RU2013106340A - METHOD FOR FORMING PERIODIC INTERFERENCE PICTURES AND A TUNABLE TWO-BEAM INTERFEROMETER - Google Patents

Abstract

1. A method of forming periodic interference patterns with a tunable spatial frequency by splitting a collimated light beam into two partial beams and then converting these beams using two mirrors on the photosensitive surface of the recording element at a variable angle of convergence, characterized in that there are two transparent optical elements called the first and second, rigidly dock the first flat surfaces to the beam splitting mirror on both sides, The aforementioned optical elements are made in such a way that their other two flat surfaces, called exit surfaces, are located mirror symmetrically with respect to the beam splitting mirror, the collimated light beam is directed to the beam splitting mirror so that the partial beam reflected from the beam splitting mirror passes through the output surface of the first optical element, and the transmitted through a beam-splitting mirror, the partial beam passed through the output surface of the second optical element, on These partial beams that are emitted establish the two mentioned mirrors motionless and mirror symmetrically with respect to the beam splitter so that the partial beams reflected from them intersect each other, the photosensitive surface of the recording element is placed in the region of intersection of the partial beams with the possibility of moving the recording element along the plane of the beam splitter, the convergence angle set by changing the angle of incidence of the collimated light beam on the beam splitting mirror. 2. Per

Claims (2)

1. A method of forming periodic interference patterns with a tunable spatial frequency by splitting a collimated light beam into two partial beams and then converting these beams using two mirrors on the photosensitive surface of the recording element at a variable angle of convergence, characterized in that there are two transparent optical elements called the first and second, rigidly dock the first flat surfaces to the beam splitting mirror on both sides, The aforementioned optical elements are made in such a way that their other two flat surfaces, called exit surfaces, are located mirror symmetrically with respect to the beam splitting mirror, the collimated light beam is directed to the beam splitting mirror so that the partial beam reflected from the beam splitting mirror passes through the output surface of the first optical element, and the transmitted through a beam-splitting mirror, the partial beam passed through the output surface of the second optical element, on the two partial mirrors that are emitted are fixed and mirror symmetrically with respect to the beam splitting mirror, the two mentioned mirrors so that the partial beams reflected from them intersect each other, the photosensitive surface of the recording element is placed in the intersection of the partial beams with the possibility of moving the recording element along the plane of the beam splitting mirror, the convergence angle set by changing the angle of incidence of the collimated light beam on the beam splitting mirror. 2. A tunable two-beam interferometer, which includes a collimated light beam source sequentially located along the beam, a beam splitting element that divides this beam into two partial beams, two mirrors mounted on the path of the partial beams, and a recording element with a photosensitive surface that is placed in the region of intersection of partial beams, characterized in that the beam splitting element consists of a beam splitting mirror and rigidly docked to it from two sides with the first flat surfaces of two transparent optical elements, the said optical elements are made in such a way that their other two flat surfaces, called output, are mirrored symmetrically with respect to the beam splitter, the two mirrors are fixed and mirror symmetrically with respect to the beam splitter, beam splitter, two the mirrors and the recording element can rotate together relative to the collimated light beam around any axis perpendicular to the plane in which the partial beams are located.