CS244606B1 - Low frequency power amplifier - Google Patents

Abstract

The essence of the solution is that in each branch of the supply voltage of the integrated circuit - operational amplifier and an auxiliary summing resistor at the output, a stabilizing transistor is connected, the emitter of which is connected to the supply voltage terminal of the integrated circuit, its base is connected via a Zener diode to the common terminal of the amplifier's supply voltage and through a resistor to the supply voltage terminal of the entire amplifier, and its collector is connected via a sensing resistor to the supply terminal of the entire amplifier. In each branch, there is also a power transistor, whose base is connected to the collector of the stabilizing transistor, its emitter is connected to the supply voltage terminal of the amplifier, and its collector is connected to the output terminal of the amplifier. Circuits with stabilizing transistors and Zener diodes stabilize the supply voltage of the integrated circuit - operational amplifier to an optimal value, depending on the fluctuations in the supply voltage of the entire amplifier. The current through the sense resistors corresponds to the current into the powerful compensating resistor. The voltage drop across the sense resistors causes the power transistors to open and the input voltage of the amplifier is amplified at the output terminal of the amplifier. These voltages can be much greater than the maximum allowable supply voltage of a separate integrated circuit.

Description

INVENTOR MUST HAVE VÍTEK ing., HOLESOV, PETER, GOTTWALDOV (54) Low-frequency power amplifier

The essence of the solution consists in that in each branch of the supply voltage of the integrated circuit - the operational sealant and the auxiliary resistor at the output is connected to the stabilization transistor whose omitter is connected with the power supply terminal of the integrated circuit. and the collector is connected via the sensing resistor to the power supply terminal of the entire sealant and the power supply terminal of the entire sealant. In each branch, a power transistor, yeah, is connected to the collector of the stabilizing transistor, its emitter is connected to the power supply terminal of the amplifier, and its collector is connected to the output terminal of the amplifier. The circuits with stabilizing transistors and Zoner diodes stabilize the supply voltage of the integrated circuit - the operational amplifier to the optimum value, dependent on the supply voltage fluctuation of the whole amplifier. The current through the sensing resistors corresponds to the current into the powerful load resistor. The voltage drop across the sensing editors causes the power transistors to open and the amplifier output terminal has amplified input voltage. These voltages can be much greater than the maximum allowable voltage of a single integrated circuit.

The present invention relates to a power amplifier of low frequency signals which are used, for example, in acoustic reproduction devices, for powering motors in automation technology and the like.

Increasing the power of the amplifier is done either by increasing the supply voltage or by reducing the load resistance. Increasing the supply voltage is limited by the maximum permissible breakdown voltage of the elements used, especially transistors.

The currents in the amplifier circuits increase as the load resistance decreases. Voltage losses at the junction of the semiconductor elements in the amplifier and in the power supply for the amplifier are dependent on the current drawn.

The resistance of the supply conductors and connections, eg on the connectors, is not negligible due to the load resistance, the achievable efficiency decreases. At high current values the transistor amplification factor decreases.

Due to the design of the windings, the motors cannot be solved by using low resistors.

Amplifiers in the form of a monolithic integrated circuit are known. Their achievable power for the appliance is limited by the manufacturer approximately 20 * at the maximum accessible supply voltage + 20 V / = 40 V /.

Monolithic integrated circuits are not produced for higher performance. High power power amplifiers are usually composed of discrete transistors. The production of such amplifiers is laborious, places high demands on the qualification of the workers, requires the use of special measuring instruments for their adjustment and is therefore expensive.

Hybrid integrated circuits are produced for special purposes. However, due to their high cost, their use is not an option in the mass production of consumer products.

Power amplifiers are known which form a monolithic integrated circuit to which they are connected symmetrically in the positive and negative branches of the supply voltage of the Zener diodes, sensing resistors and emitters, and the base of a complementary pair of power transistors; their collectors are connected to the output terminal of the amplifier and via feedback with inverting integrated circuit input.

Zener diodes reduce the voltage across the power supply of the integrated circuit from the power supply voltage for the power transistors, which provide greater output power. If the maximum permissible voltage of the integrated circuit is to be used to the maximum, the supply voltage of the whole amplifier must be stabilized.

