DE1209606B - Electronic chain switch for successive, brief switching of the received pilot frequencies to a common amplifier in a method for setting orthogonal equalizers for multi-channel carrier frequency transmission systems - Google Patents

Description

Electronic chain switch for consecutive, short-term Switching the received pilot frequencies through to a common amplifier a method for setting orthogonal equalizers for multi-channel carrier frequency transmission systems Addition to the patent: 1143 236 The main patent relates to a method for setting of orthogonal equalizers for attenuation and transit time equalization, in particular of Cosine equalizers for multi-channel carrier frequency transmission systems in which the Obtaining the setting criterion by transmitting constantly sent pilot voltages takes place, the frequencies of which are distributed over the frequency range of the transmission system are evaluated and their level at the receiving end and for setting the orthogonal equalizer to be used. The setting of the individual equalizer elements is automatic one after the other by means of adjusting devices that operate purely electronically carried out gradually.

The individual pilot voltages are each received via a Filter sifted out and a chain switch which is a fully electronic device with bistable flip-flops and diode gates can be supplied to the pilot voltages one after the other from the lowest to the highest frequency and vice versa in the rhythm of one low-frequency repetition or clock frequency (e.g. 1000 Hz) periodically switches a common high-frequency amplifier with a downstream rectifier.

The time constant of the rectification is chosen so that on Output of the rectifier is the low-frequency envelope of the sampled pilot voltages, d. H. the repetition or clock frequency and its harmonics appear. This envelope represents a time-periodic voltage curve, which is to be equalized Simulates the attenuation curve of the transmission path and its spectral amplitudes the amplitudes of a series of orthogonal functions, in particular a cosine series, correspond. This low-frequency voltage is broken down into its components by band filters decomposed, and the low-frequency components filtered out become automatic Setting the cosine equalizer used.

It is already known to use a reversible shift register as a chain switch (German patent specification 1172 319). For n pilot frequencies, the shift register consists of n bistable trigger circuits (flip-flops). A clock provides the incremental pulses for the chain switch, so that each clock pulse shifts the excited state of the shift register from one flip-flop to the next. The counting direction is determined by a special directional flip-flop that is controlled by the first and last flip-flop of the shift register. In one position of the directional flip-flop, the shift register switches forwards (from the first to the last flip-flop). When the last flip-flop of the shift register is excited, it switches the directional flip-flop to the other position and the shift register counts down. When the first flip-flop is excited, it switches the directional flip-flop back to the first position and the shift register counts up again. This game is repeated as often as you like.

However, this circuit is prone to failure. It can happen that in addition to the one excited flip-flop of the shift register, another is excited by a glitch. Then the counting cycle of the shift register shortened by as many steps as the number of flip-flops between the two excited flip-flops located flip-flops is. There are always two pilot voltages at the same time switched through. Of course, the number of simultaneously excited flip-flops also be bigger than two. In any case, the whole function of the procedure is grave disturbed, and an incorrect setting of the equalizer elements is the result.

This difficulty is eliminated according to the invention that once within each counting cycle from the first or from the last flip-flop of the shift register in its excited state the rest Flip flops by one Feedback pulse can be influenced so that they are not excited.

An exemplary embodiment of the invention is illustrated with reference to FIGS. 1 explained. For the sake of simplicity, a shift register with only five flip-flops is considered. F1 to F5 are the flip-flops of the shift register. F ,. is the directional flip-flop. (Circuit symbols were selected in accordance with DIN standard 40 700.) Have in the excited state the outputs A1 to A5 of the transistorized flip-flops of the shift register den State 0, i.e. i.e. the transistors in the upper field are blocked.

First of all, the first flip-flop F1 is excited. Then is at the input E, .1 of the directional flip-flop F ,. the value 0, and its output Ar, has the value 1. The static inputs of the logic elements V12, V23, V34 and V45, which are at the output Arl, also have the value 1, and the shift register can count up. In addition, the base of a transistor Ts receives the value 1 from the output As of the flip-flop F1, Ts is blocked, the static feedback inputs ER2, ER3, ER4 and ER5 of the upper fields of the remaining flip-flops F2 to F5 receive the value 0, and these flip-flops are held in the non-excited state. Even if some of these flip-flops were erroneously excited, they are returned to the non-excited state.

