DE1138432B - Electronic adjustment device, especially for level control in multi-channel carrier frequency transmission lines - Google Patents

Description

The main patent relates to one particularly applicable to line control in carrier frequency systems Electronic adjustment device for gradual adjustment of one by at least one Variable resistor flowing current with a counter circuit controlled by setting pulses from bistable Flip-flops with two amplifier elements each, in particular transistors, in which one amplifier elements via a resistor corresponding to the respective current stage to the common Working rheostat.

The invention is based on the object of the counting circuit shown in FIG. 2 of the main patent specification to improve that with the same structure and the same dimensions of the individual Flip-flops of the counting circuit and with the same rating of the operating voltages for the flip-flops and the rheostat - apart from residual collector current components - no current through the rheostat flows when the transistors working on it via a resistor are blocked.

According to the invention, this is achieved by using Schmitt triggers, preferably as bistable multivibrators those in transistorized design are used, in each of which the output electrode of the second amplifier element fed back to the input electrode of the first amplifier element via a capacitor and a voltage divider is provided which generates a DC voltage at the latter electrode, which is greater in absolute terms than the lower threshold voltage of the Schmitt trigger, when the first amplifier element is conductive and which is lower than the upper threshold voltage of the Schmitt trigger when the first amplifier element is blocked that the variable resistor over the respective current stages corresponding resistors with the second amplifier elements of the Schmitt trigger is connected and is connected to the operating voltage, and that when switching on with the first Amplifier elements a further switching of the counting circuit and when switching with the second Amplifier elements a switching back of the counter circuit is effected.

An embodiment of two successive Schmitt triggers of the counting circuit of a setting device according to the invention is shown in the drawing and explained in more detail below.

The upper, first Schmitt trigger contains two transistors TsI and Ts 2 with collector load resistors R 1 and R 2 and a common emitter series resistor R 3. The base connection of the second transistor Ts 2 is on the one hand via a resistor Electronic setting device,
especially for level control in multi-channel carrier frequency transmission lines

Addendum to patent 1118 831

Applicant:
Telefunken

Patentverwertungsgesellschaft mb H.,
Ulm / Danube, Elisabethenstr. 3

Dipl.-Phys. Erich Bächle, Backnang (Württ),
has been named as the inventor

R 4 is connected to the collector connection of the first transistor TiI, on the other hand, via a resistor R 5 to ground, ie to zero potential. The base connection of the transistor TsI is at the tapping point of a voltage divider consisting of two resistors R ₆ and R ₁ and is connected to the collector connection of the transistor Ts 2 via a capacitor C ₁ . The input terminal k for the control or switching pulses Fort is guided over biased by resistors R8 and R9 in the blocking diodes D 1 and D 2 to the base terminal of the transistor TsI and Ts. 2 The collector connections of the transistors TsI and Ts 2 are connected to the base connections of the transistor Ts 3 via capacitors C 2 and C 3 and reverse biased diodes D 1,4, D 1,3 and D 2,4, D 2,3 or Ts 4 of the following Schmitt trigger, which - like all other Schmitt triggers - has the same structure and dimensions as the first, upper Schmitt trigger. The second Schmitt trigger is connected to the following Schmitt trigger via terminals α and b , as described in more detail in the main patent specification. The control resistor R _{a is} connected to the collector connections of the transistors Ts 2, Ts 4 etc. via resistors R _n , R _n etc. to the general operating voltage U ₀ , to which the Schmitt triggers are also connected.

To ensure that the individual Schmitt triggers work properly in a wide range of ambient temperatures To ensure that the two response thresholds of each Schmitt trigger as far apart as possible. It is necessary,

209 678/244

that the upper threshold voltage is at least twice as large in absolute terms as the lower. As is known, this is achieved by making the collector load resistance Rl at least twice as large as the collector load resistance R 2. In addition, the absolute value of the lower threshold voltage must not be too small. It is preferably chosen to be greater than 0.5 volts. The purpose of the voltage divider R ₆ , R ₇ is to keep the base unchanged in its original position. So only one of the size flows through the resistor R ₁₀

is greater than the lower threshold voltage of the Schmitt trigger when the first transistor is conductive and which is less than the upper threshold voltage when the first transistor is blocked.

