JP2002271155A - Audio amplifier - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve S/N and the nose level of an audio amplifier. SOLUTION: The audio amplifier is provided with a variable voltage dividing circuit 22 of the resistance division type, to which audio signals are supplied, an amplifier 23 to which the output of the variable voltage dividing circuit 22 is supplied, and a second variable voltage dividing circuit 26 of the resistance divided type, which is connected to a negative feedback pathway of the amplifier 23 and change the amount of its feedback. The voltage division ratio of the variable voltage dividing circuit 26 is maintained to be a constant value from the minimum output level up to a specified output level, and the gain of the amplifier 23 is maintained at a constant value. By changing the voltage division ratio of the variable voltage dividing circuit 22, the gain is controlled to a targeted total gain. The voltage division ratio of the variable voltage dividing circuit 22 is maintained to a constant value from the specified output level up the maximum output level, and the output level of the variable voltage dividing circuit 22 is maintained to be maximal. By changing the gain of the amplifier 23 by changing the voltage division ratio of the variable voltage dividing circuit 26, the gain is controlled to a targeted total gain.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an amplifier having improved S / N and noise level.

[0002]

2. Description of the Related Art In FIG. 8, reference numeral 10 denotes a general audio amplifier.
In, the audio signal is supplied to the speaker SP through the signal line of the input terminal 11, the variable voltage dividing circuit 12, the preamplifier 13, the main amplifier 14, and the output terminal 15.

In this case, the variable voltage dividing circuit 12 functions as a so-called volume control. Although not shown, the variable voltage dividing circuit 12 is constituted by a resistance voltage dividing circuit and a plurality of switch circuits to form a resistance-divided attenuator circuit. The switching circuit is switched by a microcomputer for controlling the voltage dividing ratio, and as a result, the output level is controlled. Further, the preamplifier 13 is subjected to negative feedback by resistors 16 and 17,
The voltage gain A13 is, for example, 20 dB. The voltage gain A14 of the main amplifier 14 is, for example, 28 dB.

Further, in the case of a two-channel stereo amplifier or a multi-channel amplifier, an audio amplifier 1
0 is provided for the channel, and the variable voltage dividing circuits 12 of each channel are linked with each other.

[0005]

However, when the audio amplifier 10 is configured as described above, the amplifiers 13 and 14 can be adjusted regardless of the amount of attenuation of the variable voltage dividing circuit 12. Amplifies the audio signal with a fixed fixed gain (A13 + A14).
The noise component generated in step 2 is amplified by the gain (A13 + A14).

When the audio amplifier 10 is configured as described above, when the movable element (output terminal) of the variable voltage dividing circuit 12 is at the upper end or the lower end (the position of the maximum level or the minimum level) in the figure. , Preamplifier 1
3, the impedance when the variable voltage dividing circuit 12 is viewed becomes minimum, and at this time, the S / N of the preamplifier 13 itself becomes the best.

However, when the audio amplifier 10 is actually used, the movable element of the variable voltage dividing circuit 12 is often used at a knob position near 12:00. Becomes large, and as a result, the S / N of the preamplifier 13 itself deteriorates.

[0008] The present invention is to solve the above problems.

[0009]

According to the present invention, for example, a resistor-divided first variable voltage dividing means to which an audio signal is supplied, and an amplifier to which an output of the first variable voltage dividing means is supplied. And a resistor-divided second variable voltage dividing means connected to the negative feedback path of the amplifier to change the amount of the negative feedback. The voltage dividing ratio of the variable voltage dividing means is kept constant, the gain of the amplifier is kept constant, and the first
The target total gain is controlled by changing the voltage dividing ratio of the variable voltage dividing means, and the voltage dividing ratio of the first variable voltage dividing means is kept constant from the predetermined output level to the maximum output level. While maintaining the output level of the first variable voltage dividing means to the maximum, and changing the voltage dividing ratio of the second variable voltage dividing means to change the gain of the amplifier, the desired overall level is obtained. The audio amplifier is controlled to have a gain. Therefore, when the gain of the first variable voltage dividing means and the gain of the amplifier change in conjunction, the total gain of the audio amplifier changes.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In FIG. 1, reference numeral 20 denotes an example of an audio amplifier according to the present invention. In this audio amplifier 20, an audio signal is supplied from an input terminal 21 → a variable voltage dividing circuit 22 → a preamplifier 23 → The signal is supplied to the speaker SP through the signal line from the main amplifier 24 to the output terminal 25. Further, a variable voltage dividing circuit 26 is connected to an output terminal of the preamplifier 23, and the variable voltage divided output is fed back to the preamplifier 23 to be subjected to negative feedback.

