DE2020695A1 - Pulse generator - Google Patents

Description

N.V. Philips'Gloeilampenfabrieken, Eindhoven / Holland

Pulse generator

The invention relates to a pulse generator for ^ Generation of pulses with a desired shape, preferably for controlling magnetrons, which uses a pulse shaping network, a charging device for the network, which has a primary circuit connected to a supply source and a secondary circuit connected to the network, as well as a controllable switch that periodically connects the network and the load in series shorts. There must be a charge between every two discharges and if high pulse repetition rates are desired it is important that the element that made the discharge possible is completely blocked before it is recharged. Even a hydrogen thyratron may need 20 / ua to recover, ™ which can be annoying, and controllable silicon cells can even require 50 to 100 / us.

JSs is also desired that the charging be vibratory takes place because, as is well known, a discharge voltage is available that is almost twice the input voltage amounts to. Further means of increasing the discharge voltage without reducing the input voltage needs to be increased would often be welcome. It would also be advantageous if a circuit for

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Discharge voltage regulation could be added without the loss of energy that is associated with most DC stabilization circuits are affected (except when the input voltages drop to minimum values or the loads to maximum values It is desirable that when more than one element is switched, the switching is done simultaneously and on one low voltage level occurs.

The invention at least in large part fulfills the desires with regard to the mentioned recovery time of the SteuemLementes and the vibrational charging and that in itself well-known (passive) Pulse Shaper Network (FFN) that has a PFN capacitance contains, is charged via the secondary winding of a transformer from a first capacity. To this Purpose, a pulse generator of the type mentioned is characterized by that the primary circuit of the charging device contains a time-dependent control element which has a control input and is provided with an output connected to a switch in series with the supply source and the primary winding a transformer is inserted, and that the secondary circuit of the charger is the series connection of two in the same forward direction arranged diodes parallel to the controllable switch and the series connection of one Contains capacitor and the secondary winding of the transformer in parallel with one of the diodes.

The tension can easily be stabilized by using means with a large time constant which perceive whether the peak charge voltage of the PFN capacitance deviates from a reference voltage and any deviations as a result counteract that they regulate the duration of the charging times of the first capacity. A general upward or downward trend in the final pulse voltage is based on this Way almost balanced. Ss is beneficial to these loading times by means of the return to a stable state of a trigger pulse brought into the unstable state-

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ten monostable gate direction to regulate, the tent of this Return can easily be influenced by changing a preload.

An exemplary embodiment of the invention is shown in the drawing and is described in more detail below. Show ea *

Fig. 1 a ready proposed pulse circuit,

2 shows the circuit arrangement of the embodiment in question, and

Fig. 7-7 Pulse Time Diegremme in various

Points of the circuit arrangement according to Fig. 2 * ä

In Fig. 1, a DC voltage, which is fed to longitudinal terminals 1, charges an IBpuleformernetZWerk (PFN) via a diode 5 In a way that is due to the presence of a Series pink elapule 4 and a capacity in the PFN vibrationally runs. The PFH is initially achwingungsweiee on a Voltage charged, the faat daa double the input voltage at the terminals is 1, and then has the tendency to calibrate discharged, but this is prevented by diode 3.

At precisely determined times, the PFN is discharged via a load 5 from a switch 6 controlled by a trigger pulse, so that the desired pulse series i results. The load 5 acts as an adapted ohmic load for the discharge PFN 2 _t but as a negligible impedance in the PFN charging circuit.

The PFN capacitance can e.g. consist of several capacitors, the connection points between an equal number Connect small coils connected in series with a common line, so that T-members result, whereby each capacitor by a different number of coils

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being charged and discharged. Various such devices are known, all of which have a distributed capacity and include inductance or calibrated repeating patterns of capacitance and inductance.

The IC series connection in the PPH should generate a square pulse, i.e. a pulse raits vertical elanks when the PFN is over the (probably) ohraeche burden 5 »that of the present one Embodiment of the high-voltage circuit of a radio measuring transmission magnetron is (via a voltage increase pulse transformer, not shown), via the controlled switch 6, e.g. a thyratron or a thyristor (SCR) is discharged.

Such vertical edges could be achieved with a single capacitor which, when discharged, has an exponential voltage curve forms, cannot be won.

