DE1270097B - Pulse shaper circuit for converting one-sided pulses in any direction into one-sided pulses in a given direction with suppression of interference pulses and noise - Google Patents

Description

Pulse shaper circuit for converting any one-sided pulses Direction in one-sided impulses of a given direction with suppression of interference impulses and noise The invention relates to a pulse shaper circuit for converting unilateral impulses in any direction in unilateral impulses in a given direction with suppression of glitches and noise, especially for use as Read circuitry of a memory device by connecting an input signal source to the Primary winding of a transformer is located above its center tap of a Sampling pulse generator controlled secondary winding of two oppositely connected in series Diodes is bridged, the connection point of which serves as an output.

Known circuit arrangements of this type have essential Disadvantages than once apart from the diodes which only act as a rectifier Ordered amplifier must be provided to receive signals of sufficient amplitude To be able to provide, and on the other hand glitches from the storage device cannot be transmitted even outside the sampling time intervals, but on Interference directly affecting the amplifier input cannot easily be switched off are. Quite apart from that, there is no discrimination during a sampling time interval made according to signal pulse amplitudes, so that then during such an interval interference signals can also be transmitted to the amplifier input.

On the other hand, it has been proposed to use a reading circuit of tunnel diodes in which a first clock pulse generator is connected to the primary winding of a transformer is connected, the secondary center tap of which is connected to the control voltage source. The control voltage source is on the other hand to the Connection point connected in series connected tunnel diodes, whose unequivocal Electrodes are interconnected and those at the ends of the secondary winding lie. The connection point of the two tunnel diodes is also via an inductance applied to a fixed potential. So now according to the applied control signals Output signals with a longer pulse duration are generated, this becomes inductance a second clock pulse train with compared to the first half repetition frequency also via tunnel diodes whose electrodes of different names are connected to one another.

This circuit is very complex and requires that the frequency relationship is kept fairly exactly between the two clock pulse trains.

The object of the invention is to provide a pulse shaper circuit to provide, with the least possible effort, the generated by a generator, distorted impulses with interference impulses of any sign direction converts into one-sided pulses of a given sign direction and thereby interference pulses and largely eliminates noise.

However, known circuits that do justice to this task are very expensive, as they do this, for. B. differential amplifiers, rectifier stages and need further amplifier stages.

The pulse shaper circuit according to the invention solves the problem with relatively little effort by the sampling pulse generator on the one hand is in a known manner on the center tap of the secondary winding, but on the other hand via a resistor acting as an output load to the connection point of the two connected diodes represented by tunnel diodes, the resistance is dimensioned so that in the unloaded state of the pulse shaping circuit the characteristic of both tunnel diodes through the resistance line determined by the resistor into three Points is cut.

Advantageously, according to a further concept of the invention, a Control circuit for timing both the sampling voltage generator and also provided by the generator for the pulses to be processed.

The pulse shaper circuit has a locking effect because the Output pulse persists regardless of the duration of the input pulse the scanning voltage is supplied.

Further advantages of the invention emerge from the following Description based on an exemplary embodiment with the aid of the drawings Invention explained in more detail, and from the claims. It shows F i g. 1 is a block diagram the pulse shaper circuit according to the invention and FIG. 2 is a graphical representation the tunnel diode characteristic with resistance lines to explain the mode of operation the pulse shaper circuit according to the invention.

The circuit according to the invention consists of a pair of tunnel diodes 10, 12 which are connected in parallel between a common terminal 14 and the terminals 16 and 18 of the secondary winding 20 of a transformer 22. The transformer winding 20 has a center tap 24 which connects the two parallel circuits is assigned by the diodes 10 and 12 together. The blanking voltage is fed from a blanking voltage generator 28 via a load resistor 26 to the common terminal 14. The return line from the common center tap 24 of the secondary winding 20 to the blanking voltage generator 28 takes place via earth.

The signal is fed to the circuit via the primary winding 40 of the transformer 22 connected to the terminals 42 and 44 of the signal source, e.g. B. the Output read line of a memory matrix 46 is connected. The memory 46 may be of known design and contain switching units that are capable of the memory elements for generating a signal at terminals 42 and 44, respectively query the stored values. Especially in the cases of known memory, which are queried by coincident currents, may the polarity of the signal which represents a logical one, has no meaning, and a logical zero may through Absence of a signal can be shown.

The arrangement according to the invention senses that on the terminals 42 and 44 occurring voltages at certain times according to the operation of the Memory matrix 46 to provide a corresponding output voltage at the output terminal 50 to deliver. Accordingly, switching means are provided to control the operation of the blanking voltage generator 28 in cooperation with the sensing circuits of the Memory 46 to control. The cooperation of the blanking voltage generator with the Memory matrix 46 may, for example, by a central control circuit 52 of the Storage system are monitored.

