KR20150069447A - Constant load control noise suppression circuitry - Google Patents

Abstract

Disclosed is a method to remove a control noise by always making a current to prevent a constant current load from floating in an amplification circuit using the constant current load as a load. An amplifier is connected to a base of an input terminal (IN2) and an amplification element (Q22), and comprises an emitter of the amplification element (Q22); a second node (A2) connected to an end of a constant current load (CC21) and a collector of the amplification element (Q22); and the other end of the constant current load (CC21).

Description

[0001] The present invention relates to a constant current load control noise suppression circuitry,

An amplifier circuit using a constant current source as a load.

1 is an amplifier circuit based on a constant current load CC11.

A constant voltage across the eleventh Zener diode Z11 is supplied to the base of the eleventh transistor Q11 by the eleventh resistor R11 and a constant voltage across the emitter of the eleventh transistor Q11 is supplied to the emitter of the eleventh transistor Q11 by the twelfth resistor R12 11 The current flowing through the emitter and collector of the transistor Q11 is always constantly controlled.

A normal bias is supplied to the base of the twelfth transistor Q12 and the eleventh capacitor C11 is a coupling capacitor for DC separation from the input signal source and the base of the twelfth transistor Q12. It is assumed that the collector voltage of the twelfth transistor Q12 is set to a half voltage of the power source anode power supply VPP1.

In FIG. 1, when the input signal to the input IN1 is 0, the 12th transistor Q12 is supplied with a normal bias, so that the collector voltage of the 12th transistor Q12 is 1/2 of the anode voltage VPP1, ice_Q12 is equal to the collector current of the eleventh transistor Q11 of the constant current load CC11 CC1.

The current ice_Q11 of the constant current load (CC11)

ice_Q11 = (V_Z11 - Vbe_Q11) / R12

.

The first node A1 connected to the collector of the eleventh transistor Q11 of the constant current load CC11 and the collector of the twelfth transistor Q12 is connected to the eleventh Zener diode Z11 and the twelfth resistor R12, And the constant current load CC11 composed of the eleventh transistor Q11.

The constant current load CC11 is set such that the both terminal voltage Vr12 of the twelfth resistor R12 is equal to the base voltage and the emitter voltage Vbe_Q11 of the eleventh transistor Q11 at the both terminal voltage Vz11 of the eleventh Zener diode Z11 And the eleventh transistor Q11 always controls so that the subtracted voltage is maintained.

If you write in mathematical formulas

Vr12 = Vz11 - Vbe_Q11 (Expression 11)

.

Describing the constant current operation by the eleventh transistor Q11

When the voltage across the resistor R12 (Vr12 in Equation 11) decreases, the current flowing through the base and emitter of the eleventh transistor Q11 increases and the collector current of the eleventh transistor Q11 increases, The voltage across the resistor R12 increases to maintain the constant current. On the other hand, when the voltage across the resistor R12 (Vr12 in Equation 11) increases, the current flowing through the base and emitter of the eleventh transistor Q11 The collector current of the eleventh transistor Q11 decreases, and the voltage across the twelfth resistor R12 decreases to maintain the constant current.

When the input signal having the positive polarity is input to the input IN1, the base current of the twelfth transistor Q12 increases, the impedance between the collector and the emitter of the twelfth transistor Q12 decreases, and the current of the constant current load CC11 A constant current is going to flow, and the voltage of the first node A1 is lowered. (Operation 1)

When the negative input signal is input to the input IN1, the base current of the twelfth transistor Q12 decreases and the impedance between the collector and the emitter of the twelfth transistor Q12 increases, and the current of the constant current load CC11 becomes constant The current tries to flow and the voltage of the first node A1 becomes high. (Operation 2)

Describing the operation in which the control noise is generated by the eleventh transistor Q11

In operation 1, when the voltage of the first node A1 is temporarily lowered until the collector voltage of the eleventh transistor Q11, that is, the voltage of the first node A1, is lowered The voltage of the first node A1 is maintained in the immediately previous state but the current continues to flow through the collector of the 12th transistor Q12 and the collector voltage of the 11th transistor Q11, The voltage of the node A1 is lowered to a steady state.

In operation 2, when the voltage of the first node A1 is temporarily increased, the voltage of the collector of the eleventh transistor Q11, that is, the voltage of the first node A1 is increased The voltage of the first node A1 is maintained at the immediately previous state, and the current flow to the collector of the twelfth transistor Q12 is cut off and becomes a floating state. (Operation 3) After the time elapses, the collector voltage of the eleventh transistor Q11, that is, the voltage of the first node A1, becomes high, and the current flows to the collector of the twelfth transistor Q12 to be in a steady state.

Here, in the operation 3, the collector of the 12th transistor Q12 is opened and the collector of the 11th transistor Q11 is also in an open state, so that the voltage of the first node A1 is in a floating state, It may be changed to an abnormal voltage, and it may be affected by ambient noise and may appear as noise in the output signal.

This noise is an example of control noise caused by a constant current load.

For example, in an audio amplifier, a very irritating sound is mixed with the sound, which is not heard for a long time, and is easily tired.

This paper presents a method to remove control noise caused by constant current load in an amplifier using a constant current load.