The exact type of PFN and the exact form of the pulses are irrelevant for an understanding of the invention; Suffice it to say that there must be a constant time interval between the pulses with such a short farmer that the recovery time from an "on ^w state to an" off state of known controllable switching devices, e.g. controllable silicon rectifiers, is included, however, a quantity which is difficult to predict when the circuit is designed.

The shortest recovery time is likely to occur with a hydrogen thyratrone on, but even this can be so long that the start of a new charging cycle via the diode 3 and the choke coil 4 must be delayed after the discharge via the load 5, otherwise the switch 6 would be the charging source short-circuits, causing damage to the switch and loss of energy can occur while the PFN remains discharged (the switch 6 can even be closed as a result of the short-circuit current stay). In any case, the use of tubes, because of their volume and their high supply voltage, leads to power loss etc., most "inconvenient, such that solid-state switches are almost always preferable, even when their recovery times

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- 5 are usually much longer *

Therefore, it is desirable to prevent a charging current the switch for a certain amount of time after each discharge pulse, which is regulated or set in advance reached from PFN 2 to load 5.

It would be advantageous if the delaying circuit element could itself also act as a charging coil, so that this need not be provided separately, while maintaining the voltage doubling properties of the circuit arrangement according to Fig. 1. It would be convenient if this circuit element had some adaptability or stretchability would allow in the choice of an input voltage. It would be " very useful when the delay in recharging the PFN harmless the stabilization of the voltage to which the PFN is charged in each case or on average over several cycles will, could include.

The circuit arrangement according to FIG. 2 satisfies the above requirements, contains further elements and operates as follows. The supply voltage at terminal 1 is supplied by a capacitor 7 is charged from an oil calibration voltage source 8 with the illustrated polarity at times that of a second controlled switch 9 via a transformer 10, whose polarity is reasonable by the points g give to be determined. The switch 9 (which can expediently be a power transistor because it must be able to switch the average high voltage power of the Magnettron and any losses, although not necessarily to consume) is controlled by a monostable device so that it after a certain time every time at which the monostable device is triggered via an input 12, is held in the ^{n in n} state. As can be seen from the following, the device 11 is triggered precisely at the times at which the switch 6 ^{w on w} is switched in order to discharge the PFN.

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den, creating an intricate staggered cyclic commissioning The two switches are avoided. Another very important advantage is that switching by the Element 9 in the primary circuit and thus at a low voltage takes place.

When the switch 9 is located in the ^w Bin "-Zustamd, the primary winding of the transformer 10 receives current from the DC voltage source S ₉ and the Seksndirwlcklung of the transformer provides the capacitor 7 is a non-oscillating charging current over a Biod © 13" when conducting, forms a short circuit and thus isolates all circuit elements lying to the right of this diode 13 in the drawing against this charging circuit In this way, while the capacitor 7 is charged more or less exponentially, the diode 3 is not polarized, with the anode of this diode on Uullpotential remains, and the hat holder 6 remains unpolarized and thus receives © i ^ ea l ^ holiingszeltraum, as explained in more detail with reference to FIG

After a certain time since ₉ the dettaeli is determined that the monostable device 11 returns to the stable state by itself, the switch 9 ^ off ^ -switched, and the voltage in the load circuit becomes Muli, so && Q the charging of the capacitor 7 at a Voltage of about M times the DC supply voltage ceases _¥ where If da is »step-up transformation ratio or one» and the diode 13, which is always blocked, prevents the capacitor 7 from back-discharging via the secondary winding of the transformer, and allows this capacitor 7 to reverse the diode 3 in the forward direction ^ polarized This leads DI® se & wingungsweise charging of P3? N from de »£ ond @ BgMtt @ r 7 on the load and the secondary winding of Xranefonmstors 1O ₉ now as a choke coil (see 4 in Fig. 1) with a lot of larger impedance than that of the load, a «The capacitor 7 works in this way as an old one of the Kingan feeders.

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source of Figure 1 equivalent intermediate voltage source. When the Irapulsformernetswerk 2 is charged and the capacitor 7 is partially discharged, the diode 3 is again blocked so that the now fully charged PFN waits for its discharge, which takes place at the next ^{n on n} switching of the controlled switch 6.

An important property of this embodiment of the circuit arrangement according to the invention is the following:

In the case of impulse gauges of this type (Fig. 1), an "inverted mode" with two electrodes and thus uncontrolled must usually be connected in parallel with switch 6 (as indicated by dashed lines in Fig. 1). The purpose of this "reverse stupid" is to remove any negative charge that may have been left over as a result of a lack of adaptation to the load (e.g. as a result of a spark or a short-circuit in the load) before charging starts again.

