DE3535606A1 - Regenerator for signals in AMI code - Google Patents

Abstract

The main components of the described regenerator for signals in AMI code are a Schmitt trigger (ST), a time decider (ZE) and a code rule violation tester (VP). The AMI-coded signal, and two mutually complementary output signals of the time decider (ZE), are fed via symmetrical base time-lag devices (VZ1, VZ2, VZ3) to the code rule violation tester (VP). The dimensions of the base time-lag devices (VZ1, VZ2, VZ3) are such that, taking into account the typical signal transit times through the Schmitt trigger (ST) and the time decider (ZE), the edges of the delayed AMI-coded signal (SA3) appear exactly one signal element timing period earlier than the assigned edges in the delayed output signals (SA1, SA2) of the time decider (ZE). To avoid the need to equalise the base time-lag devices (VZ1, VZ2, VZ3) again if a deviation from the typical signal transit times occurs, the output signal of the time decider (ZE) is additionally delayed asymmetrically (V1, V2) by a fraction of a signal element timing period, the AMI-coded signal is delayed symmetrically (V3) by a half, and a change-over switch in the code rule violation tester (VP) is replaced by two mutually independent switches. <IMAGE>

Description

The invention relates to a regenerator for signals in AMI code that is sent to the input of a Schmitt trigger are led, at the exit of which a time decider is indicated is closed, two complementary from each other clock signals of the time decider and the AMI-coded Signal via symmetrical basic delay elements Inputs of a code rule violation tester supplied and the code rule violation checker has two thresholds contains comparators, of which one ver equal to the delayed AMI-encoded signal with the lower threshold voltage and the other with the upper Threshold voltage of the Schmitt trigger is carried out.

Such a regenerator is in DE-OS 32 14 555 be wrote; is one of its essential components a code rule violation checker that indicates an error gives the impulse when in the AMI to be regenerated coded signal two positive or two negative pulses occur in succession. The basic mode of operation of the regenerator is that z. B. a positive impulse in the AMI-coded signal via a Schmitt trigger, one Time decision maker and one or more symmetrical Delay elements a preparation signal for the Code rule violation tester triggers by the pre enable signal is enabled (activated), a following positive pulse in the AMI-coded Display signal as code rule error. (Delay equation which are called symmetrical in the following if they rising and falling edges of a signal by the same Delay times; become rising and falling edges  delayed differently are called delay elements asymmetrical). When dimensioning the symmetrical ver Delay elements must be ensured that the Preparation signal triggering positive pulse is not itself to an error-indicating pulse of the code rule injury examiner leads.

In the known regenerator, the symmetrical Delay elements dimensioned so that the preparatory signal exactly by one step clock period of the AMI-coded Signals later at an input of the code rule auditor arrives as the impulse that prepares signal has triggered. This leads to the after part that the delay elements are made for each provided a copy of a regenerator adjusted separately need to be in the delay time of preparation the signal runtimes of the Schmitt-Trig gers and the timekeeper and these times differed from case to case due to the distribution of specimens can be.

Therefore, the invention has for its object a Re generator of the type mentioned at the beginning a comparison of the delay elements because of the copy scatter can be omitted.

This object is achieved in that the delay of the symmetrical basic delay elements so dimensioned is that taking into account the typical ver Delays of the Schmitt trigger and the time ent separator for the delayed output signals of time decision results in a symmetrical total delay, which is one step cycle longer than the symme basic basic delay of the AMI-coded signal, that additional delay elements are provided,  which the output signals of the time decider by one Delay a fraction of the step cycle period asymmetrically and the AMI-encoded signal by about half the amount symmetrically delay that the code rule violation checker contains two switches, one of the first and the second of the second of the two symmetrical and asym metric delayed output signals of the time decider is controlled and that the first switch the first Threshold comparator and the second the second Threshold comparator activated.

Advantageous embodiments of the invention contain the Subclaims.