The next four clock pulses from the clock generator TG shift the excitation state of the shift register to the last flip-flop F5. Then the input Er2 of the directional flip-flop F, receives. the value 0, F ,. switches to the other position and its output Are receives the value 1. The static inputs of the logic elements V21, V32, V43 and V54, which are connected to the output Are , also have the value 1, and the shift register can only count backwards.

The resetting of the flip-flops F2 to F5 is only done in position 1 of the shift register.

F i g. 2 shows the circuit of the logic elements V12, V23, Y341 Y451 V211 v32, V43 and V54. The capacitor C differentiates the transition edge from 0 to 1, and a 1-pulse appears at the output of diode D, if at the resistor R is also a 1.

The flip-flops of the shift register and the directional flip-flop have Base leakage resistors between the base terminals of the transistors and Ground potential are arranged. The feedback inputs ER2, ER3, ER4 and ER, as well as the inputs Er, and Er2 of the directional flip-flop are expediently designed in such a way that that the associated base leakage resistors are not directly connected to ground potential, but are connected to the aforementioned input terminals. During the return of the Shift registers or the flip-over of the directional flip-flop receive the associated Transistors across the base leakage resistors base current and become conductive. Located If the first flip-flop F1 is in the non-excited state, the collector of the transistor Ts and thus the feedback inputs almost ground potential, and the others Flip-flops can be stimulated. The basic leakage resistances of the Directional flip-flops at ground potential if the first or the last flip-flop of the shift register is not excited.

The resetting of the shift register by something other than a corner flip-flop does not guarantee that no errors will occur in the case of the reset flip-flop is not excited and the reset is prevented.

The resetting of the flip-flops of the shift register can also be done by the directional flip-flopF, because this is done simultaneously with the first or the last flip-flop of the shift register is operated. However, it must be included the output pulse of the directional flip-flop can be differentiated because this flip-flop changes its state only twice in each cycle, while the default only changes may work for a short time.

The reset by the first or last flip-flop of the shift register prevents all chain switch failures except in the event that all flip-flops are not stimulated. In this case the chain switch stands still, and not a single one Pilot voltage is switched through. This error can be caused by an automatic setting the cosine equalizer present control circuit that detects the missing pilot voltage responds, can be remedied by adding this control circuit to any flip-flop of the shift register stimulates briefly.

Claims (5)

Claims: 1. Electronic chain switch for successive, brief switching through of the received pilot frequencies to a common amplifier in a method for setting orthogonal equalizers for multi-channel carrier frequency transmission systems, in which the setting criterion is obtained by transmitting constantly transmitted pilot voltages, the frequencies of which are over the frequency range of the transmission system are distributed and their receiving-side level is evaluated and used to set the orthogonal equalizer, in that the individual pilot voltages are each filtered out through a filter and fed to a chain switch that switches the pilot voltages one after the other from the lowest to the highest frequency and vice versa in the rhythm of a low frequency Repetition frequency (e.g. 1000 Hz) switches periodically to a common high-frequency amplifier with a downstream rectifier, according to patent 1 143 236, with a chain switch on reversible shift register from a number of bistable multivibrators (flip-flops) is used, gekennzeichn et that once within each counting cycle from the first or last flip-flop of the shift register in its excited state, the remaining flip-flops are influenced by a feedback pulse that they are not stimulated. 2. chain switch according to claim 1, characterized characterized in that the resetting of the remaining flip-flops (F2 to F5) of the shift register happens from the first flip-flop (F1) via a transistor (Ts). 3. Chain switch according to claim 1 and 2, in which base leakage resistances in the flip-flops of the shift register are arranged between the base connections of the transistors and ground potential, characterized in that one of the flip-flops to be reset (F2 to F5) Matching base leakage resistance (in Fig. 1 the base leakage resistance of the den upper fields of the Flip-flops associated transistors) not directly with ground potential, but with the collector of the additional transistor (Ts) connected is. 4. chain switch according to claim 1, wherein the counting direction of the shift register by a directional flip-flop controlled by the first and last flip-flop of the shift register is determined, characterized in that the resetting of the flip-flops of the shift register is made by the directional flip-flop (Fr) with differentiated pulses. 5. Chain switch according to claim 1, in which in the automatic setting the cosine equalizer has a control circuit is present, which responds to the lack of pilot voltage, characterized in that that this control circuit when responding to any flip-flop of the shift register briefly stimulates.