DE1043542B - Generator for the generation of a saw tooth voltage, which is created by charging and discharging a capacitor - Google Patents

Description

GERMAN

The invention relates to a generator for generating a sawtooth voltage, which by the Charge and discharge of a capacitor arise, whereby the voltage of the capacitor on the Acts control electrode of a directional conductor.

Arrangements of this type are known as "Miller integrators". They serve that To linearize the leading edge of a sawtooth voltage. This linearization is desirable if the Edge of a sawtooth pulse for purposes of modulation technology scanned by periodic pulses will.

Well-known Miller integrators consist of an electron tube and a capacitor between the anode and the control grid of the tube. This known arrangement also includes a Electronic switch, the switching and blocking status of which is controlled by a square-wave pulse. In the conductive state of this switch, the grid of the electron tube has a negative constant control potential, whereby the anode current is low. During this period the one between the anode and the grid has Capacitor the highest value of its charging characteristics. When the square pulse occurs the switch reaches its blocking state and the negative control potential of the grid is switched off. After this point in time, the capacitor begins to discharge through the resistors of a Discharge circuit. The falling voltage characteristic on the capacitor controls the tube in the sense an increasing anode current. This causes a voltage drop in the anode resistance of the tube circuit, whereby the anode voltage also decreases. The voltage of the connected to the anode Therefore, the capacitor changes during the discharge process by the influence of the electron tube. This process linearizes the exponential characteristic of the capacitor. at Interruption of the square pulse, the negative control voltage of the tube is switched on again, whereby the original constant voltage is reapplied to the capacitor. This is where the Charging of the capacitor, the charging voltage of which is not influenced by the tube and therefore an exponential characteristic having.

In such a device it is also known to automatically determine the duration of the leading edge of the saw tooth to control. This control is carried out by an adjustable signal, which comes from the discharge voltage of the capacitor is derived.

The known arrangements have the disadvantage that the trailing edge of a sawtooth pulse has no effect can be. A linearization and ver. There is therefore no change in the duration of this period Generator for generating a

Sawtooth voltage, which by

the charge and the discharge

a capacitor arises

Applicant:

Electric & Musical Industries Limited,
Hayes, Middlesex (Great Britain)

Representative: Dr.-Ing. B. Johannesson, patent attorney,
Hanover, Göttinger Chaussee 76

Claimed priority:
Great Britain February 3, 1955 and January 26, 1956

Hugh Lyon. Mansford,

Uxbridge, Middlesex (Great Britain),

has been named as the inventor

possible. For the oscillographic recording of curves, the pulse trailing edge is influenced however, this is desirable for the purpose of linearization and changing the period duration.

These disadvantages are avoided in that, according to the invention, the trailing edge of the sawtooth voltage in a discharge circuit is linearized by a directional conductor and a resistor, which the potential the emission electrode of the directional conductor controls.

An exemplary embodiment of a sawtooth generator according to the invention will be described below with reference to the drawing.

In the drawing, 1 denotes a capacitor, on which during operation of the arrangement the desired sawtooth is generated. The output voltage is provided by the output terminals 2 and 3 removed. The arrangement consists of three tubes 4, 5 and 6, which, although shown as triodes, can also be pentodes. The tube 4 acts alternately as the tube of a Miller integrator and as a discharge tube for the capacitor 1, while the tubes 5 and 6 are part of the switching arrangement form which controls the capacitor for its alternating operation. The tubes 5 and 6 are about the Resistors 7, 8, 9 and: 10 connected to one another in such a way that that a conventional, bistable DC-coupled breakover circuit is formed wuxLJDer resistor 7

; £ 8 S 678/323

connected to the positive terminal + HT of the anode voltage source. The anode of the tube 5 is connected to the anode of the tube 4 via a resistor 11 and a rectifier 12, which can be, for example, a crystal diode. The capacitor 1 connects the anode to the control electrode of the tube 4. The control electrode is also connected via the resistor 13 to the negative terminal - HT of the anode voltage source and to the negative grid bias voltage source 14 of e.g. B. -10 V via a rectifier 15, which can also be a crystal diode, connected. The cathode of the tube 4 is connected to the negative .HT terminal via the resistor 16 and to ground via the rectifier 17, e.g. B. a crystal diode connected. The control electrode of the tube 5 is connected to the junction of the resistors 18 and 19 which connect the anode of the tube 4 to the negative HT terminal. In practice, a cathode amplifier can also be switched on in order to separate the load resistance of the resistors 18 and 19 from the capacitor 1. In addition, other cathode amplifiers can also be provided in the circuit.