In this case, although specific examples of the variable voltage dividing circuits 22 and 26 will be described later, these are constituted by a resistor dividing type attenuator circuit by a resistor voltage dividing circuit and a plurality of switch circuits, and a microcomputer for system control ( (Not shown), the switch circuit is switched to control the divided output (divided ratio) V22, V26.

At this time, the variable voltage dividing circuits 22, 2
The partial pressure characteristic of No. 6 is, for example, as shown in FIG. 2A. That is, the instruction value (in terms of a rotary volume control, the rotation angle of the operation knob) θ of the total gain or output level of the audio amplifier 20 is 0% to 100%
%. Then, the variable voltage dividing circuit 22
2A is 0% ≦ as shown by the solid line in FIG. 2A.
In the range of θ ≦ m% (0 <m <100, for example, m = 50%), the value monotonically increases from 0% as the indicated value θ increases, and becomes 100% when θ = m%. And m% ≦ θ
In the range of ≤100%, the state of V22 = 100% is maintained.

Further, the variable voltage dividing circuit 26 is interlocked with the variable voltage dividing circuit 22, and the divided voltage (voltage dividing ratio) V26 of the variable voltage dividing circuit 26 is, as shown by a broken line in FIG.
In the range of 0% ≦ θ ≦ m%, the state of 100% is maintained. However, in the range of m% ≦ θ ≦ 100%, the value monotonically decreases from 100% as the indicated value θ increases. At 100%
0%.

The maximum voltage gain A of the preamplifier 23
23 is, for example, 20 dB, and the voltage gain A of the main amplifier 24 is
24 is, for example, 28 dB. In the case of a two-channel stereo amplifier or a multi-channel amplifier, the audio amplifier 20 is provided only for that channel, and the variable voltage dividing circuits 22 and 26 of each channel are linked with each other.

According to such a configuration, the variable voltage dividing circuit 2
2 shows a voltage dividing characteristic as indicated by the solid line in FIG. 2A with respect to the instruction value θ of the total gain, and therefore, the gain A22 of the variable voltage dividing circuit 22 is 0% ≦ as shown by the solid line in FIG. 2B. In the range of θ ≦ m%, the value monotonically increases from −∞ [dB] as the indicated value θ increases, and becomes 0 dB when θ = m%. And
In the range of m% ≦ θ ≦ 100%, the state of A22 = 0 dB is maintained (the level position of −∞ [dB] cannot be shown in the drawing, but is shown for convenience).

A negative feedback is applied to the preamplifier 23 through a variable voltage dividing circuit 26, and the variable voltage dividing circuit 2
The output voltage V26 of 6, ie, the amount of negative feedback changes as shown by the broken line in FIG. 2A. Therefore, the preamplifier 23
The gain A23 is 0% ≦ θ ≦, as shown by the broken line in FIG. 2B.
In the range of m%, the state of 0 dB is maintained, but m% ≦
In the range of θ ≦ 100%, it monotonically increases from 0 dB as the indicated value θ increases, and becomes 20 dB when θ = 100%.

Then, the power amplifier 2 is connected to the input terminal 21.
Since the gain APR up to the input terminal of No. 4 is the sum of the gain A22 and the gain A23, the gain APR has a magnitude that is monotonically proportional to the indicated value θ, as indicated by a chain line in FIG. 2B. That is,
The gain APR corresponds to the rotary volume control 12 shown in FIG.
As in the case where was adjusted, changes between -∞ [dB] and 20 dB. It should be noted that the signal level or the gain distribution in each section of the audio amplifier 20 is shown as a solid line in FIG.

