DE1159033B - Fully electronic remote control device for remote control of additional equalizers for multi-channel carrier frequency wide-area systems - Google Patents

Description

Fully electronic remote control device for remote control of additional equalizers for multi-channel carrier frequency wide area systems The invention relates to a fully electronic one Remote control device for remote control of additional equalizers for multi-channel carrier frequency wide-area systems, in the case of a remote control office, the individual equalizers that lead to different Coaxial lines or coaxial pairs belong in one cable and in different ones Main offices are appropriate, one after the other for automatic adjustment be initiated.

Long-distance carrier frequency systems in the main offices, which occur every 50 to 100 km, are equipped with additional equalizers, which are intended to equalize the residual distortions that are not recorded by the line control. These are orthogonal equalizers, e.g. B. Cosine Equalizer. In the older systems these additional equalizers were set by hand, while the newer systems received additional equalization that worked automatically (German patent 1130002).

So that several additional equalizers working simultaneously do not influence each other in a transmission path, it is expedient to cause the individual additional equalizers to set one after the other from a terminal office, the remote control office, by means of a remote control. After an equalizer has been set, it should send a feedback signal to the remote control office, and then the remote control should automatically activate the next equalizer. In the event of a malfunction, i . if the setting process does not proceed properly in any equalizer, this should be indicated in the remote control office after a certain time, an alarm should be triggered and further regulation should be interrupted. In order to be certain that the equalizer according to the program has really been set, the feedback signal should be used for checking purposes. and if this check is negative, an alarm is to be triggered and further regulation to be interrupted.

A cable can contain several tubes; with p tubes there are p / 2 independent systems. In this case it makes sense to use a common remote control system for the entire cable. In addition, the remote control system can be used jointly for several cables and especially for branches.

The object on which the invention is based is explained in more detail below with reference to FIGS. 1 and 21. In Fig. 1 , the remote control system for m main offices is shown schematically. From the remote control office FZ the main offices H are to H ", causes on the LeitungL1 successively for the automatic adjustment of its equalizer, each of which a feedback signal via the Uitung L 2 at the end of their setting automatically return to Fernsteuerarnt. In Fig. 2, the remote control device is in a Main office shown schematically with p equalizers E 1 to Ep. The control signal receiver SE switches through one of the switching devices DE 1 to DEp when it receives a corresponding control signal St-S, so that the automatic setting EA, which is only present once in the main office, actuates the associated equalizer At the end of the setting process, the automatic setting system EA causes the feedback signal transmitter RS to send back a feedback signal Rm-S to the remote control office.

Remote control systems are known (E. Baranowski: "A remote control system for shortwave transmitters" in "Telecommunications Journal" NTZ, 1962, Issue 2, pp. 79 to 83) which are remotely controlled via WT channels. They are mainly equipped with relays, so they require a great deal of power and space and work relatively slowly. The necessary WT facilities for the sender and receiver mean additional work.

A fully electronic remote control device to trigger the automatic Adjustment and regulation of the equalization elements of additional equalizers for multi-channel carrier frequency wide area systems, in the case of a remote control office, the individual equalizers that lead to different Coaxial lines or coaxial pairs belong in one cable and in different ones Main offices are attached, caused one after the other for automatic recruitment and the completed setting of each equalizer is reported back to the remote control office will, will realized according to the invention that over one of the coaxial pairs or individual control signals via an accessory cable from the remote control office sent out and received in every main warning and there a known, Activate the irreversible, 11-step binary reception counter, which counts after the reception the corresponding remote control pulses the corresponding equalizer for setting causes, and that after completion of the adjustment process of each equalizer a binary coded feedback signal to the remote control office with the help of the reception counter is sent back that sets n independent flip-flops of the coding accordingly and an automatic coincidence measurement with one running in the remote control office Comparison counter initiated for the purpose of error control.

For example, the control and feedback signals can be transmitted as sampled alternating voltages with a constant control carrier frequency and these signals can be filtered out, amplified, rectified and checked for the correct pulse duration using a pulse filter known per se (German patent specification 1133 754), which only evaluates pulses of the prescribed length and receive. This ensures that no incorrect pulses can interfere with the remote control.

The mode of operation of the irreversible binary counter used is explained on the basis of the schematic representation of a four-stage, preferably transistorized counter in FIG. 3 . The left outputs (collector connections of the transistors) AW A211 A 31 of the flip-flops F "F, and F, are connected via capacitors C and diodes D to the inputs E., E., or E. 1, E32 or ZW-E41, E4, connected to the next flip-flop.

