SU161527A1 - - Google Patents

Description

The known methods of ultrasound modeling, based on transposing sound signals into the ultrasound region of the spectrum, as well as the method of ultrasound modeling based on the transfer of acoustic signals into the ultrasound region, do not allow modeling the frequency dependences of the acoustic parameters of the room or result in the emission of such wide spectra. (on the order of hundreds of kilohertz), that the technical realization of radiating and receiving devices is almost impossible.

The proposed method of modeling acoustic processes in closed rooms using ultrasound signals emitted and received in a reduced model of the investigated room differs from the known ones in that the low-frequency signal to be converted into an ultrasonic is divided into two components — low frequency and high frequency. the low-frequency component is transformed into ultrasound by transposing the spectrum upward, in accordance with the scale of the model, by recording it on a magnetic tape, and high-frequency and the component is by amplitude modulating by it the sinusoidal oscillation of a certain high frequency and subsequent extraction and emission in the model of one sideband of the modulated oscillation.

The drawing shows a flowchart for implementing the proposed method.

The original electrical signal / i, the spectrum of which contains frequencies from Ff F g, is reproduced in the model and is fed to a dividing filter / of conventional type with a separation frequency F. Here the signal / 1 is divided into low and high frequency components / 1, Component / 1 „contains frequencies from Ff to F, and the component / la- frequencies from Pp to fg. The low-frequency component is fed to tape recorder 2, where it is recorded on magnetic tape at a tape speed V. Then the recorded tape signal / "is reproduced at tape speed and the spectrum of signal IIH is transposed and now occupies the frequency range from to fl N, Fp .

The received signal, we denote it by /, g, is fed to the "low-frequency ultrasonic power amplifier 3 and further to the low-frequency ultrasonic emitters 4 installed in the room model, which are models of the low-frequency links of the loudspeakers. The signal received by the sound receiver 5 installed in the model enters the ultrasonic cross-over filter 6, which has a separation frequency and, from its "low-frequency output," into the microphone

amplifier 7. From the last output, the signal goes to tape recorder 2, where it is applied to the tape at tape speed y. The recorded signal is reproduced at a tape speed V. This produces a signal, the spectrum of which, like the spectrum of the original signal (1 "), lies within Rc-Fp. This last signal enters tape recorder 2 and is recorded in the corresponding tape track of the tape recorder.

The high frequency component of the original signal from the output of the separation filter / is fed to the modulator 8, where it modulates in amplitude the sinusoidal voltage / o from the generator 9 operating at frequency / o. The modulator output signal is fed to a band-pass filter 10 having a transmission band from fo-l-Pp TO / O + eFilter passes the signal / og - the upper side frequency band of the amplitude-modulated signal generated in the modulator 8. The signal / 2b goes to " the high-frequency ultrasonic power amplifier // and, from its output, to the high-frequency ultrasonic emitters 12 installed in the model, which are models of the high-frequency links of the loudspeakers. The output signal of the installed sound model 5 /.gg from the high-frequency output of the ultrasonic cross-section filter 6, the separation frequency fp of which also satisfies the condition, through the high-frequency ultrasonic microphone amplifier 13 is sent to the demodulator 14, where the carrier voltage is also applied frequencies from oscillator 9. In a demodulator, conventional methods used in radio communication technology detect the sound received by the receiver. The output of the demodulator / 48, as a low-frequency signal / 4n, is recorded on the corresponding track on the tape recorder 2, after which both signals (and) are reproduced simultaneously, mixed in the mixer 15 and recorded on the last track on the tape recorder 2. After that they can supplied to the appropriate measuring device 16 and to the input of the audio reproducing apparatus 17.

Subject invention

A method of modeling acoustic processes in closed rooms with the help of ultrasonic signals emitted and received in a reduced model of the investigated room, characterized in that, in order to narrow the frequency range, the low frequency signal to be converted into ultrasonic is divided into two components: low frequency and high-frequency, the low-frequency component being converted into ultrasound by transcending the spectrum upwards, according to the scale of the model, by recording it on a magnetic tape, and the high-frequency component — by its amplitude modulation of a sinusoidal oscillation of a certain high frequency and the next emission emission in the model of one LATCH of the modulated oscillation.

2. Method but n. 1, characterized in that, in order to synchronize the low-frequency and high-frequency components of the signal passing through the model, the low-frequency and high-frequency 1 components of the signal are pre-recorded on separate tracks of one tape of a multi-channel tape recorder and then played alternately, and the low-frequency component is correspondingly increased on speeds, and the signals received during the alternate reproduction of the low-frequency and high-frequency components are recorded on other tracks of the same magnetic tapes.