DE1939014C3 - Pulse shaper - Google Patents

Description

35

The invention relates to a pulse shaper- +5 stage for deriving a narrow rectangular pulse with a large edge steepness from two successive ones Pulses or half-sine waves of different polarity, consisting of a four-pole network, which in two shunt branches two oppositely polarized, applied with reverse biasing in retirement Contains memory switching diodes.

Well-known Impolsformer stages of this kind (see. "Frequency" Vol. 20/1966, No. 2, pp. 52 and 53, in particular Fig. 7 and 8 and German patent specification 12 05 140) are constructed in such a way that both shunt branches are connected in parallel to one another, so that the cathode potential the one memory switching diode is identical to the anode potential of the other. It follows that both memory switching diodes cannot be in the conductive state at the same time. Caused in detail the first input-side pulse a through-control of the one storage switching diode in the forward direction, while the second input-side pulse reverses the polarity of the same in the reverse direction. Accordingly the accumulator charge recorded in the passage phase is then obtained after the so-called Storage time a blocking of the first memory switching diode. Only then can the tension build up of the second memory switching diode in accordance with the rising edge of the second input-side pulse increase to such an extent that it is driven into the pass band after the reverse bias voltage has been exceeded and the polarity is reversed again in the reverse direction when the pulse subsides. An analog locking process on the second memory switching diode is the result of these processes. From the locking processes of both Memory switching diodes are derived from the leading and trailing edges of the square-wave pulse on the output side.

If pulse shaping stages of this type are used to derive very narrow square-wave pulses, it turns out that the blocking processes that occur shortly after one another in this case, if they occur at the same time as the second pulse on the input side, have a very detrimental effect on the function of the circuit: namely, the after The pulse portion that occurs later is transferred to the output of the pulse shaper stage , whereby the steepness of the trailing edge of the emitted square pulse is significantly reduced. On the other hand, it is not possible with the known pulse shaper stages to delay both locking processes so far that they only occur after the second pulse on the input side has decayed, in which case one of the two storage switching diodes could no longer take up any storage charge and thus could not carry out a locking process. As a result, it is not possible with the known pulse shaping stages of this type to derive extremely narrow square-wave pulses with extremely large edge steepness.

The invention is based on the object of eliminating this disadvantage and adding a pulse shaper stage create that allows the derivation of extremely narrow output pulses of extremely large edge steepness. this is achieved according to the invention, starting from a pulse shaper stage of the type mentioned at the outset, that an ohmic series resistor is arranged between the two shunt branches and that the memory switching diodes are polarized so that the first pulse or the first sine half-wave the memory switching diode in the shunt arm located on the output side of the series resistor, the second pulse or the second half sine wave modulates the input-side memory switching diode in the forward direction.

The advantage achievable with the invention is in particular that the locking processes of both Memory switching diodes and thus the extremely steep edges of the derived output pulse are very dense can lie next to each other without a reduction in the steepness of the edge, in particular due to the trailing edge of the second feeding pulse occurs.

The invention is explained in more detail below with reference to a preferred exemplary embodiment shown in the drawing. It shows

Fig. 1 shows the basic circuit of a pulse shaper stage according to the invention and

FIG. 2 shows timing diagrams of the currents or currents occurring at various circuit points in FIG. Tensions.

In Fig. 1, a pulse generator 1, the internal resistance of which is denoted by 2, generates two successive ones Pulses or half-sine waves of different polarity that are sent to input 3, 4 of a four-pole network 3, 4, 5, 6 are performed. In two cross-branches there are two oppositely polarized storage

1*.

Schaitdioden Dl and Dl arranged, of which Dl is equivalent to carriers in Dl . This locking process

With a first reverse bias voltage Un and Dl, the voltage source 7 vom is switched off

a second reverse bias Um is applied. Quadrupole output 5, 6 and thus the termination of the

Un and Um are output-side square-wave pulses in the form of a

7 and 8 generated, the possibly high-frequency _s extremely steep trailing edge (compare i _L and

can be bridged. Between the cross branches ui).

an ohmic series resistor 9 is provided. By inserting the ohmic series resistance 9

Pulse voltage of 1 is denoted by u _g , which it is possible to Dl after the point in time / ₂ by means of i _m in

Four-pole input current with / ₉ , which control the pass band, while Dl

Currents flowing across branches with im and im and i _{0 are} already controlled in the reverse direction, but still

the current flowing through the series resistor 9 conducts, which is explained by the fact that at 9 such a

With /". The current i _L occurring at the output 5, 6 becomes Po «entialdifferenz drops so that the potential at the

a load resistor R _L supplied to which an anode of Dl under the influence of u _{g + is} sufficient

Voltage u _L drops. If necessary, a limiter is greatly increased. Subsequently, this results in the

diode 8 in series with the output 5, 6 of the four-pole network i ₅ possibility of the two blocking times ta and t _s2 very

provided at the factory. to be placed close to each other so that a starting point

The mode of operation of the basic circuit according to FIG. 1 impulse u _L or i _{L of} extremely small width is produced. As can be seen in greater detail from FIGS. 2f and 2g with the aid of the timing diagrams according to FIG. 2. 2a shows the voltage-time - the points in time ta and r, ₂ lie according to the diagram u _g (t) of a pulse end of u _g * that pulls the four-port input 3, 4. This ensures that led Impuises, Fig. 2b shows the temporal voltage the trailing edge of M ₉₊ the output-side right slope Wa (O at Vierpoleingang 3, 4, Fig. 2c the eckimpuls not distorted, and thus the slope of its temporal voltage curve ul at the load resistor The trailing edge is reduced, which would be the case if ta Rl, Fig. 2d, the temporal course of the ohmic and ui were before the end of u _g .. From this, the series resistance 9 flowing through current i _K , Fig. 2e 25 explains the property of Pulse shaping stage the four-pole output current i _L as a function of the time, according to the invention, output-side square-wave pulses, Fig. 2f the diode current i _m for Dl and Fig. 2g extremely steep edge and in particular the diode current ioi for Dl.
In the diagrams, the positive signs apply to the directional arrows shown in FIG. 30 height of u _g - causes an increase in the area Fl,

