DE1144331B - Bootstrap circuit - Google Patents

Description

GERMAN

PATENT OFFICE

T17723 Vraa / 21a ¹

REGISTRATION DATE: JANUARY 14, 1960

NOTICE THE REGISTRATION ANDOUTPUTE EDITORIAL: 28. F E B R U A R 1963

The invention relates to generators which supply voltage curves with a linearized rise. There are already Bootstrap circuits consisting of a capacitor connected by a parallel The switch is discharged and then charged again from a voltage source via a series-connected charging resistor, and one as an emitter amplifier switched transistor, its base with the capacitor and its emitter via a feedback line is connected to the end of the charging resistor remote from the capacitor. It is well known that with such a bootstrap circuit, which should deliver a linear sawtooth voltage when charging the capacitor at the in The charging capacitor lying in series with the capacitor has a constant voltage. An acquaintance Measure to achieve a constant charging current is to use a capacitor, which lies in the feedback line leading from the output electrode of the emitter amplifier (or Cathode amplifier) leads to the upper end of the charging resistor. A substantially linear sawtooth voltage can only be achieved with such an arrangement if, when charging the The capacitor arranged in parallel with the switch does not change the voltage across the capacitor arranged in the feedback line, d. H., when the capacity of the latter capacitor is much larger than the capacity of the one to be charged Capacitor. In these known circuits it is therefore a capacitor with a very high capacitance and therefore required with large dimensions. However, as the voltage of each capacitor passes through Charge loss decreases over time, the voltage on the charging capacitor also changes, which in turn affects the linearity of the sawtooth voltage. The present invention lies now the task of improving a bootstrap circuit of the type mentioned above so that it can with Safety delivers an absolutely linear sawtooth voltage and is of simple construction, in particular to achieve a constant charging current no capacitors of high capacity and requires large dimensions.

In order to achieve this, the invention is used in a bootstrap circuit of the type mentioned above the arrangement is made so that to keep constant when charging the capacitor through the charging resistor flowing current, a Zener diode is built into the feedback line.

Using zener diodes is like using of capacitors for span bootstrap purposes

Applicant:

Thompson Ramo Wooldridge Inc.,
Los Angeles, Calif. (V. St. A.)

Representative: Dipl.-Ing. M.Licht,

Munich 2, Sendunger Str. 55,

and Dr. R. Schmidt, Oppenau (Renchtal),

Patent attorneys

Jack Caylor Smeltzer, Woodland Hills, CaHf.

(V. St. A.),
has been named as the inventor

stabilization has been known for a long time. It has also been known for a long time to connect a Zener diode as a coupling element between two amplifier elements. In the present case, the novel use of a Zener diode leads to the above Way to an unexpected technical advance and simplification.

There follows a description of the invention with reference to the drawings listed below.

Fig. 1 is a circuit diagram of a prior art populated with transistors Sawtooth vibration generator, the

is shown to aid in understanding the invention;

Fig. 2 is a circuit diagram of a likewise known waveform generator equipped with transistors, shown to aid understanding of the invention;

Fig. 3 is a circuit diagram of a pattern of the present invention.

Fig. 1 is a circuit diagram of a known sawtooth wave generator. It contains a transistor 10 with the elements base 12, emitter 14 and collector 16. Between the collector 16 and the Emitter 14, a capacitor 18 is switched on. A charging branch for the capacitor 18 contains one Resistor 20, which connects capacitor 18 to a voltage source 22. The emitter 14 is grounded. A diode 24 connects the capacitor 18

