JPS62260411A - Power amplifier circuit - Google Patents

Abstract

PURPOSE:To prevent the parasitic oscillation of an amplifier means by providing an impedance element between output sections of the 1st and 2nd amplifier means so as to omit a capacitor compensating the high frequency characteristic. CONSTITUTION:A potential across an impedance element 24 placed between the 1st and 2nd amplifier means (power amplifiers 20a, 20b) is set to a common DC output voltage VDC, then a DC current flowing to the impedance element 24 is prevented to prevent the power loss. Since the impedance element 24 acts like an imaginary ground point to the output of the 1st and 2nd amplifier means (power amplifiers 20a, 20b), the impedance element 24 has the same function as the capacitor even when the capacitor is omitted. Thus, the parasitic oscillation of the 1st and 2nd amplifier means (power amplifiers 20a, 20b) is prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a power amplifier circuit for driving an electroacoustic transducer such as a speaker or a headphone, and particularly relates to improving drive characteristics such as prevention of oscillation.

[Conventional technology]

Since the speaker includes a voice coil inside thereof, the impedance characteristic is inductive, and the impedance increases in proportion to the frequency. Therefore, a power amplifier that drives such a speaker tends to cause oscillation in a high frequency range.

Especially 1. This type of power amplifier uses a feedback power amplifier to achieve high-fidelity voltage drive, which also makes oscillations more likely to occur.

In addition, the power amplifier that drives the hesodophone in addition to the speaker has a connector that allows the hesodophone to be attached and removed, so when the hesodophone is removed, the impedance of its output section becomes infinite, and this It also causes oscillation.

FIGS. 3 and 4 show the configuration of a conventional power amplifier circuit for driving an electroacoustic transducer such as a speaker or a bed phone.

In this power amplifier circuit, a feedback circuit 8 consisting of a resistor 4.6 is provided in a power amplifier 2 to constitute a feedback type power amplifier circuit. Input terminal 1 of power amplifier 2 from the amplification means on the previous stage side
The input signal added to 0 is amplified by a power amplifier 2,
The output signal is applied to the speaker 14 after the DC component is removed by the capacitor 12. The speaker 14 is
It is driven by the AC component in the amplified output and generates audio output.

[Problem that the invention seeks to solve]

As a measure to prevent oscillation in such a power amplifier circuit, as shown in FIG. 3, by connecting a capacitor 16 in parallel to the speaker 14, the increase in impedance of the speaker 14 in the high frequency range can be reduced. , countermeasures are taken to reduce the impedance of the capacitor 16 in the high frequency range.

However, when the power amplifier 2 is configured with an emitter follower type circuit, oscillation may occur in a high frequency range due to the capacitance of the capacitor 16. In such a case, as shown in FIG. 4, a resistor 18 is connected in series with the capacitor 16 to prevent an extreme drop in impedance and prevent oscillation.

In this way, when the resistor 18 with a low resistance value is connected in series with the capacitor 16, there may be a loss due to the resistor 18, but since the capacitor 16 has a capacitance of 0.1 μF or less, the speaker There will be no problem such as a decrease in audio power for the 14.

However, since the capacitor 16 is for high frequency compensation and is required to have excellent high frequency characteristics in order to maintain high fidelity, an expensive capacitor such as a polyester film is used, for example.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a power amplifier circuit that eliminates the need for such a capacitor for high frequency compensation and prevents oscillation in a high frequency range.

[Means for solving problems]

As shown in FIG.
a first amplifying means (power amplifier 20a) that amplifies the input signal Va of the input signal Va, and amplifies the second human power signal Vb;
DC output voltage V of the first amplification means (power amplifier 20a)
■ DC output voltage same as OC. . A second amplification means (power amplifier 20b) that generates a Electroacoustic conversion means (speakers 22a, 2
2b) and an impedance element 24 installed between the output parts of the first and second I171)' amplification means (power amplifiers 20a, 20b).

[For production]

With this configuration, the first amplifying means (power amplifier 2
0a) to the electroacoustic converting means (speaker 22a).
) and the second amplifying means (power amplifier 2
0b) to the electroacoustic converting means (speaker 22b).
). In this case, the first and second amplification means (
The output parts of the power amplifiers 2Qa, 20b) are coupled by an impedance element 24, and the DC output voltage VD of the first and second amplification means (power amplifiers 20a, 20b) is
The DC potential across the impedance element 240 is set by t.

In this way, the first and second amplification means (power amplifier 2
When the potentials across the impedance element 24 installed between the output parts of 0a and 20b) are set to a common DC output voltage VDe, direct current is prevented from flowing through the impedance element 24, and power loss is prevented. . Since the impedance element 24 functions as a virtual ground point for the output parts of the first and second amplification means (power amplifiers 20a, 20b), even if the capacitor 16 shown in FIG. 3 is omitted, the impedance element 24 Element 24 has the same function as capacitor 16, and parasitic oscillation of the first and second amplification means (power amplifiers 2Qa, 20b) is prevented.

〔Example〕

FIG. 1 shows an embodiment of the power amplifier circuit of the present invention.

