DE1287604B - - Google Patents

Description

When data pulses are transmitted over lines, the line capacitance is noticeable in a disruptive manner. As a result of the relatively large reloading time constant, a is arranged in a receiver Transistor held for a long time in the range of high sensitivity and is during this period extremely susceptible to glitches.

To compensate for disruptive line capacitance, it is already known to apply a voltage to the line to apply and thereby cause a low-resistance charge reversal. The known arrangements for creating this voltage are expensive and require a second voltage source. Also is subject to the z. B. became known by the Auslegeschrift 1056172 Arrangement of strict tolerance conditions.

The aim of the invention is to apply a voltage to compensate for disruptive line capacitance to simplify and to keep tolerance problems free. This is achieved by the invention in that ao by the end of a pulse transmitted over the line, a transistor associated with the line is switched conductive, the emitter-collector path of which connects the line to the negative pole of the Receiving source connects. The circuit arrangement according to the invention makes it possible to compensate to use the existing voltage source if there is a disruptive line capacitance. The creation of the Voltage is directly dependent on the useful pulse that is transmitted over the line, so it is not controlled by derived or centralized facilities, which always accept time tolerances must be taken.

Some embodiments of the invention are shown in the drawing. It shows

1 shows a circuit arrangement for data transmission with compensation at the incoming end of the line,

2 shows a circuit arrangement for data transmission with compensation at the outgoing end of the line.

In the circuit arrangement shown in Fig. 1 connects a line L, the capacitance C _{L is} indicated by dashed lines, a transmitting point S with a receiving point E. If the contact ^ is closed, by controlling a transistor Γ2 of the transmitting point S can positive pulses via a diode be transferred to the line L.

The incoming end of the line L lies in the receiver E at a branch point of a voltage divider formed from the resistors R1, R2 and R3. The base of a transistor Γ3 is located at a further branch point of this voltage divider. Usually the transistor is switched to be conductive.

A positive pulse arriving via the line L blocks the transistor T 3. The base of a transistor Tl is connected to the collector of the transistor via a capacitor C _K , the emitter-collector path of which is able to connect the line L to the negative pole of the voltage source . The transistor Tl is usually blocked by the negative bias voltage applied to its base via a resistor R4. The negative voltage transmitted via the capacitor C _K when the transistor Γ 3 is blocked has no effect on the transistor Tl .
At the end of the pulse transmitted via line L, transistor Γ 3 becomes conductive again. Positive voltage is applied to the collector and thus to the coupling capacitor C ^. This positive voltage change switches the transistor Π conductive, so that it temporarily applies the negative voltage to the line and thus quickly reloads the line L again. As a result, the full line capacity is available again, which has an integrating effect on brief interference pulses. Interference pulses can therefore not affect the transistor T 3 of the receiver.

In the case of the in FIG. 2, an additional transistor TA for rapid charge reversal of the line capacitance is arranged at the outgoing end of the line L. The transistor TA is switched to be conductive in the idle state, since its base is at negative potential via a resistor R 6. Since contact & is open in the idle state, no collector current flows.

At the incoming end of the line L, the transistor T 3 is also switched to be conductive via the voltage divider formed from the resistors R1, R2 and R3.

If the contact k is closed for the transmission of data pulses at the transmission point 5, then a larger negative voltage is applied to the line L via the emitter-collector path of the transistor TA , and as a result, the transistor T 3 is heavily overdriven at the incoming end of the line. Strong overload means little susceptibility to interference.

If a positive pulse is transmitted to the line at the transmission point by controlling transistor T 2 , this generates a voltage drop across a silicon diode D (Si) which is parallel to the base-emitter path of transistor T 4. As a result, the transistor TA is blocked for the duration of the pulse. At the end of the pulse, the transistor TA immediately becomes conductive again and again switches the negative voltage on to the line L , through which the line capacitance C _{L is} rapidly reloaded.

Claims (3)

Patent claims: 1. Circuit arrangement for compensating disruptive line capacitance by applying a Voltage during data transmission, characterized in that the end of a pulse transmitted over the line (L) a transistor (Π, Γ 4) assigned to the line is switched to conductive, its emitter-collector path the line connects to the negative pole of the voltage source. 2. Circuit arrangement according to claim 1, characterized in that a transistor (T 3) of the receiver at the incoming end of the line (L) at the end of the pulse temporarily ^{gives voltage to the transistor (7 1} I) assigned to the line in order to switch it conductive. 3. Circuit arrangement according to claim 1, characterized in that the associated with the line Transistor (Γ4) on the transmitting side at the outgoing end of the line is usually conductive is switched and by the during the transmission of a pulse on one of its base-emitter path parallel connected diode is blocked for the duration of the pulse.