DE1119913B - Method and circuit arrangement for converting information in binary form into decadic form - Google Patents

Description

Method and circuit arrangement for implementing a in binary form present information in decadic form The invention relates to a method and a circuit arrangement for converting information present in binary form in decadic pulse trains and relates in particular to a dial converter in telecommunications systems. This method provides a common ring counter that takes over the information from a memory as binary complement values and the is switched on by a common pulse generator until a predetermined one Switch position (e.g. zero position) of the ring counter is reached. Until this one At the moment, the pulses from the pulse generator are also sent to the pulse output and thus to the consumer, which can be controlled in open-circuit or closed-circuit operation. A known method of this type now provides that after reaching this predetermined Switching position of the ring counter interrupts the transmission of the pulses and a special timing device is switched on. The timing device gives the Ring counter only after a time determined by you, the so-called free selection time, free for the conversion of the next piece of information. This procedure and the one that has become known However, circuit arrangements for performing the method have the disadvantage that a special measuring device is required to measure the free choice time.

The invention has now set itself the task of providing a method find, in which the free selection time through the interaction of pulse generator and ring counter can be derived. = This is achieved by using the common ring counter after reaching this predetermined switching position (e.g. zero position) by additional Switching means in a further predetermined switching position for counting the free selection time brought between series of impulses and during this time the emission of impulses is suppressed via the output and that the ring counter after reaching this further predetermined switching position in turn by the additional switching means for implementation the information is switched back.

It is a further object of the invention to provide a circuit arrangement for To carry out this procedure. The circuit arrangement according to the invention is characterized in that a) that a common ring counter, which is controlled by a pulse generator is incremented, in certain predetermined switch positions controls a flip-flop stage via a switching stage, 2 b) that in a switching state the flip-flop stage the pulses from the pulse generator reach the output for as long as until the switch position of the ring counter specified by the code conversion is reached is, c) that when this predetermined switching position of the ring counter is reached, the Flip-flop stage is overturned, whereby the emission of the pulses is prevented and the ring counter for counting the free selection time for a new specific switch position being prepared; and d) that after this new predetermined switch position has been reached the flip-flop stage is reset by the switching stage, the output for the transmission of the impulses released and in the ring counter for information conversion again the - The first predetermined switching position is marked. Procedure and circuit arrangement will now be explained in more detail using an exemplary embodiment.

When the arrangement is occupied, a positive pulse is given via the input R 1, which moves the ring counter RZ to the starting position (transistors BZ 2, BZ 4, BZ 6, BZ 8 conductive) and the common flip-flop stage to the position (Transistor QX conductive, transistor PX non-conductive), which indicates the state of the code conversion, can be brought. At the same time, the counting chain J 1 ... J 5 of the pulse generator JG is brought into the starting position (J 1 conductive) by a negative pulse via the input R 2. In the meantime, the complementary binary number has been taken over from the memory via the inputs V 1 to V 4. This is obtained by forming the number of all possibilities of the levels of the binary code and subtracting the value of the binary number from this. Is z. If, for example, the ring counter is formed from four flip-flop stages, there are two possible positions 24 = 16 possibilities for these four elements. Do you want to z. If, for example, five pulses are received at the output, a binary (16-5) = 11 is stored in the four-stage ring counter via the lines V 1 to V 4.

The ring counter therefore only needs five more pulses via its pulse input J to return to the starting position (BZ2, BZ4, BZ6, BZ8 conductive). During this time, the pulse generator also works on output A and thus on consumer V. The pulse generator used in the embodiment is z. B. controlled by a 20 ms clock, which is derived from a 50 Hz square wave generator. It makes it possible to easily count the cycle of 60 ms impulse and 40 ms pause common in telephone technology using a five-link counting chain. The output of this pulse generator can now optionally be switched so that open-circuit or closed-circuit operation is possible for the consumer. In the exemplary embodiment, closed-circuit operation should now be assumed. After the input pulses via R 1 and R 2, the pulse generator starts counting the pause time, which is counted by the elements J 1 and J 2. During this time, the transistors J1 and J2 take over the supply of the consumer. When the pulse generator is switched to element J3, ie after 40 ms, the output line is interrupted for the duration of the pulse, ie 60 ms. After the end of the pulse, transistor J 1 of the counting chain becomes conductive again and switches it one step further via input J of the ring counter. If the ring counter reaches its zero position at the end of the fifth pulse when J1 becomes conductive, the control input St of the switching stage S is released and the common flip-flop stage F is switched over with the transistor EX (QX blocked, PX conductive). As a result, the power to the consumer is taken over by the transistor PX during the free selection time that now follows. The transistor QX has been blocked, the relay Q has dropped out and has separated the fourth stage of the ring counter from the common switching stage. The pulse generator counting chain continues and switches the ring counter one step further every 5 - 20 = ms via the transistor J 1 and the pulse line J. After the first step, the transistor BZ1 of the ring counter is conductive again, which means that the switching stage remains blocked via the control line St until the first three stages of the ring counter are again in the rest position (BZ 2, BZ 4, BZ6 conductive). Then the switching stage S becomes conductive again and switches the common flip-flop stage back again (QX conductive, PX blocked). The pulse output A is switched through to the pulse generator and controlled from there. The Q relay responds again and the conversion of a new digit begins.