The arrows 60, 62 indicate the directions of the blanking currents which, in the absence of a sensing signal in the primary winding 40, flow in the same strength from the common terminal 14 through the diodes 10 and 12 and the associated halves of the secondary winding 20 to the common earth terminal 24. The size of these currents is determined by the voltage of the blanking pulse, which is supplied by the terminal 54 of the blanking voltage generator 28, the value of the load resistor 26 and the voltage drop across the diodes 10 and 12. Since these currents 60 and 62 in the opposite direction through the Secondary winding 20 flow from the terminals 16 or 18 to the center tap 24, no magnetic flux is created in the core of the transformer.

When a current flows in the direction of arrow 64 through the primary winding of the transformer, a voltage is generated in the secondary winding of the transformer, which flows from secondary winding 20 in the direction of arrow 66 via terminal 16, tunnel diode 10, terminal 14, the Tunnel diode 12 and terminal 18 to secondary winding 20 flows back. If this current flows in the direction of arrow 66, it must flow through one tunnel diode 10 in the reverse direction and through the other tunnel diode 12 in the forward direction. If the current flows in the primary winding 40 in the opposite direction, the current in the secondary winding will also flow in the opposite direction, ie in the forward direction through the diode 10 and in the reverse direction through the diode 12. As later in connection with FIG. 2, the parameters of the circuit are dimensioned so that the blanking currents 60, 62 and the current 66 of the sensing pulse operate the tunnel diodes 10 and 12 in their essentially linear regions with low impedance, so that no mutual interference of the two diodes occurs and that thus the potential at terminal 14 remains practically at ground potential. Accordingly, there is no output signal at output terminal 50.

However, if a blanking signal on terminal 54 occurs during the occurrence of sensing signals appears on the primary winding 40, the operating point is the brought a tunnel diode into the range of their negative resistance, and the resulting shift of the blanking current to the other tunnel diode drives these also in their negative resistance range, so that both tunnel diodes adopt a new, stable operating point very quickly, with a fixed voltage drop at the diode, which appears as the output voltage at terminal 50. The direction the countdown voltage in the primary winding 40 only determines the direction of the Current 66 in the secondary winding and thus only determines which of the switch both diodes 10 and 12 first. The sense current has none in its size Influence on the output signal at terminal 50.

The operation of the circuit is shown in FIG. 2, in which the curve 70 represents the current-voltage characteristic of the diodes 10 and 12. If there is neither a sense input on primary 40 nor a blanking signal on terminal 54, the diodes are not conducting current and are at their stable point A on the curve. When a current 64 occurs in the primary winding 40, the resulting current 66 in the secondary winding flows in the forward direction through the tunnel diode 12, shifting its operating point to point B on the curve 70, and in the reverse direction through the diode 10, as through the Arrow 66 'is indicated in order to move its operating point to point C on curve 70.

If a blanking pulse occurs alone, the associated currents 60 and 62 flow in the forward direction through the associated tunnel diodes 10 and 12 in order to shift their operating points to point D, the first intersection of curve 70 with resistance straight line 72, the position of which is determined by the applied voltage at terminal 54 and by the ohmic resistance of resistor 26.

It can be seen that because of the extensive linearity of section B to C of the characteristic curve, which is traversed by the operating point as a result of a sensing signal, and on the other hand because of the symmetrical arrangement of the circuit, there is practically no output signal at terminal 50 due to the sensing signal at terminals 42 and 44 is produced. On the other hand, the voltage at the output terminal 50 achieved by the shift of the operating point from A to D as a result of a blanking pulse alone is negligible.

However, if the two input pulses occur simultaneously, the working shifts from A to B to D are superimposed, whereby the maximum value E of the characteristic curve of the diodes (diode 12) for the assumed current direction is exceeded, so that the diode is in the negative range of its characteristic curve 74 transforms.

For this reason, the diode 12 can no longer take over its share of the blanking current, and a part of this current is conducted via the other diode 10 . This diode 10, which would otherwise have the operating point F, corresponding to the blanking current component A to D minus the sensing current component A to C, is now itself forced to rise above the maximum value E due to the additional blanking current. Since the switching behavior of the tunnel diodes is very fast, the working point of the diodes reaches the point of intersection G of the characteristic curve with the straight line resistance 72 on the positive rising branch 76 of the characteristic curve. The resistance characteristic can assume the position of line 78, depending on the properties of the output circuit connected to output terminal 50, so that the operating point comes to be at H. The resistance line 78 illustrates z. B. the effect of the base current of a connected to the output terminal 50 . Transistor.

