NO145969B - WIRELESS AMPLIFIER FOR FIRETRAAD INFORMATION TRANSFER DEVICES. - Google Patents

Description

The invention relates to a line amplifier for four-wire information transmission devices, containing two directional amplifiers which are connected in parallel with respect to direct current via a connection line, and a localization generator whose output signal is fed into both transmission devices, while the connection line is led over at least two disconnecting links.

Such a power amplifier is known, cf. Siemens Zeitschrift

45 (1971), booklet 12, pages 905-911, especially picture 6. In this case, intermediate amplifiers which are distributed over a transmission line are each provided with their own localization generator.

If the localization frequency produced by such a generator is to be fed into both directional amplifiers of an intermediate amplifier or line amplifier that is part of a four-wire transmission path, then it must be ensured that this ratio does not influence the required values for crosstalk attenuation between the two transmission directions.

In the case of the known line amplifier, the localization generator is therefore built up next to one of the two directional amplifiers and the localization signal is led over a direct current connection line which leads to another directional amplifier. With such a structure, it is necessary, among other things, a separate, shielded chamber for the localization generator next to the one directional amplifier as well as two additional pins to separate the respective localization signal from the supply direct current.

The task of the invention is to provide instructions for such a design of a line amplifier of the type indicated at the outset, that firstly the extra pens can be dispensed with and secondly a constructively favorable structure is made possible without the localization generator influencing the crosstalk attenuation between the two directional amplifiers.

In order to solve this task, according to the invention, the line amplifier is designed so that the location generator is connected to the connecting line at a place that lies between the decoupling and shoe bends.

With this precaution, the advantage is obtained that the feed inputs

until the two directional amplifiers, by means of the decoupling links, are high-frequency decoupled, not only from each other, but at the same time also from the feed input of the location generator.

As a further design of the object of the invention, the line amplifier is made so that the localization generator's output is led to the directional amplifier's inputs via a single wire, and that the localization generator's reference potential is connected via a capacitor to the amplifier part's reference potential. A defined connection of the localization signal in the two transmission paths is thus obtained in a favorable manner.

The four wires resp. Coaxial cables that end at the line amplifier are suitably connected with their outer conductors to the metallic amplifier capsule that accommodates the two directional amplifiers. As a further development of the invention, the line amplifier is simultaneously designed so that the localization generator is arranged in an external recess in the amplifier capsule which accommodates the two directional amplifiers, and with its reference signal via a capacitor is connected to the amplifier capsule, which with regard to alternating voltage is at the potential of the cable outer conductor. Such an arrangement of localization generator and directional amplifiers offers particularly favorable conditions for routing both the connecting line that runs between the directional amplifiers' feed and direct current inputs, and the single-wire supply lines. which serves to enter the localization frequency in the two transmission paths.

The external recess which serves to accommodate the localization generator is suitably provided by the outer walls of the amplifier capsule being meander-shaped in such a way that a groove-shaped recess is obtained to accommodate the localization generator. At the same time, the localization generator is preferably designed as flat or leader building group and placed lying in the recess. If the recess is provided with a cover, it is not necessary to use a separate capsule for the localization generator flat building group.

As a further development of the inventive idea, the line amplifier is designed so that the localization generator's output is fed to the two directional amplifiers' inputs via one and one adjustable damping link. These damping elements are then appropriately dimensioned so that a damping that increases with the frequency is obtained. At the same time, the attenuators serve advantageously for high-frequency decoupling of the directional amplifiers from one of the levels of the localization signal.

A particularly favorable structure for the line amplifier is achieved by the fact that the amplifier capsule has a right-angled parallelepiped shape, and that the recess is located on the side of one of the medium-sized surfaces of the parallelepiped, and that approximately in the middle between the two largest surfaces of the parallelepiped there is a dividing wall that reaches the recess and serves to separate the two directional amplifiers. In that case, the openings in the side walls of the amplifier capsule's recess through which the localization generator's output leads reach the directional amplifiers are arranged diametrically opposite each other.

