DE4224202A1 - DC control circuit for audio appts. - contains stabilised voltage output circuit for Zener diode, generating reference voltage - Google Patents

Abstract

The controller receives an unregulated voltage and regulates its output voltage in dependence on the DC circuit output voltage changes. There is a circuit delivering a stabilised voltage, which control a Zener diode (8) to generate a reference voltage. An amplifier (4) is controlled by the stabilised voltage to amplify the output voltage changes w.r.t. the reference voltage. It transmits the amplified changes of the output voltage to the control of the output voltage. Pref. the voltage stabilising circuit generates a stabilised voltage from the supplied, non-regulated voltage. USE/ADVANTAGE - For Hi-Fe audio appts. DC control circuit, with high output DC circuit facility.

Description

The invention relates to a DC regulator according to the Ober Concept of claim 1.

The invention provides a DC regulator, in particular a DC control circuit, whose DC voltage output is highly stabilized.

For high fidelity, audio equipment must be operated with a DC power supply that delivers a stable, low noise voltage to the respective circuits within the audio arrangement regardless of changes in the load. Fig. 2 shows an example of a known regulator, the lie stabilized DC voltage to the audio circuits or audio circuits. According to Fig. 2A operates a transistor 3 for regulating an unregulated DC voltage to a circuit Eingangsan 13 of the controller is applied, so that a stable con stant voltage at an output terminal 14 occurs. The stabilized voltage is then applied to the load. The change in the voltage applied to the load is divided by resistors 5 and 6 and the divided voltage change is then applied to a negative input terminal of a differential amplifier 4 . A resistor 7 and a Zener diode 8 generate a reference voltage Re and lead this to a positive input terminal of the differential amplifier 4th The differential amplifier 4 amplifies the differences between the two input signals applied to it and couples the amplified difference back to the base of the transistor 3 , whereby it operates in such a way that the change in the output voltage of the regulator is always eliminated.

In the known control circuit, the differential amplifier 4 is supplied with a non-regulated voltage (as electrical power), ie with the input voltage to the regulator. The unregulated voltage contains a large amount of ripple components or ripple components. Thus, the ripple in the voltage causes changes in the voltage across the Zener diode so that the reference voltage is not a completely uniform, constant voltage. The changes in the voltage across the Zener diode then appear at the output terminal 14 of the energy supply circuit, which shows a slight ripple-reducing effect. The ripple components in the unregulated input voltage also occur at the output of the amplifier 4 .

A circuit shown in FIG. 2B can be used to avoid the disadvantages of the known control circuit according to FIG. 2A. According to Fig. 2B, the differential amplifier 4 and the Zener diode 8 are fed by the regulated output of the transistor 3. The base voltage of transistor 3 must be the output voltage of the regulator plus the voltage V _be (about 0.6 V) of transistor 3 . The maximum output of the differential amplifier 4 is approximately 2 V below the supply voltage of the differential amplifier 4 , which is not sufficient to control the transistor 3 directly. Thus, the output of the amplifier 4 controls the transistor 10 , which cooperates with the Zener diode 12 to shift the output of the differential amplifier 4 in terms of its level, so that the base of the transistor 3 in a suitable manner to a voltage of the output of the amplifier 4th plus the voltage across the Zener diode 12 is biased, while at the same time changes in the output of the differential amplifier 4 occur directly on the basis of the transistor 3 . The Zenerdio de 12 and the transistor 10 are driven by a constant current source 11 and serve to operate as a level shift circuit or level change circuit (level coupling circuit). However, the level shift circuit has two disadvantages: one disadvantage is that the current through the Zener diode changes when the output signal of the amplifier 4 changes and the other disadvantage is that noise generated in the Zener diode adversely affects the noise characteristic of the controller output signal.

In addition, low gains of the transistor 10 at higher frequencies cause increased regulator output impedances, which result in large changes in the regulator 20 output voltage when the load varies at high frequencies.

The supply circuits must be protected by fuses (fuses) or other protective circuits if the output connection is accidentally or accidentally grounded or if a load current is drawn above the nominal value. The current drawn by the output terminal is, for example, at least ten times greater than the normal load current if the output terminal is accidentally grounded. The setpoint of the fuse 15 is usually chosen so that it is a multiple times larger than the normal maximum load current in order to ensure the reliability of the supply during normal operation and a reliable blowout of the fuse if the output terminal is accidentally grounded becomes.

