SU649146A1 - Vocoder with two-dimensional filtration - Google Patents

Description

I

The invention relates to communication technology.

A two-dimensional filtering vocoder is known, containing on its non-interrelated side a successively connected spectrum analyzer and a fundamental tone extractor, analyzing a two-dimensional filter and a synchronization unit whose outputs are connected to the control inputs of the first switch and analog-digital converter, and on the receiving side a digital-analog converter synthesizing a two-dimensional filter, a first switch, a speech spectrum generator and a synthesizer sequentially connected, and a synchronization unit whose outputs are key to the control inputs of the first switch, a synthesizer and a digital to analog converter, the other input of which is connected to the input of one sync block.

However, such a vocoder is characterized by a greater rate of information transmitted.

The purpose of the invention is to reduce the speed of transmitted information.

Claims (2)

To do this, in the proposed two-dimensional filtering vocoder containing on the transmitting side a serially connected spectrum analyzer and a pitch selector, analyzing a two-dimensional filter and a synchronization unit, the outputs of which are connected to the control inputs of the first switch and the analog-digital converter to the side - a digital-to-analog converter, a synthesis filter, a two-dimensional filter, a first switch, a series-connected speech spectrum generator and a synthesizer, as well as a synchronization unit, Exit which are connected to the control inputs of the first switch, a synthesizer and a digital to analog converter, the other input of which is connected to the input sync block, on the transmission side administered serially connected to "tyuch and second switch. The other outputs of the spectrum analyzer are connected through the first switch and the analyzing two-dimensional filter connected in series to one key input, the output of the pitch selector is connected to another input of the second switch, while the other outputs of the synchronization unit are connected to the control inputs of the analyzing two-dimensional filter, key and second switch. At the receiving side, the second switch and key are connected in series, the output of the digital-to-analog converter is connected to the input of the second switch, the other output of which is connected to the input of the speech spectrum generator, and the key output through the serially connected synthesizing two-dimensional filter and the first switch is connected to other synthesizer inputs. The remaining outputs of the synchronization unit are connected to the control inputs of the second switch, the key and the synthesizing two-dimensional filter. Analyzing two-dimensional filter and synthesizing two-dimensional filter can be made in the form of a discrete-analog delay line, the outputs of which through the weight resistors are connected to the inputs of the adder. The first and second inputs of the discrete-analog delay line are the corresponding inputs of the analyzing and synthesizing two-dimensional filters, and the outputs of the adders are respectively the outputs of these filters. FIG. 1 shows a block diagram of a proposed vocoder; in fig. 2 - timing diagrams of the transmitting side of the vocoder; in fig. 3 - timing diagrams of the receiving side of the vocoder. Vocoder with two-dimensional filtering contains on the transmitting side 1 serially connected spectrum analyzer 2 and pitch selector 3, analyzing two-dimensional filter 4, synchronization unit 5, the outputs of which are connected to the control inputs of the first switch 6 and the analog-digital converter 7, and serially connected key 8 and the second switch 9. Other spectrum analyzer outputs 2 through the first switch 6 connected in series and the analyzing two-dimensional filter 4 are connected to the same key input 8, the output is selected The main tone 3 is connected to another input of the second switch 9, the remaining outputs of the synchronization unit 5 are connected to the control inputs of the analyzing two-dimensional filter 4, the key 8 and the second switch 9. At the receiving side 10 there is a digital-to-analog converter 11 synthesizing the two-dimensional filter 12, the first the switch 13, the speech spectrum generator 14 and the synthesizer 15 connected in series, as well as the synchronization unit 16 whose outputs are connected to the control inputs of the first switch 13, the synthesizer 15 and the digital-to-analogue converter The receiver 11, the other input of which is connected to the input of the synchronization unit 16, and the second switch 17 and the switch 18 are connected in series. The output of the digital-to-analog converter 11 is connected to the input of the second switch 17, the other output of which is connected to the input of the speech spectrum generator 14, and in series Synthesizing two-dimensional filter 12 and the first switch 13 are connected to other inputs of the synthesizer 15. The remaining outputs of synchronization unit 16 are connected to the control inputs of the second switch 17, key 18 and synthesizing two-dimensional filter 12. Analyzing