JP2001275184A - Mfb speaker system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve a problem in a conventional MFB speaker system, that the capability of its amplifier cannot efficiently be used because the sound pressure level is decreased in a frequency band higher than a minimum resonance frequency f0 when the reproduction frequency band is extended toward a low audio frequency. SOLUTION: In the MFB speaker system provided with an enclosed cabinet 5, a speaker unit 4, a vibration displacement detection means 6 and a vibration velocity detection means 7 to detect a vibration displacement and a vibration velocity of the diaphragm of the speaker unit 4, an adder 2 that superimposes an external input signal on a feedback signal, and a power amplifier 3 that amplifies the total signal outputted from the adder 2, the vibration displacement signal and the vibration velocity signal are positively fed back to the adder 2.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to M
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a FB (motional feedback) speaker, and more particularly, to an MBF speaker system capable of expanding a reproduction frequency band in a low sound range without lowering a sound pressure level.

[0002]

2. Description of the Related Art FIG. 10 is a diagram showing a speaker system (up and down) edited by Takeo Yamamoto (Radio Engineering Co., Ltd., July 15, 1977).
The conventional M disclosed in Japanese publication, pages 406 to 410)
It is a figure showing the composition of the FB system speaker system. FIG.
At 0, 101 is a signal input terminal to the speaker, 10
2 gain of G _A amplifier, 103 speaker gain G _S, is 104 a feedback circuit gain beta. The symbol E
_i is the input voltage, E _v is the input voltage to the speaker, the E _s shows the output voltage from the speaker.

In this conventional MFB speaker system, an amplifier 102 is used as a drive source of a speaker 103. The amplifier 102, the speaker 103, and the feedback circuit 104 form a closed-loop control system. Further, in the conventional MFB speaker system, the signal input to the feedback circuit 104 is returned with a negative polarity to the input signal (negative feedback) in order to reduce distortion and improve bass characteristics.

Next, the operation will be described. The acoustic signal input from the signal input terminal 101 is amplified by the amplifier 102 and drives the speaker 103. In the speaker 103, sound is emitted by the vibration of the diaphragm, and the vibration of the diaphragm is detected by vibration detection means (not shown) provided inside the speaker 103, and a detection signal relating to the vibration of the diaphragm is generated. Output to the feedback circuit 104. The feedback detection signal is superimposed on the input signal input from the signal input terminal 101, and amplifies the generated composite signal to drive the speaker 103.

[0005] In the MFB speaker system shown in FIG. 10, when a system (speed type MFB system) for increasing the feedback gain β for a signal proportional to the speed of the diaphragm is used for the detection signal from the speaker, for example.
The sharpness Q ₀ of the speaker system decreases, and the sound pressure level near the lowest resonance frequency f ₀ decreases. Further, when a method of increasing the feedback gain β for a signal proportional to the acceleration of the diaphragm with respect to the detection signal from the speaker (acceleration MFB method) is adopted,
Although the lowest resonance frequency f ₀ of the speaker system is lowered and sound reproduction up to a lower sound range is possible, the sound pressure level is lowered and the sharpness Q ₀ is increased. Further, when a method (displacement type MFB method) for increasing the feedback gain β for a signal proportional to the displacement of the diaphragm with respect to the detection signal from the speaker is adopted, the lowest resonance frequency becomes high and the speaker system becomes The sharpness Q ₀ increases.
In a conventional MFB speaker system, a composite signal obtained by combining signals proportional to the vibration speed, vibration acceleration, and vibration displacement as described above is often fed back.

FIG. 11 shows the above-mentioned “Speaker system (vertical)” edited by Takeo Yamamoto (Radio Engineering Co., Ltd., p.
FIG. 9 is a graph showing frequency characteristics of a velocity type MFB, an acceleration type MFB, and a displacement type MFB disclosed in FIG. That is, in the conventional MFB speaker system, when the feedback amounts D ₁ , D ₂ , and D ₃ for each system are increased, the characteristic tendency as described above with respect to the lowest resonance frequency f ₀ , the sharpness Q _0, and the sound pressure level is obtained. It is shown that it can be obtained.

[0007]

Since the conventional MFB speaker system is configured as described above, an acceleration type MFB system is adopted as a feedback system in order to expand a reproduction frequency band in a low frequency range. . In acceleration-type MFB method, as shown in FIG. 11 (b), but reproduction frequency band reduces the minimum resonance frequency f ₀ when the feedback amount D ₂ is increased to enlarge the bass, than the lowest resonance frequency f ₀ There has been a problem that the sound pressure level is reduced in a high frequency band and the ability of the amplifier cannot be used efficiently.

[0008] MFB type speaker system The present invention has been made to solve the above problems, without causing a decrease in efficiency of the amplifier in a frequency band higher than the lowest resonance frequency f _0, to expand the reproduced frequency band The purpose is to provide.

[0009]

An MFB speaker system according to the present invention comprises a closed cabinet, a speaker unit attached to the closed cabinet, and a vibration displacement detecting device for detecting a vibration displacement of a diaphragm of the speaker unit. Means, an amplifier for amplifying a vibration displacement signal output from the vibration displacement detection means, a feedback adder for superimposing an externally input input signal and a feedback signal, and a composite signal output from the feedback adder And a power amplifier that drives the speaker unit by amplifying the vibration displacement signal, so that the vibration displacement signal is positively fed back to the feedback adder.

An MFB speaker system according to the present invention comprises a closed cabinet, a speaker unit attached to the closed cabinet, a vibration speed detecting means for detecting a vibration speed of a diaphragm of the speaker unit,
An amplifier that amplifies the vibration velocity signal output from the vibration velocity detection means, a feedback adder that superimposes an input signal and a feedback signal that are input from the outside, and an amplifier that amplifies a composite signal output from the feedback adder. And a power amplifier for driving the speaker unit, and the vibration velocity signal is positively fed back to the feedback adder.