The necessary stabilizer has large dimensions, it is necessary to solve the problem of cooling and the efficiency of the stabilizer is problematic.

These problems and disadvantages are solved by the low frequency power amplifier according to the invention. It is based on the fact that the integrated circuit, formed as an operational amplifier, is connected in each branch of the supply voltage to the emitter of the stabilizing transistor, whose collector is connected to the sensing resistor and the base of the transistor and its base is connected via a Zener diode to a common terminal voltage of the amplifier and supply the voltage of the whole amplifier through a resistor with a terminal.

The positive transistor power transistor is of the FNP type, the positive transistor Zener diode is poled by a cathode based on the NPN-type stabilizing transistor.

The power transistor of the negative branch of the supply voltage is of the NPN type, the Zener diode is negative

24460 «

The supply voltage branches are poled by the anode on the ramp of a PUP-type stabilizing transistor.

The amplification of the amplifier according to the invention obviates the disadvantages of the previously known amplifier type. The voltage for supplying the integrated circuit is constant as the supply voltage of the entire amplifier changes and the magnitude of the current flowing through the stabilizer into the integrated circuit is almost identical to the magnitude of the current flowing through the sensing resistors.

An example of a particular embodiment of an amplifier according to the invention is shown in FIG. 1. The monolithic integrated circuit 1 which constitutes the power operational amplifier is connected to the positive terminal 2 of the supply voltage by an NPN emitter of stabilizing transistor g stabilizing the positive supply voltage. it is connected to the emitter of the PNP stabilizing transistor g, which stabilizes the negative supply voltage.

The output terminal 2 of the monolithic integrated circuit 2 is connected via a common load resistor 2 ee by a common supply voltage terminal g. The collector of the transistor 3 is connected to one end of the sensing resistor 2 and also to the base of the PNP power transistor 10.

The emitter of the power transistor 10 is connected to the other end of the sensing resistor g and the positive terminal 11 of the supply voltage of the entire amplifier. The collector of the stabilizing transistor g is connected to one end of the sensing resistor 12 and to the base of the power transistor 13 of the NPN type.

The emitter of the power transistor 13 is coupled to the other end of the sensing resistor 12 and the negative terminal 14 of the supply voltage of the entire amplifier. The base of the stabilizing transistor g is coupled via a zener diode 18, a polarized cathode based on the stabilizing transistor g, to a common supply voltage terminal g, and via a resistor 16 for supplying the base of the stabilizing transistor g and Zener diode 15 to the positive terminal 11. supply voltage of the whole amplifier.

The base of the stabilizing transistor g is connected via a Zener diode 17 to a polarized anode based on the stabilizing transistor g, with a common supply voltage terminal g, and via a resistor 1g for supplying the base of the stabilizing transistor g and Zener diode 17 with a negative terminal 14 of the supply voltage of the amplifier.

The collectors of the power transistor 10 and the power transistor 13 are connected β to the first end of the feedback resistor 19 and to the output terminal 20 of the entire amplifier. An appliance 21, e.g. a loudspeaker or motor, is connected between the output terminal 20 and the common supply voltage terminal g.

The other end of the feedback resistor 19 is coupled to the inverting input 22 of the monolithic integrated circuit 1 and via the feedback resistor 23 to a common supply voltage terminal g.

To amplify only an AC signal without a DC component, a feedback resistor 23 is connected in series with a capacitor 24.

The non-inverting input 25 of the monolithic integrated circuit 1 is connected via a resistor 27 for supplying the integrated circuit input with a common supply voltage terminal g. The connection of the non-inverting input 25 of the monolithic integrated circuit 1 and the resistor 27 is connected to the input terminal 26 of the amplifier.

To amplify only an AC signal without a DC component, the decoupling input capacitor 28 is connected in series with the input from the amplifier input terminal 26 to the connection of the non-inverting input 25 with a gg resistance. The input signal to the amplifier is applied between the amplifier input terminal 26 and the common supply voltage terminal g.