With the circuit according to the invention, one is unnecessary Such separate words were stupid, because the fields 3 and 15 in series perform this task if necessary.

Sine more important "property of the circuit arrangement according to the invention is" dal 9 and 6 gleicheei- the two switches are switched tig * "so that it is not necessary when using the same control pulse ansuwenden 1st, a relative Yereögerung.

The side · JLfelaaf the effect of the circuit arrangement is apparent from FIGS. 3 to 7, which are voltage-time diagrams with the same time scale, FIG. 3 showing regularly repeated very short control pulses which the input 12 of the mono-stable gate direction 11 and the control electrode dee switch 6 Stt and their frequencies the repetition frequency of the output pulses dee

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Magnetrons (or other load) intended. The switch 6 iet a controllable silicon rectifier and is in the kept conducting as long as the FPN is in pulse form mig discharges (actually a little longer, i.e. plus the "switch-off" time, the compensation of which is a purpose of the invention is) while the one-shot device 11 is driven in the unstable state for a period of time that is determined by a timing circuit forming part of the device 11 so that the one-shot device supplies a bias voltage at the output 14 during the same time, which turns the transistor switch 9 on. Of the Eollektorstrom this transistor is in Fig. 4 in the form of a more or less rectangular pulse with a positive Direction sense shown, which drops to zero when the monostable device again returns to the stable state.

When the transistor 9 ″ is switched on ¹¹ , its collector voltage, which is shown in FIG. 5, drops from the supply voltage to zero and remains zero, but a current with a shape corresponding to FIG. 4 (but in the opposite direction) flows due to the presence of the transformer 10 and capacitor 7, which polarizes the diode 13 in the forward direction so that the junction of its cathode and the anode of diode 3 is kept at zero, as shown in FIG. 6, which shows the voltage at this junction When the current through the primary winding is switched off by the switch 9 fc at the time indicated by the vertical dashed line b, the voltage on the collector of the transistor switch 9 increases (Fig. 5) due to the fact that the transformer is thereby in the opposite direction acts that the diode 3 is conductive and its anode (Fig. 6) accepts the rising voltage of the FFN accordingly, when this over the Secondary winding of the transformer from the now charged capacitor 7 is charged. .

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Pig. 5 follows FIG. 6, and in this way the latter voltage rises to nearly three times the voltage E ₀ to which the capacitor 7 has been charged, it being assumed that this capacitor has a much larger capacitance than the whole capacity available in the PFN.

As Fig. 6 shows, the voltage at the anode of the diode 3 drops to a value of once Έ shortly after this voltage has _{gone asymptotically towards 2E C} at the time £, because the diode 3 at the time at which the oscillation voltage is above the Network 2 begins to reverse, is blocked. As a result, the capacitor stops discharging and the anode of the diode 3 takes on the potential to which the "capacitor is still charged (as is assumed, about the voltage E _c> from which it started at time b).

A look at FIG. 7, which shows the charge potential of the PFN, ie the cathode voltage of the diode 3, shows that the oscillation peak voltage 2E from the point in time £ from the now non-conductive diode 3 to a later point in time <1 (which of course increases very quickly the time £ can follow because the time interval £ - d only serves to give the diode 3 the opportunity to block) is maintained, at which point in time the next control pulse ^ sum switching of the switch 6 (and the monostable device g 11) occurs . The switch 6 now enables the PFN to discharge via the load 5, and at the same time the switch 9 begins a new conduction period, as already described above, the capacitor 7 being charged and the diode 13 conducting while the diode 3 remains blocked.

In the drawing, the voltage-time diagrams repeat themselves after the point in time d, which is an oversimplification because the capacitor 7 is completely discharged, but the pattern repeats itself qualitatively and the PFN is ready to move

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of 2E_, i.e. about or on the order of 2N-times the supply voltage fed to the primary winding, each time the controllable Silieiuraglelehrichterschalter 6 becomes conductive.

This approximate 2N draw can be changed within wide limits ^{by a suitable choice of the w} A ^B ~ time of the holding transistor 9.

Another optional possibility is described below.