The arrangement works in the following way: Whenever the ring counter has reached the preset via the Q relay, the release takes place the switching stage S, whereby the relay E responds. The switching level controls everyone Address the flip-flop stage with the relays Q and P. If the relay Q is energized, then an information conversion is carried out. Switching stage S with relay E only responds again when the ring counter has reached its end position. the required number of setting pulses from the pulse generator also appear on Output A. If the flip-flop stage is reversed, relay Q has dropped out, and there is another predetermined switching position of the ring counter for the measurement of the Free choice time marked. Since the switching stage PX is energized with the relay P, it does not take place the transmission of the pulses transmitted by the pulse generator. Identify relays Q and P. the state of the information conversion and that of the free voting time. The relay E that always responds when the ring counter reaches the predetermined switch position, indicates the point in time at which from information conversion to free election time, and vice versa, is passed over.

The free choice time that is reached in: the embodiment is 800 ms. If another free choice time, z. B. 400 ms, desired, then must through the common flip-flop stage also the output of the third stage of the ring counter of the switching stage S. However, the arrangement can also be expanded that after the code conversion, caused by the flip-flop stage, the ring counter in any switching position can be brought, so that 1 - 100 = 100 ms to 16 - 100 = 1600 ms for the free selection time can be counted. By different interpretation the clock circuit and the pulse generator can also be a different pulse and / or Achieve break time and free choice time.

In a further development of the invention, switching stage S no longer becomes tipped over the common flip-flop stage, but the input of the flip-flop stage is sent directly to the output of the fourth stage when the series of pulses is sent Measure the free choice time directly at the output of one of the desired free choice times corresponding stage of the ring counter.

Claims (1)

PATENT CLAIMS: 1. Method for converting information available in binary form into decadic form with a common ring counter, which takes the information from a memory as binary complementary values and is switched on by a common pulse generator until the ring counter has reached a predetermined switching position, characterized in that the common ring counter (RZ) after reaching this predetermined switching position (z. B. zero position) by additional switching means (z. B. an electronic switching stage S and a flip-flop stage F) in a further predetermined switching position for counting The free selection time is brought between two series of pulses and during this time the transmission of pulses via the output (A) is prevented and that the ring counter is switched back again by the additional switching means for converting the information after this further predetermined switch position has been reached. 2. Circuit arrangement for carrying out the method according to claim 1, characterized in that a) that a common ring counter (RZ), which is incremented by a pulse generator (JG) , in certain predetermined switching positions via a switching stage (S) a flip-flop Stage (n controls, b) that in a switching state (transistor QX conductive, transistor PX blocked) of the flip-flop stage, the pulses from the pulse generator reach output (A) until the switching position specified by the code conversion (transistors BZ 2, BZ 4, BZ 6 and BZ 8 conductive) of the ring counter is reached, c) that when this predetermined switching position of the ring counter is reached, the flip-flop stage is turned over, the transmission of the pulses being prevented and the ring counter to count the free selection time for a new specific switch position (e.g. transistors BZ 1 or BZ 1 and BZ 3 or BZ1, BZ3 and BZ5 or BZ1, BZ3, BZ5 and BZ 7 conductive) is prepared, and d) that after reaching In this new predetermined switching position, the flip-flop stage is reset by the switching stage, the output for the transmission of the pulses is released and the first predetermined switching position is marked again in the ring counter for information conversion. 3. Circuit arrangement according to claim 2, characterized in that during the impulse the coupling of the switching stage to the transistors (BZ1 BZ3, BZ5 and BZ7) of the ring counter, during the free selection time to the transistors (BZ 1 or BZ 1 and BZ 3 or BZ 1, BZ 3 and BZ 5 or BZ 1, BZ 3, BZ 5 and BZ7). 4. Circuit arrangement according to claim 1, characterized in that the input of the common flip-flop stage when sending the series of pulses is connected directly to the output of the fourth, when measuring the free selection time directly to the output of a level of the ring counter corresponding to the desired free selection time. 5. Circuit arrangement according to claim 2, characterized in that in quiescent current operation during the free selection time the transistor (PX) of the common flip-flop stage also supplies the quiescent current for the output (A). 6. Circuit arrangement according to claim 2, characterized in that. that via the inputs (R 1 and R 2) the arrangement is brought into the defined initial state (the transistors BZ2, BZ4, BZ6, BZ8 of the ring counter and TR J 1 of the pulse generator conductive) at the beginning of the conversion.