An MFB speaker system according to the present invention comprises a closed cabinet, a speaker unit attached to the closed cabinet, vibration speed detecting means for detecting a vibration speed of a diaphragm of the speaker unit,
An in-phase amplifier that amplifies the vibration velocity signal output from the vibration velocity detection means to the same phase; an antiphase amplifier that amplifies the vibration velocity signal output from the vibration velocity detection means to the opposite phase; and amplification from the in-phase amplifier. Switching means for selecting and outputting one of a signal and an amplified signal from an antiphase amplifier, a feedback adder for superimposing an input signal and a feedback signal input from the outside, and an output from the feedback adder. And a power amplifier that amplifies the combined signal to drive the speaker unit, and selectively provides positive or negative feedback of the vibration velocity signal to the feedback adder.

An MFB speaker system according to the present invention includes a vibration speed detecting means for detecting a vibration speed of a diaphragm of a speaker unit, and an amplifier for amplifying a vibration speed signal output from the vibration speed detecting means. In addition to positively feeding back the vibration displacement signal to the feedback adder, the vibration velocity signal is also fed back to the feedback adder.

The MFB speaker system according to the present invention has a vibration speed detecting means for detecting a vibration speed of the diaphragm of the speaker unit, and an in-phase amplifying the vibration speed signal output from the vibration speed detecting means to the same phase. An amplifier,
An antiphase amplifier for amplifying the vibration velocity signal output from the vibration velocity detection means in an opposite phase, and a switching means for selecting and outputting one of the amplified signal from the in-phase amplifier and the amplified signal from the antiphase amplifier; In addition to positive feedback of the vibration displacement signal to the feedback adder, the vibration velocity signal is selectively positively or negatively fed back to the feedback adder.

An MFB speaker system according to the present invention includes a vibration speed detecting means for detecting a vibration speed of a diaphragm of a speaker unit, and an amplifier for amplifying a vibration speed signal output from the vibration speed detecting means. In addition to the positive feedback of the vibration displacement signal to the feedback adder, the vibration velocity signal is negatively fed back to the feedback adder.

An MFB speaker system according to the present invention includes an integrating adder for superimposing an amplified signal output from an amplifier for amplifying a vibration displacement signal and an amplified signal output from an amplifier for amplifying a vibration velocity signal. It is like that.

An MFB speaker system according to the present invention includes an integrating adder for superimposing an amplified signal output from an amplifier for amplifying a vibration displacement signal and an amplified signal output from a switching unit. is there.

The MFB speaker system according to the present invention includes an amplifier for amplifying an output signal output from the integrating adder.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below. Embodiment 1 FIG. FIG. 1 shows M according to Embodiment 1 of the present invention.
It is a figure showing the composition of the FB system speaker system. In the figure, 1 is a signal input terminal to which an external signal is input, 2 is an adder (feedback adder) which superimposes an external input signal and a feedback signal described later and outputs a synthesized signal, 3
Is a power amplifier for inputting and amplifying a synthesized signal, 4 is a speaker unit driven by a signal output from the power amplifier, 5 is a closed cabinet to which the speaker unit 4 is attached, 6 is a diaphragm of the speaker unit 4 Vibration displacement detection means for detecting the vibration displacement of
7 is a vibration speed detecting means for detecting a vibration speed of the diaphragm of the speaker unit 4, 8 is an amplifier for amplifying a signal output from the vibration displacement detecting means 6 and outputting an in-phase amplified signal, 9 is This is an amplifier that amplifies the signal output from the vibration speed detecting means 7 and outputs an in-phase amplified signal. Referring also to the symbols, x is the vibration displacement signal, v of the speaker unit 4 is vibration velocity signal of the speaker unit 4, a gain of k _1, k ₂ respectively amplifiers 8, 9, X is outputted from the amplifier 8 vibration An amplified signal having the same phase as the displacement signal x, and V is an amplified signal having the same phase as the vibration velocity signal v output from the amplifier 9.

Next, the operation will be described. An input signal externally applied to the signal input terminal 1 is amplified by the power amplifier 3 and the amplified signal drives the speaker unit 4. In the speaker unit 4, the diaphragm vibrates to generate sound to the outside. At this time, the vibration displacement detecting means 6 and the vibration velocity detecting means 7 detect the vibration displacement and the vibration velocity relating to the vibration of the diaphragm, respectively. Based on the detected vibration displacement and vibration speed, the vibration displacement detecting means 6 and the vibration speed detecting means 7 output a vibration displacement signal x and a vibration speed signal v, respectively. The amplifier 8 receives the vibration displacement signal x and outputs an amplified signal X having the same phase as the vibration displacement signal x. The amplifier 9 receives the vibration velocity signal v and outputs an amplified signal V having the same phase as the vibration velocity signal v. The adder 2 superimposes an external input signal, the amplified signal X, and the amplified signal V to output a combined signal. The power amplifier 3 amplifies the combined signal and drives the speaker unit 4 with the amplified signal. Since the amplified signal X and the amplified signal V are superimposed on an external input signal in the adder 2, the vibration displacement signal x and the vibration speed signal v are positively fed back.

Here, the meaning of positively feeding back the vibration displacement signal x and the vibration speed signal v will be described. In the conventional MFB speaker system shown in FIG. 10, the feedback signal is fed back with a negative polarity. For this, as shown in FIG. 11 (a), the velocity type MFB system, the sound pressure level decreases at the lowest resonance frequency f ₀ near the feedback amount D ₁ is increased. Further, as shown in FIG. 11 (c), the displacement-type MFB system, the lowest resonance frequency f ₀ is increased when the feedback amount D _S is increased.

