JP2546699B2 - Charging circuit - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial field of application) The present invention relates to a signal voltage for driving a mute circuit, for example, at a predetermined charging voltage, and an amplifier for converting the charging voltage after the mute circuit is operated. Charging circuit used as a bias voltage for the circuit of FIG.

(Prior Art) This type of charging circuit is composed of a series circuit consisting of a resistor connected between a power source and ground and a charging / discharging capacitor, and the charging voltage of the charging / discharging capacitor is used as the drive voltage of the mute circuit. In addition, there is one used as a bias voltage of a controlled circuit such as an amplifier controlled by the mute circuit.

In the charging circuit having such a configuration, the charging / discharging capacitor is charged by the charging current flowing through the resistor when the power is turned on, and the rising speed of the charging voltage is the resistance value of the resistor. It is determined by the time constant, which is the product of the capacitance value of the charge / discharge capacitor.

Then, when the charging voltage of the charging / discharging capacitor becomes a constant value after a lapse of a predetermined time (called mute time) according to the time constant after the power is turned on, the mute circuit connected to the output part of the charging circuit changes the charging voltage. Driven by, and outputs a mute signal from its output section. Then, the controlled circuit such as an amplifier connected to the output section of the mute circuit becomes operable. The enabled controlled circuit is operated using the charging voltage as a bias voltage.

(Problems to be Solved by the Invention) By the way, in the charging circuit having such a configuration, the rising speed of the charging voltage of the charging / discharging capacitor changes due to the fluctuation of the power supply, so that the mute time is changed. There's a problem. Further, the bias voltage after the controlled circuit becomes operable increases at a speed according to the time constant, and there is a problem that it takes a long time to reach a predetermined bias voltage.

The present invention has been made in view of the above problems, and can make the mute time constant regardless of the fluctuation of the power supply and can increase the rising speed of the bias voltage to the controlled circuit. The purpose is to do so.

(Means for Solving the Problems) In order to achieve the above object, the present invention provides a series circuit including a resistor and a charge / discharge capacitor connected between a power source and ground, a power source, and a resistor in the series circuit. Constant current source inserted between the common connection part of the charge and discharge capacitor, the first current mirror circuit, and the common connection part controlled by the output current of the first current mirror circuit. A second current mirror circuit connected between the earth and the ground, the first charge mode is entered after the power is turned on, and the charge / discharge capacitor is charged by the first charge current from the constant current source. At the same time, when the charging voltage of the charging / discharging capacitor reaches a predetermined value, the constant current source and the first current mirror circuit are controlled so that their outputs are stopped.
In the charging mode, the charging / discharging capacitor is charged by the second charging current passing through the resistor.

(Operation) In the first charging mode after the power is turned on, the output current of the second current mirror circuit is controlled by the output current of the first current mirror circuit. That is, the current flowing through the resistor in the series circuit flows as its output current in the second current mirror circuit. Therefore, the second charging current from the resistor does not flow in the charging / discharging capacitor, but the first charging current is supplied from the constant current source, and the charging / discharging capacitor is charged thereby. When the charging voltage of the charging / discharging capacitor reaches a predetermined value, the output of the constant current source and the first current mirror circuit is controlled to stop, and as a result, the second charging mode is entered and the charging / discharging capacitor passes through the resistor. Two
It is charged by the charging current of.

Therefore, in the present invention, in the first charging mode,
Since the charging / discharging capacitor is charged by the constant current source, the rate of rise of the charging voltage of the charging / discharging capacitor is constant even if the power supply fluctuates. The circuit can always output the mute signal at a constant timing regardless of the fluctuation of the power supply. Further, the rising speed of the charging voltage of the charge / discharge capacitor in the second charging mode after the mute circuit operates can be arbitrarily set by appropriately setting the resistance value of the resistor. When the charging voltage is the bias voltage of the controlled circuit, for example, the amplifier, the rising speed of the bias voltage can be increased, for example.

(Example) Hereinafter, an example of the present invention will be described in detail with reference to the drawings. FIG. 1 is a circuit diagram of a charging circuit according to an embodiment of the present invention, and FIG. 2 is a voltage waveform diagram of each part used for explaining the operation of the embodiment. In FIG. 1, reference symbol SC indicates two diodes D1 and D2 connected in the forward direction, which are connected between the power source Vcc and the ground, the resistor R1, the charge / discharge capacitor C and the resistor R.
It is a series circuit formed by connecting two parallel circuits in series. I
cc is a series circuit with power supply Vcc and ON / OFF switch SW3
It is a constant current source inserted between the resistor R1 in the SC and the common connection part a of the charging / discharging capacitor C. The on / off switch SW3 is configured to turn off in response to a mute signal described later.

The first CM1 is composed of transistors Q2 and Q3 whose emitters are commonly connected to the power supply Vcc and a resistor R3.
Is a current mirror circuit of. The collector of the transistor Q2 of the first current mirror circuit CM1 is grounded via the resistor R3, the on / off switch SW2, and the collector / emitter of the transistor Q1. This on / off switch SW
2 is also configured to turn off in response to a mute signal described later. CM2 is composed of transistors Q4 and Q5 whose emitters are commonly grounded. The collector of transistor Q4 is connected to the collector of transistor Q3 of the first current mirror circuit CM1, and
The collector of Q5 is the second current mirror circuit connected to the common connection portion a.