An embodiment of the Er invention are explained in more detail. It shows

Fig. 1 shows the principle circuit diagram of a regenerator,

Fig. 2 pulse diagrams to explain the operation of the regenerator and

Fig. 3 shows an embodiment of the code rule violation tester.

In the examples according to FIG. 1, the AMI-coded signal SEA is applied to a terminal EA . On the one hand, a Schmitt trigger ST and on the other hand, via a symmetrical basic delay element VZ 3 and a further symmetrical delay element V 3, are fed to an input E 1 of a code rule violation tester VP .

The output signal of the Schmitt trigger ST changes from binary zero to binary one level when the AMI-coded signal SEA exceeds the upper threshold value U 1 of the Schmitt trigger ST and it changes from binary one to binary zero level if a negative one Pulse in the signal SEA below the lower threshold value U 0 lying in the negative voltage range. The Schmitt trigger ST converts as the AMI-coded signal SEA into a representation in the differential binary code. The output signal of the Schmitt trigger ST is sampled with a time decider ZE - here a D- flip-flop, which is clocked with the step clock STE applied to a terminal TE . The signals at the Q and Q outputs of the flip-flop ZE are fed to two further inputs E 2 and E 3 of the code rule violation tester VP via identical symmetrical basic delay elements VZ 1 and VZ 2 and via further asymmetrical delay elements V 1 and V 2 . The regenerated signal in the differential binary code is forwarded to further units of the regenerator, not shown here, via a terminal AZE .

The error-indicating pulses are present at a terminal AVP of the code rule violation tester VP . Test pulses can be applied to the terminals P 1 and P 2 , with which the functionality of the code rule violation tester VP is checked. Other connections e.g. B. the code rule violation tester VP are not shown in Fig. 1, since they are of minor importance for the invention.

In the circuit diagram according to FIG. 1, the asymmetrical delay elements V 1 and V 2 only delay the positive edges of their input signal by a time t ; the negative edges remain undelayed. The time t is an arbitrary fraction of the step cycle period of the signal SEA . The delay elements VZ 1 and V 1 or VZ 2 and V 2 can also be combined into a single asymmetrically delaying unit. The same applies to the symmetrical delay elements VZ 3 and V 3 . Embodiments in which the asymmetrical delay elements only delay the negative edges are also possible. The decisive factor is now the design of the basic delay elements VZ 1 , VZ 2 and VZ 3 . Is this dimensioning according to the state of the art to be carried out so that for each individual regenerator (individual adjustment) z. B. a rising edge in the signal SA 1 occurs exactly one step cycle period after the rising edge of a positive pulse in the signal SA 3 , which caused the rising edge in the signal SA 1 ver, so in the present case when considering the delay times or the signal transit times of the Schmitt trigger ST and the time decider ZE only the typical values of the signal transit times are set. The typical values mean mean values, which are usually also given by the manufacturer of the modules and from which the actual delay times can deviate. If all the actual delay times happen to coincide with the typical ones - this case should be assumed for the further explanation - there is no difference between the prior art and the teaching according to the invention.

In Fig. 2, the pulse diagram SA 3 shows a section from the output signal SA 3 of the basic delay element VZ 3 ; it represents the delayed AMI-coded signal SEA . Then, for the same period of time, the signals SA 1 and SA 2 follow at the outputs of the basic delay elements VZ 1 and VZ 2 . The next diagram shows the output signal SE 1 of the symmetrical delay element V 3 , that is to say the signal which has been delayed compared to the signals SA 3 and t / 2 . In the last two diagrams the signals SE 2 and SE 3 are plotted, which occur at the terminals E 2 and E 3 . They emerge from the signals SA 1 and SA 2 due to asymmetrical delay, namely that the rising edges are delayed by t , while the falling edges remain undelayed.

In the example according to FIG. 2, the time t is half a step period.