In contrast, in the MFB speaker system according to the first embodiment of the present invention shown in FIG. 1, the speaker unit 4 attached to the closed cabinet 5
When the vibration displacement signal x and the vibration velocity signal v are positively fed back, the change in the frequency characteristics of the sound pressure level is opposite to that in the conventional MFB speaker system. That is,
For velocity type MFB system, increasing the gain k ₂ of the amplifier 9, the lowest resonance frequency f ₀ sound in the vicinity of pressure level is increased. Further, the displacement type MFB system, increasing the gain k ₁ of the amplifier 8, the sound pressure level is only the lowest resonance frequency f ₀ is lowered without lowering. Therefore, the positive feedback of the vibration displacement signal x allows the lowest resonance frequency f ₀ without lowering the efficiency of the power amplifier 3.
And the reproduction frequency band is extended to a lower sound range as a speaker system. Further, by positively feeding back the vibration velocity signal v, the sharpness Q _{0 and the} sound pressure level increase near the lowest resonance frequency f ₀ .

In the embodiment shown in FIG. 1, a configuration is provided in which the vibration displacement detecting means 6 and the vibration speed detecting means 7 are provided with separate vibration detecting means. It is also possible to extract both signals via a differentiating circuit or an integrating circuit using only the means. Also,
It is also possible to take out a vibration velocity signal and a vibration displacement signal by using a vibration acceleration detecting means via an integration circuit.

As described above, according to the first embodiment, the vibration displacement detecting means 6 for detecting the vibration displacement of the diaphragm of the speaker unit 4 attached to the closed cabinet 5, and the vibration of the diaphragm A signal speed detecting means 7 for detecting a speed, an amplifier 8 for amplifying a signal output from the vibration displacement detecting means 6 and outputting an amplified signal having the same phase, and amplifying a signal output from the vibration speed detecting means 7 An amplifier 9 for outputting an in-phase amplified signal, an adder 2 for superimposing an amplified signal X output from the amplifier 8 and an amplified signal V output from the amplifier 9 on an input signal input from the outside. , since it is configured to include a power amplifier 3 which drives the speaker unit 4 amplifies the synthesized signal output from the adder 2, a high frequency band smell than the lowest resonance frequency f ₀ Thereby enabling expansion of the reproduction frequency band without also causing a decrease in efficiency of the power amplifier,
An effect that it is possible to increase the sound pressure level at the minimum resonance frequency f ₀ near.

In the MFB speaker system according to the first embodiment shown in FIG. 1, only one of the combination of vibration displacement detecting means 6 and amplifier 8 or the combination of vibration velocity detecting means 7 and amplifier 9 is used. As a configuration provided, only one of the vibration displacement signal x and the vibration velocity signal v can be positively fed back. When a configuration in which only the vibration displacement detecting means 6 and the amplifier 8 are provided is adopted, the lowest resonance frequency f ₀ is lowered without lowering the efficiency of the power amplifier, and the reproduction frequency band is extended to a lower frequency range as a speaker system. The effect that it can expand is produced. Further, in the case of employing a configuration in which only vibration speed detection means 7 and the amplifier 9, an effect that it is possible to increase the sound pressure level increase the sharpness Q ₀ at the lowest resonance frequency f ₀ near .

Embodiment 2 FIG. 2 is a diagram showing a configuration of an MFB speaker system according to Embodiment 2 of the present invention. 2, the same reference numerals as those in FIG. 1 denote the same or corresponding parts, and a description thereof will not be repeated. 11 is an amplifier (in-phase amplifier) that amplifies the signal output from the vibration velocity detecting means 7 and outputs an amplified signal of the same phase, and 12 amplifies the signal output from the vibration velocity detecting means 7 and An amplifier (opposite-phase amplifier) 13 for outputting an amplified signal is a switch (switching means) for selecting either the amplified signal from the amplifier 11 or the amplified signal from the amplifier 12. V ′ is an amplified signal having the opposite phase to the vibration velocity signal v output from the amplifier 12.

Next, the operation will be described. Amplifier 11
Receives the vibration velocity signal v and outputs an amplified signal V having the same phase as the vibration velocity signal v. The amplifier 12 receives the vibration velocity signal v and outputs an amplified signal V ′ having a phase opposite to that of the vibration velocity signal v. The switch 13 is switchable, and feeds back either the amplified signal V from the amplifier 11 or the amplified signal V ′ from the amplifier 12 to the adder 2. When the amplified signal V from the amplifier 11 is selected by the switch 13, the operation is the same as that in the first embodiment, and the description is omitted.

[0027] When the amplified signal V from the amplifier 12 by the switch 13 'is selected, depending on the increase of the absolute value of the gain "-k _2" of the amplifier 12, the lowest resonance frequency f ₀ tone in the neighborhood The pressure level drops. That is, the sound pressure characteristics of the speaker system in this case are similar to those of the speed type MFB in the conventional MFB speaker system. Therefore, the MFB according to the second embodiment
In the loudspeaker system, the vibration displacement signal x is positively fed back, and the vibration velocity signal v can be selected from either positive feedback or negative feedback. Therefore, by positive feedback of the vibration displacement signal x, to lower the lowest resonance frequency f ₀ without reducing the efficiency of the power amplifier 3, a speaker system, reproduction frequency band is expanded to a lower frequency range. Further, the switch 13 is switched to arbitrarily select the polarity of the vibration velocity signal v to be fed back, and adjust the sharpness Q ₀ in the low frequency range.

As described above, according to the second embodiment, the vibration displacement signal x output from the vibration displacement detecting means 6
An amplifier 8 that amplifies the signal and outputs an in-phase amplified signal; an amplifier 11 that amplifies the vibration speed signal v output from the vibration speed detecting means 7 and outputs an in-phase amplified signal; An amplifier 12 that amplifies the vibration velocity signal v output from the amplifier and outputs an amplified signal of the opposite phase.
Amplifying signal or since it is configured to include a switch 13 for selecting one of the amplified signal from the amplifier 12 from the reproduction without causing a reduction in efficiency of the power amplifier also in the higher frequency band than the minimum resonance frequency f ₀ It is possible to expand the frequency band, and it is possible to arbitrarily select the polarity of the vibration velocity signal v to be fed back by switching the switch 13 to adjust the sharpness in the low frequency range.