The arrangement shown is a self-excited and the two phases of each cycle in which the The leading and trailing edges of a sawtooth are generated by the two operating states of the bistable circuit controlled. In the first phase, the tube 5 is blocked; its anode potential has its greatest positive value. The tube 6 carries current and holds the common cathode potential of the tubes 5 and 6 is higher than that of the control grid of the tube 6. The capacitor 1 is overcharging the resistor 11, the diode 12 and the resistor 13 on. The current in the resistor 11 is around the Amount of current that flows through the tube 4, greater than that in the resistor 13. The tube 4, the Capacitor 1 and the associated switching elements work as a self-regulating Miller circuit. The current in the tube 4 changes, in such a way that the charging current for the capacitor 1 remains constant. During this phase, the potential at the control electrode of the tube 4 remains the bias potential 14, so that the diode 15 blocks. In addition, the current in the tube 4 is sufficient to keep the diode 17 conductive, which represents a small impedance between cathode and ground. Of the Potential rise at output terminal 2 corresponding to the charging of capacitor 1 has to The result is that the potential at the control electrode of the tube 5 rises until this tube carries current.

When the tube 5 conducts current, its anode potential drops, and so does the tube 6 and the diode 12 no currents flow. The potential at the control electrode of the tube 4 then falls until the diode 15 Current leads. This potential drop at the control electrode of FIG. 4 is due to an equal change accompanied by 2, creating a step in the shape of a sawtooth. Then the resistor 13 is only A current is supplied through the diode 15, and the control electrode of the tube 4 is at a fixed potential held. This potential has such a reduction of the cathode current of the tube 4 has the consequence that the cathode potential falls and the diode 17 blocks. This creates the conditions for the second phase of the cycle, during which the capacitor 1 discharges through tube 4 to produce the trailing edge. The discharge circuit consists of the switching elements 15, 1, 4 and 16. The cathode potential of the tube 4 now regulates itself and brings the grid-cathode potential to a value that is determined by the current in resistor 16. The tube 4 thus conducts as a result of the feedback in the cathode circuit through the resistor 16, which is to be suitably dimensioned for this purpose, a constant Current. When the capacitor 1 discharges, the potential at the control electrode of the tube 5 drops until the Tube 6 becomes conductive and thus initiates the first phase of the next cycle.

ίο It should be noted that the states of the constant Current flow during the two phases of the cycle by changing the values of the resistors 13 and 16 or by changing the potential at the negative ends of these resistors independently of one another can be changed. If the latter route is chosen, means are required to exploit the potentials at the negative ends of the resistors 13 and 16 independently of each other and independently of the negative anode voltage supply ITF for other parts of the arrangement, which should remain unchanged, to change. This allows the inclinations of the leading and trailing edges of the saw teeth produced can be changed independently of each other. It is possible to increase the duration of the trailing edge than that of the leading flank. By changing the capacitance of the capacitor 1, the inclinations grained both the leading and trailing edges can be changed. In the drawing are the switching elements 1, 13 and 16 shown as changeable.

The circuit described can be converted into a circuit can be converted with only one circuit, if external control is desired, such as. B. in oscilloscopes the case is. The external control is based on one of two stability levels or so-called »Waiting conditions«. In such an operation, it is desirable to note the deviations in the potential the anode of the tube 5 by the addition of two limiting diodes in a known manner small zti keep. Such diodes are shown in dashed lines and denoted by 20 and 21. Be that way also limits the amplitudes of the potential deviations anywhere in the array, and above In addition, the amplitude of the saw teeth generated is made independent of the stray capacitances.

