DE2064117B2 - Multi-level switching network with electronic crosspoint contacts - Google Patents

Description

40

The subject of the main patent is a multi-stage switching network, the connection paths of which between switching network connections each lead via an intermediate feed line located between two coupling point contacts, the latter being connected to a battery via a choke, so that the choke current fed into a connection path is shown in power parts on the intermediate feed line , each of which flows to one of the interconnected switching network connections. The cross-point contacts of the switching network require an operating direct current that exceeds the holding current in order to remain in the conductive state. In the coupling network, the current components of the choke current each represent the operating direct current, while they flow in an established connection path. A limiter circuit is connected to the intermediate feed line, which limits the value of the potential of this intermediate line to a range that lies between two limits which differ by a finitely large value. The limiter circuit D can also, for. B. be formed by two anti-parallel and series-connected Zener diodes, this series connection being parallel to the choke, as shown in the figure belonging to the main patent.

An essential task of the subject of the main palent and its further development is the removal of disturbances both when setting up a connection path via a multi-level switching network with electronic crosspoint contacts as well as in maintaining the same.

The object of the present invention is also the reduction of disturbances, which in particular the Maintaining, but also affecting the establishment of the connection path via such a switching network can. It has been shown that, in particular, long-lasting interference voltages caused by a switching matrix connection, sometimes for an interruption the established connection path or to prevent the establishment of a connection path if these glitches try to generate a current in the established connection path, which is opposite to the hook current.

In order to avoid the disturbances described, the invention provides that, in the coupling network designed according to the main patent, the operating direct current branches into two direct current components in a connection path established between each of the interconnected coupling network connections and the coupling point adjacent to the respective coupling network connection, each of which branches off via an e-nen high alternating current resistance having terminal resistance are conducted that in each case at the switching matrix connection in the longitudinal direction to the relevant connection path between the switching matrix connection and the adjacent coupling point a permeable for the first direct current component diode is inserted that on one side of this diode, namely between this diode and the relevant adjacent coupling point , in the transverse direction to the connecting path, the second connection resistor, which absorbs a direct current component which at least slightly exceeds the holding current, is attached. and that on the other side of this diode the first connection resistor, which takes up the second direct current component, is connected.

The invention and further developments thereof are explained in more detail using the exemplary embodiment shown in the figure.

The figure represents a connection path between the two switching network connections Ki. Kl represent. Before the establishment of the connection path. After the crosspoint contacts of this connection path have been switched to the conductive state, the connection path can be set up, and c ^{c r |} It flows in the established connection path, as in the house. . ^r t stated, in general about the BattL'ie ' the throttle /. or in special cases about Be _t - ^ pose D, an inductor current loading or

Grenzerstto.il into the intermediate feed line Z In the intermediate feed line Z , this current is split into two parts, the first part flowing to the switching network connection Ki and the second current part flowing to the switching network connection K2.

In particular to avoid the disturbance that once constructed passageway through long-lasting, at the switching matrix terminals Ki, K2 overvoltages is undesirably interrupted again, the diode Di, DA are according to the invention inserted in the longitudinal direction in the passageway, between the switching network terminal Ki or Kl and the adjacent coupling point Hi or HA. According to the invention, between this diode / 73 or DA and the relevant adjacent coupling point Hi or HA , in each case in the transverse direction to the established connection path, the second connection

Terminal resistor 52 attached Each of these terminal resistors can therefore be regarded as a component of the coupling field connections Ki, Kl , since these terminal resistances are attached to the coupling field connections. In addition, in this exemplary embodiment, the first connection resistor S1 is attached between this diode and the relevant switching matrix connection in each case in the transverse direction / around the connecting path constructed.

