DE1218525B - Amplifier with switchable gain - Google Patents

Description

Switchable Gain Amplifiers The invention relates to a circuit for amplifying electrical signals with a switchable gain. In some amplifier applications, the input signals are very different Amplitude. There are cases in which the useful signals to be amplified are relatively small amplitude occur, while unwanted interference signals with large amplitude get an idea. If the times at which the useful signals to be amplified are expected are known and the interference signals are expected at other times, you can provide an amplifier in a known manner, which only during the useful signal times is controlled permeable, while it is blocked at the other times. Such Amplifiers are z. B. as a read amplifier for matrix memory, e.g. B. Magnetic core matrix memory, used. With such memories when switching the magnetic cores of one Remanence position in the other in the reading wire common to all magnetic cores a useful signal induced by positive or negative polarity. But in this reading wire also from the information wire, which is also common to all cores of a matrix is, and interference voltages coupled in from the selection wires, which are much greater can be than the useful signals. In order to suppress the interfering signals, it has therefore become known to use a differential amplifier as a sense amplifier for matrix memories which the amplifying transistors are blocked in the idle state and only during the duration of a pulse to be amplified can be controlled permeably for a short time (German interpretation 1116 724).

In such an amplifier, the large collector voltage jumps turn out to be caused by the switching process, as additional interfering signals that the Signal-to-noise ratio during the useful signal time, d. H. in permeable controlled Condition of the amplifier, worsen significantly.

Another difficulty arises when other than the above described task of the amplifier apart from its function as a pure pulse amplifier should carry out an amplitude evaluation of the useful signal in the sense that between amplitudes below a given threshold and those above this threshold are differentiated, so that accordingly different binary output signals can be achieved. The strong modulation by the known arrangement would generate additional interference signals when switching, A zero point shift, particularly in the case of amplifiers with no DC-free coupling cause the threshold value circuit, which only disappears after a long time and would falsify the amplitude evaluation.

The invention is based on the idea outlined above Solving difficulties by @ dimensioning the amplifier so that it is suitable for the useful signal has the correct dynamic range, while its gain in the time segments in which interference signals are to be expected, to a significant extent smaller value is switched without generating an additional interference signal the amplifier is completely switched off. According to the invention, this is done in that a switch is provided, which resembles by connecting points Potential to provide a resistance that essentially determines the voltage gain. or switches off.

Different implementation options are initially based on the F i g. 1 to 4 in application to a known amplifier stage with a NPN transistor shown in common emitter circuit. The transistor is in each case with 1, the input terminal with 2 and the output terminal with 3. The F i g. 5 to 8 show the application of these circuit options to differential amplifier arrangements or push-pull amplifier with npn transistors 1 and 1 ', the input terminals 2 and 2 'and the output terminals 3 and 3'. Finally, FIG. 9 a detailed one Circuit example based on the principle of FIG. 7, where as a switch one Diode bridge is provided, in one diagonal of which the points to be connected the same potential and in the other diagonal one of the diodes opens or blocking control voltage is supplied.

F i g. 1 shows an amplifier stage known per se with an npn transistor 1 in emitter circuit, to which the signals to be amplified are fed via terminal 2 at the base, which is connected to 0 volt operating voltage via a resistor 4. The collector operating voltage -i- U2 is supplied via the load resistor 5 and the output voltage is taken from the output terminal 3 connected to the collector. Between the emitter and a negative operating voltage - Ui, there is a negative feedback resistor, which consists of the series connection of the two partial resistors 61 and 62. According to the invention, the connection point of these two partial resistances is connected via a switch 7 to the auxiliary voltage source - Uh , the potential of which is of such a magnitude that when switch 7 is closed, no change in potential occurs at the connection point of 61 and 62, that is, this switch also does not carry direct current when closed.

The switch 7, which is shown schematically in the drawing as a mechanical switch, is expediently designed as an electronic switch. The auxiliary voltage source - Uh should have a dynamic internal resistance which is so small that it can be neglected compared to the other resistances. If the resistance values of the resistors 5, 61 and 62 are denoted by R5, Rsi and R62, the voltage gain vi is calculated approximately when the switch 7 is open When switch 7 is closed, the gain is If R61 is selected to be significantly smaller than R62, then, due to the significantly reduced negative feedback when switch 7 is closed, the gain v2 becomes very much greater than v1. In the above-mentioned application example of the invention as a read amplifier for magnetic core memory matrices, the switch 7 is kept open in the idle state, so that interference voltage peaks occurring during this time are only slightly amplified and only close during the times when a read signal can occur.

