SU1190331A1 - Device for checking inhomogeneities of planar optical waveguide - Google Patents

Abstract

A DEVICE FOR THE CONTROL OF THE INHOMOGENEALITY OF THE PLANAR OPTICAL WAVEGUIDE, containing a radiation source, a collimator, a trihedral prism, the collimator being installed between the radiation source and the prism axis perpendicular to the pattern, in order to reduce the figure. in the form of a series of transparent elements, and a transparent plate with parallel scattering surfaces made on one side with a width and pitch equal to but the width of the gap and pitch between the transparent elements of the radiation separator, the radiation separator is installed between the collimator and the prism parallel to its edge, and the plate is attached to the base of the prism and set by Wlen by light-scattering strips sl along the projections of the axes of the transparent elements of the separator on the base of the prism with offset strips from these axes by half a step. Si e OE co

Description

I The invention relates to integrated optics and can be used in production lines for the manufacture of planar optical waveguides. The purpose of the invention is to reduce the control time. The drawing shows a diagram of the device. The device comprises a laser I, a collimator 2, a laser radiation separator 3, a triangular prism 4, and a transparent plate 5. The position 6 denotes a controlled plenary optical waveguide. The collimator 2 is made, for example, of cylindrical lenses. The separator 3 is made, for example, in the form of a number of point-shaped diaphragms or in the form of a holographic plate. In the latter case, a thick-layer hologram of point sources located regularly in one row is recorded on the holographic plate. Then when a visible laser radiation falls on it and when using an electro-optical converter and an invisible range, secondary radiation will be restored as a series of sources of collimated radiation . The prism 4 has a refractive index greater than the refractive index of the waveguide layer of the controlled waveguide 6. The transparent plate 5 is made of an optically transparent material, such as glass, with a refractive index less than that of the waveguide layer 312 of the waveguide 6. The strips on its surface are parallel to each other. using a luminescent paint or cutter. The plate is installed with stripes to the waveguide. The device works as follows. The laser radiation, the optical block 2 and the separator 3, pass in the form of parallel beams by inputting the 1st prism D excites a controlled waveguide 6. As a result, many parallel beams pass through the waveguide. The strips are oriented so that, in the absence of defects in the waveguide, the rays in it pass between the strips, without causing any luminescence. If there is a defect that causes a curvature of the trajectory of a beam, this beam falls on the boundary of the waveguide with a light-scattering strip, which causes a glow in this place. In the case of a scattering defect, luminescence is observed both directly in the defect and from rays scattered by the defect and then intersecting with the stripes. During control, the waveguide is installed, if necessary, in different positions relative to the strips, for example, with a shift perpendicular to the strips relative to the first position of the waveguide by half a step between the strips, etc. The device allows to drastically reduce the monitoring time, since in one act of monitoring a vast area of the waveguide is covered.

Claims (1)

DEVICE FOR CONTROL OF INHOMOGENEITIES OF A PLANAR OPTICAL WAVEGUIDE, containing a radiation source, a collimator, a trihedral prism, the collimator being installed between the radiation source and the prism axis perpendicular to its diagonal face, so that it introduces into it to reduce the monitoring time a radiation separator made in the form of a series of transparent elements, and a transparent plate with parallel light-scattering reparations made on one side of it with a width and pitch equal to respectively the gap and the step between the transparent elements of the radiation separator, while the radiation separator is installed between the collimator and the prism parallel to its edge, and the plate is docked to the base of the prism and installed with light-scattering strips along the projections of the axes of the transparent elements of the separator on the base of the prism with the strips shifted by half step. SU, .., 1190331 I 1 190331