JPH01231598A - Loudspeaker system - Google Patents

Abstract

PURPOSE: To make possible high quality acoustic reproducing by connecting the input terminal of a corresponding attenuating/correcting try pole to the input terminal of each loud speaker and connecting the combined output terminal of the attenuating/correcting try pole to the 2nd input terminal of a comparison amplifier. CONSTITUTION: An input signal concerning an input clamp 1 is amplified by the comparison amplifier 3 and added to the input terminal of a passive crossover 6. Then, the signal is separated into each frequency band by the passive crossover 6 means, and the separated signals are added to the input clamps of respective loud speakers 9 and 10. Voltages concerning the input clamps of the loud speakers 9 and 10 are attenuated by each corresponding attenuating/ correcting try pole 12 or 15, and added to the 2nd input terminal of the comparison amplifier 3. An auxiliary feedback is introduced into a frequency area larger than an acoustic band by a complementary attenuating/correcting try pole 18. Thus, even when loud speakers different in characteristic sensitivity and impedance are used by a feedback means, fine balanced frequency characteristic is achieved.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to a loudspeaker comprising at least two loudspeakers and whose consumer application is limited to high quality sound reproduction in the field of electronics.

[Conventional technology]

For high-quality sound reproduction, the loudspeaker system has two
Equipped with more than one loudspeaker.

Professional use allows optimal electro-acoustic conversion over the entire audio range. The processed signal must be divided into two or more frequency bands.

There are passive loudspeaker systems in which said division is done by passive electronic circuit means, so-called crossovers.

[Problem to be solved by the invention]

However, the disadvantages of passive loudspeaker systems arise from practical crossover and loudspeaker characteristics. The frequency dependence of the impedance for a loudspeaker affects both the precision with which the signals used are divided into the respective passbands and the overall frequency response of the loudspeaker system, and is also adversely affected by production tolerances regarding the individual components of the crossover. is given. Therefore, additional non-linear strain is introduced, for example using a coil with a magnetic core. Air-core coils affect the functionality of the crossover due to their mutual coupling and are also considerably more expensive. Electrolytic capacitors reduce the long-term stability of the loudspeaker characteristics due to aging, and the capacitance accuracy for the capacitors is generally inadequate. Both the impedance and the characteristic sensitivity for all loudspeakers used in a system must be approximately the same value. Although the above-mentioned disadvantages can be partially eliminated, keeping the impedance etc. at the same value always damages the cylinderization of the crossover and leads to high costs. Another disadvantage lies in the insufficient attenuation of the fundamental resonance for mid-tone loudspeakers and tweeters, due to the increase in the output impedance of the associated output end at frequencies outside the transmission band of the corresponding passband. .

This results in an increase in intermodulation distortion and a deterioration in the transient characteristics of the loudspeaker system.

Similarly, in the case of more complex lossovers, the oscillations of the crossover itself, which to a large extent cannot be eliminated, become significant and degrade the transient performance of the entire system.

Furthermore, active loudspeaker systems are well known and use a suitable number of power amplifiers to feed each loudspeaker separately. Similarly, active loudspeakers use active filters to separate the signal into corresponding frequency bands, and the entire loudspeaker, power amplifier, and active filter are usually combined with the necessary baffles to form an assembled unit device. Active loudspeaker systems do not exhibit the disadvantages of passive systems, but tend to be very expensive when large numbers of power amplifiers are used.

It is an object of the present invention to eliminate said disadvantages and to provide a loudspeaker system comprising an amplifier and a passive crossover, the loudspeaker system being configured such that at least two loudspeakers are connected to the output of the crossover. The goal is to provide a system.

[Failure to solve the problem]

The gist of this system is that the input of a corresponding attenuation-correction tripole is connected to the input of each loudspeaker, and the combined output of said attenuation-correction tripole is connected to the second input of a comparison amplifier. At the point. Comparison amplifier first
An input clamp is connected to the input of the amplifier, and an output of the amplifier is connected to a passive crossover. An input of an additional attenuation-correction tripole may be connected to the output of the comparison amplifier, and the output of the additional attenuation-correction tripole is connected to a second input of the comparison amplifier.

[For production]

By means of negative feedback means, the loudspeaker system according to the invention achieves a well-balanced frequency response even when using loudspeakers with different values of characteristic sensitivity and impedance.

Undesirable characteristics of the crossover components are significantly suppressed and the required accuracy regarding the characteristic sensitivity and impedance values is lower. Unwanted transient behavior of the crossovers used is likewise suppressed and, for some types of crossovers, even the attenuation of the fundamental resonances of mid-tone loudspeakers and tweeters is improved. By using only one power amplifier per baffle, the loudspeaker system is also advantageous from an economical point of view.

〔Example〕

An embodiment of the present invention will be described in detail below with reference to the drawings.

FIG. 1 is a diagram showing the overall circuit configuration of a loudspeaker system. The configuration of this embodiment will be explained below. In the figure, the input clamp 1 is connected to the first input terminal 2 of the comparator amplifier 3.
The output terminal 4 of the passive crossover 6 is connected to the input terminal 5 of the passive crossover 6 .

