RU2042284C1 - Sound-reproduction stereo system - Google Patents

Abstract

FIELD: domestic appliances. SUBSTANCE: sound-reproduction stereo system includes attenuators connected through adder and amplifier to low-frequency radiator. Acoustic wide-band radiators are linked through high-frequency filters to information inputs of system which are coupled to one of attenuators directly and to others through high-frequency filters. EFFECT: expanded application range. 1 dwg

Description

 The invention relates to sound engineering, and in particular to improved quality stereo systems used in stationary and automotive equipment.

 Sound reproducing stereo systems are known in which the improvement of sound quality is achieved by improving the reproduction of low frequencies, which is achieved by the inclusion of additional low-frequency speakers installed in one large case ("High-quality stereo speaker system Radio, N 9, 1970, p. 59; Butenko A. Three-way acoustic system Radio, N 5, 1960, p. 32).

 Known systems are widespread and essentially the same. The main emitters (which can contain both one wide-band loudspeaker and several narrow-band loudspeakers) and an additional low-frequency radiator, contain, as a rule, two low-frequency loudspeakers connected to the output of a two-channel power amplifier through an additional high-current crossover crossover filter, with which low frequencies with amplifier outputs are fed to the low-frequency speakers of the low-frequency emitter, and medium and high frequencies are fed to the main emitters.

 The disadvantages of this type of system are as follows.

 High-current isolation filters contain labor-intensive winding products inductors.

 Tuning the frequency of the partition is practically impossible, since at least the winding products in this case become even more time-consuming and expensive.

 It is practically impossible to connect a low-frequency emitter containing one low-frequency speaker with one winding.

 Improving the sound of the system is achieved only due to the discrepancy between the amplification frequency band of the two-channel amplifier and the reproduced frequency band of the main emitters, i.e. The quality of the amplifier exceeds the quality of the main emitters.

The stereo systems described in the article by N. Troshin "Loudspeaker with EMOS" Radio, N 8, 1989, p. 51-56 and the prospectus of the Bose Acoustic wave cannon system do not have almost all of these drawbacks. In these systems, the crossover isolation filter is made active and is switched on between the sound signal source having only a low-current output and a three-channel power amplifier. The system allows you to get rid of the winding nodes. The low-frequency emitter may include one low-frequency speaker. Improving the sound compared to a conventional two-channel stereo system is achieved by optimizing the band of amplified and reproduced frequencies in the two main and additional low-frequency channels, as well as due to the balanced power of the channels. The technical solution of crossovers in these systems does not allow for the operative tuning of the crossover frequency in order to optimize the channel parameters when connecting the main and additional emitters of various models depending on the spectral composition of sound programs coming from the output of the sound signal source. This disadvantage is eliminated in [1]
In the device [1] the formation of medium-high frequency playback signals occurs using low-pass filters and subtractors. Therefore, it is enough to rebuild the cutoff frequency of the low-pass filters to rebuild the crossover section frequency.

 The main significant drawback of these systems is that if the sound source contains its own two-channel power amplifier, then using this amplifier without using additional inputs and outputs is impossible. Indeed, the source of sound signals can be a radio, radio or music center, incorporating a two-channel power amplifier. Such additional devices are not equipped with any additional line outputs or inputs, therefore the audio signal outputs are intended for connecting loudspeakers.

 Of the known solutions in technical essence, the closest is the device [2] taken as a prototype.

 A sound reproducing stereo system contains the main emitters of the left and right channels connected to the outputs of the main amplifier of the left and right channels. Filters and attenuators are connected to these outputs, to which an additional low-frequency radiator containing one low-frequency loudspeaker is connected through an additional two-channel amplifier, the inputs of the main emitters and attenuators have positive and negative outputs. When connected, the polarity is respected.

 In a stereo system, improved reproduction of low frequencies is achieved only due to the simultaneous operation of the main and additional emitters on this range. But the return of the system as a whole in the entire sound frequency range is limited by intermodulation and non-linear distortions arising from the reproduction of the entire sound range by the main emitters, which, in turn, are often performed with small-sized ones with a lower boundary reproducible frequency of about 100 Hz. This becomes evident if we take into account the peculiarities of auditory perception, namely, at the same intensity of sound signals emitted by the stereo system of different frequencies, the subjective perception by the hearing of the intensity is different, i.e. at different frequencies, sounds of different intensities can have the same volume. For example, in order for the volume of sinusoidal sound signals with frequencies of 100 and 1000 Hz to be the same at a radiation intensity of 50 lB, it is necessary to have a radiation intensity at 100 Hz of 67 dB (Ioffe V.K. et al. Acoustics Reference. M. Communication, 1979, p. 31). Then, to fulfill these requirements, the main emitters and the additional emitter must provide a radiation intensity at a frequency of 100 Hz of 64 dB, which exceeds the level of the frequency of 1000 Hz emitted by the main emitters, more than 20 times in power and almost 10 times in the output voltage of the main amplifier , which, in turn, leads to the appearance of non-linear distortion of the amplifier in the low frequency region even at a low level of mid frequencies to a large level of intermodulation distortion of the emitters to which the frequencies are applied s below reproduced by them.