If the inputs Eil, E U of the first flip-flop Fi receive pulses from a pulse source, the counter changes its position with each pulse. In Fig. 3 the initial position of the counter is shown, with all left transistors conductive and all right transistors blocked (see circuit symbols in Valvo: "Technische Informations fürdielndustrie", issue 14, February 1962, pp. 1 to 4). The following table shows the possible positions of the four-stage counter, whereby the conducting state of a transistor is designated with "0" and the blocked state with "L" and the left and right columns for the left and right transistors of the individual flip-flops are valid: Position F, F, F. F ,. 1 0 L 0 L 0 L 0 L. 2 L 0 0 L 0 L 0 L 3 0 L L 0 0 L 0 L. 4 L 0 L 0 0 L 0 L 5 0 L 0 L L 0 0 L. 6 L 0 0 L L 0 0 L 7 0 L L 0 L 0 0 L. 8 L 0 L 0 L 0 0 L. 9 0 L 0 L 0 L L 0 10 L 0 0 L 0 L L 0 11 0 L L 0 0 L L 0 12 L 0 L 0 0 LL 0 13 0 L 0 L L 0 L 0 14 L 0 0 LL 0 L 0 15 0 L L 0 L 0 L 0 16 L 0 L 0 L 0 L 0 A counter with n flip-flops can assume 2n different positions. Each position of the counter can be assigned a switching transistor that only becomes conductive when the counter has assumed the position corresponding to it. A switching transistor in the kth position is connected with its base via n diodes Dk to the outputs of those transistors of the n flip-flops which are blocked in the kth position of the counter.

For n = 4 and k = 9 , FIG. 4 shows the Ari coupling of the switching transistor Ts9 via n = 4 coupling diodes Dk to the corresponding outputs A ″, A221 A32e A41 of the binary counter not shown in detail in FIG.

If only one of the aforementioned diodes Dk is on the collector of one conductive transistor (outputs of flip-flops F to FJ, so it also holds the base of the associated switching transistor at low potential, and it remains blocked. Only when all diodes Dt are blocked, the base of the switching transistor receives Ts. Sufficient forward potential from the operating voltage source Ul # via the base series resistor R, and the switching transistor becomes conductive. Thus, in every position of the counter only one switching transistor conducting, while all other switching transistors remain blocked.

The sequence of the equalizers to be set is chosen so that always one transmission system - first the tube of one transmission direction and then the tube of the other transmission direction - is completely equalized before the next system is activated. A receiver with a binary reception counter according to FIG. 3 is thus provided in each main office, which, with p tubes and m remote-controlled main offices, successively activates p different switching transistors according to FIG. by switching the automatic setting of the equalizer, which is also common for all tubes of an office, through to the corresponding equalizer via diode gates (Fig. 2). The reception counter must therefore be off - Rounded up to an integer n - consist of levels.

The operation of the feedback signal transmitter RS schematically illustrated in FIG. 2 will be explained with reference to the block circuit in FIG. 5. So that the feedback signal Rm-S corresponds to the equalizer that has just been set, the reception counter EZ of the control signal receiver SE is also used for coding. A known ring counter RZ (German patent specification 1130 002) with at least n + 1 steps is also used for coding, which is present in the automatic setting system in every office. In addition, there is a monostable multivibrator M, with a pulse duration that is slightly longer than the duration of the feedback signal, another monostable multivibrator M, with a pulse duration that is equal to a character duration of the feedback signal, an astable multivibrator TG1 as a clock with a frequency , which is equal to the repetition frequency of the characters of the feedback signal, and a sine generator G1, which generates the carrier frequency for the feedback pulses, is present.

When the setting of an equalizer is finished, the automatic setting system, not shown in FIG. 5, sends a pulse to the input E1 of the monostable multivibrator M, which responds for the duration of a feedback signal and releases the clock TG via the holding diode Dj. The clock generator has two outputs at which pulses occur one after the other at the same time interval. One output A, supplies pulses to the parallel-connected inputs of the diode gate Ti and the n - = 4 diode gates T "while the second output A., supplies incremental pulses for the ring counter which are offset by the clock time compared to the pulses from output A , is only controlled by the first flip-flop of the ring counter and lets the first preparation pulse through to the input E, of the multivibrator M. The flop of the receiving counter EZ and the corresponding flip-flop of the ring counter RZ unlock the diode gates simultaneously via the resistors R. The ring counter, which is advanced by the incremental pulses, unlocks one diode gate in succession at the rate of the incremental pulses to the input E 2 of the multivibrator M., which just the position de s binary counter - corresponds to. The multivibrator M "is activated by each pulse that occurs for a period of time and, via the holding diode Dh2, enables the sine wave generator G, which outputs an alternating current pulse to the line.

