HU189237B - Bc power amplifier - Google Patents

Abstract

The class BC power amplifier according to the invention, for amplifier devices, contains a series circuit comprising a balanced push-pull pre-amplifier, an intermediate amplifier and a power amplifier, the two arms of which are implemented using identical transistors with different line types and are designed with one amplifier stage operating in the B-mode and at least one amplifier stage operating in the C-mode. <IMAGE>

Description

BACKGROUND OF THE INVENTION The present invention relates to a BC-class power amplifier comprising a symmetrical two-stroke preamplifier, an intermediate preamplifier and a power amplifier connected in a circular configuration, having transistors having the same and reverse conductivity, corresponding to the polarity of the power supply and with at least one class C amplifier stage, wherein the emitter of each class B transistor is connected via a suitable protective diode to the corresponding corner of the power supply and the common point of the collectors of the two class B transistors is connected to one end of the load resistor. the outputs of the intermediate preamplifier are grounded through a suitable output resistance divider, and the intermediate points of the are connected to the base of a transistor, the emitter of which is connected to an active end of the load resistor through a suitable second protective diode, while its collector is connected to the active end of the corresponding first autumn transistor amplifier operating in the tank.

The BC-class power amplifier of the present invention can be used in amplifiers where volume, weight, cost, and power consumption per unit of useful power are of utmost importance, and when increased voltage is required from a low-voltage DC power supply without the use of a converter. '

A class BC power amplifier is known which comprises a circuit-connected symmetrical two-stroke preamplifier, intermediate preamplifier and power amplifier having two strands with the same parameter transistors, backscatter conductivity, at least one class B of the power supply polarity and connected in series has a preamplifier stage.

The emitter of a class B transistor is connected to the appropriate corner of the power supply via a suitable protective diode. The common point of the collectors of the two class B transistors is connected to one end of the load resistor while the other end is grounded.

At the output of the intermediate preamplifier, a suitable resistor is grounded by a divisible path and so on. their intermediate points are connected to the bases of the respective comparator transistors, while the emitters are connected via second protective diodes to the active end of the load resistor, and the collectors are connected to the bases of the corresponding class C first transistor amplifiers.

The operation of this known BC class amplifier is as follows:;

At rest, a maximum current is passed through the transistors of the intermediate preamplifier close to the saturation current. Class B transistors have minimal current flow, while Class C transistors are closed as well as the corresponding comparator transistors (Class C). «·· I '

In the case of a signal at the input of the amplifier, the upper or lower branches are activated according to the polarity. For weak signal (approx. To a maximum of 50%) in class B operating transistors ve ⁵ zérlik flowing through a load while the power is supplied directly from the low voltage power supply.

In the case of a strong signal, comparator transistors operate class C transistors, ¹⁰ . which are powered by a high voltage power supply.

A disadvantage of this amplifier and other BC-class amplifiers lies in two voltage source is required to achieve ^5-stage effects, three-stage effect three voltages required ségforrás etc.

This circumstance limits the field of application to amplifiers that are powered by AC power or converter, or • transformers, which are expensive, complicated, and bulky equipment.

A further disadvantage is that no high voltage power supply to (for example, 24V járműakkumulá ²⁵ tor) the possibility of achieving a high output voltage or consistency with the load without adding a feszúltségemelő output transformer, which added complexity and power increase, gain in weight and strength was ³⁰ much value index of degradation bring it with you.

It is an object of the present invention to provide a simplified BC class power amplifier with increased output voltage.

³⁵ According to the invention the object is achieved by a BC-class power amplifier comprising interconnected symmetrical stroke preamplifier intermediate preamplifier and a power amplifier in a chain form in which the two arms are formed of the same transistors as regards proper backing ⁴⁰ conductivity parameters, in accordance with the power supply polarity, and connected in series amplifier stage equipped with a class B amplifier and at least one class C amplifier stage ⁴⁵ .

The class B transistor of each branch has an emitter connected to the corresponding corner of the power supply via a suitable diode.

The collector ⁵⁰ of the two class B transistors has a common point connected to one end of the load resistor while the other end is grounded.

The outputs of the Intermediate Amplifier are grounded through an appropriate resistor output divider whose midpoints are the appropriate pins 55. The emitter is connected to the bases of transistor amplifiers, while the emitter is connected to the active end of the load resistor via a second protective diode corresponding to the crank, while its collector is coupled to the base of the corresponding first class C transistor amplifier.

The collectors of the appropriate comparator transistors are connected to the bases of the corresponding class C transistor through a suitable resistor. The emitters 65 of the class C first transistors are coupled to a corresponding storage capacitor whose second terminals are coupled to the emitters of the corresponding class B transistors.

The corresponding reference transistor collectors are also connected to the second com- ⁵ parative emitters of the transistors via a third corresponding protective diode, when each second reference transistor base of the power supply is connected to the respective corners of at a suitable fourth protection diode, as well as azo ^one preceding θ MOT C class transistors. collectors and emitters of the next class C transistors through a suitable storage capacitor.