As a first embodiment,

2,

The base of the 21st transistor Q21, the anode of the 21st Zener diode Z21, and one end of the 21st resistor R21,

The emitter of the twenty-first transistor Q21 and one end of the twenty-second resistor R22,

The cathode of the twenty-first Zener diode Z21 and the other end of the twenty-second resistor R22 are connected to the positive electrode power source VPP2,

Connected to the other terminal of the twenty-first resistor R21 and the negative power source VNN2,

A first constant current stage connected to the collector of the 21st transistor Q21 and the second node A2;

Connected to the base of the twenty-second transistor Q22 and the input terminal IN2,

An emitter of the twenty-second transistor Q22 is connected to one end of the twenty-third resistor R23,

Connected to the other terminal of the 23rd resistor R23 and the cathode power source VNN2,

An amplification stage connected to the collector of the twenty-second transistor Q22 and the second node A2;

An output terminal to which the second node A2 and the output terminal OUT2 are connected;

Is connected to one end of the second node (A2) and the twenty second constant current source (CC22)

Connected to the other terminal of the twenty second constant current source (CC22) and the negative electrode power source (VNN2);

Configured constant current load control noise elimination circuit.

The constant current load (CC21) is prevented from being temporarily floated by the twenty-second constant current source (CC22), thereby preventing noise in an unstable state and flowing a current through the constant current load (CC21) And does not affect the characteristics of the load in comparison with the case of using a resistor instead of the 22th constant current source (CC22), so that a clean and high-fidelity amplification can be performed. When applied to acoustical instruments, the amplified output signal is not irritating but is clean, stable and has high fidelity amplification.

1 is an amplifier circuit diagram using a constant current load according to the prior art.
Figure 2: Amplifier circuit diagram using an improved constant current load according to one embodiment.

In FIG. 2, the constant current load CC21 is used as a load of the amplifier of the twenty-second transistor Q22. This constant current load (CC21) has very high equivalent impedance and it is used by lowering the gain by negative feedback by an amplifier circuit such as a negative feedback amplifier.

When an amplifier using such a constant current load is used in a sound apparatus, it is commonly heard as an irritating sound, and this irritating and impulsive sound is generally referred to as a transistor tendency.

The cause of this irritating noise is caused by the control noise generated in the constant current load which we are trying to improve here.

The above background art will be described with some quotations

2,

When the input signal having the positive polarity is input to the input IN2, the base current of the twenty-second transistor Q22 increases to decrease the impedance between the collector and the emitter of the twenty-second transistor Q22, The voltage of the second node A2 tends to decrease due to a constant current and the collector voltage of the twenty-first transistor Q21, that is, until the voltage of the second node A2 becomes low (the distribution capacity of the circuit and the circuit element The voltage of the second node A2 is kept in the immediately previous state and the current continues to flow to the collector of the twenty second transistor Q22 and then the second node A2 ) Is lowered to a normal state to perform normal amplification operation. (Operation 21)

However, when a signal of negative polarity is input to the input IN2, the base current of the twenty-second transistor Q22 is decreased to increase the impedance between the collector and the emitter of the twenty-second transistor Q22 and the current of the constant current load CC21 The voltage of the second node A2 tends to increase and the collector voltage of the 21st transistor Q21 till the voltage of the second node A2 rises The voltage of the second node A2 is maintained at the immediately previous state and the current flow is interrupted at the collector of the twenty-second transistor Q22 to be in a floating state and the twenty-second transistor Q22 is turned off, The collector of the twenty-first transistor Q21 is also in an open state, and the voltage of the second node A2 becomes a floating state (operation 22) so that the output voltage can be changed to an abnormal voltage, Job of Can be affected by noise or the like and may appear as noise in the output signal.

In the state of operation 22, the voltage of the second node A2 is unstable and can be changed to an output voltage which is completely different from the voltage output until immediately before, and the impedance is very high, resulting in an abnormal output voltage due to external noise. At this time, it may appear as an irritating impulse, and this pulse stimulates the ear and becomes a cold and dry sound.

As a method of preventing the state of operation 22 from occurring, a twenty-second constant current source CC22 is provided so that current always flows through the collector and emitter of the twenty-first transistor Q21 of the constant current load CC21 as shown in FIG.

Describing the current flow by the twenty-second constant current source CC22

The second node A2 which is the collector of the twenty-first transistor Q21 from the emitter of the twenty-first transistor Q21 via the twenty-second resistor R22 from the anode power supply VPP2, CC22 to the negative power source VNN2.

When the collector of the twenty-second transistor Q22 is temporarily opened by flowing a current through the twenty-second constant current source CC22, a current always flows through the twenty-first constant current source CC21. In any case, the twenty-first transistor Q21 Is not plotted.

As in the case of operation 22, even when the collector of the twenty-second transistor Q22 is open and floating, since the current flows through the collector of the twenty-first transistor Q21, the output voltage remains unchanged and the impedance is low. The output signal is stable and clean.

The twenty-second constant current source CC22 has a high impedance when the operating current is set small and does not affect the load characteristics of the twenty-first constant current source CC21.

A resistor may be used instead of the 22th constant current source (CC22). However, if a resistor is used, it is the same as that connected in parallel with the load of the 21st constant current source (CC21) none.

(21st constant current source; CC21) and a 22th constant current source (CC22) are connected in series to constitute a constant current load (21st constant current source; CC21) as a constitutional method for eliminating the control noise of the constant current load (CC21) So that the current always flows. As a result, it can be said that the twenty second constant current source CC22 is connected in parallel with the twenty second transistor for amplification Q22.

It should be understood that the present application is not limited to the amplifying circuit shown in Fig. 2, but applies to all amplifying circuits using a constant current source as a load.

Claims (1)

Connected to the input terminal IN2 and the base of the amplification element Q22;
An emitter of the amplifying device (Q22);
A second node A2 connected to one end of the constant current load CC21 and the collector of the amplifying element Q22;
The other end of the constant current load CC21;
In an amplifier composed of
One end of the constant current source CC22 is connected to the emitter of the amplifying device Q22,
The other end of the constant current source (CC22) and the collector of the amplifying element (Q22)
Connected constant current load control noise elimination circuit.

Images