The mode of operation of the circuit is as follows: In the rest position of the counting circuit, the first transistors of the Schmitt trigger TsI, Ts 3 etc. are conductive and their second transistors Ts 2, Ts 4 etc. are blocked.

ses resistance corresponding current through the variable resistor R _a .

If a second positive incremental pulse is now applied to terminal k, then - as described above - both transistors TsI are momentarily. and Ts2 blocked. The capacitor C ₁ then charges in a circuit containing the resistors R 2, R ₆ and R ₁

potential of the first transistors TsI, Ts 3 , etc. to io. If the charging time constant of this circle is to bring a value that is sufficiently large in absolute terms, so that immediately after the disappearance of the incremental pulse, the voltage at the base terminal of transistor TsI exceeds the upper threshold voltage of the Schmitt trigger in absolute terms, then it tips over, and the transistor TsI becomes conductive and the transistor Ts 2 is blocked. Now occurs at the collector connection of the transistor Ts 1 a positive voltage jump, which after differentiation across the capacitor

Only 20 C 2 flows through the control resistor R _a as a positive pulse via the switching on a collector residual current component, which comes from the adjusted pair of diodes D 1,4, D 1,3 to the second ratio of the collector load resistors R2 to Schmitt trigger and this overturns. Here the corresponding resistances R ₁₀ , R ₁₁ , etc. are produced at the collector terminal of the transistor. With every Schmitt trigger, the Ts 3 harbors a negative voltage jump, which, according to the differential coating of the capacitor C ₁ at the potential - U ₀ 25, rentiation as a negative impulse does not affect the following and the left coating only slightly above the lower one, the Schmitt trigger can reach, so this in threshold value. leaves its original position. Stay with it

If a positive incremental pulse now arrives at terminal k as well as all other Schmitt triggers at their original level, the current position will be. The transistor Ts 2 is now done both transistors TsI and Ts2 blocked. By 30 blocks, the transistor Ts 4 ^ conductive ^ This flows through the positive pulse, the voltage at the base resistor R ₁ ^Λ " ^ ^ - ^ .., __ ..

connection of the transistor TsI under the lower
Schmitt trigger threshold lowered. As soon
If the impulse has disappeared, then it tips over
Schmitt trigger in the opposite position: If a third positive pulse arrives at the sistor Ts 2 becomes conductive and the transistor TsI is terminal k, the first Schmitt trigger is blocked again, because as a result of the corresponding dimensioning of the
Voltage divider R ₆ , R _7, the voltage at the base terminal of the transistor TsI the upper threshold

of the Schmitt trigger no longer exceeds. Thereby 40 rheostat. If the setting device now supports this process, the capacitor C _1, for example, is set to switch back, with its discharge via the parallel connection of the resistors at the terminal w a high and at the Kiemmez R2 and R 3 and the parallel connection of the a low, negative blocking potential is, then resistances R ₆ and R ₇ and now has a fourth positive impulse at the terminal k after the effect, the charge on both surfaces is about the same potential. At 45, the first Schmitt trigger flips over again. The tilting of the Schmitt trigger creates a negative voltage lector connection of the transistor TiI at the transistor Ts2 , a positive satorC3 does not apply to the second Schmitt trigger after differentiation via the capacitor KoUektor connection of the transistor Ts 2, because the voltage jump . By differentiation via the diodes D 2,3 and D 2,4 negative impulses blocking capacitors C2 and C3, these voltages are ren. The positive resulting at the transistor TsI