This is very desirable in every application in which absolutely uniform pulses must occur in the load, at least on average over a small number of pulses . The invention offers this opportunity to implement this feature without any special Difficult Celts, at least if the switching of the transistor 9 is a monostable circuit used WiEa ₈ because the duration of the unstable state when the device it has once assumed, is controllable by means of a voltage. The stabilization is obtained in a desired way with the lowest possible line losses, ie without additional voltage drop in transistors or resistors.

This results in a control voltage using a Time constant mean corresponding to the required correction speed by means of a peak voltage detector, the one in Pig. 2 is not shown in more detail, but which is connected to the anode of the diode 3, the peak voltage to the Time £ of Figure 6 supplies the control voltage.

The line 15 in Fig. 2 is essentially the course of the Control your voltage in the circuit arrangement to which an input 16 of the monostable device is used to determine the duration of the unstable state of each cycle is supplied on the basis of an average value over a shorter or longer period

/ * of the fully charged network, i.e. the tension

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Tent is taken

The arrangement is made in such a way that a decrease in the peak voltage leads to the switching transistor 9 "switched on · let) and thus also the charging time of the capacitor 7 is extended, with the original voltage drop is balanced and no energy is lost in the vicinity.

This system could be adapted to run on a "from the pulse-BU-pulse" basis stabilized, in which case more correlated circuitry is required.

The circuit arrangement shown above provides the Recovery for the controllable silicon rectifier wanrend the time interval _§- Jfc in which the diode 13 "switched on" and the diode 3 "switched off" so that the controllable silicon rectifier or the thyratron 6 no voltage can be supplied Choice or setting of the duration of the unstable state of the monostable device can be set beforehand. The circuit arrangement also includes a single element, i.e. the Transformer 10, ami supplying the inductance for the aweiaa charging and sum stepping up (or stepping down) the input voltage according to the required PFH voltage (which is twice the voltage across the load in the case of a pairing, using a voltage boosting pulse transformer from the tiblloherweiee is taken into account will. A low input voltage, e.g. a battery, can be the original source. This also enables a loss-free impulse discharge stabilization.

Fig. 8 Adds a practical embodiment, in which the corresponding cases old then glaiohen reference numbers and / or letters as in Fig. 2 are included. The right transistor 16 the monostable gate direction 11 is only conductive if the Input a trigger pulse is executed and remains during

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a time conducting which is the recovery time for the switch 6 is determined and shown in Fig. 4, because the output 14 is the same troansäßig over © ine buffer stage with the control switch 9 is coupled, the "switched on" period of transistors 16 and 9 is determined by a fixed RO time circuit 17

which connects the transistor 16 to the base of the conductive transistor 18 in the stable state of the monostable device, with the changes required by the use of a biasing circuit with a differential amplifier 19, which amplifier the peak voltage, which is transmitted via the line 15 from the The anode of the diode 3 (Fig. 6) is removed, äcfa. the peak PFN voltage, with a reference voltage supplied by a zener diode 20. The output voltage of the differential amplifier 19 bridges the resistance part of the RC circuit 17 with a value which depends on the difference β between the two input voltages supplied to the amplifier. If necessary, the pulse peaks can be regulated by means of an adjustable voltage divider 21, 22, 23, the one input voltage for the differential amplifier being set beforehand in accordance with the voltage taken from the diode 3. In this way, the RC circuit 17 and the two input voltages for the amplifier 19 determine the "switched on" period of the switch 9, the direction of the action of the amplifier 19 being such that it counteracts any change in the peak voltage of the FFN.

The unstable "on" state of transistor 16 is also an emitter amplifier stage via a second output line 24 25 supplied, which the square pulses'des Transistor 16 differentiates and simultaneously with the switching on of the switch 9 of the control electrode of the controllable Silicon rectifier 6 has a positive very sharp pulse (Flg. 3) KUfuhrt. The conductive state of the switch 6 ends about 50 to 100 as after the end of the impulse discharge of the network 2, as described above, (but the switching off can sometimes be facilitated by the fact that a small

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Reversal of the ΡίΊΤ voltage is generated in that the resistance value of the load 5 is slightly smaller than the characteristic Impedance of the PM is made, but this is not a property unique to the embodiments of the invention).

In this way, both switches are opposite to the monostable Device buffered so that they do not affect its response and they are put into operation simultaneously, with the switch 9 at a voltage of 30 volts or less switches.