309 537/342

with a limiting voltage source 26. The FIG. 3 is a circuit diagram of a course of the invention can be taken from a terminal 28, pattern, the linear sawtooth waveforms which at the junction between the consump- tion using transistors, however, avoided 20 and capacitor 18 is connected. Um dung supplies high voltages. The transistor 10 Deriving a sawtooth input voltage 32 will lead to the same discharge function for the condenser Pulses 30 of the type shown are transmitted to the input gate 18, as is the case in connection with FIG clamp 11 was applied, which was connected to the base 12 of the transfer mechanism. A voltage source 60 is across sistor 10 is connected. Each pulse makes it the one resistor 62 on the charging resistor 20 on capacitor 18 possible to get between collector and closed. A second transistor 64 with a base Discharge emitter. Thereafter, upon termination of the im- io 66, a collector 68 and an emitter 70 will be Pulses reaches charging potential "is used by the resistor. A load resistor 72 is between-20 in the capacitor 18. see a source 74 of negative voltage and the

After transistor 10 blocks, emitter 70 charges. A source 76 of the clamping voltage The capacitor in the sense of the value of the voltage is connected to the collector 68. A source of return 22 on until it reaches the value of the limiting voltage 15 coupling path is provided for the resistor 20, voltage source 26 reached. In order to increase the span this way contains a diode 78 with the character which is equal to the required sawtooth rise, ristics that the voltage drop across it is essentially linear To shape, the value of the voltage must borrow despite changes in the through current source 22 is much greater than the value of the limit remains the same. The diode 78 is known per se voltage source 26 or made large enough 20 zener diode. It has the required characteristics be that the capacitor is linear during the within a particular voltage range, the Charges period of time in which the diode 24 does not conduct. can be taken from their characteristic curve. Often times it is inconvenient, if not impossible, to have a narrow pulse 30 on the during operation

High-voltage charging potential with transistors to base 12 of transistor 10 are applied. To use together with it. As a result, one demands that the 25 becomes the transistor 10 conductive, thereby achieving the con-linearity in other ways. The capacitor 18 is discharged. At the end of the bootstrap loop pulse, a well-known means of creating a high resistance parallel to transistor 10 is linearity without high voltages. He to the capacitor 18, and this is then charged using a discharge tube and a cathode, ",.,. , “ _{Λ £ ΤΛ TJi} · ^. E. ■ amplifier to recover the charge energy. 30 ^{the forest level 20 on} · ^The charging current is - £ where

2 is a circuit diagram and shows a tran- E _x the Zener voltage of the Zener diode 78 and R _x the sistor bootstrap circuit based on a value of the charging resistor 20. The output chip tubes are equipped with a circle to generate sawing £? ₀ , the tooth waveforms from the emitter of transistor 64. The tube circuit is well received, follows very precisely the voltage on the know and in the book "Schwingungsformen" of 35 capacitor 18 because of the emitter amplifier scarf chance and others, published by the tang. However, the characteristics of the Zener diode McGraw-Hill Book Company, 1949, on pp. 269-78 leave its voltage drop unchanged, while Figures 16 and 270 are shown and described. The transistor circuit voltage on capacitor 18 changes. Also contains a discharge circuit for the capacitor 18, the voltage at the charging resistor 20 is kept unchanged as before a transistor 10 with the base 12, 40, since the base-emitter voltage of the trandem collector 16 and the emitter 14 includes transistor 64 very low and its change serves insignificant and the same functions as it is in Fig. 1 tend in comparison with the value of the Zener voltage. shown and described. The charging resistor for the voltage source 60 and the resistor 62 20 is via a diode 41 with a voltage source, the values have been selected so that they are connected to -40. In addition to the charging branch from the span 45, the Zener diode 78 in the best part of its identification source 40, another branch is provided to make the line work. The voltage source 74 includes a transistor 42 with a collector 44, one biases the transistor 64 for the emitter amplifier base 46 and an emitter 48. The base 46 activity before.

of transistor 42 is connected to the junction of the transistor 64 performs a second function in

