radiation on the anisotropic dye layer changes, as a result of which its radiation absorption coefficient changes. The radiation that passes through the anisotropic layer is received by the receiver 5 and, by changing the magnitude of the signal from the receiver, is judged about the angle of rotation of the object. 5 il.

Description

The invention relates to measurement technology and can be used to measure the angle of rotation of an object in geodesy, navigation, and mechanical engineering.

The aim of the invention is to expand the range of measurable angles and increase sensitivity.

FIG. 1-5 shows the variants of the device construction scheme.

The device comprises a radiation source 1, an angle sensor 2 comprising a layer of anisotropic absorbing dye 3, for example, a Langmuir film of azo dye, a substrate 4 of optical material and a radiation receiver 5 with a processing unit.

The drawings also indicate reflective coatings 6, conductive optical coatings 7 (electrodes), control unit 8, rotation ellipsoid 9, the angle between the direction of radiation and the normal to the angle sensor.

The device works as follows.

The radiation from source 1 is directed to angle sensor 2. The transmitted (Fig. 1, 3) or reflected (Fig. 2, 4, 5) radiation is received by the receiver 5. When the object rotates, the angle 6 changes. The absorption coefficient of the anisotropic layer of dye 3 depends on the angle of incidence of the radiation on the angle sensor, resulting in the intensity of the beam at the input of the receiver 5 changes, by the change of which the value of the angle of rotation of the object is judged.

To increase the sensitivity of the device, the radiation is passed twice (Figs. 2, 5) through the layer of anisotropic dye 3 or repeatedly (Fig. 3), transforming the radiation between reflective coatings deposited on the anisotropic layer of dye, resulting in increased radiation absorption effect and the dependence radiation intensity

WITH

(A SA

passed through layer 3, from the angle 0.

Applying the electrode 3 to the surface of the layer 3 increases the sensitivity of the device. When a variable or frequency-pulse voltage is applied to the source, a variable deformation of the spectral absorption band of dye 3 (Stark effect) occurs, resulting in a periodic change over time. reflected (transmitted) radiation.

The reduction of the dimensions of the angle sensor is implemented using the rotation ellipsoid (Fig. 5) as a transfer system and placing the angle sensor in one of its two foci and the radiation receiver in the other.

Claims (5)

1. A goniometric device comprising successively installed radiation source, angle sensor and radiation receiver with a processing unit, characterized in that, in order to expand the range of measured angles, the angle sensor is made in as a substrate coated with a layer of anisotropic absorbing dye. 2. An apparatus according to claim 1, characterized in that the Langmuir azo dye film is used as the material of the anisotropic layer. 3. The device pop. 1, characterized in that, in order to increase the sensitivity, a reflective coating is applied between the anisotropic layer and the substrate. 4. Device on PP. 1, which is distinguished so that, in order to increase the sensitivity, a reflective coating is applied to another surface of the anisotropic layer and the reflective coatings are displaced one relative to another by the magnitude of the source aperture. 5. The device pop. 1, in order to increase the sensitivity, it is provided with a control unit, and conductive optically transparent coatings electrically connected to the control unit are applied to both surfaces of the anisotropic layer. Sit th Ohno and figure 1 cpueZ  / / / U J 6 fig.Z FIG. four