The mode of operation of the feedback signal receiver in the remote control office and the subsequent control devices is explained below using the schematic circuit in FIG. The feedback signal receiver consists of an amplifier V, rectifier Gl and an above-mentioned and known pulse filter F. To evaluate the feedback signal, there is also a monostable multivibrator M 3 with a pulse duration that is slightly longer than the duration of the feedback signal, an astable multivibrator TG 2 as a clock with a frequency that is equal to the repetition frequency of the characters of the feedback signal, a binary auxiliary In n counter HZ with - ] n2 - rounded up to an integer value - levels, a binary comparison counter VZ with n = 4 levels and n + 1 individual flip-flops Bi to B " and B. The output of the pulse filter F is also via n diode ports Th, which are supplied by the auxiliary counter HZ via the resistors Rh and via connections, not shown in the figure, between the associated terminals K, K2, K3 , K, are connected to the inputs of the n = 4 flip-flops B to Bn.

When a preparation pulse is received, the multivibrator M, responds and releases the clock generator TG, via the locking diode Dh 3 , which emits a pulse to the auxiliary counter HZ after a certain small delay, which is followed by further pulses in the rhythm of the clock frequency. At the same time brought about the only permeable Diodentor of th flip-flop B "(in the illustrated embodiment, B) in the time necessary to receive the feedback signal position, namely the same position as B, B, etc. The Fort switching pulses from the clock generator TG 2 let the auxiliary counter HZ take its n possible positions one after the other in the rhythm of the clock and symbol frequency and successively switch through the n diode gates Th so that the n possible feedback pulses can activate the corresponding flip-flops B to B "in their chronological order. If any pulse is missing, the corresponding flip-flop also remains in its old position.

The comparison counter VZ, which is constructed in the same way as the receive counters present in the control signal receivers and is actuated by the transmitted control pulses, has the position that the receive counter that has just been reported back should have. If the correct equalizer reports back, the flip-flops of the comparison counter and the corresponding flip-flops B to B "have the same position. This coincidence is evaluated, for example, so that after receiving the feedback signal from the monostable multivibrator M 3 when it returns in its rest position emitted pulse via 2 "diode gates T", which are controlled in pairs by the associated coinciding flip-flops Bi to B "and those of the comparison counter and which work on two identical primary windings of a differential transformer ÜL), is sent.

The same pulse voltages will arise on both windings of the n differential transformers, the series connection W, the secondary windings of the above-mentioned differential transformers VI, will remain de-energized, the input E of the flip-flop B will not receive an excitation pulse and thus the flip-flop B will not respond. A monostable multivibrator M, also stimulated by the multivibrator M when it returns to its rest position, with the pulse duration of a control pulse, releases the sinus generatorG, not shown, which is present in the remote control office and which emits a further control pulse.

If there is no coincidence between the flip-flopsB1 due to an error bisB, and the flip-flops of the comparison counter VZ, so arises in any Primary winding of the transformer ül) a pulse voltage that is not due to the same Pulse voltage in the associated winding is compensated, and the flip-flop B, that from the series connection W, the secondary windings of the differential transformer contains an impulse, triggers an alarm and prevents it by holding the multivibrator M4 sends out a further control pulse via the retaining diode Dh4.

Possible asymmetry errors of the differential transformer ül) preferably rendered harmless by not using any for the transmitters, whose hysteresis shows a rectangular shape and at which the output voltage is only then builds up when the resulting magnetic flux of the core a certain has exceeded a fixed value (response threshold).

Claims (2)