The constant current source 11 of FIG. 2B must therefore be able to deliver a base current that is ten times greater than the normal base current during an accidental short circuit to ground. This shows that the normal base current is quite small and most of the current from the constant current source 11 flows into the Zener diode 12 and into the transistor 10 during normal operation.

So the current through the level shift circuit is too big, for low noise and good ripple rejection guarantee ratio (ripple voltage ratio).

The invention has for its object a high performance To create a DC control loop for audio equipment.

This object is achieved by the features of Pa claim 1 solved.

Further refinements of the invention result from the Un claims.

The invention provides a feed circuit with improved Noise characteristic with respect to the DC output voltage and reduces output impedance characteristics or impedance curve at high frequencies. The circuit is also designed so that the operation of the protection circuit is guaranteed.

The invention provides a DC voltage control circuit or a DC control loop, the output voltage of which regulating unit receives an unregulated voltage that this Unit is supplied and the output voltage of the same ent regulating the changes in the output voltage. A voltage stabilizing circuit provides a stabilized Voltage from which a zener diode generates a reference voltage begets; an error amplifier has the function of amplification of changes in the output voltage compared to the reference Tension. The amplified changes in the output voltage  are fed to the output voltage control device.

Below are preferred embodiments of the invention using drawings to explain other features and Advantages described. Show it:

Fig. 1 is a schematic diagram of a first exporting approximate shape of a DC regulator according to the OF INVENTION dung,

Figs. 2A and 2B known DC regulator,

Fig. 3 shows the ripple components and the noise level, which come from the source into the output signal of the audio device, with A the ripple components and the noise are designated when the DC control circuit according to FIG. 1 is used, while B the ripple components and that Noise is designated when using the feed circuit according to FIG. 2B,

Fig. 4, the output impedance characteristic of the power source of FIG. 1,

FIGS. 5 and 6 modified embodiments of the DC regulator having according to the invention, both a Nebenschlußre geltransistor and a transistor for series or main-circuit control, in which Fig. 5 is a positive voltage supply, and Fig. 6 represent a negative voltage supply, and

Fig. 7 shows an embodiment of a direct current control with shunt control transistor.

A preferred embodiment of the invention is described in detail below with reference to FIG. 1.

Fig. 1 is a schematic representation of a DC regulator 20 according to the invention. A reference regulator 9 has, for example, the form of an IC regulator with three connections (an integrated circuit such as NJM78M12FA for a positive voltage and NJM79M12PA for a negative voltage), which an input voltage that is supplied to it in a stabilized output voltage converts, which is higher than the output voltage of the DC regulator 20 plus the base-emitter voltage V _{be of} the transistor 3 as a device controlling the output voltage. The reference regulator 9 controls a Zener diode 8 (HZ5BLL) to supply a reference voltage and also feeds the differential amplifier 4 .

The supply circuit of FIG. 1 operates on the same principle as the power supply circuit of FIG. 2 according to the prior art.

Since the differential amplifier 4 is controlled by the output voltage of the reference controller 9 and fed, which supplies a voltage which is much higher than the output of Reg coupler 20, the output of the amplifier 4 in a position, a voltage and a current supply, that are sufficient to control or modulate the transistor 3 . Thus, a level shift circuit according to FIG. 2B is not required. Fig. 3 shows the ripple components and the noise level coming from the feed circuit into the output signal of the audio device; curve A shows the ripple components and noise when the DC control circuit 20 of FIG. 1 is used, while the graph of B illustrates the ripple components and noise when the known feed circuit of FIG. 2B is used. The level of the ripple components and the noise is shown in decibels (dB) compared to the output signal of the audio device. Curve A illustrates that the noise-reducing effect is significantly improved, in contrast to curve B of the known circuit.

In Fig. 4, curve A shows the output impedance curves of a control IC with three connections, curve B the output impedance curve of the known circuit according to FIG. 2B and curve C the corresponding curve of the control circuit 20 according to the inven tion. The output impedance curve of the circuit according to the invention is significantly improved, as can be seen from a comparison of curves A and B. While the embodiment described above with respect to a positive voltage regulator uses an NPN transistor 3 , a negative voltage regulator using a PNP transistor as the transistor 3 may also be provided.