In the MFB loudspeaker system according to the second embodiment shown in FIG. 2, the combination of the vibration displacement detecting means 6 and the amplifier 8 is excluded, and the vibration velocity detecting means 7, the amplifier 11, the amplifier 12, and the switch 13
Only the vibration velocity signal v can be fed back as a configuration in which only the combination of the above is provided. When such a configuration is adopted, there is an effect that the polarity of the vibration velocity signal v to be fed back by switching the switch 13 can be arbitrarily selected to adjust the sharpness Q ₀ in the low frequency range.

Embodiment 3 FIG. 3 is a diagram showing a configuration of an MFB speaker system according to Embodiment 3 of the present invention. 3, the same reference numerals as those in FIG. 1 denote the same or corresponding parts, and a description thereof will not be repeated. Reference numeral 21 denotes an amplifier that amplifies the vibration velocity signal v output from the vibration velocity detection means 7 and outputs an amplified signal V ′ having the opposite phase.

Next, the operation will be described. An input signal externally applied to the signal input terminal 1 is amplified by the power amplifier 3 and the amplified signal drives the speaker unit 4. In the speaker unit 4, the diaphragm vibrates to generate sound to the outside. At this time, the vibration displacement detecting means 6 and the vibration velocity detecting means 7 detect the vibration displacement and the vibration velocity relating to the vibration of the diaphragm, respectively. Based on the detected vibration displacement and vibration velocity, the vibration displacement detection means 6 and the vibration velocity detection means 7 output a vibration displacement signal x and a vibration velocity signal v, respectively. The amplifier 8 receives the vibration displacement signal x, and outputs an amplified signal X having the same phase as the vibration displacement signal x.
Is output. The amplifier 21 receives the vibration velocity signal v and outputs an amplified signal V ′ having a phase opposite to that of the vibration velocity signal v. The adder 2 superimposes the input signal from outside, the amplified signal X, and the amplified signal V ′ to output a synthesized signal. The power amplifier 3 amplifies the combined signal and drives the speaker unit 4 with the amplified signal. Since the amplified signal X and the amplified signal V 'are superimposed on an external input signal in the adder 2, the vibration displacement signal x is positively fed back, and the vibration velocity signal v is negatively fed back.

[0032] Therefore, the vibration displacement signal x be to positive feedback, by lowering the minimum resonance frequency f ₀ without reducing the efficiency of the power amplifier 3, a speaker system, expanding the reproduction frequency band to a lower frequency range . Also,
By performing the negative feedback of the vibration velocity signal v, the same operation as the velocity type MFB of the conventional MFB speaker system occurs. That is, the sharpness Q ₀ in the low frequency range is reduced. For example, due to such that the volume of the cabinet 5 is small, when the sharpness Q ₀ as the speaker system is too large, by increasing the absolute value of the gain "-k _2" of the amplifier 21, the optimum sharp The degree can be adjusted to Q ₀ .

As described above, according to the third embodiment, the vibration displacement signal x output from the vibration displacement detecting means 6
11 that amplifies the signal and outputs an in-phase amplified signal X
And a vibration speed signal v output from the vibration speed detection means 7
21 that amplifies the signal and outputs an amplified signal V ′ having the opposite phase
Therefore, even in a frequency band higher than the lowest resonance frequency f _{0, the} reproduction frequency band can be expanded without lowering the efficiency of the power amplifier, and a speaker system having a large sharpness Q ₀ can be sharpened. There is an effect that the degree Q ₀ can be reduced and adjusted to an optimum value.

Embodiment 4 FIG. 4 is a diagram showing a configuration of an MFB speaker system according to Embodiment 4 of the present invention. 4, the same reference numerals as those in FIG. 1 denote the same or corresponding parts, and a description thereof will not be repeated. 31 is the amplifier 8
Signal X having the same phase as vibration displacement signal x output from
And an adder (integration adder) that superimposes the vibration velocity signal v output from the amplifier 9 and the amplified signal V having the same phase. Z ₁ is a feedback signal obtained by superimposing the amplified signal X and the amplified signal V.

Next, the operation will be described. Amplifier 8
An amplified signal X having the same phase as the vibration displacement signal x output from the vibration displacement detection means 6 is output. The amplifier 9 outputs an amplified signal V having the same phase as the vibration velocity signal v output from the vibration velocity detection means 7. The adder 31 superimposes the amplification signal X and the amplified signal V and outputs a feedback signal Z _1. Adder 2
Superimposes the input signal from the external and feedback signal Z ₁ and outputs the combined signal. Other operations are the same as those in the first embodiment, and a description thereof will be omitted. Since the feedback signal Z ₁ given as a sum signal of the amplified signal X and the amplified signal V is superimposed on the input signal from the outside in summer 2, the vibration displacement signal x and the vibration velocity signal v is a positive feedback Will be.

In contrast to the two feedback loops in the first embodiment, in this embodiment, only one feedback loop exists by providing the adder 31.
As a result, the vibration displacement signal x and the vibration speed signal v are fed back to the adder 2 as a sum signal without being individually fed back. Therefore, handling of return becomes easy. Further, as in the first embodiment, the vibration resonance signal x is positively fed back, thereby lowering the lowest resonance frequency f ₀ without lowering the efficiency of the power amplifier 3 and reproducing the sound to a lower frequency range as a speaker system. The frequency band expands. Further, by positively feeding back the vibration velocity signal v, the sharpness Q _{0 and the} sound pressure level increase near the lowest resonance frequency f ₀ .

As described above, according to the fourth embodiment, the same effect as that of the first embodiment can be obtained, and the amplified signal X having the same phase as the vibration displacement signal x output from the amplifier 8 can be obtained. And the adder 31 for superimposing the vibration velocity signal v output from the amplifier 9 and the in-phase amplified signal V, so that the vibration displacement signal x and the vibration velocity signal v are not individually fed back. Since the signal is fed back to the adder 2 as a sum signal, there is an effect that handling of the feedback becomes easy.

