DE1275155B - Circuit arrangement for automatic compensation of the difference in attenuation of telecommunication lines of different lengths - Google Patents

Description

Circuit arrangement for automatic adjustment of the difference in attenuation Telecommunication lines of different lengths The subscriber stations of telephone switching systems receive their microphone supply current from certain in the conversation state in general Connection sets in which at the same time the line sections belonging to a connection Coupled with one another in terms of alternating currents, but separated from one another in terms of direct currents are. The different attenuation of the subscriber lines of different lengths is so far taken into account that the hearing and speaking capsules in the individual Participant devices are used, depending on their sensitivity the length of the individual subscriber lines can be selected. Be like that at the moment the participant sets are equipped with earphones and speech capsules, which are divided into three Microphone and four earphone groups are divided, and it is with the establishment of a subscriber line always the right group for the individual case to determine the speaking or listening capsules. To the number of capsule groups for reasons To be able to reduce a simpler posture, it is already known, depending of the current flowing through the subscriber set and thus as a function of the respective resistance of the subscriber line the transmission property to change the subscriber set. A current-dependent resistor is used for this purpose placed in the subscriber line at the subscriber station, which ensures that the micro feed current is kept largely constant and the transmission properties the hybrid circuit contained in the subscriber set of the respective line length remain largely independent.

Since there is such a current-dependent resistance in each of the subscriber sets is to be switched on, this arrangement would be relatively expensive. It was already a circuit arrangement for automatic adjustment of the attenuation difference Telecommunication lines of different lengths proposed in which the telecommunication line for the transmission of telecommunication signals as well as the feed energy for one at the end of the communication line arranged consumer is used and at least a feed resistor is connected to a central DC voltage source and at the beginning of the telecommunication line a network is switched into the telecommunication line is a damping that can be changed by controllable ohmic and capacitive resistances for the telecommunication signals and its attenuation value by at least one the DC voltage, which can be drawn off at the resistors of the voltage divider, can be changed continuously is. The invention is also based on the object of regulating the transmission loss to effect by circuit parts, which several communication lines in common are. In contrast to the proposal mentioned above, this object is achieved according to the invention solved in that the inductive transformer of the feed bridge of the communication line is equipped with variable damping.

The inductive transformer can expediently through the pre-magnetized according to the respective line resistance setting feed current that the transmission loss of the line and the transformer containing entire connection section regardless of the length of this transformer coupled line remains constant.

But it can also be the inductive transformer with a special winding be equipped, which can be short-circuited via a rheostat, whereby the adjustment of the rheostat by the according to the line resistance adjusting supply current takes place.

Appropriately, it is used as a control resistor to form the short circuit an externally heated thermistor was used for the additional winding of the transformer, whose volume resistance is determined by the line current flowing in each case will.

The heating coils for the thermistor can be in series with the Windings of the feed relay of the relevant connection set or in series the transformer windings of the relevant line through which direct current flows associated side of the inductive transformer be switched. Even it is possible to use the short circuit for the additional winding of the transformer to be dimensioned in such a way that the distortion of the frequency band to be transmitted, the distortion caused by the line system largely compensated.

While in the circuit arrangement proposed so far, the Through loss of the connection set in question is regulated, remains the Feed current still depends on the length of the respective subscriber line. If the supply current is also to be kept constant, this can be achieved by that the feed current via the controlled electrode path is even with the smallest possible Line current in the saturation area operated transistor of the respective line is fed and that this is based on the respective line resistance at this Electrode path-setting potential for regulating the transmission loss evaluated will.

The electrode path of the transistor in question can be used for control - the transmission loss - the heating winding of a winding of the transformer short-circuited NTC thermistor can be connected in parallel.

But it is also possible via the one on the controlled electrode path of a transistor, corresponding to the respective line resistance potential a controlled electrode path bridged by a winding of the transformer to influence another transistor, in such a way that with the help this electrode path a more or less low-resistance short circuit of the relevant Transformer winding takes place.

In the drawings are various embodiments of the invention shown in principle. In the individual drawings are the same in each case Provide components with the same designations. While in F i g.1 the coupling shown by subscriber lines with a connection set via dialers is limited the illustration in FIG. 2 to 7 on the respective inductive transformer containing part of the connection set with the respective feed point for the Supply direct current.

In Fig. 1, the individual subscriber intercom stations Tln are connected to the bank field of voters W via subscriber lines TAL, which are of different lengths. The different line lengths of the subscriber connection lines TAL and thus their different resistance is indicated by the resistors R 1, R 2, which are adjustable.

The selector W is able to couple a plurality of subscriber lines TAL of different lengths to the input a 1, b 1 of the connection set VS in a known manner. The connection set VS consists of a local line transformer OLtt having two input windings I and II as well as two this balanced output windings HI and IV. The feeding of the direct current for the subscriber line TAL via feed resistors Wi 1 and Wi 2 in a known manner. According to the invention, the local line transformer OLt7 is now designed so that it is premagnetized by the DC feed current flowing through its windings I and II in accordance with the respective line length of the connecting line TAL, so that the total attenuation of the attenuation of the connecting line TAL and the attenuation of the connection set VS and the line extending to the output terminals a2 and b2 remains essentially constant. If the subscriber line in question is very long, it has a comparatively high resistance, so that a comparatively low bias of the windings I and II of the transformer OLtt takes place; the damping is hardly increased as a result. However, if the connection lines TAL are very short, a relatively strong direct feed current will flow and thus cause a very strong premagnetization of the local line transformer OLü, which in turn brings about a considerable increase in attenuation. Thus, regardless of the line length, the transmission loss of the connection set V is kept at an essentially constant value.