In order to establish the first waiting state, current is fed into the connection point of the resistors 8 and 9 and so the mean potential at the control electrode of the tube 6 is raised. So that will the tube 5 kept locked even when the charging of the capacitor 1 has stopped because that The anode potential of the tube 4 has reached its upper limit, which is indicated by one of the inserted diodes (the Maximum limiting diode 20) is specified. The cycle is thus at the positive tip of the sawtooth interrupted. Control of the arrangement for a single cycle of operation can thereby be effected that a negatively polarized pulse is applied to the cathodes of the tubes 5 and 6, the one has such a size that a current in tube 5

flows. ...

The second waiting position is established by a current flowing from the junction of the resistors 8 and 9 flows to lower the mean potential at the control electrode of the tube 6. This Current keeps the tube 6 blocked, even if the discharge of the capacitor 1 has stopped because the Diode 12 passes a current from the anode of the tube S, whose potential is inserted by the other Diode (the minimum value limiting diode 21) is limited. Here the cycle is started at the negative

tive tip of the sawtooth interrupted. A keying of the arrangement to generate a single Operating cycle can be effected by applying a positive polarized pulse to the cathodes of tubes 5 and 6 is applied, which is so large that it blocks the flow of current in the tube 5.

Synchronization can also be achieved in self-excited operation of the circuit by applying control pulses to the cathodes of the tubes 5 and 6.

The value of the resistor 11 is to be selected in such a way that the one fed into the anode of the tube 4 Current is limited during the charging phase. This current must be equal to the amount of the current, which flows through the tube 4, be greater than that required to charge the capacitor 1. One to large current will overload the tube 4 and give too large a charge of the capacitor 1. A to small current will reduce the current in the tube 4 to a value which is below that the diode 17 is kept conductive, and thus the current in the tube 4 will stop flowing.

Claims (1)

Patent claims: 1. Generator for the generation of a sawtooth voltage, which is caused by the charge and the discharge of a capacitor arises, and in which the voltage of the capacitor is applied to the control electrode a directional conductor acts, which linearizes the leading edge of the sawtooth voltage, characterized in that the trailing edge of the sawtooth voltage is in a discharge circuit is linearized by a directional conductor (4) and a resistor (16), which the potential of the Controls emission electrode of the directional conductor. 2. Generator according to claim 1, characterized in that between the emission electrode of the Directional conductor (4) and a bias voltage, a rectifier (17) is arranged, which during the discharge of the capacitor (1) blocks the flow of current and conducts current while the capacitor is being charged is. 3. Generator according to claims 1 and 2, characterized in that the charging and discharging periods of the capacitor (1) are controlled by a multivibrator (5, 6) and that between the multivibrator and the capacitor (1) a rectifier (12) is arranged via which the Capacitor is charged and the charging circuit during the discharge of the capacitor completely interrupts. 4. Generator according to claim 3, characterized in that the rectifier (12) is connected to the anode of a tube (5) of the multivibrator and that the control electrode of this tube is connected to the tap of a voltage divider (18,19) which is connected between the Anode of this tube and a point of certain fixed potential (-AT) is arranged. 5. Generator according to claims 1 to 4, characterized in that the sawtooth voltage is formed on a variably adjustable capacitor (1), which is connected between the control and the collecting electrode of the directional conductor (4) is arranged. 6. Generator according to claims 1 to 5, characterized in that between the control and the emission electrode of the directional conductor (4) influencing the capacitor voltage adjustable resistors (13, 16) are arranged. 7. Generator according to claims 1 to 6, characterized in that between a control electrode the directional conductor (4) influencing the capacitor voltage and a bias voltage a rectifier (15) is arranged, which blocks the flow of current while the capacitor is being charged and is conductive during the discharge of the capacitor. Considered publications:
Electronic Engineering, March 1953, pp. 94 to 97. 1 sheet of drawings 11.5 «