 This is especially evident in automotive systems in which the output voltage is limited by an on-board supply voltage of 12 V, and the main emitters often contain one wide-band small-sized loudspeaker.

 Suppose, firstly, that all acoustic emitters are equidistant from the listening position; secondly, all measures have been taken to eliminate non-linear and intermodulation distortions in the low-frequency acoustic emitter, and the amplifier does not introduce distortions; this is possible if positive current feedback is introduced (the amplifier has negative resistance or electromechanical feedback from the emitters); thirdly, the output impedance of the source of sound signals is almost zero.

Denote the signals that are received at the input of the speaker system: L ^{e is the} signal received at the input of the left channel; P ^{e the} signal received at the input of the right channel.

Then the signal will be emitted to the listening point by the first broadband emitter
L ^A + L _NI ^A + L _IN ^A (1)
A second broadband emitter will emit a signal at the same listening point
P ^A + P _NI ^A + P _IN ^A (2)
Low frequency emitter signal
L _LF ^A + P _LF ^A , (3) where L ^A and P ^{A are the} left and right acoustic signals formed from electric signals L ^e and P ^e ;
L _low ^A and P _low ^{A A} acoustic signals formed from electrical signals L _low ^e and P _low ^e, respectively, which, in turn, are formed by filtering the frequencies of electrical signals L ^e and P ^e ;
L _NI ^A and P _NI ^A acoustic signals of nonlinear distortions arising in the electromechanical system of broadband emitters;
L _IN ^A and P _IN ^A acoustic signals of intermodulation distortions arising in the electromechanical system of broadband emitters.

Thus, at the listening point in the acoustic signals L ^A and P ^{A, the} level of low frequencies will always be increased and there will be distortion signals.

 The goal is to develop a semi-active stereo speaker system with high quality reproduction of signals in the entire range of audio frequencies.

 The goal is achieved by the fact that in the known semi-active stereo speaker system containing the first and second broadband acoustic emitters, a series-connected amplifier and a low-frequency radiator, series-connected the first high-pass filter, the input of which is the first information input of the system, and the first attenuator, connected in series with the second filter treble, the input of which is the second information input of the system, and the second attenuator, introduced the third and fourth att nuators and an adder, the inputs of which are connected to the outputs of the first, second, third and fourth attenuators, the adder output is connected to the amplifier input, the input of the third attenuator is connected to the first information input of the system, the second information input of which is connected to the input of the fourth attenuator, the inputs of the first and second broadband acoustic emitters connected to the outputs of the first and second high-pass filters, respectively.

 Comparison of the claimed solution with the prototype shows that it differs from the prototype in the presence of new nodes and new connections between the nodes. This gives the right to consider the claimed device in accordance with the criteria of the invention of "Novelty."

 The inventive step of the proposed device lies in an unconventional method for solving the problem. Improving the sound quality of the system is achieved by reducing intermodulation and non-linear distortions.

 Intermodulation distortion is reduced by lowering the level of low-frequency components in the electrical signals supplied to the input of the broadband acoustic emitters, while increasing the level of these frequencies in the electrical signals supplied to the input of the low-frequency acoustic emitter, and ensuring the tuning of the cross-section frequency between the frequency bands reproduced by the broadband acoustic emitters and low-frequency emitter, while maintaining the original parameters of the signals at the location with ushatelya.

 Non-linear distortions are reduced by isolating the non-linear distortion signal from the low-band acoustic emitters and emitting them in antiphase by the low-frequency acoustic emitter to the listening location.

 The drawing shows a diagram of the proposed sound reproducing stereo system.

 The system comprises a first high-pass filter 1, a first acoustic broadband emitter 2, a third attenuator 3, a first attenuator 4, an adder 5, an amplifier 6, a low-frequency emitter 7, a fourth attenuator 8, a second attenuator 9, a second high-pass filter 10 and a second acoustic broadband emitter 11. Positions 12 and 13 indicate the first and second information inputs of the stereo system, respectively.

