The invention relates to a method according to the preamble of the attached claim 1 of matching a line driver circuit for different transmission lines and to a line driver circuit according to the at¬ tached claim 4. The line driver circuit according to the invention is intended to provide a desired signal level for a digital connection established by a transmission line, which may vary between at least two transmission lines having mutually different characteristic impedances. A transmission line means in this connection any transmission medium having a certain impedance level, such as a twisted pair or a coaxial cable.

It is often desirable to use the same line driver circuit in connection with transmission lines having different characteristic impedances (connected e.g. to a 75 ohm cable or a 120 ohm cable). Then the line driver circuit has to provide suitable signal levels for the very transmission line to which it is connected each time. Each transmission line having a specific characteristic impedance has specific re¬ quirements for the amplitudes of pulses to be trans- mitted.

In known line driver circuits intended for use in connection with transmission lines having two dif¬ ferent impedance levels, a secondary winding is pro¬ vided with a tapping constituting an interface for a transmission line having another impedance level. Figures 1 and 2 illustrate such a line driver circuit according to the prior art, in which a driver stage

11 inputs an output signal via a transformer coupling

12 to a transmission line 13 connected to a secondary winding 12b of the transformer. Each output terminal

of the driver stage is connected via a separate out¬ put resistor R to the respective terminal of a pri¬ mary winding 12a. The driver stage typically com¬ prises two transistors Trl and Tr2, one of which is conductive during a positive pulse and the other one during a negative pulse. An emitter of each transis¬ tor is connected to earth and a collector of each transistor constitutes the respective output terminal of the driver stage, which terminal is connected to the respective output resistor R. The line driver circuit provides an output signal for the transmis¬ sion line, the signal levels of which signal are as desired and which signal may conform e.g. to an HDB3 line code known per se (a coding method recommended by the CCITT and used in PCM systems). The primary winding 12a of the transformer is provided with a tapping, which is connected to the operating voltage +V.

The driver stage may be e.g. a commercially available XR-T5675 manufactured by Exar, which cir¬ cuit is intended to drive PCM lines up to a 10 Mbit/s rate.

The secondary winding of known line driver cir¬ cuits is provided with a separate tapping, whereby two outputs are generated, depending on the impedance level of the cable to be used. If it is desirable to use the line driver circuit e.g. in connection with a 120 ohm symmetrical pair, the cable is connected to a corresponding terminal indicated by reference mark T120 and to a common terminal TCOMM (Figure 1 ) . On the other hand, if it is desirable to use the line driver circuit e.g. in connection with a 75 ohm co¬ axial cable, the cable is connected to a correspond¬ ing terminal (tapping) indicated by reference mark T75 and to a common terminal TCOMM (Figure 2).

Drawbacks of the known solution described above are associated with the separate tapping of the sec¬ ondary winding. Firstly, the separate tapping in¬ creases the complexity of the line driver circuit and thus the costs therefor. In this case, even the three terminals of the secondary winding have to be wired to a connector situated at the interface of the transmission line. This causes two other drawbacks. Firstly, an unused "floating" terminal tends to in- crease capacitive and inductive components in the output circuit, which may distort the shape of the signal to be transmitted, especially at high trans¬ mission speeds. Secondly, these wirings render the practical structure more complicated than before, particularly on circuit boards having several inter¬ faces.

In known solutions, the line driver circuit may be provided, according to Figure 3, with terminals A to C, which are connected mechanically according to the impedance level used each time. When a 120 ohm cable is used, the terminals A and B are connected, and when a 75 ohm cable is used, the terminals B and C are connected. However, it should be preferable to try to avoid using mechanical switches for the selec- tion of impedance level, because they make the struc¬ ture more complicated and may cause crosstalk in some cases. Figure 3 shows the transistors Trl and Tr2 of the driver stage 11 as switches SI and S2 (consti¬ tuted by the transistors) describing their operation. The object of the present invention is to get rid of the drawbacks described above and to provide such a line driver circuit in which the impedance level of a transmission line may be changed automa¬ tically without any changes being necessary in the line driver circuit. This is achieved by means of a

method according to the invention, which is charac¬ terized in what is set forth in the characterizing portion of the attached claim 1. The line driver cir¬ cuit according to the invention is, in turn, charac- terized in what is set forth in the characterizing portion of the attached claim 4.

The inventive idea is to determine output re¬ sistances and turns of windings in such a way that the signal levels required by the transmission lines are achieved without any changes in the circuit.

The circuit according to the invention has a simple structure, because transmission lines are sup¬ plied from the same terminals (thus only two terminals are needed) and no changes are necessary in the circuit when the impedance level of a connection is changed. The transformer coupling will also be simpler and cheaper, because no separate tapping of the secondary winding is needed any longer. Then the above problems caused by a floating connection are also avoided. However, since the structure is based on existing structures as well as possible in other aspects, the available technique may be utilized here as well as possible.