A first loudspeaker 9 is connected to a first output 7 of the passive crossover 6 and a second loudspeaker 10 is connected to a second output 8 of the passive crossover 6 . 1st
The input of the loudspeaker 9 is connected to the input 11 of a first attenuation-correction tripole 12 . The second loudspeaker 100 input has a second attenuated-corrected tripole 1
It is connected to the input terminal 14 of 5. The output 13 of the first attenuation-correction tripole 12 and the output 16 of the second attenuation-correction tripole 15 are connected to a second input 20 of the comparison amplifier 3. The output 4 of the comparison amplifier 3 is connected to the input 17 of a complementary attenuation-correction tripole 18, the output 19 of which is connected to the second input 20 of the comparison amplifier 3.

Next, the operation of this embodiment will be explained. The signal applied to the input clamp 1 is amplified by a comparator amplifier 3 and applied to the input end 5 of a passive crossover 6. This passive crossover 6
By means of , the signal is divided into two frequency bands and applied to the input clamps of loudspeakers 9 and 10 . The voltage on the input clamp of the first loudspeaker 9 is attenuated by a first attenuation-correction tripole 12 and applied to the second input of the comparison amplifier 3.

The voltage on the input clamp of the second loudspeaker 10 is attenuated by a second attenuation-correction tripole 15 and applied to the second input 20 of the comparison amplifier 3 .

By adding negative feedback, most of the undesirable characteristics of both passive crossovers and amplifiers are suppressed and high reproduction quality of the loudspeaker system is achieved. By selecting the attenuation ratio of each attenuation-correction tripole 12, 15, it is possible to compensate for differences in the characteristic sensitivity and/or impedance magnitude of the individual loudspeakers 9.10 without additional losses. By using attenuation-correction tripoles 12, 15 with adjustable attenuation, the output power radiated in each transmission band can be controlled without losses. By means of the complementary attenuation-correction tripole 18, auxiliary negative feedback is introduced in the frequency range above the audio band, ensuring high frequency stability of the comparator amplifier 3. The comparator amplifier 3 itself has two selectivities; FIG. 2 shows a non-inverse conversion amplifier, and FIG. 3 shows an inverse conversion amplifier.

The loudspeaker system according to the invention is intended for high-quality sound reproduction, especially in the field of consumer electronics. However, it is equally suitable and convenient for professional use.

[Effects of the Invention] As described above in detail, according to the present invention, the input signal related to the input clamp 1 is amplified by the comparator amplifier 3 and applied to the input terminal of the passive crossover 6. Thereafter, the signal is divided into frequency bands by means of a passive crossover 6 and applied to the input clamp of each loudspeaker 9,10. The voltages on the input clamps of the loudspeakers 9, 10 are determined by the corresponding attenuated-corrected tripole 1
It is attenuated by 2°15 and applied to the second input of the comparator amplifier 3. By means of the complementary damping-correction tripole 18, auxiliary negative feedback is introduced in the frequency range above the acoustic band.

Therefore, the loudspeaker system is suitable and convenient for professional use and can be expected to be advantageous from an economical point of view.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing the overall circuit configuration of the loudspeaker system, FIG. 2 is a diagram showing a non-inverting conversion amplifier, and FIG. 3 is a diagram showing an inverting conversion amplifier. DESCRIPTION OF SYMBOLS 1... Input clamp, 2... First input end of proportional amplifier 3, 3... Proportional amplifier, 4... Output end of proportional amplifier 3, 5... Input end of passive crossover 6 , 6... Passive crossover, 7... First output terminal of passive crossover 6, 8...
second output of the passive crossover 6, 9...first loudspeaker, 10...second loudspeaker, 11...input of the first attenuation-correction tripole 12, 12. ...first attenuation-correction tripole, 13...
Output end of first attenuation-correction tripole I2, 14... Input end of second attenuation-correction tripole 15, 15... Second attenuation-correction tripole, 16...
Output end of second attenuation-correction tripole 15, 17... Input end of complementary attenuation-correction tripole 18, 18... Complementary attenuation-correction tripole, 19... Complementary attenuation-correction tripole 18 20... the second input terminal of the comparator amplifier 3;

Claims (1)

[Claims] 1. In a loudspeaker system comprising an amplifier and a crossover and having at least two loudspeakers connected, at the input end of each loudspeaker 9, 10 a corresponding attenuation -
A correction tripole 12, 15 is connected, the combined output 13, 16 of the attenuation-correction tripole is connected to a second input 20 of the comparator amplifier 3, and an input to the first input 2 of the comparator amplifier 3. A loudspeaker system, characterized in that a clamp 1 is connected, and an input terminal of a passive crossover 6 is connected to an output terminal 4 of the comparator amplifier. 2. The output terminal 4 of the comparison amplifier 3 is connected to the input terminal 17 of the complementary attenuation-correction tripole 18, and the output terminal 19 of the complementary attenuation-correction tripole is connected to the second input terminal 20 of the comparison amplifier 3. A loudspeaker system according to claim 1, characterized in that: