DE2417793C2 - Circuit arrangement for counting telephone charge units - Google Patents

Description

The present invention relates to a circuit arrangement for counting telephone numbers Charge units, with a receiving stage for the acquisition of a frequency / oscillating charge ren impulse trains and one depending on the output of the receiving stage in the "ON" state controllable and after a predetermined time in the "OFF" state retractable flip-flop, those an output frees a clock generator working on a display counter during the "ON" state there, the output of the clock generator except the display counter feeds a coding counter whose output at one input of a comparator is that with a second input at the output of a Reference value stage is connected, and the output of the comparator if the output matches of the coding counter with the reference value an output pulse for resetting the multivibrator in the "OFF" state, while a second output of the flip-flop then a reset input of the coding counter applied with a reset signal, according to patent 22 47 833.

With the help of such a circuit arrangement, a telephone subscriber is enabled to Counting device to read immediately how much money a phone call has cost him without him afterwards a conversion of units into a corresponding amount of money would have to undertake. In the Circuit arrangement according to the main patent is precisely monitored how many pulses the pulse generator after receiving a charge pulse, and exactly when this number of pulses generated corresponds to the number of pulses required for a charge pulse, the pulse generator is shut down. The adjustment of the ratio of output pulses from the pulse generator / charge pulses can be done digitally take place, for example, by using a suitable code plug, the reference value stage against a reference value stage with a different ratio of grant amount unit / fee unit is exchanged.

However, there remains the need to use the display counter to feed by means of the sequence of individual pulses emitted by the clock generator and these individual pulses to be recorded simultaneously via the coding counter and evaluated by means of a comparator. It means that a minimum time must be available for the transmission of the charge information, namely the time it takes to get the result of that To transmit the clock generator of emitted single pulses serially to the display counter or the coding counter.

The object of the present invention is to provide an advantageous alternative to the circuit arrangement according to to create the main patent, in which on the generation of individual pulses by a clock generator and accordingly their serial acquisition is waived and instead with corresponding fee units Information sizes can be worked, which are not only newly each time by appropriate counting are formed by Finzelimpulses, but on

are immediately available and can be passed on to the advertisement in many forms.

This object is achieved according to the invention, J ₁₆ amendment, that instead of the troop containing the coding counter and the display counter, an arithmetic unit connected to the output of the loading stage and a decoding stage on the output side Display feeds, and instead of j clock generator one fed by the flip-flop

In the meantime, the command control unit feeding the arithmetic unit is provided are.

This makes it possible to use a quantity of information that represents the amount of money corresponding to a fee unit, by means of corresponding activation of the techenwerk via the command control unit in parallel Form to be called up directly from the reference value stage, with newly triggered ones corresponding to a fee unit Information quantities of the reference value level are added to the quantities already recorded. Through the parallel information transfer of the information quantity that has already been firmly ordered and corresponds to a fee unit can be shorter compared to the serial information transmission according to the main patent The acquisition times and, in connection with this, also an even greater reliability and accuracy of the method of operation achieve the circuit arrangement.

Further refinements of the invention emerge from the subclaims.

The invention is illustrated below by means of an exemplary embodiment explained in connection with the accompanying drawing. In the drawing shows

F i g. 1 schematically shows a block diagram of the opposite the circuit arrangement according to the main patent modified circuit arrangement,

F i g. 2, a block diagram of one possible embodiment of the circuit arrangement, going further in detail according to FIG. 1 command control unit used,

F i g. 3 a block diagram of the circuit arrangement according to FIG. 1 used Arithmetic unit and

F i g. 4 is a pulse diagram showing the signal curve at various essential points in the circuit arrangement according to FIG. 1 and FIG. 2 and 3 shows.

In detail, the with F i g. 1 reproduced, generally designated 10 circuit arrangement recognize a structure which, from an antenna 13 to a flip-flop 14, has the same structure as that Has circuit arrangement according to the main patent. The antenna 13 wirelessly detects the usually one frequency of 16 kHz having charge pulses that were delivered to a receiving stage 12. Over some additional stages, which will be explained further below, affect the output of the receiving stage 12 the flip-flop 14, which goes into the "EI N" state when a charge pulse occurs.

As already stated in the main patent, since only relevant charge pulses are evaluated, but not interference pulses, a monostable multivibrator in the form of a monostable multivibrator 34 can be connected upstream of the flip-flop 14, which acts as a flip-flop. The monoflop 34 is triggered by each edge of a partial pulse of a charge pulse and remains in the switched-on state for a period of time which is in any case greater than Mf, but less than 2 //. The monoflop 34 accordingly remains, since it is constantly restarted, in the switched-on state as long as partial charge impulses of a charge impulse occur one after the other, while it switches off shortly thereafter.

The output of the monoflop 34 acts on the input of an astable multivibrator 36, which is thus during the switch-on time of the monostable multivibrator 34 continuously outputs pulses that are generated by a pulse comparison counter 38 are counted. The pulse comparison counter 38 is working in turn to a decoder 40. Is the pulse comparison counter 38 by the output pulses of the astable Multivibrators 36 have been brought to a counting value that is decoded by the decoder 40, so the Decoder 40 emits an output signal by means of which flip-flop 14 goes into the "E1N" state. There are thus only those pulses are able to flip the flip-flop 14 that are long enough or a sufficient number of partial pulses have to the astable multivibrator 36 a number predetermined by the decoder 40 exceeding Number of pulses to be given. On the other hand, know a one. Interference pulse corresponding input pulse If only one or a few edges appear, the monoflop 34 only remains in the switched-on state for a short time, which is not is sufficient to let the astable multivibrator 36 emit the number of pulses at which the decoder 40 would emit an exit signal. Reverses the monoflop 34 returns to its "OFF" state, an output pulse is emitted, which controls the pulse comparison counter 3 «resets to zero.

With your interference suppression circuit 32, all impulses are separated out that have a shorter duration than those to be detected Have charge impulses. The detection of interference pulses with an amplitude that is too small can also be used can be switched off from the outset in that the monostable flop 34 is preceded by a Schmitt trigger 42 which only responds and emits an output pulse to the monoflop 34 when the receiving stage 12 output pulse has an amplitude that is greater than the threshold value of the Schmitt trigger 42 is

The flip-flop 14, which has gone into the "ON" state, acts on a command control unit S'.l via a line 60 ', so that this initially causes the arithmetic unit 54 via an output line 74' to transfer the reference value stage, designed as a coding plug 28, via the line i ^r 2 'and to deliver the value received via a decoding stage 20 to a display 22, which then displays, for example, the value "20 Dpf." This value is also entered into a working register contained in the arithmetic unit 54, as will be explained in more detail below. The command control unit 52 then issues a further command to the arithmetic unit 54 via its output line 70 'to transmit the value stored in the working register to an adder, which is coupled on the input side to the output of the coding plug 28 and on the output side via a display register to the decoding stage 20, such as is also to be presented further below. After the first fee value corresponding to a fee unit has been recorded in the arithmetic unit 54 on the basis of the command given via the line 70 ', the command control unit 52 emits a further pulse via a line 14' to the flip-flop 14, so that it is in the »OFF «Status returns and is available to receive a further charge pulse train. At the same time, the flip-flop 14 then gives a signal to the command control unit 52 via its output line 66 ', so that this is prepared for the evaluation of a further charge pulse sequence *:.

With F i g. 2 and 3 is illustrated in block diagram form, like those previously generally in connection with mi

F i g. 1 explained functions of the command control unit 52 or the arithmetic logic unit 54 can be realized. .

According to FIG. 2, the command control unit 52 has an astable multivibrator 60 which is coupled to the flip-flop 14 on the input side via the line 60 ' The output feeds the counting input of a counter 62, which is connected to a decoder 64 on the output side is. The command control unit 52 is available via the output side of the decoder 64 by means of the lines 70 'and 74' with the arithmetic unit 54, but via the output line 14 'with the reset input of the flip-flop 14 in Connection. In addition, the flip-flop 14 acts on the output side via a line 66 'on a in the command control unit 52 contained monoflop 66, which acts on the output side on the reset input of the counter 62. If the flip-flop 14 now supplies a signal to the astable multivibrator 60 via the output line 60 ', then there is this a series of pulses to the counter 62, which successively the counting states "1", "2", "3" can be assumed, naturally starting from the counting state "0". The decoder 64 connects the (four) outputs of the counter 62 with the lines 74 ', 70' and 14 'in such a way that in the "0" state of the counter 62 none of the three Lines 14 ', 70', 74 'carry a signal, in counting state "1" line 74' carries a signal, in counting state "2" the line 70 'and in the counting state "3" the line 14' carries a signal.

If flip-flop 14 has been reset via line 14 ', it is via its output line 66 'to the monoflop 66 a pulse which is sent via the monoflop 66 for a reset of the counter 62 to the "Zero" state ensures.

As with F i g. 3, the arithmetic unit 54 has a display register 74 which, on the output side, communicates with the Display 22 feeding decoding stage 20 is connected, on the other hand, on the input side, to the output of a Adder 72 is connected, the first input of which is connected to the coding plug 28 via the line 72 ' is. The other input of the adder 72 is connected to the output of a working register 70, its an input with the output of the display register 74 acting on the decoding stage 20 and its other; Input is connected to the output line 70 'of the command control unit 52. An entrance of the display register 74 is connected to the output line 74 'of the command control unit.

If a charge unit acquisition cycle now begins, the working register 70 is empty, and so is the adder 72 only carries the charge information value fed in from the coding plug 28 via the line 72 '. An output signal corresponding to this charge information value is applied to the display register 74, which sends its register contents to the decoding stage 20 (and thus to the display 22), but also transmits one input of the working register 70 as soon as it is input via the output line 74 ' the command control unit 52 receives a corresponding trigger signal. Is now, after a corresponding issue a follow-up pulse through the astable multivibrator 60 to the counter 6Γ, the line 70 'a trigger signal to the working register 70, this supplies a signal corresponding to its content to the adder 72 thus the sum of the signals of the working register 70 on the one hand and the coding plug 28 on the other hand ready for delivery to the display register 74 and can deliver to this as soon as over the line 74 'a new trigger pulse acts on the working register 74. First, however, the astable multivibrator switches 60 the counter 62 in its third counting state, so that via the decoder 64 the output line 14 'is signal-carrying and the flip-flop 14 resets for the detection of a new charge pulse train, wherein the flip-flop 14 in turn via the line 66 'and the monoflop 66 for resetting the counter 62 cares. In the working register 70, however, is still the charge value last displayed by the display 22 is stored, and that of the adder 72 with an additional charge unit information value of the coding plug 28 is summarized, so that the sum of the previous display value, increased by an additional charge unit information value, from the display register 74 to the display 72 (and at the same time to the working register 70) can be as soon as a new trigger pulse is supplied via line 74 '.

A pulse diagram is shown with FIG. 4, which illustrates the time allocation of various relevant signal voltages. As in the main patent, the pulse sequence a shows three 16 kHz charge pulses, each corresponding to a charge unit. In the example shown, each charge pulse consists of six charge partial pulses. Each edge of a partial charge pulse triggers the monoflop 34, which remains in the switched-on state for a period of, for example, 1.6 / "(in the present example /" = 16 kHz). The output signal of the monoflop 34 acting on the input of the astable multivibrator 36 therefore corresponds to the pulse sequence b. The output signal is retained until a time corresponding to 0.6 // "has passed after the last partial charge pulse of a charge pulse of the pulse train a. Then the monoflop switches back to its" OFF "state Pulse train c for each charge pulse of the pulse train, for example twenty pulses, which are counted by the pulse comparison counter 38. The pulse comparison counter accordingly emits a pulse train that is decoded by the decoder 40. If the decoder 40 is preset to the number "20", for example, the The decoder 40 emits an output signal corresponding to the pulse sequence d , which causes the flip-flop 14 to pass into the "ON" state according to the pulse sequence e. As soon as the flip-flop 14 has reached the "ON" state, the astable multivibrator 60 of the command control unit 52 becomes set in motion via line 60 ', so that it successively generates the pulses "1.", "2." and "3." of the pulse sequence f The trailing edge of the pulse "1." of the pulse train f causes the counter 62 to pass into the counting state "1" until the trailing edge of the pulse "2." of the pulse train f appears, as illustrated by the pulse train g. As soon as the trailing edge of the pulse »2.« de: pulse train f has occurred. the counter 62 goes over to the counting state "2", which it holds until the trailing edge of the pulse "3." of the pulse train f , as illustrated by the pulse train ti . At this point in time the counter 62 takes the counting state " 3 «so that the flip-flop 14 over the line; 14 'is reset and the monoflop 66 in turn resets the counter 62, which then accordingly goes into the counting state "0", as is shown by the pulse sequence I'. As soon as a new charge pulse of the pulse train a appears, the same cycle is triggered again.

