DE1276095B - Electronic coding device with a counter that accumulates incoming pulses - Google Patents

Description

Electronic coding device with a counter that counts incoming pulses accumulated The invention relates to electronic coding apparatus having a of several decadic steps connected in series, which is in any sequence of incoming impulses accumulated as well as with one for reading out the additional decadic storage level for the accumulated numerical value the ones place, the content of which normally changes with that of the counter.

Monitoring systems are often required in various branches of industry, the certain conditions and operating values of a system, such as B. a flow rate, measure and transmit the corresponding data to a centrally located station, where the measurements are displayed, monitored and / or recorded. Where the top transmission of commercial data, such as B. of invoice amounts or the like., From a Controlling computers set up in the headquarters is of course one extremely precise data transmission to the computer is required. With flow measurements highest accuracy are generally used measuring mechanisms with positive movement, as these are more accurate than other types.

In principle, such flow meters have a simple piston or a rotary piston, wherein electrical contacts are arranged such that they change with each piston stroke or with each rotation of the piston by a certain amount Close angle. An electrical circuit connected to the contact is thereby given Pulse signals in random sequence, with the specified sequence number during a time interval indicates the flow rate during this time and the number of during The time received from the electrical circuit is a measure of the pulses received through the measuring mechanism is the amount of liquid that has flowed.

As will be readily appreciated by those skilled in the art, flowmeters are those described Kind, d. H. those in which individual output pulses are generated are then selected, if a transmission of the measurement data over a greater distance is necessary. Opposite to Flowmeters with an analog output signal avoid possible errors, resulting from voltage losses during transmission.

In general, the computer in the central station is the receives readings from one or more flow meters, a digital computer with a certain code scheme and a stored program that can be used in successive Sections of the timing control performs various calculations. For this reason can they values given by the measuring device in random order are not directly as Input data for the digital computer, but must first be in Digital numbers can be converted to a binary code using the special calculator is coordinated in the head office.

In order to continue to accurately transfer flow rates in a larger area, Of course, digital signals with many binary digits are required for playback. For reasons of economy, it is also advantageous between the coding device and the lowest possible number of transmission channels for the central computer or to use lines, which amounts to the output data of the encoder to be transferred to the computer in series.

The problem, the pulse signals generated in the flow meter in random Result in digital signals in a computer-accepted binary code to convert is made difficult by the fact that the flow rate to be measured is completely independent of the computer program. Therefore it can happen that the Computer requests measurement data during such time intervals in which the flow rate is relatively high, or vice versa, during those time intervals in which it is zero is. In the first case, a usable coding device must constantly read the measured value Record pulse signals and accumulate while at the same time the Data to be sent to the computer from the data on the coding device during the transmission time Incoming signals must remain independent in order to keep the transmitted data not the biggest mistakes can occur.

This latter property is best seen on the basis of a particular one Understand example. Provided that the data from the coding device is generally in series and the individual digits of a digital number are transferred according to decreasing powers it could happen that the value 09999 erroneously transferred as 00000 is, if just at the moment in which the top digit is coded a single impulse was sent to the encoder that actually gave the numerical value would increase to 10,000; provided, of course, that not the transmitter part of the coding device works independently of the receiver part during the transmission time.

It is already made up of a counting part and a memory part Decade counter known in which each individual counter decade has its own storage circuit assigned. To transmit the respective accumulated numerical value, all Storage circuits separated from the counting levels and queried.

Furthermore, a counter is known that operates with a very specific frequency of a clock counts. With this counter, the count is interrupted during the query.

The present invention is based on the object of a simple Electronic device for counting incoming pulses in any sequence, for example from a flow meter, to create, simultaneously with the transmission of a value already contained in the counter, the counter's counting function is retained got to.

This is achieved in that the decadic storage level of the first decade stage is downstream and during one of it and the downstream Decade stages taking place reading process by an inhibition circle against changes their count is protected while the first decade of counting continues uninterruptedly responds to incoming signals.

This creates an improved electronic coding device which counts and saves input pulses received in random order. The saved Information is then read while in series during a selected period that the information is protected against change and still further information be recorded and counted. So that the values stored in the counter are independent can be read from the simultaneous reception of further input signals a separate memory level is also provided, which is normally dependent on is switched by the immediately preceding counter stage. During a read however, the value in this storage level is protected against changes, too if the value in the previous stage is due to the occurrence of an or several pulse signals from the flow meter is changed. The device is with a new type of scanning provided that not only the required data in series processed, but also the value stored in the meter in the 2-out-of-5 test code implements. Signals arriving in random order are thus continuously accepted and a plurality of appropriately modified information codes into a selected one converted output signals issued in series. The device can preferably be connected used with a forced motion flow meter to display accumulated measured values as digital data.

According to a further embodiment of the invention is a test bit generator the seven-four-two-one, 7-4-2-1 code used in the counting stages to transfer information into a 2-out-of-5 code. As for checking the 7-4-2-l-O test code is used, the individual counter digits are not in the standard 8-4-2-1 code, but stored in a binary code, its individual place values 7-4-2-1 are. Therefore, a new type of circuit is used for each counter stage, which ensures that no more than 2 bits occur and the digit, if it contains the value 9, when the next is received Pulse is set to zero. The test bit generator sets the one used in the counter binary 4-bit code at the output into a 2-out-of-5 code. To get the data out in series To read out the decadic counter, a new sampling circuit is conveyed.

The coding apparatus of which a preferred embodiment is given below is described in detail, consists of a five-digit decimal counter, the counts and accumulates the pulses emitted by the flow meter. For the transfer high accuracy of the digital data is achieved using the 2-out-of-5 code, nevertheless the construction of the counter is simple, because every decade the Stores data in conventional binary code and a check bit generator for each decade converts the 4-bit binary code into the desired 2-out-of-5 code.

Further advantages and features of the invention emerge from the the following description with reference to the drawing, in which F i g. 1 the block diagram of a preferred embodiment of the coding device according to the invention, FIG. 2 an electrical circuit diagram of the counter stage, partly executed as a block diagram of the in FIG. 1 reproduces the device shown, FIG. 3 similar to FIG. 1 represents the memory unit shown in FIG. 4 similar to FIG. 2 the in F i g. 1 illustrated location scanner and FIG. 5 similar to FIG. 2 den Figure 1 illustrates the output sampler and test bit generator shown in FIG.

Although the device according to the invention has general applicability, it is in particular a known device for the remote transmission of measured values adapted, which consists of a control center and remote substations. Each substation contains provisions for measuring and monitoring selected ones Operating parameters and for controlling several instruments and devices installed there. At the command of the control center, the called substation gives digital data - in the case of special ones Execution of this device in 2-out-of-5 code - starting with the various measured values or the positions of the individual control organs. From the ones listed above Reasons such as the random repetition rate or the problem of data being transferred at the same time receive and transmit, it is necessary that each substation Encoders to ensure that the data received from flow meters or similar devices is correct transferred to. As can be seen from the following description, the inventive Device preferably intended for use in such extensive systems.

As in Fig. 1, the one flowing through the line 10 is shown The amount of liquid measured by means of a flow meter, which has a Sequence of signals generated whose repetition frequency is proportional to the flow rate is in line 10. The measuring device 12 is a known flow meter according to the principle of compulsory movement. and one arising at output 14 Signal indicates that a predetermined amount of liquid is passing measuring mechanism 1.2 Has.

If z. B. the flow rate in the line 10 is zero, Of course, no pulses appear on line 14 either. On the other hand, is the flow rate maximum, so also has the number of appearing on line 14 per unit of time Signals have a maximum that in a typical system has a repetition rate of 100 Hz corresponds.

At other flow rates, the repetition rate is accordingly between the limits of 0 and 100 Hz.

According to FIG. 2 the relay receives 15 pulses from the flow meter 12 over the terminals of the line 14. Usually the measuring mechanism, the winding of the Relay 15 and the leads between the measuring mechanism and the relay are highly inductive Character, so that the current curve requires a considerable settling time and sharp pulses cannot be obtained directly from the flow meter.

The relay 15 responds to the current generated by the meter and creates the desired steep pulse edges by closing its contact.

A diode parallel to the relay winding provides a current path for represents the current surge that occurs when the inductive circuit of the relay winding is interrupted. When the contact is open, a point 19 lies over a connecting one Resistor 21 at ground potential; if the contact closes, it becomes a positive one Voltage of 6 volts directly to point 19 and to the decadic counter 16 of the F i g. 1 created. In this way, the relay 15 speaks to the flow meter 12 generated signal and generates at the input of the first stage of the counter 16 one sharp impulse.

The counter 16 contains the conventional decadic counting stages 18, 20, 22, 24 and 26 and the ones storage stage 28. Each of the counting stages counts from zero to nine and is reset to zero with the next received pulse, where a carry over to the next higher level is generated. There are five levels in total provided that count to 99999.

The units storage stage 28 present in the counter 16 is normally connected directly downstream of the counter of the units digit 18, d. i.e., the one in the storage unit The value stored in 28 is exactly the same as that in the ones digit 18. How, however is to be explained in detail further below, the value in the storage unit 28 during a read operation under the control of a count suppressing circuit 30 "frozen", i.e. H. Protected against changes, even if over the Line 14 at point 19 appearing further impulses cause the One digit 18 changes the value. At the end of the read, the suppression circle becomes 30 is switched off, with the result that the memory unit 28 automatically stores the in this moment in the units digit 18 assumes the value present. Also registered the memory unit 28 also determines whether during the reading process from the ones digit 18 a carry was generated, so that the now in the memory unit 28 and the decade digits 20, 22, 24 and 26 is exactly the same as the one in digits 18, 20, 22, 24 and 26 including the pulses generated by the measuring mechanism during the reading process 12 were submitted. In this way, the storage unit 28 separates the counter 16 from meter 12 during an encoding cycle so that errors in the output signal are prevented and, moreover, certainly no input pulse remains uncounted, which of course would also result in an incorrect output signal.

During a reading process, the memory unit 28 and the decadic counting stages 20, 22, 24 and 26 in sequence interrogated a digit scanner, which with the various stages through the multiple lines 34, 36, 38, 40 and 42 is connected. The output of the data code generator, which is stored in the encoder is normally set in advance, is also with the digit scanner 32 connected via a multi-point line 46 to the beginning of the transmitted message generate a digital output signal to identify the type of data. As each Decade stage, as well as the output of the data code generator 42 by the digit scanner 32 is selected, the outputs of the switch elements in the relevant Place sequentially interrogated by the output scanner 48. The scanner 48 effects in addition, that the 7-4-2-1 code in which the data is stored in each position, is automatically converted into the desired 2-out-of-5 output code. The assignment Table 1 shows between the 7-4-2-1 code and the 2-out-of-5 code.

Table 1 7-4-2-1 code 2 out of 5 code Decimal place value place value value 7 4 2 1 7 4 2 1 O 0 0000 11000 1 0001 00011 2 0010 00101 3 0011 00110 4 0100 01001 5 0101 01010 6 0110 01100 7 7 1000 10001 8 1001 10010 9 1010 10 100 In addition, an end-of-message character generator 51 is provided which is connected to the output line 50 from the output scanner 48 via the line 52 and delivers a digitally coded signal at certain times which indicates the end of the reading process. It can thus be seen that the output signal appearing on line 50 during a conversion process consists of seven groups of characters, namely a function character, the five digits of the stored number and the end of message character. The details of the special circuitry required for this are described below.

As already indicated in Fig.1, the conversion process is through Application of a read command signal initiated by the control center via line 54. This command sets a K-time generator 56 into action, that of the one described here Embodiment of the invention operates to respond to such a signal as a whole six equally long time intervals K until K6 defines. With one exit of the K-time generator 56 is connected to a B-time generator 58, each time interval K divided into five sections B1 to Bs. The outputs of the generator 56 are with the position scanner 32 connected via a multiple cable 60, and that of the generator 58 are connected to the output scanner 48 via a further multiple cable 62. This will give the necessary time signals for the correct sequence of outgoing Message generated. The initiation of a K time interval causes the other Output of the generator 56 outputs corresponding signals, which suppress the counting 30 and switch on the data code generator 44. The simultaneous occurrence of a K,; - time interval and a Bs-section actuated via the "And" gate 64, which thus becomes conductive, the end-of-message character generator 51 after a predetermined time delay and switches off the counter suppression 30 and the data code generator 44.

For all decade counters occurring in the device according to the invention, as they are designated in Fig. 1 in the block diagram as 18, 20, 22, 24 and 26, any of the known circuits can be chosen. A preferred embodiment for such a counting stage, which is especially suitable, binary data in 7-4-2-1 code however, is shown in FIG. Thereafter, a counter level contains four flip-flops 70, 72, 74 and 76 connected in series, the circuit diagram only for the first is shown, while the rest are shown in block form. The in F i g. The circuit shown in FIG. 2 belongs to the ones digit 18, it should be noted is that the remaining decade stages with the exception of relay 15 are identical. All Flip-flops of this stage are initially activated by a reset pulse via the Line 78 is reset to the binary zero state. This negative default impulse is connected via a diode 80 to the base of a transistor 82 in the flip-flop 70 and in parallel for this purpose via the lines 84, 86 and 88 to similar circuits of the flip-flops 72, 74 and 76 created. Since all flip-flops are the same, the corresponding one is used Circuits of the flip-flops shown in block form are not referred to here, when not required.