Each of the signals SE 2 and SE 3 controls a switch of the code rule violation tester VP . It should be assumed that each switch is switched on by a high potential in the signals SE 2 and SE 3 and thereby activates an associated threshold comparator of the code violation tester VP and that the threshold comparator that activates the signal SE 1 is activated by the signal SE 2 checked for two successive positive impulses. A comparison of the two signals SE 2 and SE 3 then shows that both threshold value comparators are never activated at the same time and both are in the deactivated state for a time t . The falling edge z. B. the first positive pulse in signal SE 1 , which leads to a high potential in signal SE 2 , is separated from the associated rising edge in signal SE 2 by time t / 2 ; If the time t / 2 remains below a step cycle period, then two immediately successive pulses in the signal SE 1 can also be displayed as errors. The same applies to negative pulses in the signal SE 1 and for the signal SE 3 .

If the actual signal transit time of the Schmitt trigger ST or the time decider ZE deviates from the typical signal transit time, this means a rela tive shift of the signals SE 1 and SE 2 or SE 1 and SE 3 against each other. As long as this shift remains smaller than t / 2 for each copy, no adjustment of the delay elements is necessary.

Fig. 3 shows details of the code rule violation auditor VP and its wiring. Components and connections that have the same designation in FIG. 3 as in FIG. 1 are identical. The threshold value comparator of the Codere gel violation tester VP are formed by both transistor pairs T 1 , T 2 and T 3 , T 4 ; the emitters of the transistors belonging to a pair are connected to one another. The collectors of transistors T 1 and T 4 are connected to reference potential via a common collector resistor R 1 . The same applies to the transistors T 3 and T 2 and the resistor R 2 . The impulses indicating errors can be taken from the AVP terminal. The delayed AMI-coded signal SE 1 is passed via the terminal E 1 to the base of the transistors T 1 and T 3 , while the base of the transistor T 2 via the terminal ES 1 with the low potential threshold and the base of the transistor T 4 the connection ES 2 is hit with the high potential threshold of the Schmitt trigger ST .

It is also possible to apply an inverted and delayed AMI-coded signal to terminal E 1 . In this case, the connection ES 1 with the high and connection ES 2 with the low potential threshold; the error-indicating pulses then appear at the AVP 1 terminal.

The two switches via which the threshold value comparators T 1 , T 2 and T 3 , T 4 are activated consist of the two transistor pairs T 5 , T 7 and T 10 , T 12 . The emitters of the two transistors of each pair are connected to one another and to a current source. The collectors of the transistors T 5 and T 12 are set to reference potential, their base connections ES 3 and ES 4 are subjected to a fixed reference potential, with the aid of which the applied to the base connections E 2 and E 3 of the transistors T 7 and T 10 Binary values are recognized. If the potential at terminal E 2 is higher than at terminal ES 3 , the collector current of transistor T 7 can flow. This current flows through the resistor R 1 and the collector-emitter path of the transistor T 1 , as long as the AMI-coded signal is more positive than the low potential threshold; otherwise it flows through the resistor R 2 and the collector-emitter path of the transistor T 2 . The same applies to the connection E 3 , the connection ES 4 , the transistor T 10 and the transistor T 4 .

By means of suitable potentials at the connections P 1 and P 2 , the threshold value comparators can also be activated via the transistors T 6 and T 11 independently of the switching state of the switches T 5 , T 7 and T 10 , T 12 . The asymmetrical delay elements V 1 and V 2 are formed according to FIG. 3 by the two pnp transistors T 8 and T 9 , whose emitters are connected to one another and are connected to a reference potential via a common resistor R 3 . The collectors of the transistors T 8 and T 9 are led to the negative pole of a supply voltage source via resistors R 4 , R 5 and R 6 . The asymmetrically delayed and, in the present case, additionally inverted signals are tapped at the collectors. The base of the transistor T 8 is driven by the signal SA 1 and the base of the transistor T 9 by the signal SA 2 . The asymmetry of the delay is achieved in that the transistors - provided as switches - the switch-on processes run faster than the switch-off processes.