Embodiment 5 FIG. 5 is a diagram showing a configuration of an MFB speaker system according to Embodiment 5 of the present invention. 5, the same reference numerals as those in FIG. 2 denote the same or corresponding parts, and a description thereof will not be repeated. 41 is the amplifier 8
Adder (an integration adder) that superimposes the amplified signal X output from the amplifier 13 and either the amplified signal V output from the amplifier 11 or the amplified signal V ′ output from the amplifier 12 in response to the switching of the switch 13. Container). Also, Z ₂
Is a feedback signal obtained by superimposing the amplified signal X and the amplified signal V or the amplified signal V ′.

Next, the operation will be described. Amplifier 8
An amplified signal X having the same phase as the vibration displacement signal x output from the vibration displacement detection means 6 is output. The amplifier 11 outputs an amplified signal V having the same phase as the vibration velocity signal v output from the vibration velocity detection means 7. The amplifier 12 outputs an amplified signal V ′ having a phase opposite to that of the vibration speed signal v output from the vibration speed detection means 7. The switch 13 is switchable, and outputs either the amplified signal V from the amplifier 11 or the amplified signal V ′ from the amplifier 12 to the adder 41.

When the amplified signal V from the amplifier 11 is selected by the switch 13, the adder 41 outputs the amplified signal X
And superimposing the amplified signal V and outputs a feedback signal Z ₂ and. Further, the amplified signal V ′ from the amplifier 12 is switched by the switch 13.
Is selected, the adder 41 superimposes the amplified signal X and the amplified signal V ′ to output a feedback signal Z ₂ . The adder 2 superimposes the input signal from the outside and the feedback signal Z ₂ and outputs the combined signal. The other operations are the same as those in the second embodiment, and a description thereof will be omitted. Since the feedback signal Z _2, given as a superposition signal and the amplified signal X amplified signal V or the amplified signal V 'is superimposed on the input signal from the outside in summer 2, the vibration displacement signal x is positive feedback, With respect to the vibration velocity signal v, either positive feedback or negative feedback can be selected.

In contrast to the two feedback loops in the second embodiment, in this embodiment, only one feedback loop exists by providing the adder 41.
As a result, the vibration displacement signal x and the vibration velocity signal v are fed back to the adder 2 as superimposed signals without being individually fed back. Therefore, handling of return becomes easy.
Further, as in the second embodiment, the vibration resonance signal x is positively fed back, thereby lowering the lowest resonance frequency f ₀ without lowering the efficiency of the power amplifier. Expands. Further, the switch 13 is switched to arbitrarily select the polarity of the vibration velocity signal v to be fed back, and adjust the sharpness Q ₀ in the low frequency range.

As described above, according to the fifth embodiment, the same effect as that of the second embodiment can be obtained, and the amplification signal X output from the amplifier 8 and the switching of the switch 13 can be changed. Since the adder 41 configured to superimpose the amplified signal V output from the amplifier 11 or the amplified signal V ′ output from the amplifier 12 is provided, the vibration displacement signal x and the vibration speed signal v are individually fed back. Since the feedback signal is fed back to the adder 2 without being superimposed, the feedback is easily handled.

Embodiment 6 FIG. FIG. 6 is a diagram showing a configuration of an MFB speaker system according to Embodiment 6 of the present invention. 6, the same reference numerals as those in FIG. 3 denote the same or corresponding parts, and a description thereof will not be repeated. 51 is an amplifier 8
Signal X having the same phase as vibration displacement signal x output from
And an adder (integrating adder) that superimposes the vibration velocity signal v output from the amplifier 21 and the amplified signal V ′ having the opposite phase. Z ₃ is a feedback signal obtained by superimposing the amplified signal X and the amplified signal V ′.

Next, the operation will be described. Amplifier 8
An amplified signal X having the same phase as the vibration displacement signal x output from the vibration displacement detection means 6 is output. The amplifier 21 outputs an amplified signal V ′ having a phase opposite to that of the vibration speed signal v output from the vibration speed detection means 7. The adder 51 superimposes the amplified signal X and the amplified signal V ′ and outputs a feedback signal Z ₃ . The adder 2 superimposes the input signal from the external and feedback signal Z ₃ and outputs the combined signal. The other operations are the same as those in the third embodiment, and the description thereof is omitted. In addition,
Since the feedback signal Z ₃ given as a sum signal of the amplified signal X and the amplified signal V 'is superimposed on the input signal from the outside in summer 2, the vibration displacement signal x is positive feedback, vibration velocity signal v is negative Will be returned.

In contrast to the case where there are two feedback loops in the third embodiment, this embodiment has only one feedback loop by providing the adder 51.
As a result, the vibration displacement signal x and the vibration velocity signal v are fed back to the adder 2 as superimposed signals without being individually fed back. Therefore, handling of return becomes easy.
Further, similarly to the third embodiment, the lowest resonance frequency f ₀ is reduced without lowering the efficiency of the power amplifier 3 by positively feeding back the vibration displacement signal x, so that the speaker system is reproduced to a lower frequency range. The frequency band expands.
Further, the sharpness Q ₀ in the low range decreases by causing negative feedback vibration velocity signal v. For example, due to such that the volume of the cabinet 5 is small, when the sharpness Q ₀ as the speaker system is too large, by increasing the absolute value of the gain "-k _2" of the amplifier 21, the optimum sharp The degree can be adjusted to Q ₀ .

As described above, according to the sixth embodiment, the same effect as in the third embodiment can be obtained, and the amplified signal X having the same phase as the vibration displacement signal x output from the amplifier 8 can be obtained. Is configured to include the adder 51 that superimposes the vibration velocity signal v output from the amplifier 21 and the amplified signal V ′ having the opposite phase, so that the vibration displacement signal x and the vibration velocity signal v are individually fed back. Since the feedback is fed back to the adder 2 as a superimposed signal, the feedback is easily handled.

