DE2608104B2 - Transmission interface for clock signals - Google Patents

Description

2Tt

- 1

25th

30th

and that Uo is the knee voltage of the diode, Tt is the clock period and τ is the duration of the clock pulse.

2. Transmission interface arrangement according to claim 1, characterized in that the primary or the secondary winding of the transformer (Tr), a first capacitor is connected in parallel.

3. transmission interface arrangement according to claim 2, characterized in that the first Capacitor is chosen so that in connection with the transformer a resonance circuit for the Fundamental wave of the clock signal to be transmitted results.

45

The invention relates to a transmission interface arrangement for the transmission of pulses existing clock signals on a transmission line with a switch that is activated by the incoming Clock signals control the connection between a power source and a series circuit of a Resistance and a primary winding of a transformer closes and when connected to a secondary winding of the The transmission line is connected.

For the interference-free transmission of clock signals and to protect the operating personnel of the connected devices, earth symmetrical lines are used which are connected to the devices via ungrounded, earth symmetrical interfaces. To prevent interference caused by reflections at the connection points, the transmission line must be terminated at the ends with its characteristic impedance. In order to meet these requirements, transformers are used in the usual way, the transmission ratio of which is suitably selected. Such a known transmission interface arrangement for clock signals is shown in FIG. The transmission interface arrangement contains an output transformer TrO, the primary connection of which is connected to the connection for the operating voltage UB via a series circuit made up of a controlled switch 5 and a resistor RO. On the secondary side, the transformer TrO is connected to a transmission line, which is represented by its characteristic impedance Z.

The switch 5 is controlled by the clock to be transmitted; it closes the connection between the operating voltage source and the transformer periodically with the clock period 7Y for the duration τ. Correspondingly, a DC-free clock signal appears at the connections 2, 2 'of the secondary winding of the transformer TrO. By suitable selection of the resistance RO and the transformation ratio ü between the primary winding and the secondary winding of the transformer, the circuit can be adapted to the characteristic impedance Z of the transmission line, which acts as a load, while the switch 5 is closed. As a result, the adaptation is only secured during the period when switch S- is closed. The transmission interface arrangement according to the prior art has the disadvantage that there is no adaptation when the switch 5 is open. As a result, disturbances that get from the transmission line to the transmission interface arrangement while the switch is open are reflected by the latter and can simulate a clock pulse in its receiving point or even cancel it in the case of a different phase position.

The object of the invention is therefore to provide a transmission interface arrangement of the type mentioned at the beginning Type to be specified, also in the pauses between the transmission of the individual clock pulses to the connected Transmission line is adapted.

According to the invention, the object is achieved in that the series connection of the resistor and the primary winding of the transformer is connected in parallel with a diode polarized in the reverse direction for the supply current and that the product of the resistance value of the first resistor and the square of the transmission ratio ü, which is the quotient the number of turns of the primary winding and the number of turns of the secondary winding is at least approximately equal to the characteristic impedance of the transmission line connected on the secondary side and that the operating voltage Ub is selected to be so high that

■ U " .

U _D * - τ

and that Ud is the knee voltage of the diode, Tt the clock period and τ the duration of the clock pulse.

The main advantages of the transmission interface according to the invention are that the aforementioned Requirements could be met with relatively little effort and that, in addition, universal applicability is guaranteed in a wide frequency range.

The invention is based on the knowledge that adaptation is possible even when the switch is open is, provided that it consists of the primary winding of the transformer and the upstream resistor Primary circuit is closed by another switch.

When switching transistors with inductive loads, so-called overshoots can lead to falsifications of the square-wave pulses to be switched occur. To the

To avoid this overshoot in a transmission interface arrangement according to the invention, it is useful to that the primary or the secondary winding of the transformer, a first capacitor connected in paral el is.

Another variant of the invention results from the fact that the first capacitor is chosen so that In connection with the transmitter a resonance circuit for the fundamental wave of the to be transmitted Clock signal results. This arrangement results in a sinusoidal cycle.

The invention is to be described in more detail below with reference to the exemplary embodiments shown in the drawing explained. In the drawing shows

F i g. 1 a transmission interface arrangement according to the state of the art,

F i g. 2 shows the basic circuit diagram of a transmission interface arrangement according to the invention,

3 shows an embodiment of the invention Transmission interface arrangement,

F i g. 4 shows another basic circuit diagram of the invention Transmission interface arrangement to explain their function and

Fig. 5 Pulse plans for the input and output voltage and the input current.

