RU1795537C - Dispersing delay line on acoustic surface waves - Google Patents

Description

fi of the acoustic signal reflected by this element (bt Va / 2fi).

One of the gratings 6 of the inclined reflective elements and one of the dispersion gratings 8 are placed in the first 2 acoustic channel, and the second gratings, 7 and 9, respectively, in the second acoustic channel 3. The gratings 6 and 7 of the inclined reflective elements are located opposite each other. The input converter SAW 4 is placed between the grating of the inclined reflective elements 6 and the dispersion grating 8. The output converter 5 is, respectively, between similar gratings 7 and 9. The inclined reflective elements of the gratings 6 and 7 and the reflective elements of the dispersion gratings 8 and 9 are divided in length by two parts, respectively, 10, 11 and 12, 13, mutually offset along the acoustic channels 2 and 3 by a distance equal to the width of the corresponding reflective element, i.e. bi and ak, respectively.

The drawing shows the design of a DLS on a SAW for generating a LFM-down signal, in which the pitch of the gratings 6 and 7 of the inclined reflective elements, as well as the dispersion gratings 8 and 9, increases in the direction from the converters 4 and 5.

In the signal conditioning mode, the proposed DLZ operates as follows.

A short pulse is applied to the input converter 4, the spectrum of which contains, in particular, all frequencies in the passband: DLS. The acoustic wave emitted by the input transducer 4 propagates along the working surface of the sound duct 1 in the first acoustic channel 2 to both sides of the transducer 4 and reaches the reflective elements of the gratings 6 and 8. The tilted reflective elements of the grating 6 enter the acoustic wave of the reflector at an angle 90 ° from its mutually displaced parts 10 and 11 in antiphase and does not enter the reflective elements of the grating 7.

An acoustic wave entering the reflective elements of the dispersion grating 8 is reflected from its mutually displaced parts 12 and 13 in the form of acoustic waves, respectively. AI and Ar, which again arrive at input converter 4. The quarter-wave displacement of parts 1-2 and 13 causes the acoustic waves AI and A2 to be in antiphase and not to direct on the busbars of the input signal converter 4. The passage further to the inclined reflective elements of grating b, the antiphase waves AI and A2, are reflected, respectively, from parts 10 and 11 of this grating and, having received an additional relative half-wave phase shift, arrive in the form of syn. phase acoustic waves on the inclined reflective elements of the grating 7. Mutual, half-wave displacement of the parts 10 and 11 of these elements leads to the fact that from the grating 7 in the direction of the output transducer 5 propagates two antiphase acoustic waves Az (reflected from parts 10 / and A4 / reflected from parts 11). When entering the output transducer 5, these two waves are not induced on its electrical buses of the output signal. Passing further onto the reflective elements of the dispersion grating 9, the Az waves are reflected from the mutually displaced parts 12 and 13 of this grating, an additional half-wave phase shift is obtained, and they are in phase fed to the output transducer 5, where they are converted into an electrical signal.

The design of the dispersion delay line makes it possible to obtain large values of the dispersion delay time without increasing the size of the sound pipe.

Significantly lower insertion loss of the proposed DLZ is due to the absence of inevitable losses inherent in the prototype (at least 12 dB) associated with partial reflection of the acoustic wave to the sides of the substrate.

SUMMARY OF THE INVENTION A surface acoustic wave (SAS) dispersion delay line comprising a sound pipe. on the working surface of which there are surfactant input and output transducers placed in parallel acoustic channels, two gratings of counter-inclined reflective elements, one of which is located in the first and the other in the second

acoustic channels opposite each other, and two dispersion gratings of reflective elements perpendicular to the longitudinal axes of the acoustic channels, one of which is located in the first and the other in the second acoustic channels, and the reflective elements of the dispersion grating placed in the first acoustic channel are separated by two parts long, mutually offset along the acoustic channel by

a distance equal to the corresponding width into two parts, mutually offset by a reflecting element, inclusive along this channel, inclined reflective so that, in order to reduce the introduced elements of the grating placed in the second loss, each surfactant transducer is sized by an acoustic-acoustic channel, divided by length into chips between the corresponding grating into two parts, mutually displaced along this acoustical reflective elements of the true channel, the displacement of the dispersion grating being reflective elec The first reflective element of any of the dispersion grating portions of the placed grating is equal to the width of the corresponding reflection in the second acoustic channel, separated by the element.