In the following, the invention will be explained in more detail by way of examples which are illustrated in the drawing. Fig. 1 is a connection core for a line amplifier with two directional amplifiers and a location generator.

Fig. 2 shows a section of the current flow in fig. 1, and

fig. 3 shows an amplifier capsule with a recess to accommodate a location generator.

Fig. 1 shows the diagram for an intermediate amplifier or line amplifier for a broadband low frequency transmission system. The information to be transmitted is amplified in one direction by the directional amplifier 5 and in the other direction by the directional amplifier 6. The directional amplifier 5 is located between the incoming coaxial cable 11 and the outgoing coaxial cable 12. The directional amplifier 6 is inserted between the incoming coaxial cable 13 and the outgoing coaxial cable 14.

The intermediate amplifier, together with the additional intermediate amplifiers on the transmission line, is remotely fed in series with direct current. In the case of such a remote feed, as is well known, a remote feed direct current is fed into the inner conductors of the cables 11 and 14 in one of the end stations. At the other end of the transmission line, the inner conductors of the cables 12 and 13 are connected to each other with regard to direct current to terminate the remote power supply circuit.

Between each of the cables 11 - 14 and the respective directional amplifier 5 or 6, one and a pair of clamps 15 - 18 are arranged there. These clamps 15 - 18 have the task of separating useful signals, whose frequency range does not reach down to frequency 0, from the remote supply direct current. On its way from the cable 11 to the cable 12, the remote feed current is led over the direct-current parallel connection of the directional amplifiers 5 and 6 and the location generator 40, under which the connection line 75 is inserted between the low-pass filters or pins 15 and 16 for this one transfer direction. In the other transmission direction, the direct current is led past the directional amplifier 6. For this purpose, the inner conductors of the cables 13 and 14 are connected to each other via a series connection of chokes 71 and 72. For high-frequency disconnection of the feed inputs to the directional amplifiers 5 and 6 serve line chokes 44 and 45. These line chokes 44 and 45 have two mutually magnetically coupled windings with the same number of turns. In each conductor of the connection line 75 is one of the two windings. The winding direction for the two windings is chosen so that the choke is inactive for symmetrical signals, while signals that run in the same direction over both conductors and are thus asymmetrical, undergo a large attenuation.

The line chokes 44 and 45, whose chain connection is included in this connecting line 75, ensure that sufficient crosstalk attenuation occurs between the directional amplifiers 5 and 6. Between these line chokes 44 and 45, the feed input for the location generator 10 to the connecting line 75 is connected. In this connection, the line chokes 44 and 45 are also advantageously utilized for decoupling between the localization generator 40 and the directional amplifiers 5 and 6.

Thanks to the direct current parallel connection of the feed inputs or the power supply connections, a parallel connection is obtained by the consumer resistors 50, 60 and 49 active at the feed inputs, which are formed by the directional amplifiers 5 and 6, resp. the location generator 4. The feeding direct current that flows via the inner conductors of the cables induces a voltage drop across this parallel connection, namely the feeding direct voltage.

With the feed inputs, there is an output capacitor 35 and a Z-diode 36 connected in parallel. This Z-diode 36 is not absolutely necessary and appropriately has a Z-voltage which is somewhat higher than the DC supply voltage, so the diode normally does not conduct current and only has a voltage limiting effect. However, it can optionally serve as a voltage source which, based on the supply current, produces a constant DC voltage.

The outer conductors of the coaxial cables 11 - 14 are connected to each other, namely in that they are connected to one and the same amplifier capsule. The directional amplifier building groups and the localization generator building group are connected by this cable outer conductor^connection or with the amplifier capsule over a separate capacitor 34,

95, 41 which acts as an unblocking capacitor and brings the relevant building group's goods connection in terms of alternating current to the potential of the cables' outer conductors, i.e. to the b-potential a.