In the anoid according to FIG. 2, the feed current flowing through the connection line is also used to regulate the damping, but not through different direct current preloading of the transformer OLÜ, but by bridging an additional transformer winding V with a resistor HL of varying size: This resistor is, for example, an NTC thermistor equipped with external heating, both of which have heating windings the windings I, 1I of the food relay A are in series. The frequency response of the arrangement can be adjusted by a capacitor Co connected into the short circuit of the winding V of the transformer OLC.

But since, as is well known, the low frequencies are attenuated less than the higher frequencies via the subscriber connection line, it may be desirable to bring about additional attenuation of the low frequencies through the short circuit for the winding V of the transformer OLtt in order to reduce the frequency response of the entire transmission system essential to keep constant. In this case, it is not necessary to insert a capacitor Co in the short circuit for the winding V of the transformer OLtj, but you can, as indicated by dashed lines, connect the winding V of the transformer OLÜ directly to the thermistor HL .

In the arrangement according to FIG. 3, the two heating windings of the NTC thermistor HL are connected in series with the windings I and II of the transformer OLü, since here the direct current is not fed in via a separate feed relay, but via the windings of the transformer OLti itself. In this case, the on the basis of FIG. 1 also exploited the effect of the premagnetization described.

In the arrangement according to FIG. 4, the alternating feed losses resulting from the different line resistances are also compensated, ie the feed current is kept constant regardless of the respective line length. This is done by wixing out the resistors; Wiy, Wiz and the transistor Tr combined arrangement causes. The base voltage of the transistor Tr is determined by the voltage divider Wix and Wiy, the operating point of the transistor Tr being set so that a feed current of almost constant magnitude flows through the resistor Wiz regardless of the direct current resistance of the subscriber line. The size of the collector-emitter voltage of the transistor Tr is a measure of the resistance of the subscriber line. It is used to influence the attenuation of the coupling element in that the heating winding of a thermistor HL is connected in parallel to the emitter-collector path of the transistor Tr. The heating coil of the thermistor HL can be dimensioned so that the entire feed current flows through it with minimal line resistance. As the resistance increases, it is more and more short-circuited by the transistor Tr and thereby makes the control circuit more and more high-resistance in accordance with the FIG. 2 and 3 made statements. The resistor bridging the base-emitter path of the transistor Tr takes over part of the load that occurs during the supply current control and thus relieves the load on the transistor Tr.

The embodiment according to FIG. 5 corresponds to that according to FIG. 4. As a control element, ie as a variable resistor in the damping circuit, a transistor Tr2 is used here, which is controlled by the voltage present at the emitter of the transistor Trl. With this arrangement, special attention must be paid to temperature stability, which can be achieved with the aid of known circuit measures. The resistor Wi is not absolutely necessary, but can be used to relieve the transistor Tr 1 .

In order to change the transmission loss of a connection set, it is not necessary to influence the coupling itself in its damping behavior; but, like F i g. 6 shows, it is also possible to use an attenuator VDG which can be regulated in series with the coupling element. The attenuator VDG can be based on the embodiments according to FIG. 2 to 4 either with a thermistor HL or according to the embodiment according to FIG. 5 can be controlled with a transistor.

Claims (10)

Claims: 1. Circuit arrangement for automatic compensation the difference in attenuation of telecommunication lines of different lengths in which the telecommunication line for the transmission of telecommunication signals as well as the feed energy for one consumer arranged at the end of the telecommunication line, characterized in that that the inductive transformer (OLV) of the feed bridge with variable attenuation is equipped. 2. Circuit arrangement according to claim 1, characterized in that that the inductive transformer (OLÜ) by the respective respective line resistance adjusting supply current is premagnetized so that the throughput loss of the the entire connection section containing the line and the transmitter independently of the length of the line coupled to this one transmitter remains constant (F. i g. 1). 3. Circuit arrangement according to claim 1, characterized in that the inductive transformer (OLV) has an additional winding (V) which can be short-circuited via a regulating resistor (HL, Tr) (F i g. 2 to 5). 4. Circuit arrangement according to one of claims 1 and 3, characterized in that an externally heated thermistor (HL) is used as the control resistor, the respective volume resistance of which is determined by the line current flowing in each case (F i g. 2, 3, 4). 5. Circuit arrangement according to claim 4, characterized in that the heating windings for the thermistor (ZHL) in series with the windings (I, I1) of the feed relay (A) of the relevant connection set are switched (Fig. 2). 6. Circuit arrangement according to claim 4, characterized in that the heating windings of the thermistor (HL) are connected in series with the DC-carrying transformer windings (I, II) of the respective line associated side (a1, b1) of the inductive transformer (OLV) (F i g. 3). 7. Circuit arrangement according to claim 3, characterized in that the short circuit for the additional winding (V) of the transformer (OLV) is dimensioned (by means of Co) so that the distortion of the frequency band to be transmitted caused by this short circuit is the distortion caused by the line system largely compensated (Fig. 2). B. Circuit arrangement according to Claim 1, characterized in that the feed current via the controlled electrode path even with the smallest possible line current The transistor (Tr) operated in the saturation region is supplied to the respective line and that this depends on the respective line resistance at this electrode path setting potential for regulating the transmission loss is evaluated (F i G. 4). 9. Circuit arrangement according to claim 8, characterized in that parallel to the controlled electrode path of the transistor (Tr) the heating winding of a thermistor (HL) short-circuiting a winding (V) of the transformer (OLV) lies (F i g. 4). 10. A circuit arrangement according to claim 8, characterized in that a controlled electrode path of a further transistor (Tr2) bridged by a winding (V) of the transformer (OLO) via the controlled electrode path of a transistor (Tr1), corresponding to the respective line resistance ) is influenced (Fig. 5). Older patents considered: German Patent No. 1126 941.