Input voltage is applied to the non-inverting input 25 of the monolithic integrated circuit

- impose ···, it is positive. This amplified voltage appears at the output terminal 1 and induces a current flow through the auxiliary load resistor I of the IC. The magnitude of this current is virtually nearly the same as the current flowing from the positive terminal. The supply voltage of the entire amplifier through the sensing resistor 2 of the expensive collector-emitter of the stabilizing transistor 2 of the MPN type to the positive terminal 8 of the IC supply voltage.

Due to the large signaling of the PNP power transistor 1, the MPN stabilizing transistor 2 and the monolithic integrated circuit 1, the current to the base of the PUP power transistor, to the base of the NPM stabilizing transistor 2 and the power supply for the monolithic integrated circuit against the current flowing from the positive terminal 11 of the power supply of the whole amplifier through the sensing resistor 2 · ⁿ 2 positive terminal of the supply voltage of the integrated circuit and the output terminal d of the integrated circuit.

Current flowing across the positive amplifier power supply terminal 11, the sensing resistor 2 ^{to the} positive power supply terminal 2, and the IC output terminal 6 will cause a voltage drop across the sensing resistor 2 between the emitter and the base of the PUP type transistor 11 and open the output transistor 12. PUP type, resulting in amplified drunkenness at the output terminal 20 of the amplifier, and green power to the appliances.

The voltage at the positive terminal 2 of the power supply of the integrated circuit 1 is stabilized to a magnitude corresponding to the difference of the Zoner voltage of the Zener diode 12 connected between the base of the transistor 2 and the common terminal f of the supply voltage.

The integrated circuit 1 is thus supplied with an optimum voltage level regardless of the instability of the supply voltage of the whole amplifier.

For negative input voltages at the non-inverting input 22 of the monolithic integrated circuit and for negative supply voltages, the halves are symmetrically arranged! wiring applies analog current ratios.

The linearity and stability of the transmission ee is fed by a negative feedback, which is introduced from the output terminal 2ft by the feedback resistors 12 and 22 of the 4 ° input input 22 of the monolithic integrated circuit.

To amplify only the AC bass signals of the DC component, a capacitor 24 is connected in series with the resistor 22, which prevents the negative current from passing through the loop and thus the amplifier does not amplify the DC signal.

Through a resistor 27 for supplying the IC input between the non-inverting IC input 25 and the common voltage supply terminal fi and supplying the non-inverting input 25 of the monolithic IC in a zero-free state, defining the resting voltages at the amplifier output - assuming perfect symmetry it again zero.

Claims (1)

and the input capacitor 23 'is connected to the non-inverting input 22 of the monolithic integrated circuit by supplying an alternating input signal to the non-inverting input 22 of the monolithic integrated circuit. The whole amplifier does not transmit the DC signal at all. Stabilization and power transistors can be connected in a forai called Darlington connection. The power amplifier according to the invention is particularly suitable for amplifying music signals, in particular for sounding rooms and spaces, as well as for supplying two-phase asynchronous servomotors in control and auto-automation technology. P 8 E D M S T OF THE INVENTION Power amplifier of low frequency signals, which includes an integrated circuit designed as an operational amplifier, connected to the output through an auxiliary load resistor with a common terminal of the supply voltage of the amplifier, to which sensing resistors and emitters and bases complementary a pair of power transistors whose collectors are connected to the output terminal of the whole amplifier and via a feedback resistor with an inverted integrated circuit input, characterized in that the integrated circuit (1) in each supply voltage branch is connected to the stabilizer emitter input (2, 4). of a transistor (3, 5), whose collector is connected to a sensing resistor (9, 12) and the base of the power transistor (10, 13) and its base is connected via a Zener diode (15, 17) to a common terminal (8) and via a resistor (16, 19) with a terminal (1) 1, 14) of the supply voltage of the whole amplifier, whereby the power transistor (10) of the positive branch of the PNP jelly supply voltage and the Zener diode (15) of the positive branch of the supply voltage are polarized by a NPN type cathode (13) the negative branch of the supply voltage is of the NPN type and the Zener diode (17) of the negative branch of the supply voltage is polarized by the anode based on the stabilization transistor (5), which is of the PNP type.