F i g. FIG. 2 shows an exemplary embodiment of the invention in which the same basic circuit as in FIG. 1 is used for the amplifier, but in which the gain is switched by changing the working resistance in the collector circuit. The same reference numerals denote the same parts as in FIG. 1. Here, it is not the negative feedback resistor labeled 6, but the working resistor which is divided into the partial resistances 51 and 52, and the switch 7 is located between the connection point of these partial resistances and a positive auxiliary voltage source + Uh, the dynamic internal resistance of which is again assumed to be negligibly small. In the idle state, the switch 7 is closed, as shown, and the gain is calculated When switch 7 is open, the gain applies You can also see here that if R51 is very much smaller than R52, then v2 becomes very much larger than v1.

F i g. 3 and 4 show exemplary embodiments in which the change the resistance values determining the gain by connecting a with the auxiliary voltage source U ,, connected resistance to an always present Resistance happens. The parallel connection of a resistor 64 corresponds to the Negative feedback resistor 63 in F.i g. 3 to shorting resistor 62 in F i g. 1 and the parallel connection of a resistor 54 to the working resistor 53 in Fig. 4 the short-circuiting of the resistor 51 in Fi g. 2. Thereby relate the terms "short circuit" and "parallel connection" each refer to the alternating voltage; for the direct current, the auxiliary voltage source is still in series or parallel switched so that no change in the direct current potential at the relevant connection point occurs.

F i g. FIG. 5 shows an amplifier arrangement with two amplifiers of the same type according to FIG. 1, which are connected to form a differential amplifier. The corresponding circuit parts are as in FIG. 1, whereby those of one amplifier are additionally marked with a »'«. The need for a separate auxiliary voltage source is eliminated here, in that the switch 7 is connected between the potentials at the connection points of the resistors 61 and 62 on the one hand and 61 'and 62' on the other hand. These potentials are selected by appropriate choice of the base quiescent potentials of the transistors 1 and 1 'and by a correspondingly symmetrical structure of the circuit so that when the switch 7 is closed, no equalizing currents flow through the switch. Is called again with R5 the resistance value of the resistors 5 and 5 ', with R61 the resistance of the resistors 61 and 61' and with R62 the resistance of the resistors 62 and 62 ', then for the gain for anti-phase input signals when the switch 7: and with the switch closed 7 If R61 is chosen to be much smaller than R62, the gain v2 is again very much greater than v1.

The F i g. 6 to 8 show corresponding applications of the circuit measures according to FIG. 2 to 4 on differential or push-pull amplifiers. Here, too, corresponding parts are again labeled with the same reference numerals, the circuit parts of one amplifier being additionally labeled with a "'". The calculation of the degree of reinforcement results accordingly. So z. B. for the circuit of the F i g. 8, which correspond to the circuit according to FIG. 4 corresponds to the following consideration. The switch 7 is connected in series with a resistor 54 "between the collectors of the two transistors 1 and 1 '. The value of the resistor 54" in FIG. 4 is to be used with 2 - R54. For antiphase control in points 2 and 2 ', the gain factor when the switch is closed applies with the switch open So if R54 is chosen to be much smaller than R53, then v2 is very much larger than v1.

It should again be expressly pointed out that the invention not only for the application example mentioned at the beginning in a sense amplifier for Ferrite core matrices is suitable, but can also be applied in all of the cases can, in which the gain of an amplifier without the occurrence of additional Interfering signals should be switched.

On the basis of FIG. 9 is now a detailed circuit example for an amplifier according to FIG. 7, which has proven particularly useful for the formation of a read amplifier for ferrite core matrices. Here, too, the switching elements that have remained unchanged have the same reference symbols as in FIG. 7 designated. In order to enable the already mentioned setting of the resting base potentials of the transistors 1 and 1 ' , the base points of the resistors 4 and 4' are not as in FIG. 7 connected to 0 volts, but to the terminals of a resistor 11 whose tap point, which can be set for balancing, is connected to a positive voltage source -I- U3. The input terminals 2 and 2 'of the amplifier are connected via resistors 12 and 13 to the terminals of the secondary winding of a first transformer 14, the primary winding of which is supplied with the signals to be amplified. The secondary winding is grounded in the middle to ensure push-pull control of the differential amplifier.