Because of the connection resistors 52, the operating direct current, which flows in the established connection path via the coupling points Hl, tfi or H2, H4 , is shown in two direct current components at that circuit point at which the connection resistors 52 are connected to the connection path. D "'is a direct current component flowing through the terminal resistor 52, and this DC component is at least slightly exceeds according to the invention the holding power of the coupling point contacts the other direct current component flows through the diode Di and D4 -. In this embodiment without further branching - in each case by the first terminal of resistors 51, by In the present exemplary embodiment, the switching network connections Ki and K2 are blocked with the aid of capacitors C. Here it is provided that the operating synchronism in a connection path established between each of the interconnected switching network connections / Cl. K2 and the respective coupling point Hi or .f / 4 branches out into only two DC components, each of these two DC direct current components is smaller than the total operating DC current, and each of these two DC components is passed through a terminal resistor 52 and 51, respectively Termination resistors according to the invention have a high alternating current resistance, so that the useful alternating currents flowing between the switching matrix connections Ki, K2 are practically not attenuated by the connection resistances.

The interference voltages that can occur at the coupling network connections Ki, K2 cannot cause the holding current in the established connection path to be undershot: even if the diodes Di, D4 provided according to the invention are controlled by these interference voltages into the blocking state, the second connection resistor 52 continues to flow such a large current component that the connection path, once established, is no longer interrupted by the long-lasting interference voltages mentioned. The direct current component flowing through this connection resistor is, according to the invention, greater than the holding current. As long as no such interference voltages in the switching matrix terminals KW, K2 occur, the current flowing in the constructed communication path operating DC current flows each partially through the terminal resistor 52 and partly to the latter terminal resistor 51 is used via the terminal resistor 51. The diode Di and D4 safely conducting to the To control the state as long as no interference voltages occur at the relevant switching network connection.

If such interference voltages occur at the switching matrix connections Ki or K2 during the establishment of a connection path, the operating direct current can also flow with a strength exceeding the holding current at least via the connection resistor 52 if the diodes Di, DU are switched to the blocking state by the interference voltages should. The measure according to the invention also does not prevent the intended construction of a connection path and also offers a guarantee that this construction is carried out without interference even if short or even long-lasting interference voltages, which would be suitable to impair the construction, in the to be connected Switching network connections Ki, K2 should occur.

In a further development of the invention it is provided that the terminal resistor 52 and 51, which has a high AC resistance, respectively an overdriven transistor is formed. Overdriven transistors have namely as connection resistances the excellent "property that they not only have a very high alternating current resistance, but in addition, it also has a particularly small DC resistance. Because of the small DC resistance the connection resistances formed by overdriven transistors are advantageous not only the energy losses of the useful alternating currents, but also that of the operating direct current caused energy losses are particularly low.

If, in the above-mentioned development, the direct current component flowing through the overdriven transistor in question should still be too large and a limitation of this direct current component by reducing the voltage of the battery U or by a different dimensioning of the limiter circuit D is not desired in the present case, it can be used to limit the Direct current component are also provided that in series with the transistor 51 or 52, a member limiting the relevant direct current component, z. B. an ohmic resistor R is located. In this way, the power consumption of an established connection path can be kept particularly low, even if this direct current component is limited by appropriate control of the transistor 51 or 52, e.g. B. is not desirable because of the heating of this transistor.

The connection resistors are also suitable for interrupting the established connection path Serving transistors by at least partially controlling them to the non-conductive state for this purpose.

1 sheet of drawings

Claims (3)

Patent claims: 1. Multi-stage switching network with electronic coupling point contacts according to patent 17 62 661, in particular for public telephone switching systems, characterized in that the operating direct current in a connection path established between each of the interconnected switching network connections (Ki, K2) and the respective coupling point adjacent to the respective switching network connection (Hi, HA) branches into two direct current parts, each of which is activated via a high alternating current resistance having a connection resistance, that in each case at the switching network connection in the longitudinal direction to the relevant connection path between the switching network connection (Ki, K2) and the neighboring coupling point (Hi.HA) for the first direct current component permeable diode (Di, DA) is inserted, that on one side of this diode, namely between this diode (Di. DA) and the relevant adjacent coupling point (Hi. H4), the second connection resistor ( 52), which absorbs a direct current component which at least slightly exceeds the holding current, is attached. and that on the other side of this diode (Di. DA) the first connection resistor (51), which absorbs the second DC component, is connected. 2. Multi-stage switching network according to claim 1, characterized in that the connection resistance is formed by an overdriven transistor. 3. Multi-stage switching network according to claim 2, characterized in that the transistor is in series with a member (R) limiting the direct current component.