When the sense current 64 stops flowing, the operating points remain of the two diodes still at point H, so that the output voltage at the output terminal is available as long as the blanking current remains. In this regard the circuit has a locking effect. As soon as the blanking current stops flow, the working points of the tunnel diodes return to point A.

In the switching operations described, a number of factors interact in a somewhat complicated form. If the balance of the currents through the two diodes is disturbed, not only by the sense current, but also by blocking one diode so that the other takes over the current, the potential at the output terminal 14 rises steeply. When the first diode switches and the circulating current 66 begins to block, the potential at the terminals 42 and 44 also tends to increase in accordance with the resistance characteristics of the signal source in the memory matrix 46. The inductance of the primary winding 20 tends to maintain the flow of current through the first diode when it wants to switch, and in this way produces a higher voltage drop across the diode. By influencing the switching of the first diode, the inductance supports the switching of the second diode. It appears that the transformer 22 not only acts as a DC blocking and impedance matching switching means, but it also speeds up the operation of the circuit. The circuit according to the invention is largely adaptable to the various working conditions and the particular components selected. Some information and measurement results follow for a practical example: Voltage at terminals 42, 44 ............. Logical »1« ± 12 mV (if there is no blanking pulse) ................. Logical »0« ± 3 mV Secondary winding: current 66 .................. Logical »1« 200 RA (if there is no blanking pulse) ................. Logical »0« 50 RA Impedance of the sense line of the memory matrix 46 6 ohms Resistance of the current loop 66 with a diode close to the maximum value E ...................... 150 ohms Blanking voltage at terminals 54 .......... 4.7 volts Blanking voltage rise time .................. 50 nsec Resistance 26 .................. ............. 6100 ohms Intersection of the resistance line with the Ordinate (I) ................................. 380 p, A Diodes ...................................... 1N 2928A or HT90A Maximum value of the diode characteristic ............ 470 #tA, about 67 mV Transformer 22 Primary winding .......................... 10 turns Secondary winding ........................ 50 turns, about 25 @M The circuit made possible a perfect distinction between the useful signal and the noise. The blanking signals are expediently selected in such a way that they fall within the relatively noise-free times of the sensing signal. Strong noise signals can actually cause the diodes to switch, but without the blanking pulse there is no locking effect, and for this reason the operating point in each case very quickly returns to its operating point A on the diode characteristic curve 70. Such instantaneous unlocked switching processes only last such a short time that the output circuit at the output terminal 50 can easily be made insensitive to them. These glitches are z. B. very short compared to the rise time of a transistor in the output circuit. In addition, such interference pulses, which originate from noise signals without a blanking signal, are of so little energy that they cannot drive the operating point of the tunnel diode very far on the rising branch 76 of the characteristic curve.

It may be useful to tap output voltages decrease in load resistor 26, especially when the output voltage is the base of a Transistor is to be fed in emitter configuration. In such a circuit delivers z. B. the output voltage taken from the tap of the load resistor Bias to the base of a transistor before the tunnel diode switches, and thus causes a certain preparation of the transistor for a quick response on the pulses supplied by the circuit. Another benefit arises nor from the fact that the load resistor 26 is then used as a voltage divider with regard to the noise signal acts when the output terminal 54 of the blanking voltage generator 28 is at ground potential.

Claims (3)

Claims: 1. Pulse shaping circuit for converting one-sided Pulses in any direction in one-sided pulses in a given direction with suppression of glitches and noise, especially for use as a read circuit of a Storage device by connecting an input signal source to the primary winding of a Transformer is, whose over their center tap of a sampling pulse generator controlled secondary winding of two diodes connected in series in opposite directions is bridged, the connection point of which serves as an output, characterized in that that the sampling pulse generator (28) on the one hand in a manner known per se at the center tap (24) of the secondary winding (20) lies, however, on the other hand, via an output load acting resistance (26) with the connection point of the two by tunnel diodes (10, 12) shown is connected, the resistor (26) being dimensioned is that in the unloaded state of the pulse shaper circuit the characteristics of both Tunnel diodes (10, 12) through the resistance line established by the resistor (26) (72) is cut in three points. 2. Circuit according to claim 1, characterized in that that the resistor (26) is a tap for taking the output voltage with respect to on the center tap (24) of the secondary winding (20). 3rd circuit after Claim 1 or 2, characterized in that a control circuit (52) both with the control input of the signal pulse source (46) as well as with the control input of the sampling pulse generator (28) is connected to a simultaneous triggering of the Bring about signals and the sampling pulses. In. Older patents considered: German patent number 1202 321.