According to FIG. 3, the output lines of the basic deceleration members VZ 1 and VN 2 via the series connection of two resistors R 7, R 8 are joined together. The Ver connection point of the resistors R 7 and R 8 is passed through a further resistor R 9 to the negative pole of the supply voltage source. The resistor network R 7 , R 8 , R 9 is used for the reflection-free connection of the output line of the basic delay elements VZ 1 and VZ 2nd This conclusion is especially Lich with longer lines, so that the reflected components do not lead to washed-out pulse edges.

A resistor R 10 , which is located between the Q output of the time decider ZE and the input of the main delay element VZ 1 , is used for level adjustment, since the time decider ZE is generally implemented in ECL technology. The same applies to a resistor R 11 , the Q output of the time decider ZE and the input of the main delay element VZ 2 .

Claims (4)

1.Regenerator for signals in the AMI code that are fed to the input of a Schmitt trigger, to the output of which a time decoder is connected, whereby two mutually complementary output signals of the time decider and the AMI-coded signal are fed to the inputs of a code rule violation tester via symmetrical basic delay elements and the code rule violation tester contains two threshold value comparators, one of which compares the delayed AMI-coded signal with the lower threshold voltage and the other with the upper threshold voltage of the Schmitt trigger, characterized in that
that the delay of the symmetrical basic delay elements (VZ 1 , VZ 2 , VZ 3 ) dimensioned such that taking into account the typical delay times of the Schmitt trigger (ST) and the time decider (ZE) for the delayed output signals (SA 1 , SA 2 ) of the time decider results in a symmetrical total delay which is one step clock period longer than the symmetrical basic delay of the AMI-coded signal (SA 3 ),
that additional delay elements (V 1 , V 2 , V 3 ) are seen before, which asymmetrically delay the output signals of the time decider by a fraction (t) of the step clock period and that the AMI-coded signal is approximately half the amount (t / 2 ) Delay symmetrically that the code rule violation tester (VP) contains two switches (T 5 , T 7 ; T 10 , T 12 ), of which one of the first and the second of the second of the two symmetrically and asymmetrically delayed output signals (SE 2 , SE 3 ) the time decider (ZE) is controlled and
that the first switch (T 5 , T 7 ) activates the first threshold value comparator (T 1 , T 2 ) and the second switch (T 10 , T 12 ) the second threshold value comparator (T 3 , T 4 ). 2. Regenerator according to claim 1, characterized in that the asymmetrical delay elements (V 1 , V 2 ) consist of two transistors (T 8 , T 9 ), the emit ter connections are interconnected, the base of the one transistor (T 8 ) one of the asymmetrically delayed signals (SA 1 ) and the base of the other transistor (T 9 ) is driven by its complementary signal (SA 2 ) and that the two asymmetrically delayed signals (SE 2 , SE 3 ) at the collector connections of the two transistors (T 8 , T 9 ) can be tapped. 3. Regenerator according to claim 1 or 2, characterized in that after the symmetrical delay of the mutually complementary output signals of the time decider (ZE) the line through a resistance circuit (R 7 , R 8 , R 9 ) are closed without reflection. 4. Regenerator according to one of the preceding claims, characterized in that each switch (T 5 , T 7 or T 10 , T 12 ) consists of two transistors (T 5 , T 7 or T 10 , T 12 ), the emitter are connected to one another and to a current source, the base of one transistor (T 5 or T 12 ) having a reference signal and the base of the other transistor (T 7 or T 10 ) being connected to one of the two symmetrically and asymmetrically delayed output signals ( SE 2 , SE 3 ) of the time decider (ZE) is applied and the collector of one transistor (T 5 or T 12 ) is set to a fixed potential, while the collector of the other transistor (T 7 or T 10 ) is on Threshold comparator (T 1 , T 2 or T 3 , T 4 ) is activated.