₁₀ no power. On the other hand, a current corresponding to the size of this resistance flows via the resistor R ₁₁ via the variable resistor R _n .

overturned while the second remains in its previous position. A current given by the resistors R ₁₀ and R _{11 now flows through the}

jumps are transformed into corresponding negative or positive impulses. Depending on whether the circuit is switched back or switched on as a result of corresponding blocking potentials at terminals z, w

The voltage jump and thus the positive pulse generated via the capacitor C 2 does not pass through the diodes D 1,3 and D 1,4, which are provided with a high negative blocking potential. The second and all of the following-

is set, the positive pulse reaches the 55 the Schmitt trigger so keep their previous corresponding pair of diodes D 2,4, D 2,3 on the M position. Now only flows through the resistor

lowing Schmitt trigger or not and therefore overturns it or not. In both cases, the negative pulse does not reach the following Schmitt trigger via the two diodes D 1,3, D 1,4, since this pair of diodes blocks the negative pulses. The we U ₀ = 20 V

This Schmitt trigger as well as the other Schmitt trigger corresponds to that described first Schmitt trigger.

If the setting device is switched on 65 R ₄ = 5.4 kQ R ₅ =
placed, with a low and on at terminal w
terminal ζ has a high negative blocking potential
then all subsequent Schmitt triggers remain

^ Current to resistor R _a . The counting circuit is switched back further to its initial state accordingly.

An embodiment of an adjusting device according to the invention was designed as follows:

C ₁ = C ₂ = 1 nF

.R ₁ = 4.9 kQ R ₂ = 2.3 kQ

""''"1.2 kQ
R ' _a = 10 kΩ

C ₃ = 500 pF R ₃ = 185 Q R ₆ = 1.2 kQ R ₀ = 3 kQ

R ₇ = 22 kΩ

Collector current of the transistors at 25 ° C <i 10 μΑ.

Current amplification factor β of the transistors at 25 ° C;> 30.

Reverse currents of the diodes at 25 ° C and an applied reverse voltage of 20 V ^ 10 μΑ.

The setting device constructed in this way works in a temperature range from -30 to + 7O ⁰ C.

Claims (2)

PATENT CLAIMS: 1. Electronic setting device, in particular for level control in multi-channel carrier frequency transmission lines, for the step-by-step setting of a current flowing through at least one variable resistor with a counting circuit controlled by setting pulses and made up of bistable multivibrators with two amplifier elements each, in particular transistors, in which the one amplifier elements each have one the respective current stage corresponding resistor work on the common variable resistor, according to patent 1118 831, characterized in that Schmitt triggers, preferably transistorized ones, serve as bistable multivibrators, in which the output electrode of the second amplifier element {Ts2, Ts 4 . . .) is fed back via a capacitor (C ₁ ) to the input electrode of the first amplifier element (TsI, Ts 3 ...) and a voltage divider (R ₆ , R ₇ ) is provided which generates a direct voltage on the latter electrode that corresponds to the absolute value after is greater than the lower threshold voltage of the Schmitt trigger when the first amplifier element (TsI, Ts 3 ...) is conductive, and which is lower than the upper threshold voltage of the Schmitt trigger when the first amplifier element is blocked, that the The control resistor (R _a ) is connected to the second amplifier elements (Ts 2, Ts 4 ...) of the Schmitt trigger via the resistors (R ₁₀ , R _n . ..) corresponding to the respective current stages and to their operating voltage (-U ₀ ) and that when switching with the first amplifier elements (TsI, Ts 3 ...) a further switching of the counting circuit and when switching with the second amplifier elements (Ts 2, Ts 4. ..) a switching back of the counting circuit is effected. 2. Adjusting device according to claim 1, characterized characterized in that the absolute value of the upper threshold value of the individual Schmitt trigger of the counting circuit is at least twice as large as the lower response threshold value, which is preferably greater than 0.5 volts. For this purpose, 1 sheet of drawings © 209 678/244 10.62