The second reference transistors ¹⁵ kollek- Tora totality are connected through a suitable resistor operating in class C ^ bases of these transistors. Comparative last-transistor collectors of the two branches are connected namely via a suitable protection diode ²⁰ fifth cantly the corresponding last operating in class C bázi- transistors. The active end of the A-load resistor is connected to the inputs of the respective switching stages, while the outputs are connected to the emitters ^{25 of} the respective class C transistors.

The switching stages can be implemented with two transistors of equal conductivity, corresponding to the polarity of the supply voltage. The first switching transistor bases are a sixth protection diode Christianity ³ θ too kétellenállásos inlet manifolds intermediate point connected, while the collectors are connected to a suitable terminal of the power supply through a suitable load resistor, and they are connected to the second switching transistor base area ³⁵ while the latter emitters grounded together with the emitters of the first switch transistors and the passive ends of the dual-resistance input divider, while the collectors are the outputs of the switching stages. ⁴⁰

The switching stages may be implemented by a switching transistor having a conductivity corresponding to the polarity of the supply voltage, the collector of which is grounded and its base connected to the switching stage by a resistor, while the emitter 45 forms the switching stage output.

Advantages of the class BC amplifier according to the invention are the simplified design and the increased output voltage. The invention will now be further illustrated by means of an exemplary embodiment. Oo

Figure 1 is a schematic diagram of an amplifier according to the invention;

Figure 2 is a possible embodiment of the switching stage;

Figure 3 is another embodiment of the switching stage. 55

The class BC power amplifier of the present invention, as shown in FIG. 1, comprises a chain-linked symmetrical two-stroke preamplifier 1, a two-stroke intermediate preamplifier 2, and a two-stroke power amplifier. 60

Both branches of the power amplifier are constructed with transistors having the same parameters and back conductivity corresponding to the polarity of the power supply. Each of the 3 branches is comprised of a series B class 65 amplifier stage and at least four 5I transistor stages which.

She works in class C. The emitter of transistor 4, which operates in class B, is connected to the corresponding corner of the power supply via a suitable protective diode 6.

The collectors of the two class B transistors 4 have a common point connected to one end of the load resistor 7 while the other end is grounded.

The outputs of the intermediate amplifier 2 are grounded through a suitable output resistor divider 8 and 9 whose intermediate point is connected to the bases of a suitable comparator transistor 10, the emitter of which is connected via a second protective diode 11 to the active end of the load resistor 7. The collectors of the comparator transistors 10 are connected to the base of the respective first class C transistor 5.1 via the respective resistor 12.1. ·

The emitters of the first class transistors 5.1 of each power branch of the power amplifier stage 3 are coupled to a suitable storage capacitor 13.1, the other output of which is connected to the emitter of the corresponding transistor 4 operating in class B.

The collectors of the respective comparator transistors 10 are also coupled to the emitters of the respective second comparator transistors 14.1 via respective third protective diodes 15.1.

The bases of each of the second comparator transistors 14.1 are simultaneously connected via the fourth protective diode 16.1 to the corresponding corner of the power supply and to the collector of the former class C 5i +1 transistors and the emitters of the subsequent class 5i +1 transistors operating in class C, suitable for 13.i + 1 storage capacitor.

The collectors of the second comparator transistors 14.1 are connected via a suitable resistor 12.i +1 to the bases of the corresponding class 5.1 + 1 transistors operating in class C.

The collectors of the last comparator transistors 14.n -1 of each of the 3 branches are connected via a suitable fifth 15n protective diode to the bases of the latter class 5n transistors working in class C. The active end of the load resistor 7 is connected to the inputs of the corresponding switching stages 17i, while the ends are connected to the emitters of the corresponding class C transistors 5.1.

The switching stage 17.1 is implemented with two identical transistors (Fig. 2) having a conductivity corresponding to the polarity of the supply voltage. The first

The base of the switching transistor 18.1 is connected via the sixth protective diode 19.1 to the intermediate points of the second two-resistance input divider 20.1 and 21.1. The collector, on the one hand, has the corresponding 22.i; is connected to the corresponding corner of the power supply and to the base of the second switch transistor 23i, whose emitter is grounded together with the emitter of the first switch transistor 18.1, and on the other end with the passive end of the dual-resistor input divider. Its collector is the output of switching stage 17i.

The switching stage shown in Fig. 3 can be generated. 189 237 with a conductor corresponding to the polarity of the supply voltage

Switch 24.1 with a transistor whose collector is grounded and its base is connected via a resistor 25i to the input of switching stage 17i, where the output of switching stage 17i of the emitter is.