Embodiment 7 FIG. FIG. 7 is a diagram showing a configuration of an MFB speaker system according to Embodiment 7 of the present invention. 7, the same reference numerals as those in FIG. 4 denote the same or corresponding parts, and a description thereof will not be repeated. 61 is an adder 3
Amplifies the signal Z ₁ output from the 1 is an amplifier for outputting an amplified signal of the same phase. K ₃ is the gain of the amplifier 61, and Z ₁ ′ is an amplified signal having the same phase as the signal Z ₁ output from the amplifier 61.

Next, the operation will be described. Amplifier 8
An amplified signal X having the same phase as the vibration displacement signal x output from the vibration displacement detection means 6 is output. The amplifier 9 outputs an amplified signal V having the same phase as the vibration velocity signal v output from the vibration velocity detection means 7. The adder 31 outputs a signal Z ₁ are superimposed amplification signal X and the amplified signal V. Amplifier 61
An amplified signal Z ₁ ′ having the same phase as the signal Z ₁ output from the adder 31 is output. The adder 2 superimposes an external input signal and the amplified signal Z ₁ ′ and outputs a composite signal. The other operations are the same as those in the fourth embodiment, and the description thereof is omitted. Incidentally, the amplified signal Z for the signal Z ₁ given as a sum signal of the amplified signal X and the amplified signal V
_{Since 1} 'is superimposed on an external input signal in the adder 2, the vibration displacement signal x and the vibration velocity signal v are positively fed back.

The amplifier 61 integrally amplifies the sum signal Z ₁ relating to the vibration displacement signal x and the vibration velocity signal v. Therefore, the magnitude of the feedback signal to the adder 2 can be adjusted as a whole. Therefore, by combining the adder 31 and the amplifier 61, the feedback loop can be reduced to one and the magnitude of the signal transmitted through the feedback loop can be adjusted as a whole, so that the handling of feedback is further facilitated. Further, as in the first embodiment, the vibration resonance signal x is positively fed back, thereby lowering the lowest resonance frequency f ₀ without lowering the efficiency of the power amplifier 3 and reproducing the sound to a lower frequency range as a speaker system. The frequency band expands. Further, by positively feeding back the vibration velocity signal v, the sharpness Q _{0 and the} sound pressure level increase near the lowest resonance frequency f ₀ .

As described above, according to the seventh embodiment, the same effect as that of the fourth embodiment can be obtained, and the amplified signal X having the same phase as the vibration displacement signal x output from the amplifier 8 can be obtained. An adder 31 that superimposes the vibration velocity signal v output from the amplifier 9 and the in-phase amplified signal V, and amplifies the signal Z ₁ output from the adder 31 to generate an in-phase amplified signal Z ₁ ′. Since the output amplifier 61 is provided, the feedback loop can be reduced to one, and the magnitude of the signal transmitted through the feedback loop can be adjusted as a whole. It works.

Embodiment 8 FIG. FIG. 8 is a diagram showing a configuration of an MFB speaker system according to an eighth embodiment of the present invention. 8, the same reference numerals as those in FIG. 5 denote the same or corresponding parts, and a description thereof will not be repeated. 71 is an adder 4
Amplifies the signal Z ₂ output from the 1 is an amplifier for outputting an amplified signal of the same phase. Z ₂ ′ is an amplified signal having the same phase as the signal Z ₂ output from the amplifier 71.

Next, the operation will be described. Amplifier 8
An amplified signal X having the same phase as the vibration displacement signal x output from the vibration displacement detection means 6 is output. The amplifier 11 outputs an amplified signal V having the same phase as the vibration velocity signal v output from the vibration velocity detection means 7. The amplifier 12 outputs an amplified signal V ′ having a phase opposite to that of the vibration speed signal v output from the vibration speed detection means 7. The switch 13 is switchable, and outputs either the amplified signal V from the amplifier 11 or the amplified signal V ′ from the amplifier 12 to the adder 41. The adder 41 superimposes the amplification signal X and the amplified signal V, or by superimposing the amplified signal X amplified signal V 'and outputs a signal Z ₂ in. Amplifier 71 outputs an amplified signal Z ₂ ′ having the same phase as signal Z ₂ output from adder 41. Adder 2
Superimposes the input signal from the outside and the amplified signal Z ₂ ′ to output a synthesized signal. The other operations are the same as those in the fifth embodiment, and the description thereof is omitted. Depending on the selection of the switch 13, the adder ₂ generates an amplified signal Z ₂ ′ of a signal Z ₂ provided as a sum signal of the amplified signal X and the amplified signal V or a sum signal of the amplified signal X and the amplified signal V ′. Since the vibration displacement signal x is superimposed on the external input signal, the vibration velocity signal v can be selected from either positive feedback or negative feedback.

[0053] amplifier 71 amplifies the superimposed signal Z ₂ according to the vibration displacement signal x and the vibration velocity signal v as a unit.
Therefore, the magnitude of the feedback signal to the adder 2 can be adjusted as a whole. Therefore, by combining the adder 41 and the amplifier 71, the feedback loop can be reduced to one, and the magnitude of the signal transmitted through the feedback loop can be adjusted as a whole, so that the handling of feedback is further facilitated. Further, as in the second embodiment, the vibration resonance signal x is positively fed back, thereby lowering the lowest resonance frequency f ₀ without lowering the efficiency of the power amplifier. Expands.
Further, the switch 13 is switched to arbitrarily select the polarity of the vibration velocity signal v to be fed back, and the sharpness Q ₀ in the low frequency range is reduced.
To adjust.

