JPH0239711A - Electronic volume circuit - Google Patents

Abstract

PURPOSE:To change only a signal voltage level without changing a DC level by combining a first common emitter transistor circuit to divide a signal current by a volume control voltage and a second common emitter transistor circuit to divide a bias current. CONSTITUTION:Since a signal voltage (v) inputted from an input terminal 3 is converted to the signal current of a V/R2 with a voltage-current converting circuit (d) and the then bias current (current to flow at a transistor Q3 at the time of non-signal) is VBE/R2, a current ia flowing to the common emitter of transistors Q6 and Q7 becomes ia=(V/R2)+(VBE/R2). In the same way, a current ib flowing to the common emitter of transistors Q8 and Q9 becomes a bias current only to occur at a voltage/current converting circuit (e) and ib=VBE/R4. Consequently, by adjusting the impressed voltage of volume control terminals 5 and 6, a signal outputted from an output terminal 4 is controlled.

Description

DETAILED DESCRIPTION OF THE INVENTION 1. The present invention relates to an electronic volume circuit, and more particularly to an electronic volume circuit used in an audio circuit or the like and connected to a power amplifier or the like at the next stage.

Figure 2 shows an example of a conventional electronic volume circuit.

The signal input from the input terminal 3 is impedance-converted by the amplifier circuit Amp51, and then passed through the resistor R51, the transistor Q51 . Voltage-current conversion circuit A composed of Q52
The signal applied to the amplifier circuit Amp 52 and inverted by the amplifier circuit Amp 52 is applied to the resistor R52, the transistor Q53 . The output of each of the two voltage-current conversion circuits A and H is connected to a voltage-current conversion circuit B composed of transistors Q55. The common emitter of Q51E and transistor Q57. Connected to the common emitter of Q5H. Therefore, the signal current flows through the load resistance R53 of transistor Q511i and the load resistance R5 of transistor Q57.
4, the signal is converted into a signal voltage by an amplifier circuit Amp 53, and both in-phase and anti-phase signals appearing at resistors R53 and R54 are added together and outputted from an output terminal 4.

The adjustment of the signal attenuation 1 is performed by connecting the common base terminal 5 of transistors Q5G and Q57 and the transistors Q55 . It is adjusted by the potential difference between both terminals of the common base terminal 6 of Q58.

That is, by adjusting the potential difference between terminals 5 and 6, the signal current flowing through transistor Q52 is changed between transistors Q55 and QSG.
The level of the signal voltage appearing on the resistor R53 is adjusted by adjusting the ratio between the two. Similarly, for the reverse phase signal, the signal current flowing through transistor Q53 is
and Q58 is adjusted by the potential difference between terminals 5 and 6, and the signal voltage level appearing on resistor R54 is adjusted. Therefore, by adjusting the voltages at the volume control terminals 5 and 6, the amount of attenuation of the signal voltage obtained from the output terminal 4 with respect to the input signal is controlled, thereby functioning as an electronic volume.

The electronic volume shown in the conventional example of FIG. 2 has a load resistance R53.
, R54, the bias current itself changes, so the DC level of the output appearing on resistors R53 and R54 is adjusted by the volume.

That is, it fluctuates due to adjustment of the potential difference between terminals 5 and 6,
The DC level of the output obtained from the output terminal 4 also fluctuates. Therefore, when connecting a power amplifier etc. after the electronic volume,
It has the disadvantage of requiring capacitor coupling to prevent DC level fluctuations from being transmitted to the power amplifier.
Furthermore, even if the electronic volume and power amplifier circuit are integrated into an IC, the capacitance of the above-mentioned coupling capacitor is usually required to be approximately 10 μF or more, so incorporating it into the IC will increase the chip size, so it must be externally connected. This becomes an obstacle to reducing costs and reducing the area occupied by one circuit.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide an electronic volume circuit that does not cause fluctuations in the DC level through volume control.

TI,' = MENO, Technical means for achieving the above object in the present invention include two voltage-current conversion circuits, a first common emitter transistor circuit that divides the signal current by a volume control voltage, a second common emitter transistor circuit for bias current shunting; This electronic volume circuit includes a current-voltage conversion circuit that combines the output currents of the second common emitter transistor circuit and converts them into voltage.

According to the present invention, even if the signal current and bias current flowing through the transistor of the first common emitter transistor circuit that transmits to the current-voltage conversion circuit decrease by adjusting the volume control voltage, the second common emitter transistor circuit By feeding the current-to-voltage conversion circuit with a reduced bias current through the common emitter transistor, an output can be obtained in which only the signal voltage level changes without changing the DC level.

An embodiment of an electronic volume circuit according to the present invention will be described with reference to FIG.