From Fig. 2c it can be seen that the voltage ul, which is proportional to the charge stored in Dl , which occurs at the four-pole output 5, 6 and thus at the shunt arm, resulting in a corresponding increase in FT and with the diode Dl , corresponding to the negative thus an increase of ta brings with it, which can only decrease in pulse Ug until the value Fig. 2f is indicated by an arrow. As a result of this, Uμ falls below this (at point in time Z ₁ ). From 35 measure, the output pulse becomes narrower. Umda on remains ul and the output current / *, is constantly reversed by increasing the pulse height (Fig. 2e), while at the same time id2 corresponding to that of u _g * an increase in the area Fl and thus a further decrease in u _g - the memory switching diode Dl of reached by Dl absorbed storage charge, modulates in the forward direction. Of Dl here is the magnification of Fl 'and a storage charge associations is received, the delay of the area Fl of 40 has / «2 a result which corresponds to a widening (Fig. 2f). Is meant ioz according to the white square pulse on the output side. This is the chronological sequence of u _g and M ₉ . in Sperrich- is indicated in Fig. 2g by an arrow. If the polarity is reversed, then the reduction of the storage of the mentioned pulse heights begins, causing a reloading of i'ii2, which ends at the point in time Ui. At this point in time, changes in width of the derived rectangle blocks Dl and thereby causes +5 pulses, contrary to the arrows in FIGS. 2f, a sudden increase in the output current i /, and 2g.

and the output voltage ul to positive values, the function of the circuit shown in Figure 2 with reference to the formation that is, an extremely steep leading edge of a trapezoidal pulse pair u _g - square pulse occurring at Rl, M explained _9+.. In Fig. 2f, of course, it does not depend on this, tsi as the delimitation of an area FT, the fl 5 »zial pulse shape, but is also equivalent in other cases, neglecting the recombination of La pulse shapes, especially with half-sine waves, in Dl . given speaking polarity. It is also possible

The second, positive pulse w ₉ »causes a loan, the memory switching diodes Dl and Dl, the reverse bias voltages Um and Ubz and Va up to a value that corresponds to Um (FIG. 2b). 55 reverse the polarity of the pulses u _g. D ^ with result Reaching this value at time t _{2 is} limited output pulses, the polarity of which is also limited by the further increase of // ", in and im. On the other hand, it is reversed, ie negative.

begins at this time the current in the (Fig. 2g) In Fig. I is further indicated how the Grunddie recovery diode Dl off in the forward direction can be circuit-extended heading to a change, wherein the further time course of the ^6o of the pulse heights of the driving pulses u _g - and the course of u _{g +} (Fig. 2a) corresponds. Thus W will reach ₉ ^+. This is expediently done by Dl a storage charge that corresponds to that of limiter diodes 10 and 11, which corresponds in the same direction in area Fl. Due to the lowering of the span series are connected to each other and their connection Ug + , Dl is reversed in polarity and blocks the connection point with one pole 3 of the four-pole network after the storage time has elapsed at time t _S 2- In ⁶ 5 3, 4, 5, 6 connected is. In the polarity shown in the diagram according to Fig. 2g, the storage time can be taken into account by supplying a negative limiter through the area Fl ', the Fl at voltage - Uugi to the anode of the diode 10 neglecting the recombination of charge limitation of M ₉ - reached the value of - Ußgi

be, by supplying a limiter voltage + Ußg2 to the cathode of U in an analogous manner a limitation of u _g +. The setting of - Ußg \ and + UBgz to different values then requires a corresponding variation in the ratio of the pulse to the pulse width of the square-wave pulses on the output side.

By inserting a limiter diode 8 ', the negative part of the quantities «χ, and il, which occurs in each case before / _s i, can be eliminated, so that xini

heights of u _g - and u _g + and thus a change in polar output pulses arise.

1 sheet of drawings

Claims (3)

Patent claims: 1. Impulsfonnerstufe for deriving a narrow rectangular mini-pulse of large edge steepness from two successive pulses or half-sine waves of different polarity, consisting of a four-pole network which contains two oppositely polarized memory switching diodes in two shunt branches, which are biased in the idle state, characterized in that a ohmic series resistor (9) is arranged and that the memory switching diodes (Dl, Dl) are polarized so that the first pulse (u _g -) or the first sine half-wave the memory switching diode (D2) in the output side of the Lärtgswiderstand (9) lying shunt arm, the second pulse (m _{? +} ) or the second half-sine wave the input-side storage switching diode (Z) I) modulates in the transmission direction. 2. Pulse former stage according to claim 1, characterized in that the four-pole network (3, 4, 5, 6) with blocking voltages of adjustable size applied limiter diodes (10, 11) are connected in parallel on the input side and that the ratio of the pulse heights (- Uegil + UBgi) of both pulses (Ug-, Ug *) or the maximum amplitudes of both sine half-waves can be set by means of the blocking voltages. 3. Pulse shaping stage according to claim 1 or 2, characterized by one in series with the four-pole output (5, 6) arranged limiter diode (8 ').