The localization generator 40 sends a signal with a characteristic identification frequency for the relevant underground low-frequency coaxial line amplifier into the input clamps 15 and 17 of the two directional amplifiers 5 and 6. A defined input of the localization signal takes place via a .and a single-wire supply line from the localization generator - the building unit 4 directly to the two input clamps 15 and 17 for the directional amplifiers 5 and 6. Thereby, extra precautions for leakage are no longer required.

The output from the localization amplifier 40 is fed to the inputs of the directional amplifiers 5 and 6 and a T-junction. One T-connection consists of longitudinal resistors 42 and 22 and a parallel connection of two capacitors 23 and 24 located in the transverse branch. The other T-connection consists of longitudinal resistors 43 and 26 and a parallel connection of capacitors 27 and 28 in the transverse branch. The on-switching of the fault location signal takes place via the R, C, R damping links 42, 23, 22 resp. 43, 27, 26 in the entrance fees.

Damping joints 42, 23, 22 resp. 43, 27, 26 have, with regard to crosstalk attenuation for the useful bands above the localization frequency, an R, C, R structure, so they have an attenuation that increases with frequency.

The capacitors 24 and 28 are designed as trimmers, so it becomes possible to set the attenuation and thus the level of the localization signal that arrives at the input of the respective directional amplifier 5 or 6.

The localization generator's internal resistance, which lies as transverse resistance in the connection path between the clamps 16 and 17, is, with a view to strong crosstalk attenuation between the localization signal lines 470 and 480, suitably significant - especially approx. two orders of magnitude - less than the values of resistors 22, 42, 43

and 26 in the longitudinal branches. In a favorable embodiment, the values of the resistors 22, 42, 43 and 26 are each 7.5 kN and the capacitive internal resistance of the location generator 75 fi at 4 MHz.

Between the cable 11 and the directional amplifier 5 or between the cable 13 and the directional amplifier 6 there is arranged a line choke 33 or 93.

The useful signal comes from the inner conductor of the cable 11 via the capacitor 92 and a winding on the line choke 33 to the voltage-carrying connection at the input of the directional amplifier 5. The outgoing cable 12 is connected to the output of the directional amplifier 5 by means of a transformer 38. Between the secondary winding of the transformer 38 and the cable's outer conductor, a capacitor 39 is inserted there.

In the opposite direction, the useful signal comes from the inner conductor of the cable 13 via the capacitor 94 and a winding on the line choke 93 to the voltage-carrying connection at the input of the directional amplifier 6. The outgoing cable 14 is connected via a transformer 96 to the output of the directional amplifier 6. Between the secondary winding of the transformer 96 and the outer conductor of the cable has a capacitor 97.

The path for the remote supply direct current runs from the inner conductor of the cable 11 over the choke 32 to the connection point between the capacitor 31 and a winding on the line choke 33 and from there via this winding to the load connection for the directional amplifier 5. From this load connection the path continues via the parallel connection of the consumer resistors 50, 60 and 49, the thus series-connected resistance 37 and the secondary winding of the transformer 38 to the inner conductor of the cable 12.

In the opposite direction, the feeding direct current flows from the inner conductor of the cable 13 via a winding on the line choke 9 3 and chokes 71 and 72 to the inner conductor of the cable 14.

Of the section of the current flow in fig. 1 which is shown in fig. 2, it can be seen that the localization generator building unit 4 is shielded from the directional amplifiers 5 and 6 by means of the amplifier capsule 8. Of the T-joints between the localization generator 4 and the inputs of the directional amplifiers 5 and 6, the longitudinal resistance 42 resp. 43 directly at the output of the localization amplifier 40 placed in the localization generator building unit 4. From the longitudinal resistors 42 and 43, respectively, a single-wire connection leads to the building units with the directional amplifiers 5 and 6, in which the additional connection elements of the T-connections are included.