The electronic switch 7 is realized by a diode bridge, which consists of diodes 15, 16, 17, 18 and resistors 19 and 20. The connection points the diodes 15 and 17 on the one hand and 16 and 18 on the other hand are across the resistors 64 and 64 'are connected to the emitters of transistors 1 and 1' and form the one Diagonal of the bridge. The connection points of the diodes 15 and 16 on the one hand and the resistors 19 and 20 on the other hand form the other diagonal of the bridge via a second transformer 21 and a Zener diode 22, the control pulses for be fed to the switch. These points also lie across resistors 23 and 24 to a DC voltage source, which is generated by the potentials - U1 and -I- U3 given is.

In the idle state, a current flows from + U "through the resistor 24, the secondary winding of the transformer 21, the Zener diode 22 and the resistor 23 to - U1 16 on the one hand and the resistors 19 and 20 on the other hand, a voltage whose magnitude is determined by the Zener diode 22 and whose polarity is such that the diodes of the bridge are reverse biased. The electronic switch is therefore open in the idle state, and the Reinforcement is The size of the Zener voltage is to be selected so that even the greatest interference signals to be expected can make the diode bridge non-conductive and thus switch the gain to a higher value.

If a gating pulse is applied to the bridge via the transformer 21, the amplitude of which exceeds the Zener voltage of the diode 22, currents are generated in both branches of the diode bridge which should expediently be greater than the quiescent currents of the transistors 1 and 1 '. As a result, the two amplifiers are interconnected to form a differential amplifier with a high gain. Neglecting the dynamic resistance of the diodes 15 and 16, ie if this resistance is very much smaller than the resistance value R64, the gain will be The invention has been described on the basis of several basic possible embodiments and a special embodiment. However, it is not restricted to these possible applications, but can be used in many modifications and for the most varied of purposes for switching the gain.

Claims (9)

Claims: 1. Circuit for amplifying electrical signals with switchable gain, characterized in that two points, the via DC components with a third point (e.g. operating voltage) connected via a switch and possibly connected in series with it Ohmic resistors are connected in such a way that when the switch is closed, resistors which are decisive for the degree of reinforcement of the arrangement, directly or through any resistors in series with the switch are bridged, without the potentials change these two points. 2. Amplifier circuit according to claim 1, characterized in that the switch (7) is between a tap point of a negative feedback resistor (61, 62) and a low-resistance auxiliary voltage source (Uh) leading the potential of this tap point (F i g. 1). 3. Amplifier circuit according to claim 1, characterized in that the switch (7) between a tap point of the working resistor (51, 52) and a low-resistance auxiliary voltage source (Ur,) leading the potential of this tap point (F i g. 2). 4. Amplifier circuit according to claim 1, characterized in that the switch (7) is in series with an additional negative feedback resistor (64) between the connection point of the amplifier to a negative feedback resistor (63) and an auxiliary voltage source (Uh) carrying the potential of this connection point (F i g. 3). 5. Amplifier circuit according to claim 1, characterized in that that the switch (7) in series with an additional working resistor (54) between the output terminal of the amplifier and one the potential of this output terminal leading auxiliary voltage source (Uh) is (Fig. 4) - 6. Amplifier circuit according to Claim 2 or 3, characterized in that in a differential amplifier the Switch between corresponding tapping points of corresponding negative feedback or Working resistances is (F i g. 5 and 6). 7. Amplifier circuit according to claim 4 or 5, characterized in that in the case of a differential amplifier the series connection from switch and resistor between the two corresponding connection points of the reinforcing elements (Figs. 7 and 8). B. Amplifier circuit after a of claims 6 and 7, characterized in that a diode bridge is used as the switch is provided, in whose one diagonal the points to be connected lie and in whose other diagonal is supplied with a control voltage that opens or blocks the diodes (Fig. 9). 9. Amplifier circuit according to one of claims 1 to 8, characterized through their use as read amplifiers for magnetic core memory matrices in the way that the switch is designed as an electronic switch, while a read signal is expected, the amplifier from low gain to large Gain toggles. Publications considered: German Auslegeschrift # 1116 724.