As described above, according to the eighth embodiment, the same effect as that of the fifth embodiment can be obtained, and the amplified signal X output from the amplifier 8 and the switch 1
An adder 41 for superimposing the amplified signal V 'and output from the amplification signal V or amplifier 12 is output from the amplifier 11 in accordance with the third switching the amplifies the signal Z ₂ output from the adder 41 Since it is configured to include the amplifier 71 that outputs the amplified signal Z ₂ ′ of the phase,
In addition, since the magnitude of the signal transmitted in the feedback loop can be adjusted as a whole, there is an effect that the handling of feedback is further facilitated.

Embodiment 9 FIG. FIG. 9 is a diagram showing a configuration of an MFB speaker system according to Embodiment 9 of the present invention. In FIG. 9, the same reference numerals as those in FIG. 6 denote the same or corresponding parts, and a description thereof will not be repeated. 81 is an adder 5
Amplifies the signal Z ₃ outputted from the 1 is an amplifier for outputting an amplified signal of the same phase. Z ₃ ′ is an amplified signal having the same phase as the signal Z ₃ output from the amplifier 81.

Next, the operation will be described. Amplifier 8
An amplified signal X having the same phase as the vibration displacement signal x output from the vibration displacement detection means 6 is output. The amplifier 21 outputs an amplified signal V ′ having a phase opposite to that of the vibration speed signal v output from the vibration speed detection means 7. The adder 51 superimposes the amplified signal X and the amplified signal V ′ and outputs a signal Z ₃ . Amplifier 8
1 outputs an amplified signal Z ₃ ′ having the same phase as the signal Z ₃ output from the adder 51. The adder 2 superimposes the external input signal and the amplified signal Z ₃ ′ and outputs a composite signal. Other operations are the same as in the sixth embodiment, and a description thereof will be omitted. Since the amplified signal Z ₃ ′ of the signal Z ₃ given as the sum signal of the amplified signal X and the amplified signal V ′ is superimposed on the external input signal in the adder 2, the vibration displacement signal x is positive feedback. As a result, the vibration velocity signal v is negatively fed back.

The amplifier 81 integrally amplifies the superimposed signal Z ₃ relating to the vibration displacement signal x and the vibration velocity signal v.
Therefore, the magnitude of the feedback signal to the adder 2 can be adjusted as a whole. Therefore, by combining the adder 51 and the amplifier 81, the number of feedback loops can be reduced and the magnitude of the signal transmitted through the feedback loop can be adjusted as a whole, so that the handling of feedback is further facilitated. Further, similarly to the third embodiment, the vibration displacement signal x
Is positively fed back, thereby lowering the lowest resonance frequency f ₀ without lowering the efficiency of the power amplifier 3 and expanding the reproduction frequency band to a lower sound range as a speaker system. Further, the sharpness Q ₀ in the low range decreases by causing negative feedback vibration velocity signal v. For example, due to such that the volume of the cabinet 5 is small, when the sharpness Q ₀ as the speaker system is too large, by increasing the absolute value of the gain "-k _2" of the amplifier 21, the optimum sharp The degree can be adjusted to Q ₀ .

As described above, according to the ninth embodiment, the same effect as that of the sixth embodiment can be obtained, and the amplified signal X having the same phase as the vibration displacement signal x output from the amplifier 8 can be obtained. Adder 51 that superimposes vibration velocity signal v output from amplifier 21 and amplified signal V ′ having the opposite phase.
And an amplifier 81 that amplifies the signal Z ₃ output from the adder 51 and outputs an amplified signal Z ₃ ′ having the same phase, so that the number of feedback loops is reduced to one and transmitted by the feedback loop. Since the magnitude of the signal to be adjusted can be adjusted as a whole, there is an effect that handling of feedback is further facilitated.

[0059]

As is evident from the foregoing description, according to the present invention, since it is configured so as to positive feedback vibration displacement signal to the feedback adder, a low minimum resonance frequency f ₀ without reducing the efficiency of the power amplifier As a result, the speaker system has an effect that the reproduction frequency band can be expanded to a lower sound range.

[0060] According to the present invention, since constitute a vibration velocity signal so as to positive feedback to the feedback adder, to increase the sound pressure level increase the sharpness Q ₀ at the lowest resonance frequency f ₀ near It has the effect of being able to.

According to the present invention, since the vibration velocity signal is selectively fed back or negatively fed back to the feedback adder, the polarity of the vibration velocity signal to be fed back can be arbitrarily selected to be used in the low frequency range. an effect that it is possible to adjust the sharpness Q _0.

According to the present invention, the vibration displacement signal is used for feedback.
Positive feedback to the adder and vibration speed signal for feedback
Since it is configured to provide positive feedback to the calculator,
Number f ₀ Even in higher frequency bands, the power amplifier
Enables the reproduction frequency band to be expanded without reducing the rate
And the lowest resonance frequency f₀ Sound pressure level in the vicinity
The effect is that the number of files can be increased.

According to the present invention, the vibration displacement signal is positively fed back to the feedback adder, and the vibration velocity signal is selectively positively or negatively fed back to the feedback adder. thereby allowing the expansion of reproduction frequency band without causing a decrease in efficiency of the power amplifier also in the higher frequency band than f _0, the sharpness Q ₀ at arbitrarily selected and bass polarity of the vibration velocity signal for feeding back This has the effect of being adjustable.

[0064] According to the present invention, together to the positive feedback of the vibration displacement signal to the feedback adder, since it is configured so as to negative feedback vibration velocity signal to the feedback adder, a frequency band higher than the lowest resonance frequency f ₀ effect that it is as well as to allow expansion of the reproduction frequency band without causing a decrease in efficiency of the power amplifier is also possible to sharpness Q ₀ is adjusted to the optimum value by reducing the sharpness Q ₀ for large loudspeaker systems in To play.

According to the present invention, there is provided an integrating adder for superimposing an amplified signal output from an amplifier for amplifying a vibration displacement signal and an amplified signal output from an amplifier for amplifying a vibration velocity signal. Therefore, since the vibration displacement signal and the vibration velocity signal are fed back to the feedback adder as a superimposed signal without being individually fed back, there is an effect that handling of the feedback becomes easy.