FIGS. 5 and 6 show embodiments of a DC regulator according to the invention, both of which transistor a shunt rule and comprise a main circuit control transistor, where a positive voltage supply is performed at shown in FIG. 5, currency rend in the embodiment of Fig. 6 is a negative clamping voltage power is supplied .

Fig. 7 shows another embodiment of a DC regulator with a shunt control transistor.

A direct current control circuit or a direct current control circuit contains a control device for the output voltage, which receives an unregulated voltage and controls the output voltage in accordance with changes in the output voltage. A reference regulator 9 controls a Zener diode 8 to generate a reference voltage and to control a differential amplifier 4 . The amplifier 4 works to amplify changes in the output voltage compared to the reference voltage. The amplified changes in the output voltage are fed back to the device regulating the output voltage in such a way that the changes are eliminated.

Referring to FIG. 5, a positive voltage is applied to the input 113 and lated by a controller 109 having three terminals Gere, whereafter this voltage then a zener diode is fed to 108 via resistor 122 ei NEN. The Zener diode 108 generates a reference voltage and supplies it to an error amplifier 104 . The voltage across output 114 and ground is divided by resistors 120 , 121 and the divided voltage is supplied to error amplifier 104 . Controller 109 also feeds amplifier 104 . The amplifier 104 amplifies the difference between the reference voltage of the zener diode 108 and the divided voltage, so that the amplified difference is applied to the connection between the base of the transistor 124 and the collector of the transistor 123 . The transistor 123 is biased by the resistors 128 , 129 at a suitable operating point, so that the transistor 124 is controlled. The transistor 123 and the resistors 128 , 129 are also effective to direct changes in the output signal of the amplifier 104 directly to the base of the transistor 103 . Transistor 124 draws more current through resistor 125 when the load on terminal 114 is small and less current when the load on the regulator is large. In this way, the entire circuit shown in FIG. 5 operates in such a way that the voltage drop across the resistor 126 is always constant.

According to the circuit shown in FIG. 6, a negative voltage is applied to an input 213 and regulated by a regulator 209 with three connections, after which it is then applied to a zener diode 208 via a resistor 222 . The Zener diode 208 supplies a reference voltage and leads it to the error amplifier 204 . The voltage across output terminal 214 and ground is divided by resistors 220 , 221 and the divided voltage is applied to amplifier 204 . The controller 209 also feeds the amplifier 204 . The amplifier 204 ver amplifies the difference between the reference voltage of the Zener diode 208 and the divided voltage, so that the amplified difference to the base of a parallel Regel- or Steuertran sistor 224 as well as to the base of a series transistor 203 through the transistor 223 and resistors 228 and 229 is created.

According to the circuit shown in FIG. 7, a positive voltage applied to the input 313 is regulated by a regulator 309 with three connections and then applied via a resistor to a zener diode 308 , which supplies a reference voltage. The controller 309 also feeds an error amplifier 304 . The amplifier 304 amplifies the difference between the reference voltage and the voltage at the output 314 , which is divided by two resistors. The output of amplifier 304 is applied to the base of a parallel control transistor 303 .

Claims (7)

1. DC control circuit with a control for the output voltage, which receives an unregulated voltage and regulates its output voltage depending on the changes in the output voltage, characterized in that
that a circuit for supplying a stabilized voltage is provided,
that a zener diode ( 8 ) is controlled by the stabilized voltage so that a reference voltage is generated, and
that an amplifier ( 4 ) is provided which is controlled by the bilized voltage to amplify changes in the output voltage in relation to the reference voltage and outputs increased changes in the output voltage to the device regulating the output voltage. 2. DC control circuit according to claim 1, characterized, that the voltage stabilizing circuit from her supplied unregulated voltage a stabilized span generated. 3. DC control circuit according to claim 1, characterized, that the device regulating the output voltage Transistor is. 4. DC control circuit according to claim 3, characterized, that the transistor is of the PNP type. 5. DC control circuit according to claim 3, characterized, that the transistor is of the NPN type. 6. DC control circuit according to claim 1, characterized, that the voltage stabilizing circuit is a regulator from IC type is three-terminal. 7. voltage control loop according to claim 1, characterized, that the amplifier is a differential amplifier.