This power amplification circuit has a first power applied to the input terminal 26a.
A power amplifier 20a is installed as a first amplification means for amplifying the input signal Va of the power amplifier 20a.
The same DC output voltage as the DC output voltage VDC generated by ■
0. A power amplifier 2 is used as a second amplifying means to generate a second human power signal vb applied to the input terminal 26b.
0b is installed.

The power amplifier 20a has a feedback circuit 32a made up of a resistor 28.30 added thereto to constitute a feedback type power amplifier, and the power amplifier 20b also has a feedback circuit 32b made up of a resistor 28.30 added thereto. It constitutes a feedback type power amplifier. That is, each power amplifier 20a, 20b ideally has common characteristics and has the same DC output voltage VD.
Suppose that C is generated.

Output terminal 34a of power amplifier 20a and power amplifier 2
The output terminal 34b of 0b is individually connected to a capacitor 36a,
Speaker 22 as an electroacoustic conversion means via 36b
a and 22b are connected.

An impedance element 24 is installed between the output terminal 34a of the power amplifier 20a and the output terminal 34b of the power amplifier 20b.

Therefore, the input signal Va applied to the input terminal 26a
After being amplified by the power amplifier 20a and the feedback circuit 32a, it is taken out from the output terminal 34a, the DC component is blocked by the capacitor 36a, and then supplied to the speaker 22a. Further, the human power signal v applied to the input terminal 26b
After being amplified by the power amplifier 20b and the feedback circuit 32b, the voltage b is taken out from the output terminal 34b, the DC component is blocked by the capacitor 36b, and then supplied to the speaker 22b. The speaker 22a is connected to an output terminal 34a.
The speaker 22b is driven by an AC signal generated at the output terminal 34b to generate audio output, and the speaker 22b is driven by an AC signal generated at the output terminal 34b to generate audio output.

In this case, each power amplifier 20a, 20b generates the same DC output voltage VOC, so the impedance element 2
As a result of setting the same DC potential between the terminals 4 and 4, no DC current from the outputs of the power amplifiers 20a and 20b flows through the impedance element 24. For this reason, the power amplifier 20
The output terminals 34a and 34b of the output terminals a and 20b become virtual ground points by the impedance element 24, and as a result, the power amplifier 2
Parasitic oscillation in the high frequency range of 0a and 20b is prevented.

If such two sets of power amplifiers 20a and 20b are used in a stereo reproduction device, and the first input signal is the right signal and the second input signal is the left signal, the speakers 22a,
Stereo output can be obtained from 22b.

Note that the following modifications of the embodiment are possible.

(Al The impedance element 24 may be composed of a pure resistance element as shown in FIG. 2.

(b) Instead of the speakers 22a and 22b, a stereo hesodophone or the like may be used as other electroacoustic conversion means.

(Since the AC output voltage from the amplification means flows through the C1 impedance element 24, its magnitude is set to a value larger than the impedance of the electroacoustic conversion means such as a speaker. In this way, the output efficiency of the impedance element 24 can be increased. It is possible to prevent a decrease in

(d) The speakers 22a, 22b are not provided with inductive DC blocking, that is, the speakers 22a, 22b are
You may also use one without b.

(el) Although the speaker 22a, 22b has been described as being connected in a fixed manner, the present invention can also be applied to a system in which the speaker 22a, 22b or headphones are connected via a connector or the like.
When 2a, 22b and the hesodophone are removed, the phase is stabilized by the impedance element 24, and the output impedance of the amplifying means can be prevented from increasing to infinity, thereby preventing parasitic oscillation.

〔Effect of the invention〕

As explained above, according to the present invention, the amplified outputs of the first and second amplifying means are supplied to the electroacoustic converting means, and the DC output voltages are equal. The output parts of the first and second amplifying means that generate , are coupled via an impedance element, and the DC potential across the impedance element is
Since the DC output voltage of the first and second amplifying means is set to VDC, the impedance element can be used as a virtual ground point for the output parts of the first and second amplifying means, thereby compensating for high frequency characteristics. In addition to omitting an expensive capacitor for the purpose of the present invention, parasitic oscillation of the amplifying means can be prevented, and high-fidelity reproduction can be realized.

[Brief explanation of drawings]

FIG. 1 is a circuit diagram showing an embodiment of the power amplifier circuit of the present invention, FIG. 2 is a circuit diagram showing a specific circuit configuration example of the impedance element of the power amplifier circuit shown in FIG. 1, and FIG. and FIG. 4 is a circuit diagram showing a conventional power amplifier circuit. 20a...Power amplifier as first amplification means, 20
b... A power amplifier as a second amplification means, 22a,
22b...Speaker as electroacoustic conversion means, 24
...Impedance element.

Claims (2)

[Claims] (1) A first amplification means that amplifies the first input signal; and a second amplification means that amplifies the second input signal and generates the same DC output voltage as the DC output voltage of the first amplification means. means, an electroacoustic conversion means installed for each of the first and second amplification means to convert the output generated by each amplification means into sound, and an impedance installed between the output parts of the first and second amplification means. A power amplification circuit characterized by comprising an element. (2) The power amplifier circuit according to claim 1, wherein the impedance element is composed of a pure resistance element.