The operation of the class BC power amplifier according to the invention is as follows:

At rest, a maximum current is set through the transistors of the intermediate preamplifier 2, which is close to the saturated current. Minimal current flows through the transistors 4, while the class C transistors 5.1 and the comparator transistors 14i are closed. Storage capacitors 13i via switching transistors 32i or 24i. They are charged up to the same voltage as this supply voltage. At the negative signal to the input of the intermediate preamplifier 2, the upper branch 3 is activated. The supply voltage E supplies current from the + via the protective diode 6. At a certain level, an increase in excess, which corresponds to an output voltage close to supply voltage E, begins the first commutation interval - comparator 10 opens and operates the class C transistor 5.1. It's working so far. To the + point of this supply voltage is connected via the protective diode 16.1 and the collector-emitter junction of the transistor 5.1, the charged capacitor 13.1 of the supply voltage E is connected in series.

The total supply voltage is 2 E supply voltage. As the output voltage approaches 2 E, the potential difference between the collector of transistor 10 and collector of transistor 5.1 will be large enough so that the conditions for opening the first and second comparators 14.2 of branch 3 are created. This, for its part, activates the third stage of the amplifier - transistor 5.2 and storage capacitor 13.2 and so on. and the second commutation interval begins with the second peak interval.

In the next half-period, this branch will have a

The storage capacitors 13.1 are energized from the + point of the supply voltage E through the respective switching stages 17i. The operation of the second branch is quite similar.

The ratio of resistors in the dual resistor input divider 20Oi and 21.i of the switching stage 17i (Fig. 2) determines the start of the appropriate commutation interval and the distribution of the distributed power between class B and class C transistors. If control of this distribution is optional, the inputs of each switching stage 17i may be connected to the collector of the respective comparator transistors 10 and 14i instead of the amplifier output.

In cases where it is twice as high in some grades. voltage (except for the first class B), the earthed end of the respective switching stage 17i may be connected to the opposite corner of the same power supply instead of the center of the power supply.

For low power, it is possible to simplify the gear (Figure 3). In this case, the inputs of the two respective switching stages 17i of the upper and lower branches 3 must be connected to each other.

In cases where the center of the power supply is missing, it can be artificially constructed using one or two high capacity capacitors.

Claims (3)

Claims 1. A class BC power amplifier having a symmetrical two-stroke pre-connected ¹ °. comprises an amplifier, an intermediate pre-amplifier and a power amplifier having two branches is realized with transistors of the same and backside conductive relation to corresponding parameters in accordance with the power supply polarity, and ¹⁵ is resumed in an online class B amplifier stage, and at least one class C erősítöfokozattal which class each B operating via branch transistor emitter suitable protection diode of the power supply are connected to respective corners of, and operating in class ²⁰ two B transistor is connected to a junction point kollektorai- does, the load resistance to one end, the other end grounded, while the intermediate preamplifier outputs for coupled to ground corresponding output resistor divider and, as a square inner points ²⁵ are connected to the base of the corresponding reference transistor having an emitter with a corresponding second védődiód n across the load resistance connected to the active end, while its collector totality bound active end operating class first C to ³⁰ transistor amplifier stage, characterized in that the respective reference transistor (10) collector is connected in operation to the corresponding class first C-effect transistor (5.1) the base of resistor (12.1) is connected ³⁵ while the emitter of the respective first class C transistor (5.1) is coupled to a suitable storage capacitor (13.1) having another terminal connected to the emitter of the class B transistor (4) while the corresponding comparator ⁴⁰ the collector of transistor (10) is coupled via a third protective diode (15.1) to an emitter of a second comparator transistor (14.1), wherein the base of each second comparator transistor (14i) is parallel to the 45 corners of the power supply through a fourth protective diode (16.1). l, with a collector of a class C transistor (5.i) and an emitter of the corresponding subsequent class C transistor (5i + 1) via a suitable storage capacitor (13i +1) · connected to 50 while every second comparator transistor (14i) ) collector is connected to the base of the next class C transistor (5i + 1) via a resistor (12i + 1), whereby the last comparator transistor (14nj to the collector5 & base of the last class C transistor (5n) on a comparator diode (15n) is connected through the inputs, while the active end of the load resistor (7) is connected to the inputs of the switching stages (17i) and its outputs are connected to the emitters of the operation class transistors (5.1). ,. . A class BC power amplifier according to claim 2-Claim 1, characterized in that the switching stages (17.1) are formed by two dubious transistors having the same conductivity, the voltage-4i 189,237, wherein the base of the first switching transistor (18.1) is connected via a sixth diode (19.1) to the center of a two-resistance input divider (20i and 21i), while its collector is connected to a power resistor and a second switch via a load resistor (22i). connected to the base of a transistor (23i), whose emitter together with the emitter of the first switching transistor (18i) and the passive end of the dual-resistance input divider (20i and 21i) are grounded and its collector ¹⁰ forms the output of the switching stage (17i). The class BC power amplifier according to claim 1, characterized in that the switching step ⁵ (17i) is formed by a switching transistor (21i) whose collector is grounded and connected via a resistor (25i) to the input of the switching step (17i). its emitter is the output of the switching stage (17i).