PATENT CLAIMS: 1. Fully electronic remote control device for triggering the automatic setting and control of the equalization elements of additional equalizers for multi-channel carrier frequency wide-area systems, in which the individual equalizers belonging to different coaxial lines or coaxial pairs in a cable and are installed in different main offices from a remote control office , timed one after the other for automatic setting and the completed setting of each equalizer is reported back to the remote control office, characterized in that individual control signals are sent out via one of the coaxial pairs or via an accessory line from the remote control office and received in each main office and there is one per se Actuate known, irreversible, n-stage binary reception counter which, after receiving the corresponding remote control pulses, causes the corresponding equalizer to set, and that after the setting process has been completed each equalizer a binary-coded feedback signal is sent back to the remote control office with the help of the receive counter, which sets the independent flip-flops according to the coding and initiates an automatic coincidence measurement with a comparison counter running in the remote control office for the purpose of error control. 2. Remote control device according to claim 1, characterized in that the remote control signals and the feedback signals consist of one or more sampled AC voltage pulses of a suitable carrier frequency and duty cycle. 3. FernsteuereinrichtungnachAnspruchlund2, characterized in that the receivers for the remote control signals and feedback signals consist of a filter, amplifier, rectifier, pulse shaper and a pulse filter known per se, which checks the pulses for the correct duty cycle. 4. Remote control device according to claim 1, characterized in that the receiving counter per coaxial tube controls a switching transistor after receiving the corresponding remote control pulses, which causes the corresponding equalizer to adjust by the automatic setting of the equalizer, which is also for all coaxial tubes in one office is common, is switched through to the corresponding equalizer. 5. Remote control device according to claimlund4, characterized in that the switching transistors (Tsg) are connected via n coupling diodes (Dk) to the corresponding outputs (A12, A22, A321 A,) of the n flip-flops (F, ... F,) of the receiving counter and that each switching transistor has a base series resistor (R,) which connects its base to the pole (UB) of the operating voltage source assigned to the collector side (FIGS. 3 and 4). 6. Remote control device nachAnspruchlund2, characterized in that a ring counter (RZ) with at least n + 1 levels in the automatic setting of the equalizer in each main office is used to encode the feedback signal, so that at the end of the setting of the equalizer, a pulse from the automatic setting is a monostable Multivibrator (M) excites for the duration of a feedback signal , which releases a clock generator (TG,) via a holding diode (DI "), which in turn sends pulses from an output (A,) to the parallel-connected inputs of the receive counter (EZ) and by the ring counter (RZ) controlled n diode gates (T ") supplies and the incremental pulses for the ring counter (RZ) offset by half a clock time from a second output (A2) , and that one pulse in each case via one of these diode gates to a further monostable Multivibrator (M.), which in an excited state releases a sine wave generator (G iLur a duty cycle, only comes when this diode tor is unlocked by both the reception counter (EZ) and the ring counter (RZ) (Fig. 5). 7. Remote control device according to claim 1, 2 and 6, characterized in that a first pulse is triggered as a preparation pulse of the feedback signal via a diode gate (T) which is controlled by the first flip-flop of the ring counter (RZ) alone (Fig. 5 ). 8. Remote control device according to claim 1, 2, 3, 6 and 7, characterized in that the preparation pulse of the feedback signal in the remote control office stimulates a monostable multivibrator (M.) for the duration of a feedback signal via a holding diode (Dh ") a clock ( TG.) , Which in turn activates a binary auxiliary counter (HZ) with Inn steps, that the auxiliary counter in 2 (HZ) according to its different possible positions in time one after the other in a corresponding rhythm to the output of the feedback signal receiver via diode gates (T1,) controlled by it n independent flip-flops (B, bisBn) switches through, and in that the individual pulses of the feedback signal set-flops flip according to their encoding these (Fig. 6). 9. FernsteuereinrichtungnachAnspruchlund8, characterized in that the coincidence between the n independent flip-flops ( B, to B ") and the comparison counter (VZ) running in the Ferrtsteueramt is measured in such a way that a after receipt of the Feedback signal from the monostable multivibrator (M ") when it returns to its rest position, transmitted pulse via 2n diode gates (T"), which are controlled in pairs by the associated coinciding flip-flops (B, to B,) and those of the comparison counter (VZ), is applied to two identical primary windings of a differential transformer (VD) and that the series connection (W,) of the secondary windings of the n differential transformers (VD) is connected to the input (E.) of another flip-flop (B,) (Fig. 6). 10. Remote control device according to claim 9, characterized in that in the case of coincidence the flip-flop (B,) controlled via the secondary windings of the differential transformer (Vp) is not excited and that another monostable multivibrator (M,), which is excited simultaneously with the coincidence measurement is, releases a sine generator (G2) for a duty cycle, which sends out another control pulse (Fig. 6). 11. Remote control device according to claim 9, characterized in that in the event of incoincidence the flip-flop (B,) via the series connection (W,) of the secondary windings of the differential transformer (Ü [»is excited, triggers an alarm and in turn via a retaining diode (Dh 4) holds the monostable multivibrator (M4) controlling the sine wave generator (G.) so that no further control pulse is emitted (Fig. 6).