two-dimensional filter 4 is designed as a discrete-analog delay line 19, the outputs of which through the weight resistors 20 are connected to the inputs of the adder 21, and the synthesizing two-dimensional filter 12 is made in the form of a discrete-analog delay line 22, the outputs of which are through the weight resistors 23 yucheny to the inputs of adder 24. The first and second inputs of discrete analog delay lines 19 and 22 are respective inputs of the analyzing and synthesizing the two-dimensional filter 4 and 12, and the outputs of adders 21 and 24 - respectively, the outputs of these filters. Vocoder works as follows. The analyzed speech signal is transformed by the spectrum analyzer 2 into a set of spectral signal parameters f (x: i, i), which can be considered as sections of a two-dimensional function — the envelope of the instantaneous speech spectrum module F (.C, t), planes running parallel to the axis time t, through the central frequencies xi of the band-pass filters of the analyzer 2. At the same time, the main tone extractor 3 generates a voice excitation parameter that carries information about the speaker’s voice and the nature of the excitation (tonal or noise). The transfer rate of the selected spectral signal-parameters decreases if an interlaced scan is used for their compression in time, i.e., first, in order of increasing numbers, to transmit all odd signals, and then even, to form the spectral boundaries of the two-dimensional function FU, t). The required boundary formation is carried out by analyzing two-dimensional filter 4. For this, an odd number of spectral signal parameters from the output of analyzer 2 is fed to switch 6, which produces their sequential time sweep with a polling frequency corresponding to the clock frequency IT of vocoder without two-dimensional filtering. For the subsequent multiplexing of the spectral signal parameters by the signal-pitch parameter, as well as to eliminate the edge distortions arising during the two-dimensional filtering process, each even cycle of the switch 6 provides for an even number of idle cycles. The impulse response GAH (x, i) of the analyzing two-dimensional filter 4 is four delta functions shifted along the jc and t axes symmetrically relative to the origin of coordinates by sampling intervals X to T of the two-dimensional function F (x, t) and is equal to (x, t) (x + x) +6 (xx) 8 (t + -% - 6 (t + T) + fi (t-7) 5U) Two-dimensional function F (dsd), - deployed in time with a period T (taking into account the introduction of idle cycles), comes in the form of an amplitude-modulated pulse sequence (Fig. 2c) to the input of a discrete-analog delay line 19. Under the action of forward pulses, the frequency repeating Tm generated synchronization unit 5, this sequence smeshaets along discrete analogue delay line 19. Taps discrete analog delay line 19 is selected so as to satisfy the relation for Sdn (x, i). If the duration of the operation of the switch 6 and the discrete analog delay line 19 is equal to r, the taps of the discrete analog delay line 19 are located at intervals of (Hg) -2g- (7-teng), and the overall delay is 2T. The summation of the delayed pulses in the discrete-analog delay line 19 is carried out through the weight resistors 20 by means of the adder 21. As a result of this processing, a new sequence of pulses (Fig. 2c) is formed at the output of the analyzing two-dimensional filter 4, which is a smoothed two-dimensional function. The additional pulses that arise due to filtering on the edge of the group of spectral signal parameters due to the introduction of idle cycles do not lead to any distortion of the signal and are easily eliminated. The effect of intermittent sampling is achieved by excluding every second pulse from the amplitude-modulated pulse sequence (Fig. 26), which simultaneously leads to a twofold increase in the polling cycle of the spectral signal parameters to 27 (Fig. 2c). To do this, use the key 8, controlled by the synchronization unit 5 with the switching frequency, half the clock frequency f of the switch 6. The thus formed pulse sequence with a duty cycle Q 1 (Fig. 2c) can be viewed as a result of multiplying the discretization of the two-dimensional function F (x, t) with a period of 27. Additional pulses resulting from the edge distortions in the two-dimensional filtering process and the output 8 (shown in phantom in Fig. 2c) are eliminated in switch 9 by gating those intervals in which the pitch pulses are kneaded. The pulsed sequence thus refined with the recovered unit duty cycle is shown in FIG. 2g. The finally formed sequence of pulses with pulses of the fundamental tone inscribed in it (Fig. 2e) from the output of the switch 9 is fed to the analog-to-digital converter / and then, as a digital binary sequence, into the communication channel. At the receiving side 10, a digital binary sequence is fed to a synchronization unit 16 and a digital-to-analog converter 11. An amplitude-modulated pulse sequence with a unit duty cycle (Fig. 3a) from the output of the digital-to-analog converter 11 is fed to a switch 17 where it divides into two streams: main tone pulses (in Fig. 3a, marked with strokes) are transmitted to the generator 14 of the speech spectrum