Thus, in the audio amplifier 20, the gain A22 of the variable voltage dividing circuit 22 and the preamplifier 23
The gain A23 of the audio amplifier 20 changes in conjunction with the change of the gain A23. And in this case,
When m% ≦ θ ≦ 100% (0 dB ≦ APR ≦ 20 dB), the variable voltage dividing circuit 22 does not perform attenuation (A22 = 0 dB).
, The impedance when the variable voltage dividing circuit 22 is viewed from the preamplifier 23 is minimum. Therefore, at this time, the S / N of the preamplifier 23 itself becomes the best.

In the audio amplifier 10 shown in FIG. 8, since the preamplifier 13 has a gain of 20 dB, when the total gain of the audio amplifier 10 is minimum, the level of the noise component generated at a stage preceding the preamplifier 13 is:
As shown by the broken line in FIG. On the other hand, in the audio amplifier 20 of FIG.
When the total gain of 0 is minimum, A23 = 0 dB, so that the noise level of the noise component generated before the preamplifier 23 is shown by the characteristic of θ = 0% in FIG. Therefore, the total gain of the audio amplifier 20 is minimum (θ =
0%), the noise level of the audio amplifier 20 is improved by 20 dB compared to the audio amplifier 10.

Then, 0% ≦ θ ≦ m% (−∞ [dB] ≦ A
When PR ≦ 0 dB), A23 = 0 dB, so the noise level of the audio amplifier 20 is improved by 20 dB compared to the audio amplifier 10 for the same reason.

Further, in the actual use state of the audio amplifier, it is rare that the volume control is maximized (θ = 100%), and the audio amplifier is usually used near θ = m%. Therefore, according to the audio amplifier 20, the noise level in the actual use state can be significantly improved for the above-described reason.

FIG. 4 shows the audio amplifier 20 of FIG. 1 to which the present invention is applied and the audio amplifier 10 of the system of FIG.
The result of measuring the noise level is shown below. According to the measurement result, the noise level of the audio amplifier 20 to which the present invention is applied is almost uniformly improved as compared with the audio amplifier 10 to which the present invention is not applied, except for the vicinity of the maximum output.

FIG. 5 shows the audio amplifier 20 of FIG. 1 to which the present invention is applied and the amplifiers 1 of the respective companies of the system of FIG.
This is the result of measuring the S / N by setting the position of the volume control (indicated value θ) to 0 for each.

Note that "EIA (IHF)" means that the input signal level is 500 mV and the impedance of the speaker SP is 8 Ω.
At the volume position where the output is 1W. “FNAC” means that the input signal level is 500 mV, the impedance of the speaker SP is 8Ω, and the distortion factor of the output is 0.2%.
At the volume position where Furthermore, “−20d
B ”is greater than θ = 100% to correspond to the actual use condition.
This is when the volume is adjusted so that the output signal level is reduced by 20 dB.

According to the measurement results, the S / N at the maximum output is not much different from any amplifier, but when the volume is reduced, the audio amplifier 20 according to the present invention is used.
The S / N of the audio amplifier 20 according to the present invention is improved by about 10 dB, particularly, the S / N of “−20 dB” in the actual use state is improved.

FIG. 6 shows a specific example of the variable voltage dividing circuits 22 and 26. The variable voltage dividing circuit 22 is configured by cascading two variable voltage dividing circuits 22A and 22B.
That is, in the variable voltage dividing circuit 22A, the input terminal 2
1 is connected to the input terminal T2A, and this terminal T2A
Eight resistors R21 to R28 are connected in series between the resistor R21 and the ground terminal T2C, and their connection points are commonly connected to the input terminal of the variable voltage dividing circuit 22B through the switch circuits S20 to S28.

In the variable voltage dividing circuit 22B, twelve resistors R201 to R212 are connected in series between the output side of the commonly connected switch circuits S20 to S28 and the terminal T2C. Each connection point is a switch circuit S200 ~
The output terminal T2B is commonly connected through S212, and this terminal T2B is connected to the non-inverting input terminal of the preamplifier 23.
The terminal T2C is grounded.

Then, the switch circuits S20 to S28, S200
Steps S212 to S212 are on / off controlled by a microcomputer for system control. In this case, the switch circuit S20
To S28 and a switch circuit S200 to S2.
Any one of the twelve is turned on corresponding to the target gain A22.

