DE1562218C - Differential amplifier with balanced input and unbalanced output - Google Patents

Description

The invention relates to a differential amplifier with a symmetrical input and an asymmetrical one Output with a first transistor and with a second transistor complementary to the first, where the collector of the first transistor connects to the emitter of the second via a first Resistor and the collector of the second transistor through a second resistor to the emitter of the first transistor is connected, both resistors having substantially the same values, at which also the collector of the second transistor is connected to the reference potential and in the one Operating point setting is provided for both transistors.

In a known differential amplifier of this type (NTZ 1966, pp. 76 to 78) the working point setting takes place of the two transistors via another transistor, which acts as a constant current source for the two transistors are used, so that maximum gain is possible with good common-mode rejection is. The unbalanced output is between ground and the one through the collector this further transistor formed connection of the constant current source to the amplifier circuit. It is therefore only possible due to the fundamentally high-resistance nature of each constant current source, load the output with a high-resistance load. If a load other than high resistance would be connected ^ sen, the circuit could no longer work properly. Therefore, those in the above apply The cited technical parameters for this amplifier are strictly speaking only for the No-load output voltage drop and are only valid for only a very small load. It must therefore, in the known amplifier circuit, an impedance converter stage is always connected downstream in order to take into account the practical needs for changing initial loads to be able to, as is particularly the case with video transmission systems with symmetrical lines Case is.

In such transmission systems, the information is on opposite sides of the line transmitted out of phase by 180 °. Noise signals on opposite sides of such transmission lines generally have the tendency to be in phase, i.e. in common mode. Therefore one tries to suppress such common-mode signals while the desired information (180 ° out of phase) is to be transmitted.

The object of the invention is therefore to provide a much simpler, but nevertheless at least equally effective differential amplifier with common-mode rejection of the type described in the introduction, which in particular also manages without input and output transformers, as is the case, for example, in the US Pat. No. 2,839,620 known differential amplifiers with common mode rejection are provided.

The solution of this object according to the invention consists for the amplifier as described in the introduction Kind only in the fact that the operating point is set by means of two resistors in the base circuit of the transistors and that the emitter of a third transistor is connected to the collector of the first transistor, the base of which is connected to the other reference potential (or grounded) and its Collector forms the output of the amplifier.

The arrangement according to the invention has numerous advantages. So is the unbalanced amplifier output low resistance; there can therefore also be changing initial stresses without any additional measures can be connected directly. This third transistor has a double function in that it at the same time the power supply of the amplifier circuit concerned, but in contrast to the known not as a constant current source, but as a

ίο constant voltage source, since the base potential of this Transistor is tied and the voltage drop across the forward-biased base-emitter junction is negligible. As a result of the constant operating voltage for the actual amplifier circuit allows these to be linearized and adjusted much more easily, so that even with changing Output load conditions always maximum amplifications of differential signals with maximum suppression of common mode signals is guaranteed.

Finally, the amplifier according to the invention is of a simpler construction in that it already has three Transistors has a low-resistance output circuit, while in the known amplifier at least a fourth transistor stage is required to obtain a low-resistance output.

Finally, the amplifier can be used as an integrated

Circuit and / or thin-film circuit, since no inductances are required. the The size of the amplifier can therefore be made extremely small.

The invention is based on an embodiment shown in the drawing in individually explained.

In the illustrated circuit diagram of the differential amplifier designed according to the invention with a symmetrical input and an asymmetrical output, the symmetrical input signal is fed to the input connections 10 and 11. A resistor 12 and a capacitor are connected to the input connection 10 and form the network on the input side for the signal received at the input connection 10. The other side of capacitor 18 is connected to bias resistors 13 and 14 and to the base of an NPN transistor 20. The resistors 12 and 13 are connected at the other end to one another and to a reference potential or the system earth. A resistor 15 and a capacitor 19 are connected to the other input terminal 11. The resistor 15 and the capacitor 19 form the input-side network for the signal received at the input terminal 11. The other side of the capacitor 19 is connected to bias resistors 16 and 17 and to the base of an NPN transistor 21. The transistors 20 and 21 are therefore complementary to one another. At the other end , the resistors 15 and 16 are connected to each other and to the reference potential (system earth). The other sides of the bias resistors 14 and 17 are connected to the connection

βο point 28 connected, at which a negative Reference potentials, the emitter of the transistor 20 via an emitter resistor 22 and a blocking capacitor 24 are located. The other side of capacitor 24 is system ground.

The output circuit that directly supplies the unbalanced output signal has the following Construction: The collector of the transistor 20 is connected to the emitter of the via an emitter resistor 23

Connected transistor 21, which serves as a current amplifier. The collector of transistor 21 is at the connection point 28 for the resistors 14, 17 and 22 and the capacitor 24. The unbalanced output signal is delivered directly to the contracting point 29, which is the emitter of a transistor 25 leads. The transistor 25 is connected in common base, which is used for low input impedance Emitter of transistor 25 provides. The base of transistor 25 is connected to system ground, while the collector is connected to a positive reference potential source via the load resistor 26 is. If necessary, a subsequent one can be connected to the collector of transistor 25 for further amplification Amplifier 27 can be connected.

The operation of the circuit can be described simply by assuming that one input signal is supplied between the base and the transistor 20 and the reference potential point 28, while the other input signal is supplied between the base of the transistor 21 and the reference potential point 28. The bias resistors are chosen so that the transistors 20 and 21 operate in the linear range for the signals supplied. Since the transistor 25 is connected in a base circuit, its input impedance at its emitter is very low; it should be assumed to be zero. If one also assumes that the beta values, ie the current amplification factors of the transistors 20 and 21 in the emitter circuit, are infinite and that R ₂₂ = R ₂₃ = R , then

has both the desired component and a common mode component at the input terminals 10 and 11 is received. The output connection path provides an unbalanced signal at connection point 29 directly to the following amplifier stage, without a transformer are necessary that cannot be carried out in the video area.

In practice, of course, the beta values are not infinite, so that the actual Common mode rejection can be determined by taking the actual beta values and the emitter resistance values 22 and 23 can be used. It can be shown that the common mode rejection is given by

1 + 1- I-Ao - # 23 20 log 10 • # 23 ■ # 22 -1

^V 22

Zi =

U =

ing.

35

Z ₃ = Z ₁ + Z ₂ .

In order to illustrate the suppression of common-mode signals, it is assumed that the input signal V _{in_} consists of two signals in phase with the same value. Here the currents Z ₁ and i _{2 are the} same, but have opposite polarity, so that

'3 =

- z ₂ =

'Ent.

ing

¹ = 0.

It follows that the embodiment shown in Fig. 1 provides the desired signal (input voltage equal and 180 ° out of phase), but common mode signals (input voltages equal and in phase) attenuates when an input signal that As shown, the circuit can alone with With the help of capacitors, resistors and semiconductors, it can therefore also be built under Using the technology of integrated circuits and thin film circuits very compact being constructed.

Claims (1)

Claim: Differential amplifier with balanced input and balanced output with one first transistor and with a second transistor complementary to the first, in which the Collector of the first transistor to the emitter of the second via a first resistor and the collector of the second transistor through a second resistor to the emitter of the first Transistor is connected, both resistors have essentially the same values, in which the collector of the second transistor is also connected to the reference potential and in which an operating point setting is provided for both transistors, thereby characterized in that the operating point setting by means of two resistors (14,17) im Base circle of the transistors (20, 21) takes place and that to the collector of the first transistor (20) the emitter of a third transistor (25) is connected, the base of which is connected to the other reference potential is connected (or grounded) and its collector is the output of the amplifier forms. 1 sheet of drawings