If the counter 62 takes the counting status "1"

According to the pulse sequence g ¹ , s ⁿ the input register 74 receives via the decoding stage 64 and the line 74 'the command, the sum of the working register 70 and coding plug 28 contained in the adder 72 via the decoding stage 20 to the display 22 to pass on to the work register 70.

If the counter 62 then goes into counting state "2" according to the pulse sequence h ' , the working register 70 receives the command via the decoder 64 and the line 70' to actually accept the new charge value made available by the output of the display register 74 and to let act on the adder 72.

After the transition to the counting state "3", the pulse sequence I 'in the already mentioned Way, the flip-flop 14 is reset, the counter 62 returns to the "0" counting state and the astable multivibrator 60 is stopped.

The coding plug 28 corresponds, as in the main patent, to a certain amount of money ratio units / fee unit, so that by simply exchanging the coding plug 28 an adaptation to det a fee unit corresponding amount of money can be made.

For this purpose 3 sheets of drawings 609 6OE

Claims (4)

Patent claims: 1. Circuit arrangement for counting telephone charge units, with a receiving stage for the acquisition of a frequency / oscillating charge pulse sequences and an in Depending on the output of the receiving stage, it can be converted into the "ON" state and after a given time in the "OFF" state retractable flip-flop, one output of which during of the "ON" state enables a clock generator working on a display counter, whereby the In addition to the display counter, the output of the clock generator feeds a coding counter whose output at one input of a comparator, which with a second input to the output of a Reference value stage is connected, and the output of the comparator if the Output of the coding counter with the reference value an output pulse for resetting the Flip-flop in the "OFF" state, while a second output of the flip-flop then one Reset input of the coding counter subjected to a reset signal, according to patent 22 47 833, characterized by the modification that instead of the coding counter, the comparator and the group containing the display counter includes an arithmetic unit (54) connected to the output of the reference value stage is connected and on the output side feeds a display (22) via a decoding stage (20), and instead of the clock generator one fed by the flip-flop (14) and, in turn, the arithmetic unit (54) feeding command control unit is provided. 2. Circuit arrangement according to claim 1, characterized in that the command control unit (52) an astable multivibrator (60), which through an output (60 ') of the flip-flop during the "ON" state is released, as well as a counter fed by the astable multivibrator (60) (62) with at least four different counting states, the output side depending on the counting state successively first work commands to the arithmetic unit (54) and then a reset pulse to the tilting stage 3. Circuit arrangement according to claim 2, characterized in that the command control unit (52) has a monoflop (66), the input side via a line (66 ') with an output of the Flip-flop and is coupled on the output side to a reset input of the counter (62) and from the Flip-flop after the completion of a computing process that detects a fee unit, a command for A reset pulse is sent to the counter (62). 4. Circuit arrangement according to one of claims 1 to 3, characterized in that the arithmetic unit (54) one from the reference value stage on the one hand and from a working register (70) on the other hand additively fed adder (72) and a display register fed by the output of the adder (72) (74), which upon receipt of a corresponding first control command from the command control unit (52) takes over the content of the adder (72) and on the output side both with the decoding stage (20) and to a first input of the working register (70) is coupled to a second input with an output of the command control unit (52) for the delivery of a second Control command is in connection