Therefore, a source of a direct voltage of 30 volts ^ is used to generate a pulse of 3A and 3 »7 kV with a duration of 0.5 us and a repetition frequency of 1000 via a voltage booster transformer 10 with a transformation ratio of 1:20 and a load transformer (not shown) Hz to deliver. If the input supply voltage decreases, more current is consumed as a result of the longer "switched-on" ¹¹ times of the switch 9 and thus the longer charging times of the capacitor 7, and vice versa, so that the input power is more or less constant.

The magnetron works in pulsed mode with 3A and a voltage of 3f7 kV and thus absorbs an average power of 5 »5 watts (peak power 11 kW) from the charging circuits, which values must therefore be taken into account in the design Volts store using a step-up pulse transformer, and its switch-on impedance is matched to the (transformed) magnetron load. A voltage of about 500 volts is thus generated across the primary winding of the pulse transformer. The peak voltage across capacitor 7 is slightly more than 500 volts and the capacitance is about 0.5 μί ^1. The inductance of the PPN is of the order of magnitude of 2.5 mH and the capacitance is about 25 nlV These values of the Pi ¹ N result in a pulse width of about 0.5 μβ the inductance of the secondary winding of the transformer 10 is about 1 H, while

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rend the stress increase ratio is 20. The meal The tension is between 20 and 50 ToIt, and at the same time the transistor 9 must switch about 10 watts, with a power loss of about 1 watt. The © e® Werf © correspond to those for ship emergency radio measuring systems old low power, however, they do not need to be considered a limitation, of course of the invention are considered

In some cases, the delay siatlicher known controlled scarf ^ is devices in order to © INEM Seitraum of the effectiveness in the Leerlaiafauatand & w advised very annoying and Schaltungeamordnungen after Irflatong solve the problems of using ron Siliciungleioiisiclitern etc. in the pulse generation largely "It canoe & .B "the value of a PsrailelkoE & ensatoM 25 © possessed different or omitted \ ann this capacitor, Je" na 2fed®ii instantly © or long-term effective mittler® itaTOkturen the pulse voltage for the loop, with the? The control level and the impulse level must be set beforehand _{9 are} required.

Claimsι

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Claims (5)

Patent claims 8 1. ) Pulse generator * to generate pulses with a desired shape, preferably to control magnetrons, a pulse format, a charging device for the network, the iron primary circuit connected to a supply source and a secondary circuit connected to the network, as well as a controllable switch * contains the period! Boh kurBschließt the series circuit of the network and the load, characterized g ekennz eichnet that the Frlmärkrei "contains the charging device a time-dependent control member (11) having a control input (12) and old sine" provided Auegang (14) which is connected to a switch (9) which is connected in series | ■ it the supply source (8) and the primary winding of a Tr art ef ensat or β (10) is inserted, and that the secondary circuit of the charging device is the series connection of two diodes (3,13) arranged in the same forward direction in parallel with the switch (6) and the series connection contains a Xosdensatoge (1) midfier secondary winding of the transformer »parallel to one of the stupid ones. . 2.) Impulsgenerntor according to aaepnscäbi i ₉ thereby that the time-dependent control element (11) contains a mono-stable Srlggerschaltung which has a control input to bring it into the unstable state eu, in which state the switch (9) la primary circuit current through | leaves. 3.) Pulse generator according to claim 1 or 2, characterized in beichnet, daS the Steuerelngasig the side-dependent control member (11) and the controllable switch (6) coupled in this way are that a signal signal introduced from the outside the switch (9) Ib Prlairkrels and the controllable Switch (6) on the contact side in the conductive state brings. - 16 - 1 09809 / 17S5 4.) Pulse generator according to one of claims 1-3 »thereby marked that the time-determining means in the tax ΐ organ can be adjusted by a control voltage that can be set by derived from the charging voltage of the pulse generator network to stabilize the charging voltage ' • .- - ί 5.) Pulse generator according to claim 4 in conjunction with claim f 2, characterized in that a differential amplifier (19) J is provided, one input voltage of which is a fixed one. t reference voltage (20) 1st, and the other input voltage of which is the voltage of a peak detector 1st, which is connected to the _: j output side of the capacitor (7) in the secondary circuit via j a voltage divider (23, 22, 21) which can be divided into one or more units. ί.ί is coupled, the differential amplifier (19) providing a controllable bridging over an ohmic element of the timing circuit which controls a cross-coupling branch of the monostable trigger circuit. ίθ 91 Oi / 17 5 5 ORiGINALJNSPECTED Blank page