MC is a mute circuit that receives the charge voltage of the charge / discharge capacitor C as a drive voltage at its input part and outputs a mute signal from its output part when the charge voltage reaches a predetermined value. AP is a mute circuit from the mute circuit MC. An amplifier, SW1, which is activated when a signal is applied and is supplied with the charging voltage as a bias voltage in the operating state, is a power switch.

 Next, the operation will be described with reference to FIG.

First, the on / off switches SW2 and SW3 are in the on state. Then, the power switch SW1 is turned on at time t ₀ , and the power Vcc is applied to the circuit. When the power supply Vcc is turned on,
One transistor Q in the first current mirror circuit CM1
A current i2 equal to the power supply i1 flowing through the resistor R3 through the collector of 2 flows through the collector of the other transistor Q3.

Therefore, since the current i2 flows through the collector of one transistor Q4 in the second current mirror circuit CM2, the same current i3 flows through the collector of the other transistor Q5.

As a result, the current i5 flowing through the resistor R1 in the series circuit SC is canceled by the current i3 flowing through the second current mirror circuit CM2 when the resistance values of the resistors R1 and R3 are equal. The current i4 of the source Icc will flow as the first charging current (first charging mode).

Thus, the charging / discharging capacitor C is charged by the first charging current from the constant current source Icc. In this case, since the first charging current is constant regardless of the fluctuation of the power source Vcc, its charging / discharging is performed. The rising speed of the charging voltage of the capacitor C is constant. The charging curve in this first charging mode is shown from time t _{0 to} t ₁ in FIG. b is the power supply Vc
The curve of c is shown.

Next, when the charging voltage of the charging / discharging capacitor C reaches a predetermined value at time t ₁ , the mute circuit MC is driven by the charging voltage and outputs a mute signal to the amplifier AP. Then, the amplifier AP is in the operating state. At the same time, the mute signal from the mute circuit MC is also given to the on / off switches SW2, SW3 as a signal for turning them off. As a result, the on / off switches SW2, SW3 are turned off and the first current mirror circuit is turned on. The output of CM1 and constant current source Icc is controlled to stop.

Then, the current i5 flowing through the resistor R1 in the series circuit SC comes to flow to the charging / discharging capacitor C side, so that the current i5 acts as the second charging current for the charging / discharging capacitor C, The charging / discharging capacitor C is charged at a speed according to the time constant determined by the resistance value of the resistor R1 and the capacitance value of itself (second charging mode). Therefore, in the case of setting small resistance value of the resistor R1, the charging speed of charging and discharging the capacitor C, as shown at time t ₁ after the charging curve a in FIG. 2 is faster. In addition, what is shown by c shows the charging curve of the charging / discharging capacitor by the charging circuit of the conventional example. As is clear by comparing the charging curve a of this embodiment with the charging curve c of the conventional example, the time of the present embodiment is higher than that of the conventional example.
The rate of increase of the charging voltage of the charging / discharging capacitor C after t ₁ increases.

That is, in the present embodiment, the power supply voltage Vc is set during the time t _{0 to} t ₁ , which is the time zone of the first charging mode, that is, the mute time.
It is determined only by the first charging current from the constant current source Icc, regardless of the variation of c. Also, the mute circuit after time t ₁
In the second charging mode after the operation of MC, the rise time of the bias voltage applied to the amplifier AP is changed to the mute circuit MC.
It can be arbitrarily set regardless of.

(Effect) As is clear from the above description, according to the present invention, the mute time can be kept constant irrespective of the fluctuation of the power supply, and the rising speed of the bias voltage to the controlled circuit can be increased. it can.

[Brief description of drawings]

FIG. 1 is a circuit diagram of an embodiment of the present invention, and FIG. 2 is a voltage waveform diagram of each part used for explanation of operation. SC …… Series circuit, CM1 …… First current mirror circuit, C
M2: second current mirror circuit, Icc: constant current source, M
C ... Mute circuit, SW1 ... Power switch, SW2, SW2 ...
On / off switch, C ... Charge / discharge capacitor.

Claims (1)

(57) [Claims] 1. A series circuit composed of a resistance and a charging / discharging capacitor connected between a power supply and ground, and a series circuit inserted between a power supply and a common connection part of the resistance and the charging / discharging capacitor in the series circuit. A constant current source, a first current mirror circuit, and a second current mirror circuit which is controlled by the output current of the first current mirror circuit and which is connected between the common connection portion and ground. When the charging / discharging capacitor is charged by the first charging current from the constant current source after the power is turned on and the charging voltage of the charging / discharging capacitor reaches a predetermined value, The output of the constant current source and the first current mirror circuit is controlled to be stopped, the second charge mode is entered, and the charge / discharge capacitor is charged by the second charge current passing through the resistor. Charging circuit which is characterized.