 Acoustic broadband emitters 2, 11 are connected respectively to the first and second inputs of the system through high-pass filters 1 and 10. The inputs of the filters 1 and 10 are connected respectively to the inputs of the attenuators 3 and 8. The outputs of the filters 1 and 10 are connected respectively to the inputs of the attenuators 9. The outputs of all attenuators 3, 4, 8, 9 through the adder 5 and amplifier 6 are connected to the low-frequency emitter 7.

Sound reproducing stereo system operates as follows. The inputs 12 and 13 receive signals L ^e and P ^{e the} electrical signals of sound frequencies (L left, P right). The source of electrical signals of sound frequencies can be a car radio, if the speaker system will be used in a car, or a home radio complex, or any other similar equipment incorporating a stereo power amplifier.

 All the signals that enter the input of the speaker system and are formed by nodes and blocks of the speaker system are complex.

A signal ^e to the input 12 is input to high frequency filter 1, at whose output is generated the electric signal A _HF ^e. The signal P ^e from input 13 is fed to the input of a high-pass filter 10, the output of which forms an electrical signal P _RF ^e .

With attenuators 3, 9, 4, 10 electrical signals L ^e and R ^e, h _HF ^e and n _HF ^e attenuated by an amount K in order to match the electrical signal levels L ^e, n ^e, h _HF ^e, n _HF ^e with the input level of the amplifier 6 having a gain α, the value of which must correspond
α˙ k = 1 (4)
Then the level of electrical signals at the output of amplifier 6 will correspond to the level of input signals L ^e and P ^e .

 The input impedance of attenuators 3, 8, 4, 9 should be at least an order of magnitude greater than the input impedance of broadband emitters 2 and 11, so as not to affect the operation of high-pass filters 1 and 10 and broadband emitters 2, 11.

Connecting to the outputs of the filters 1 and 10 leads to a high frequency overlay to electrical signals ^e _HF and A n electric signals ^e _HF nonlinear distortions A _or ^E and P _or ^E, respectively.

At the same time, acoustic signals L _tref ^A + L _nor ^A (5), P _tref ^A + P _nor ^A (6) are emitted to the listener's location. In these expressions, there are no signals due to intermodulation distortion, since, by tuning the cutoff frequency of high-pass filters 1 and 10, the occurrence of intermodulation distortion is eliminated.

Using the adder 5 and amplifier 6, electrical signals are generated, which can be described by the expression
L ^e + P ^e - (L _hf ^e + L _neither ^e + P _hf ^e + P _nor ^e ) (7)
The electrical signals represent the difference between broadband signals L ^e and n ^e and the high-frequency signals _HF ^e -P L ^e and _HF are low-frequency signals L + R ^e _{lf lf} ^e (8)
Such formation of electrical signals for exciting a low-frequency emitter makes it quite easy to tune the cutoff frequency of high-pass filters 1 and 10 without worrying about matching the band of reproduced signals with broadband and low-frequency emitters.

Low-frequency emitter converts electrical signals
L _low ^e + P _low ^e - (L _neither ^e + P _nor ^e ) (9)
in acoustic
L _LF ^A + P _LF ^A - (L _neither ^A + P _nor ^A ), (10)
which, at the listener's location, add up to the acoustic signals of broadband emitters
L _high ^A + L _neither ^A and P _high ^A + P _nor ^A (11)
The sum of the acoustic signals at the listening point will be written as
L _HF ^A + L _low ^A + P _high ^A + P _low ^A + (A _or ^A +
+ P _neither ^A ) - (L _neither ^A + P _nor ^A ) (12)
Sum signals ^A + _HF A A ^A _LF and _HF P ^A + P _lf ^A represents the sum of the acoustic signals
L ^A + P ^A (13)
From the formula (12) it is seen that the acoustic signals of nonlinear distortions are mutually annihilated.

 Thus, the proposed speaker system allows you to get rid of intermodulation and non-linear distortions and, therefore, improve the quality of reproduction of audio signals compared to the prototype.

Claims (1)

 A PLAYING STEREO SYSTEM, comprising a first and a second broadband emitter, a serially connected amplifier and a low-frequency emitter, a serially connected first high-pass filter, the input of which is the first information input of the stereo system, and a first attenuator, serially connected to a second high-pass filter, the input of which is the second information input of the stereo system , and a second attenuator, characterized in that the third and fourth attenuators and adder are introduced into it, the inputs to connected to the outputs of the first fourth attenuators, the adder output is connected to the amplifier input, the input of the third attenuator is connected to the first information input of the stereo system, the second information input of which is connected to the input of the fourth attenuator, the inputs of the first and second broadband acoustic emitters are connected to the outputs of the first and second filters high frequencies.

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