In the following, the invention will be ex- plained in more detail with reference to the examples of Figures 4 to 6 in the attached drawings, in which

Figures 1 and 2 show a known line driver cir¬ cuit connectable to transmission lines having dif¬ ferent characteristic impedances, Figure 3 shows another known line driver cir¬ cuit connectable to transmission lines having dif¬ ferent characteristic impedances,

Figure 4 shows a line driver circuit according to the invention, Figure 5a shows an equivalent circuit of the

line driver circuit according to Figure 4 during a pulse to be transmitted,

Figure 5b shows the equivalent circuit of Fig¬ ure 5a carried a step further, and Figure 6 shows finding optimum values in the solution according to the invention.

Figure 4 shows a line driver circuit according to the invention. The basic structure corresponds entirely to the basic structure shown in Figures 1 and 2, except that the structure according to the invention has fully eliminated the tapping of the secondary winding. The line driver circuit according to the invention can nevertheless be connected to transmission lines having mutually different impe- dance levels without any changes being necessary in the circuit. This is based on the idea on determining component values (output resistances and turns of windings) in such a way that suitable signal levels are provided for both impedance levels. Line impe- dance is indicated in Figure 4 by reference mark R _L and the voltage (identical to the desired signal lev¬ el) present across it by reference mark V _L . Conse¬ quently, two terminals 13 and 14 of a secondary wind¬ ing of the line driver circuit according to the in- vention always constitute ( irrespective of the impe¬ dance level of the transmission line) those connec¬ tors to which the transmission line is connected.

It is possible to generate for the circuit shown in Figure 4 an equivalent circuit for the time of a transmitted pulse, which circuit is similar to that shown in Figure 5a and in which circuit a col¬ lector of a switching transistor is connected to one terminal of a primary winding having Nl turns, the other terminal of which primary winding being coupled to an operating voltage +V via an output resistor R.

(Nl is the number of turns of the primary winding of the transformer between the terminal of the winding and a center-tapping connected to the operating voltage, cf. Figure 4.) Terminals of the secondary winding (having N2 turns) are connected to a line impedance R _L . The saturation voltage of the switching transistor (collector-emitter voltage, when the switching transistor is conducting) is indicated by reference mark V _tr . Further, the circuit of Figure 5a may be reduc¬ ed to conform to the circuit of Figure 5b by replac¬ ing the transformer coupling and the line impedance by one equivalent impedance R _eq , the value of R _eq being By means of the equivalent circuits described above, it is possible to prove that the value of the resistor R and the turns ratio of the windings n = N1/N2 have the following dependency:

When a first transmission line, for which R _L =R _L1 and V _L =V _L1 , and a second transmission line, for which R _L =R _L2 and V _L =V _L2 , are determined, common values R _opt and n _opt may be found for the resistor R and the turns ratio n, if the following equations (2) and (3) are satisfied simultaneously:

( V. 3 ^«■ ) ) R * >pt = n -- ² opt I V 2 ~ ^V V II > o

( —LI _ LI_2 ^ ^l R _T L ₁ 1 R "L2

These equations may be reduced further to con¬ siderably simpler sets of conditions a and b : 5 a . ( V-V _tr ) >0 and -- < - and R _L2 <R _L1 and V _L2 <V _L1

_Λ b. ( V-V _tr ) >0 and g" > §" and R _L2 >R _L1 and V _L2 >V _L1 ^{J V} L2 ^Λ 2

Positive values are obtained for R _opt and n _opt , if either set of conditions, a or b, is satisfied.

20 Figure 6 shows equation (1) graphically .with the parameters R _L1 , V _L1 and R _L2 , V _L2 , respectively, of two different transmission lines. If the common point of these two parabolas happens to be at positive values of R and n, this common point determines the

25 optimal values R _opt and n _opt , by which the desired sig¬ nal level is provided for both transmission lines.

As a practical example may be mentioned a line driver circuit used either in connection with symme¬ trical pairs (a 120 ohm line) or a coaxial cable (a

30 75 ohm line) according to the CCITT recommendation G.703. The signal level required for the former and the latter transmission line is ± 3 V (± 10%) and ± 2,37 V (± 10%), respectively. By using these signal levels as values for the quantities V _L1 and V _L2 , re-

35 spectively, and by selecting typical values V = +5 V and V _tr = 0,6 V for the quantities V and V _tr , the value of the output resistance will be (since the set of conditions a is satisfied) R _opt = 63,7 ohms and the turns ratio n _opt = 0,81687.

40 Though the invention has been described above referring to the examples according to the attached drawings, it is clear that the invention is not re¬ stricted to it, but it can be modified within the

inventive idea presented above and in the attached claims. For instance, the invention is not restricted to be used in connection with the above-mentioned driver stage only, but it may be used with any driver stage the output stages of which have (transistor) switches in the manner described above. In principle, it is also possible to drive more than two transmis¬ sion lines, but then the parameters of the other transmission lines have to be such that the graph of equation (1) passes through the point (n _opt , R _opt ).