SU957415A1 - Narrow-band filter using surface acoustic waves - Google Patents

Description

(5) NARROW BAND FILTER ON SURFACE ACOUSTIC WAVES

one

The invention relates to electronics and can be used in acoustoelectronic signal processing devices.

A narrowband filter is known that contains two wideband transducers interconnected and located on opposite sides of the narrowband transducer at equal distances xj.

The disadvantage of this filter is the need to use large-sized sound lines.

The closest to the present invention is a narrow-band surface acoustic wave filter containing a suction duct, an input converter with a duration of half the required impulse response of the filter with the law of electrode overlap corresponding to one of the symmetric halves of the full impulse response of the filter, and broadband

output converters located on either side of the input converter. To form a filter impulse response with a duration of T, there is a gap vm, a duct with a common distance not less than T.V4, where V is the speed of acoustic waves

in the duct; 1 (3 - initial delay between

input and near weekend

converters.

A disadvantage of the known filter is the long length of the acoustic duct due to the need to provide a passive delay between the input and the far output converters of not less than half the duration of the entire impulse response of the filter.

Claims (2)

The purpose of the invention is to reduce the size of the acoustic duct of a narrow-band filter on surface acoustic waves. The goal is achieved by the fact that it is a narrow-band filter on surface acoustic waves containing a duct, an input converter with a duration of half the required impulse response of the filter with the law of electrode overlap corresponding to one of the symmetric halves of the full impulse response of the filter, and wideband output transducers located on both side of the input converter, an intermediate converter, intermediate selective and output selective converter The applicants, while the intermediate transducer is located on the side of maximum overlap of the electrodes of the input transducer at a distance from its edge equal to the distance from its opposite edge to the output transducer, and is connected through an amplifier with an intermediate selective converter located between the intermediate and input transducers , and the output selective converter is set at intervals of half the duration of the required filter impulse response from the intermediate elect Yelnia transducer and electrically connected to the output transducer. FIG. 1 shows a filter block diagram; FIG. 2 - graphs explaining the formation of the impulse response of the proposed filter. The narrowband filter on the SAW contains a chimney 1, an input transducer 2, an intermediate transducer 3 located from the edge of the input transducer 2 on the side of maximum electrode overlap at the same distance tp as the output transducer k, from the opposite edge of the input transducer 2, the amplifier 5 compensating insertion loss, intermediate selective transducer 6, output selective transducer 7 consisting of two identical spaced apart cables and galvanically connected ennyh sections raspolagayuschihs generally acoustic channel at the free portions koprovoda ulcer area on both sides with a small overlap of electrodes symmetrically relative to the longitudinal axis. an input transducer 2 installed at an interval of half the duration of the required impulse response T and galvanically connected with the output transducer, the filter operates as follows. When an electric signal is applied to the input transducer 2 in the form of a short 8-pulse, amplitude-modulated forward and reverse acoustic radio pulses with a duration of half the desired pulse response T of the filter and spatial weight processing, corresponding to the law of electrode overlap, form and propagate in both directions. Reaching through the initial delay time tg of the output transducer k, a direct acoustic radio pulse induces an electrical voltage at its terminals that is proportional to the degree of overlap of the electrode of the input transducer, starting from the area of least overlap, and at a time interval equal to the duration of the T / 2 acoustic radio pulse on the transducer k reception is clocked; 1 and a pulse response hj (t) is formed, equal to half the required value (Fig. 2a). Simultaneously with the start of reception of the forward acoustic pulse by the transducer k, the reverse acoustic pulse is received by the intermediate transducer 3, since the initial delays t of the transducers 3 and 4 from the edges of the input transducer 2 are the same. The signal received by converter 3 is from 1 to 1 at maximum voltage levels corresponding to the area of greatest overlap of the electrodes of input converter 2 and re-emitted preamplified by amplifier 5 to compensate for insertion loss by intermediate selective converter 6 to output selective converter 7. Symmetrical structure of construction is selective and conventional converters provide high electrical isolation between them, since the voltages induced in these metric parts of transducers of one type with transducers of another structure of electrodiode 8, have opposite signs and are compensated at the output terminals of the acoustic pulse re-emitted by the selective transducer 6 after a time interval equal to the delay between the selective acoustic transducers 6 pulse converter 3 reaches the output selective converter 7, and its reception begins with a higher voltage (Fig. 26) corresponding to the maximum overlap of the electrodes of the input transducer 2. Since the delay between the selective transducers 6 and 7 is equal to the input transducer 2, the reception of the reapplied reverse acoustic pulse by the transducer 7 doesn’t kick once at the moment when the reception of the direct acoustic impulse by the output converter. Since the output converters k and 7 are galvanically connected, the resulting output will result in the required impulse response h (t) of the filter with duration T (Fig. 2c). In this case, a conduit with a total length of (T / 2) V 4-2toV3, i.e. shorter than the sound duct of a known filter by the length of the input converter. The proposed narrowband filter on surface acoustic waves allows to reduce the level of diffraction effects, since the maximum propagation length of the acoustic signal with the minimum apertures is halved and the size of the sound cable is reduced. Invention A narrow-band filter on surface acoustic waves, containing an acoustic duct, an input converter with a duration of half the required impulse response of the filter with the law of electrode overlap, corresponding to one of the symmetrical halves of the full impulse response of the filter, and broadband output transducer / m, located on both sides of an input transducer that distinguishes the dimensions of the sound duct; an intermediate converter, an intermediate selective one and an output are inserted into the filter In this case, an intermediate converter is located on the side of maximum overlapping of the electrodes of the input converter, at a distance from its edge equal to the distance from its opposite edge to the output converter, and connected to a measure. An amplifier with an intermediate selective converter located between the intermediate and input transducers, and the output transducer from & transducer is set at an interval of half the duration of the required impulse response ltra from the intermediate pre-forming selectively and electrically connected to the output transducer. Sources of information that are taken into account in the examination 1.M.F, ievls. Triple-transit suppression fn surface-acoustic wave devices. Electrou Letters, 1972, v, J. p. 553-55. MOV 16. 2. Authors certificate of the USSR Vf 585589, M. N 03 N 9/26, 1976 (prototype).