Resistor 20 and capacitor 18 connected to this circuit through which the function of the diode 24 the. Stress resistance 50 is similar to the emitter in FIG. 1. When the tension on the condensate Transistor 42 connected. The operating voltage source 18 overrides the value of the limiting voltage 76 52 is at the collector 44 of the transistor, the base-collector junction of the conducts 42. In addition, a source 52 of negative voltage transistor 64 is heavy and limits the voltage, connected to resistor 50. A condenser 55 on which the condenser 18 can be charged, Sator 54 lies between the emitter 48 and the value of the voltage source 76 can be established End of resistor 20 that will be connected to diode 41 to limit the maximum value that the connected is. Voltage across capacitor 18 can reach. Of the

The arrangement for the transistor 42 can be as shown in Fig. 3 as either a single circuit an emitter amplifier respond, the transistor 60 sawtooth voltage rise as an output in dependent counterpart of a cathode amplifier. The in speed to a single pulse input or one The circle shown in FIG. 2 does not operate to generate waveform 80 at emitter 70 as a function Sawtooth voltages of the pulses to be repeated with reference number 32 with the waveform shape Drew kind because the capacitor 54 discharges 30 supply.

and thereby prevents that a steady 65 Next is to be noted that, during the inventing voltage during the charging time of the capacitor as described in the descriptions above is maintained at resistor 20; here- became like them depending on an impulse the resulting sawtooth rise becomes non-linear. or operated by pulses to generate a

Bringing sawtooth tension, the usefulness of the invention is not limited to it. Where to wishes to receive the rise or the capacitor charge portion of the output oscillation immediately, without first having to go through the capacitor discharge part of the waveform, the transistor becomes 10 held conductive by applying a bias to the base 12. That leaves the capacitor 18 in its discharged state. Immediately after the bias is removed, the transistor reaches 10 has a high impedance value, and the capacitor 18 can be charged as required To deliver sawtooth voltage immediately. When the bias is reapplied, the capacitor then becomes 18 quickly discharged on his retirement. This mode of operation can be preferred if one desires to perform the usual type of cathode ray tube viewing process. In reality can remove the bias from the base of transistor 10 by a pulse with a suitable Polarity to overcome this bias can be accomplished.

From the above description it can be seen that with this invention a circuit arrangement is created with which a linear sawtooth voltage waveform using transistors and low voltages can be generated. There are because of the directly coupled Characteristic of the feedback path including the Zener diode no lower limit for the operating frequency. Sawtooth voltages can do with better Linearity can be generated because a constant voltage across the charging resistor in terms of the Operating characteristics of the Zener diode is continuously maintained. The voltage 60 provides the charging voltage, however, the linearity of the sawtooth voltage with regard to the regulating action of the Feedback path including the Zener diode essentially independent of the value of the voltage source Turned 60.

The fact that this invention using transistors of the NPN type with positive The voltage shown at the collectors should not be interpreted as a limitation, as the experts say quickly recognize that pnp types and other transistor types are applied with the correct polarity Voltages and the zener diode used can be applied without being deprived of the spirit and Deviate within the scope of the present invention.

Claims (3)

PATENT CLAIMS: 1. Bootstrap circuit, consisting of a ίο capacitor, which is discharged by a switch connected in parallel and then recharged from a voltage source via a charging resistor in series, and a transistor connected as an emitter amplifier, whose base is connected to the capacitor and its emitter a feedback line is connected to the end of the charging resistor remote from the capacitor, characterized in that a Zener diode (78) is connected to the feedback line to keep the current flowing through the charging resistor (20) during charging of the capacitor (18) constant. 2. A circuit according to claim 1, characterized in that for the purpose of biasing the Zener diode in the voltage stabilizing area of the emitter (70) as an emitter amplifier switched transistor (64) via a resistor (72) to a negative potential source (74) connected. 3. Circuit according to claim 1 or 2, characterized in that the collector (78) of the transistor (64) is on a limiting potential (76), which is via the base-collector connection of the transistor (64) when charging the capacitor (18) the linear voltage increase limited upwards. Considered publications:
"Electronic Engineering", February 1958, pp. 61 to 65; "Waveforms" by B. Chance, V. Hughes et al., McGraw-Hill Book Co., New York, 1949, p. 258 and 269. 1 sheet of drawings