in order to control its frequency, and the remainder part to the key 18, which forms a new pulse sequence with increasing porosity, for example Q 2 (Fig. 36). Synchronous operation of the switch 17 and key 18 is provided by the synchronization unit 16. From the output of the key 18, the pulse sequence is fed to a synthesizing two-dimensional filter 12, which, filling in the empty spaces in this sequence, restores the original clock frequency f and the sampling period 7 (Fig. 3) . The impulse response GCHH (x, i) of the synthesizing two-dimensional filter 12 is: (:, t) 45 (x) S (i) + & (x + X + + b (JC-7) “(t) + (t + T) + + S () & (x). In the process of convolving a filtered two-dimensional function, in response to each input pulse of a two-dimensional function, a series of five pulses are formed with weights determined by the expression for (, t). At the receiving side 10, the two-dimensional filtering is carried out in the same way as at the transmitting side 1, with respect to the one-dimensional signal that has been developed. For this purpose, an amplitude-modulated pulse sequence from the output of the key 18 is fed to the discrete-analog delay line 22. Under the action of the advancing pulses with the following FT frequency, generated by the synchronization unit 16, this sequence is mixed along the discrete-analog delay line 22. The taps of this line are chosen in according to the expression for, (x, t) at intervals of time (7-g-y-t - (T-y) and the absolute delay is 2T. The pulses detained in the discrete-analog delay line 22 are summed across the weights The resistors 23 through the adder 24. As a result of this processing, a new sequence of pulses with filled gaps is formed at the output of the synthesizing two-dimensional filter 12 (Fig. Sound). At the same time, the original clock frequency {t and sampling period T is restored, i.e. a pulse sequence is formed , close to that which was fed to the input of the analyzing two-dimensional filter 4 on the transmitting side 1 (FIG. 2a) The additional pulses arising due to filtering at the edges of the restored group of spectral signal parameters (in Fig. Sv, marked with strokes) are eliminated due to the presence in the switch 13 of idle clock cycles corresponding to the intervals of the pitch pulses. From the output of the synthesizing two-dimensional filter 12, the amplitude-modulated pulse sequence arrives at the switch 13, from the output of which the signal arrives at the input of the synthesizer 15, which is excited through another input by the signal from the speech spectrum generator 14 and the synthesized speech signal is reproduced at the vocoder output. Thus, in the proposed vocoder, the speed of the transmitted information is reduced twice. The Vocoder with a two-dimensional filtering contains on the transmitting side C & a unified spectrum analyzer and a main current extractor analyzing a two-dimensional filter and a synchronization unit, the outputs of which are connected to the control inputs of the first switch and analog-digital converter, and digital-analogue on the receiving side Converter, synthesizing a two-dimensional filter, the first switch, a series-connected speech spectrum generator and synthesizer, as well as a synchronization block output which are connected to the control inputs of the first switch, synthesizer and digital-analog converter, the other input of which is connected to the input of the synchronization unit, characterized in that, in order to reduce the speed of information transmitted, the serially connected key and the second switch are entered on the transmitting side, while others the outputs of the spectrum analyzer are connected via a serially connected first switch and an analyzing two-dimensional filter connected to one key input, the output of the pitch selector is connected to The other input of the second switch is connected, the remaining outputs of the synchronization unit are connected to the control inputs of the analyzing two-dimensional filter, the key and the second switch, and the second switch and the key are connected in series at the receiving side, the output of the digital-to-analog converter is connected to the input of the second switch, the other output of which is connected to the input of the generator of the speech spectrum, and the output of the key through a series-connected synthesizing two-dimensional filter and the first switch is connected synthesizer other inputs, the remaining sync block outputs are connected to the control inputs of the second switch, a key and a two-dimensional synthesizing filter. 2. Vocoder according to claim 1, characterized in that the analyzing two-dimensional filter and the synthesizing two-dimensional filter are made in the form of a discrete-analog delay line, the outputs of which through weight resistors are connected to the inputs of the adder, the first and second inputs of the discrete-analog delay line are corresponding inputs of analyzing and synthesizing two-dimensional filters, and outputs. adders - respectively, the outputs of these filters. Sources of information taken into account in the examination 1. Pirogov A. A. Vokoderna Telefoni. M., “Holy, 1974, p. 83-95. , F, rb i PPPP., .- Pppp .- ,, PP P um