According to the present invention, since the integrating adder for superimposing the amplified signal output from the amplifier for amplifying the vibration displacement signal and the amplified signal output from the switching means is provided, the vibration displacement signal is provided. In addition, since the vibration velocity signal is fed back to the feedback adder as a superimposed signal without being individually fed back, an effect is obtained in that handling of the feedback becomes easy.

According to the present invention, since an amplifier for amplifying the output signal output from the integrating adder is provided, the feedback loop is reduced to one and the magnitude of the signal transmitted by the feedback loop is reduced. Since the adjustment can be made as a whole, there is an effect that the handling of the return is further facilitated.

[Brief description of the drawings]

FIG. 1 is a diagram showing a configuration of an MFB speaker system according to Embodiment 1 of the present invention.

FIG. 2 is a diagram showing a configuration of an MFB speaker system according to Embodiment 2 of the present invention.

FIG. 3 is a diagram showing a configuration of an MFB speaker system according to Embodiment 3 of the present invention.

FIG. 4 is a diagram showing a configuration of an MFB speaker system according to Embodiment 4 of the present invention.

FIG. 5 is a diagram showing a configuration of an MFB speaker system according to Embodiment 5 of the present invention.

FIG. 6 is a diagram showing a configuration of an MFB speaker system according to Embodiment 6 of the present invention.

FIG. 7 is a diagram showing a configuration of an MFB speaker system according to a seventh embodiment of the present invention.

FIG. 8 is a diagram showing a configuration of an MFB speaker system according to an eighth embodiment of the present invention.

FIG. 9 is a diagram showing a configuration of an MFB speaker system according to Embodiment 9 of the present invention.

FIG. 10 is a diagram showing the configuration of a conventional MFB speaker system.

FIG. 11 shows a speed type MF according to a conventional speaker system.
B is a graph showing frequency characteristics of acceleration MFB and displacement MFB.

[Explanation of symbols]

1 signal input terminal, 2 adder (feedback adder), 3
Power amplifier, 4 speaker unit, 5 cabinet, 6 vibration displacement detecting means, 7 vibration speed detecting means,
8, 9, 21 amplifier, 11 amplifier (in-phase amplifier), 12 amplifier (out-of-phase amplifier), 13 switch (switching means), 31, 41, 51 adder (integration adder), 61, 71, 81 amplifier .

Claims (9)

[Claims] 1. A closed cabinet, a speaker unit attached to the closed cabinet, vibration displacement detecting means for detecting a vibration displacement of a diaphragm of the speaker unit, and output from the vibration displacement detecting means. An amplifier for amplifying the vibration displacement signal, a feedback adder for superimposing an input signal and a feedback signal input from the outside, and amplifying a composite signal output from the feedback adder to drive the speaker unit A MFB speaker system comprising: a power amplifier; and positively feeding back the vibration displacement signal to the feedback adder. 2. A closed cabinet, a speaker unit attached to the closed cabinet, vibration speed detecting means for detecting a vibration speed of a diaphragm of the speaker unit, and an output from the vibration speed detecting means. An amplifier for amplifying a vibration speed signal, a feedback adder for superimposing an input signal and a feedback signal input from the outside, and amplifying a composite signal output from the feedback adder to drive the speaker unit A MFB speaker system comprising: a power amplifier; and positively feeding back the vibration velocity signal to the feedback adder. 3. A closed cabinet, a speaker unit attached to the closed cabinet, vibration speed detecting means for detecting a vibration speed of a diaphragm of the speaker unit, and output from the vibration speed detecting means. An in-phase amplifier for amplifying the vibration velocity signal to the same phase; an anti-phase amplifier for amplifying the vibration velocity signal output from the vibration velocity detection means to the opposite phase; an amplified signal from the in-phase amplifier or the anti-phase amplifier Switching means for selecting and outputting any one of the amplified signals from the input device, a feedback adder for superimposing an externally input input signal and a feedback signal, and a combined signal output from the feedback adder. A power amplifier that amplifies and drives the speaker unit, and selectively returns positive or negative feedback of the vibration velocity signal to the feedback adder. An MFB speaker system characterized by the following. 4. A vibration speed detecting means for detecting a vibration speed of a vibration plate of a speaker unit, and an amplifier for amplifying a vibration speed signal output from the vibration speed detecting means, wherein the vibration speed signal is fed back. 2. The MFB speaker system according to claim 1, wherein positive feedback is provided to the adder. 5. A vibration speed detecting means for detecting a vibration speed of a vibration plate of a speaker unit, an in-phase amplifier for amplifying a vibration speed signal output from the vibration speed detecting device to the same phase, and said vibration speed detection. An anti-phase amplifier that amplifies the vibration velocity signal output from the means to an opposite phase, and a switching unit that selects and outputs one of the amplified signal from the in-phase amplifier and the amplified signal from the anti-phase amplifier. 2. The MFB speaker system according to claim 1, further comprising: selectively providing positive or negative feedback to the feedback adder for the vibration velocity signal. 6. A vibration speed detecting means for detecting a vibration speed of a vibration plate of a speaker unit, and an amplifier for amplifying a vibration speed signal output from the vibration speed detecting means, wherein the vibration speed signal is fed back. 2. The MFB speaker system according to claim 1, wherein a negative feedback is provided to the adder. 7. An integrating adder for superimposing an amplified signal output from an amplifier for amplifying a vibration displacement signal and an amplified signal output from an amplifier for amplifying a vibration velocity signal. 7. An MFB speaker system according to claim 6. 8. The MFB speaker according to claim 5, further comprising an integrating adder for superimposing an amplified signal output from an amplifier for amplifying the vibration displacement signal and an amplified signal output from the switching unit. system. 9. The MFB speaker system according to claim 7, further comprising an amplifier for amplifying an output signal output from the integration adder.