Fig. 1 has already been explained in more detail in the discussion of the prior art, so that at this This is not discussed further.

The basic circuit diagram according to FIG. 2, like the arrangement according to the prior art, contains an operating voltage source Ub, a controlled switch 5 and, in series with this, a first resistor R 1 and the primary winding of the transformer TrI _1, and the transmission line represented by the characteristic impedance Z is connected to the secondary winding of this transformer connected. In addition, the transmission interface arrangement according to FIG. 2 contains a first diode D 1, which is connected in parallel to the series circuit comprising the first resistor R 1 and the primary winding of the transformer. Resistance R 1 and transmission ratio ü between the primary and secondary winding of the transformer are selected, as in the prior art, so that when the switch is closed, there is an adaptation to the characteristic impedance Z of the transmission line. When the switch is closed, the diode DX is not effective because it is polarized in the reverse direction for the operating voltage Ub. When the switch S ¹ is open, the reduction of the magnetic field in the transformer Tr 1 results in a current directed opposite to the original, for which the diode D 1 is polarized in the forward direction, so that in this case too the primary circuit of the transformer is closed and there is adaptation . The forward resistance of the diode is negligible because of its small size compared to the resistance Ri , so that the adaptation is practically retained.

The embodiment according to Fig.3 includes a controlled switch 5 according to Figure 2 an npn transistor T, also, the circuit additionally comprises according to FIG. 3, a second resistor R 12 connected between the signal input SI and to the base terminal of the npn transistor T is switched and a first capacitor Ci, which is used to eliminate the overshoots already mentioned. For the practical implementation, a transistor of the type BSY 62A and a diode of the type BAW 75 were chosen, the first resistor RH has a resistance of 910 ohms, while the resistance of the second resistor R 12 was 3.3 k ohms and the characteristic impedance Z 130 ohms. A voltage of 5 V was selected as the operating voltage, the number of turns of the primary winding of the transformer TR 1 was 325 turns while the secondary winding comprised 130 turns. The capacitor C1 was chosen to be about 40OpF. With a transmission interface arrangement of the type described, in addition to the transmission of an 8 k Hz clock, a 64 k Hz clock could also be transmitted. In a further embodiment, the capacitor Ci was chosen to be adjustable, and the number of turns of the windings of the transformer was significantly reduced, so that a resonance circuit for the fundamental wave of a clock oscillation resulted, which was at a frequency of 2048 kHz.

Is for explaining the operation of the transmission interface arrangement according to the Figure 3 a Ersatzvierpol is shown in Figure 4, 51 and 5 Γ is at its input terminals the voltage U _B, provided that the switch 5 is closed and the voltage - Uo when the Switch 5 is open. The voltage Uo is the knee voltage of the diode Di, which results from the voltage-dependent forward resistance of this diode.

A DC-free clock signal U2 (t) appears at the secondary terminals marked 52 and 52 'of the transformer assumed to be ideal

U ₁ SS = ^

+ U _D )

Has. In FIG. 5, the curves for the input voltage U ₁ (t), the input current /, (t) and the output voltage LZ ₂ (t) of the equivalent quadrupole are shown in lines 5a and 5i> one above the other.

The diode D 1 can only close the primary circuit of the transformer when the switch 5 is open if the input current U (t) flows in the forward direction of the diode D 1. With the selected positive polarity of the operating voltage U _B , the input current must also always be positive. From this the condition

U _n > Un

fin _

V τ

derive, which must be fulfilled for the functionality of the circuit.

For this purpose 2 sheets of drawings

Claims (1)

Patent claims: 1. Transmission interface arrangement for the transmission of clock signals consisting of pulses on a transmission line with a switch which, controlled by the incoming clock signals, closes the connection between a current source and a series circuit of a resistor and a primary winding of a transformer and which connects to a secondary winding of the transformer the transmission line is connected, characterized in that the series circuit of the resistor (R 1, R ll) and the primary winding of the transformer (TrX) is connected in parallel with a reverse-biased diode (D) for the supply current and that the product of the Wicierstandswert of the first resistance (R 1, Λ 11) and the square of the transmission ratio ü, which is the quotient of the number of turns of the primary winding and the number of turns of the secondary winding, is at least approximately equal to the characteristic impedance (Z) of the transmission line connected on the secondary side and that the operating fun nnung Ub is chosen so large that