Further, in the variable voltage dividing circuit 26, the output terminal of the preamplifier 23 is connected to the first terminal T2A, and between the terminal T6A and the ground terminal T6C, twenty resistors R601 to R620 are connected. Are connected in series, and their respective connection points are commonly connected to a second terminal T6B through switch circuits S600 to S620, and this terminal T6B is connected to the inverting input terminal of the preamplifier 23. The terminal T6C is grounded.

The switch circuits S600 to S620 are turned on / off by a system control microcomputer so that any one of them is turned on in accordance with a target gain A23. In addition, resistors R21 to R28, R20
1 to R212, R601 to R620 and switch circuits S20 to S2
8. S200 to S212 and S600 to S620 are integrated into one IC
Have been. As such an IC, there is "TC94A07P / F" manufactured by Toshiba Corporation.

In such a configuration, for example, if the switch circuits S24, S204, and S604 are turned on, the variable voltage dividing circuits 22, 26 are equivalently connected as shown in FIG. The same applies when the other switch circuits are turned on, and the switch circuits S20 to S28 and S200 to S2
Of 12, the voltage dividing ratios of the variable voltage dividing circuits 22A, 22B, 26 change in accordance with the switch circuit turned on.

Therefore, the variable voltage dividing circuits 22 and 26 can have the voltage dividing characteristics as shown in FIG. 2A, and as a result, gain characteristics as shown in FIG. 2B can be obtained. Moreover, at that time, the above-mentioned general variable voltage dividing IC can be used.

In the above description, the signal level when θ = 0% is −∞ [dB]. However, in practice, the signal level may be regarded as 0, for example, −95 dB. Also,
In FIG. 6, terminals T6A and T6B for the preamplifier 23 are shown.
Connection can be reversed.

[List of abbreviations used in this specification] EIA: Electronic Industries Association FNAC: Federation National ed Achats des Cadres IC: Integrated Circuit IHF: Institute of High Fidelity S / N: Signal to Noise ratio

[0035]

According to the present invention, the S / N and noise level of the audio amplifier can be greatly improved.
In particular, the noise level in the actual use state can be improved. Moreover, no special components or elements are required for that purpose.

[Brief description of the drawings]

FIG. 1 is a connection diagram illustrating one embodiment of the present invention.

FIG. 2 is a characteristic diagram for explaining the present invention.

FIG. 3 is a characteristic diagram for explaining the present invention.

FIG. 4 is a characteristic diagram showing an example of a measurement result of the circuit according to the present invention.

FIG. 5 is a diagram showing an example of a measurement result of the circuit according to the present invention.

FIG. 6 is a connection diagram showing an example of a main part of the present invention.

FIG. 7 is an equivalent circuit diagram for explaining the circuit of FIG. 6;

FIG. 8 is a connection diagram for explaining the present invention.

[Description of Signs] 20 audio amplifier, 21 input terminal, 22 variable voltage dividing circuit, 23 preamplifier, 24 power amplifier, 2
5: output terminal, 26: variable voltage dividing circuit, SP: speaker

Claims (3)

[Claims] 1. A resistor-divided first variable voltage dividing means to which an audio signal is supplied, an amplifier to which an output of the first variable voltage dividing means is supplied, and a negative feedback path of the amplifier. And a resistor-divided second variable voltage dividing means for changing the amount of negative feedback, so that the voltage dividing ratio of the second variable voltage dividing means is kept constant from a minimum output level to a predetermined output level. While maintaining the gain of the amplifier at a constant level, and by changing the voltage dividing ratio of the first variable voltage dividing means, the target overall gain is controlled. From the predetermined output level to the maximum output level, Until the above, the output voltage level of the first variable voltage dividing means is kept at the maximum while the voltage dividing ratio of the first variable voltage dividing means is kept constant, and the voltage dividing ratio of the second variable voltage dividing means is kept at the maximum. By changing and changing the gain of the above amplifier, An audio amplifier that controls the overall gain. 2. The audio amplifier according to claim 1, wherein said first variable voltage dividing means and said second variable voltage dividing means comprise a resistive voltage dividing circuit and a plurality of switch circuits. An audio amplifier in which the switch circuit is switched electronically to achieve the desired voltage division ratio. 3. The audio amplifier according to claim 2, wherein the predetermined output level is an output level set in an actual use state.