The signal input from input terminal 3 is transmitted to transistor Ql,
After level shifting in Q2, it is converted into a signal current by transistor Q3 and resistor R2 (voltage-current conversion circuit d
), transistor Q4. Through a current mirror circuit constituted by transistors Q5, transistors Q6. The first consisting of Q7
is transmitted to the common emitter of the common emitter transistor circuit a.

Similarly, transistors Q12-Q14. The current determined by the voltage-to-current conversion circuit e made up of resistors R4 and R5 passes through a current mirror circuit made up of transistors QIO and Qll, and then passes through a current mirror circuit made up of transistors Q8. Flows to the common emitter of a second common emitter transistor circuit constituted by Q9.

Said 1st. Second common emitter transistor circuit a, b
The collector of each one of the transistors Q8°Q8 constituting the transistors Q8 is grounded, and the collectors of the transistors Q8 . The collectors of Q9 are commonly connected and connected to a current-voltage conversion circuit C constituted by a resistor R3.

The signal converted back to voltage by resistor R3 is transferred to transistor Q.
Level shift and impedance conversion are performed at I5, and output from output terminal 4.

Further, the base terminals of the transistors Q6 and Q9 and the base terminals of Q7 and Q8 are connected in common and connected to the polygon control terminals 5 and 6, respectively.

The operating principle is described below.

For simplicity, it is assumed that the emitter pattern size of each transistor is all the same, and the pace emitter forward voltage is VB
E is the same.

The signal voltage V input from the input terminal 3 is converted into a crystal signal current by the voltage-current conversion circuit d, and the bias current at that time (the current flowing through the transistor BE and Q3 when there is no signal) is , the current ia flowing to the common emitter of transistors Q6 and Q7 is 1a=
It becomes L+■ Want.

2 R2 Similarly, transistor Q8. The current ib flowing to the common emitter of Q9 is only the bias current generated in the voltage-current conversion circuit e, and becomes a river.

Therefore, by adjusting the voltage applied to the volume control terminals 5 and 6, the amount of ia and ib transmitted to the current-voltage conversion circuit C is adjusted by the first and second common emitter transistor circuits a and b, and the output The signal output from terminal 4 is controlled.

That is, if the coefficient by which the amount of passage of ia and ib is controlled by the first and second common emitter transistor circuits a and b is a (0≦a≦1), then the transistor Q7
．． The collector current of Q9 is a*ia+ (1-
a) It becomes ib. Therefore, the output voltage V obtained from output terminal 4
o is Vo=R3-(a-1a+(1-a)-1b) +VB
E=R3-(a-('+"town+(1-a), village) +V
BER2R2R4 becomes.

Here, if R2 and R4 are set to the same resistance value (temporarily R
) R3R3 Vo= a @-R-@ V+ (1+[) ・VBE
Therefore, the output voltage Vo is controlled by the volume (controlling the value of a) so that the bias voltage is always (1+H
) - It is possible to obtain an output in which only the signal level changes with a constant value of VBE, and the object of the present invention can be achieved.

Furthermore, depending on the value of R3, the maximum gain (a
= 1) is determined. That is, the maximum gain is Avma
If x, Avmax= 20 Log (H)
becomes.

According to the present invention, the DC level of the output can be kept constant regardless of the volume level control.
Since it can be directly connected to the power amplifier circuit etc. connected to the next stage of the electronic volume circuit without using a capacitor, it is possible to integrate the electronic volume and power amplifier into one chip IC.
It is possible to provide an electronic volume circuit with high practical value.

b... second common emitter transistor circuit,
C... Current-voltage conversion circuit, d, e... Voltage-current conversion circuit, Q1 to Q
15. Q51-Q58...Transistor, R
1-R5, R51-R54, old...resistance, Amp51-
Amp53...Differential amplifier circuit, 11-13...
... Constant current source.

[Brief explanation of the drawing]

FIG. 1 is a circuit diagram showing an embodiment of an electronic volume circuit according to the present invention, and FIG. 2 is a circuit diagram showing a conventional example of an electronic volume circuit. 1...Power supply voltage terminal, 2...Ground terminal, 3...Input terminal, 4...Output terminal, 5.6... Volume control terminal, a...
...First common emitter transistor circuit, polyγ
Hefund draw It/Q--4, Rifusashiko, Mizu 7 transi'L 7 times μt b
---152^ Trap J Shiso 77 Trap Sufu 11 reading c---
4shishi 屹-j7L Liaojita Bow i+i Romeishi d, e・-Electric Melon-4L Toyou Filling School Fee

Claims (1)

[Claims] A voltage-current conversion circuit that converts an input signal into a current, a first common emitter transistor circuit that shunts the signal current, and a second common emitter transistor circuit that shunts the bias current. An electronic volume circuit characterized by comprising a current-voltage conversion circuit that synthesizes the output currents of the second common emitter transistor circuit and converts them into a voltage.