From fig. 3 shows further details of the device in the room. The amplifier capsule 8 has a largely right-angled parallelepiped shape and has a partition wall 83 in the middle between the two largest surfaces of the parallelepiped. On one side, the capsule 8 is provided with a recess. This recess has the form of a wide groove, so the amplifier capsule on the side with this recess has a meander-shaped profile.

In recess 82 or on an outer wall of the amplifier capsule 8, the localization generator building unit 4 is arranged. This localization generator building unit 4 is designed as a plate building group and placed horizontally in the recess. Thanks to this device, the location generator building unit 4 is electromagnetically shielded against the two directional amplifiers 5 and 6, which are placed in the interior of the capsule.

The load potential of the plate building group is via the capacitor 41 connected in terms of alternating voltage to the amplifier capsule 8. From the resistors 42 and 43, which are located on the plate building group's conductor plate, single-wire connection lines, 470 and 480, respectively, lead through one and one opening 47, respectively. 48 in the amplifier capsule 8 for the directional amplifiers. Corresponding to the location of the directional amplifiers on the two sides of the side wall 83, the openings 47 and 48 are arranged diametrically opposite each other.

Something that is not shown in more detail in fig. 3, is how the line chokes 44 and 45 are positioned. These can either be placed together with the respective connected directional amplifiers, i.e. in different chambers of the amplifier capsule 8 or together on the localization generator conductor plate. The connection line 75 is led over the location generator assembly 4, i.e. through the recess 82. For this, the same openings 47, 48 in the amplifier capsule 8 are used as for the lines 470 and 480.

The localization generator 40 is shielded against wiring

the amplifier using the amplifier capsule 8.

The recess which serves to accommodate the location generator 40 is suitably closed with a cover which is not shown in the figure.

Claims (8)

1. Line amplifier for four-wire information-transmission devices, with two directional amplifiers which are connected in parallel 1 ikes tr ønaaes s ig via. a connection line, and with a location generator whose output signal is fed in in both transmission directions, at the same time that the connection line is carried over at least two decoupling links, characterized in that the location generator (40) is connected to the connecting line (75) at a place located between the decoupling links (44, 45). 2. Line amplifier as set forth in claim 1; characterized in that the localization generator's (40) output is led to the directional amplifiers' (5, 6) inputs (51, 61) over one single-wire supply line (470, 480), and that the localization generator's (40) reference potential is connected via a capacitor (41) with the amplifier part's reference potential (B) (fig. 1). 3. Line amplifier as specified in claim 1 or 2, characterized in that the localization generator (40) is arranged in an external recess (82) in an amplifier capsule (8) which accommodates both directional amplifiers (5, 6), and with its reference potential via a capacitor (41) is connected to the amplifier capsule (8), which in terms of alternating voltage is at the potential of the cable's outer conductor. 4. Line amplifier as stated in claim 3, characterized in that one of the outer walls of the amplifier capsule (8) is made meander-shaped in such a way that a groove-shaped depression (82) appears to accommodate the localization generator (40). 5. Line amplifier as specified in claim 4, characterized in that the localization generator (40) is designed as a flat construction group (46) and placed horizontally in the recess (82). 6. Line amplifier as specified in one of the preceding claims, characterized in that the output of the localization amplifier (40) is led to the inputs (51, 61) of the two directional amplifiers (5, 6) via one adjustable damping link (42, 23, 24, 22; 43, 27, 28, 26). 7. Line amplifier as stated in one of the preceding claims, characterized in that the amplifier capsule (8) has the shape of a right-angled parallelepiped, that the recess (82) is located on the side of one of the two medium-sized faces of the parallelepiped, and that there in the middle between the two largest surfaces of the parallelepiped there is a dividing wall (83) which reaches out to the recess and serves to separate the two directional amplifiers (5, 6). 8. Line amplifier as stated in claims 2 and 3, characterized in that an ohmic resistance is inserted in the single-wire connection line within the amplifier, and that the internal resistance of the localization generator (40) is substantially less than this ohmic resistance.