The negative reset pulse applied to the base of transistor 82 causes this transistor to become conductive and the potential of the collector, which in this case is ground, via a capacitor 92 and a resistor 94 the base of a complementary transistor 90 is applied to turn it into the non-conductive To switch state or to maintain it and thereby the flip-flop in the state To offset "zero". The incoming from the flow meter 10 via the line 14 positive pulses cause alternating changes in the conductivity states of the transistors 82 and 90 according to the conventional flip-flop method, and although via a capacitor 96 and a first control diode 98, a capacitor 105 and a second control diode 102. It should be noted that the second pulse arriving on line 14 as well as any subsequent even-numbered pulse removes transistor 82 from the non-conductive switches to the conductive state and thereby the potential of the collector of minus 12 volts raises to approximately earth potential. This positive going wave is going over the line 104 is applied to the input of the flip-flop 72 to show the conductivity states to control the transistors located in it. This is how the Combination of flip-flops 70, 72, 74 and 76 make a counter that by itself can hold up to fifteen Counts and stores pulses when it receives a sixteenth pulse resets to zero and emits a carry pulse on line 106.

As mentioned above, however, a decadic counter should be used, d. H. one in which each counter stage receives a tenth pulse emits a transmission pulse and in which also the binary value in each stage is stored according to the 7-4-2-1 code shown in Table 1.

Both properties are in the circuit of FIG. 2 by inserting a pair of similar negative "or" or "neither-nor" gates 108 and 110 guaranteed, with only the "or" gate 108 being drawn as a complete circuit is. This circuit is an important feature of the invention; instead of namely that a sequence of feedback pulses is generated and sent to the individual stages The counter is applied to a decimal counter using a complex circuit a pair of relatively simple "neither-nor" gates is sufficient here, both decimal count and conversion of the standard 8-4-2-1 code in the desired 7-4-2-1 code.

Referring to Table 1 and considering that flip-flop 70 represents the digit 1 and flip-flop 76 represents the digit 7, it can be seen that when the seventh pulse is received, between normal and desired flip-flop states, there is the following difference: Table 2 Normal state Desired state Pulse of the flip-flops of the flip-flops No. 70 72 74 76 70 72 74 76 6 1 0110 7 1110 0001 2 shows that one output of each of the flip-flops 70, 72 and 74 is connected in parallel to the base of a normally conductive transistor 118 of the "neither-nor" gate 108 via lines 112, 114 and 116. If each of these flip-flops is in the "1" state, which means the number 7 in the 8-4-2-1 code, which is not wanted here, then the lines 112, 114 and 116 carry ground potential. The combination of these potentials at the base of transistor 118 causes the transistor to become non-conductive and the collector voltage to drop to minus 12 volts. This negative wave arrives via an emitter follower 120 and a diode 122 on the line 124, which is connected in connection with the line 78 to the clearing inputs of the flip-flops 70, 72 and 74, but from the clearing input of the flip-flop 76 through a diode 126 is separated. The arrival of a seventh pulse on line 14 therefore initially sets flip-flops 70, 72, 74 and 76 normally to states 1110. Under this condition, “neither-nor” gate 108 responds and sets flip-flops 70 , 72 and 74 in the state "0", whereby the resetting of the flip-flop 74 on the line 128 results in a transmission pulse which sets the flip-flop 76 in the state> 1 ". In this way, in the circuit of FIG. 2 the occurrence of a seventh pulse the desired binary sequence 0001.

Similarly, the "neither-nor" gate 110 works when receiving the tenth Pulse to reset all flip-flops to the "0" state. As in table 1, the flip-flops 70 to 76 store the number 9 in the sequence 0101, and the next pulse results in the in FIG. 2 the sequence 1101. However, this particular sequence effects via those associated with flip-flops 70, 72 and 76 Lines 112, 114 and 130 that the "neither-nor" gate 110 responds and over line 172 connected to line 78 generates a reset signal.

Finally, it should be noted that on flip-flops 70 to 76 delete inputs 134, 136, 138 and 140 are provided to special counting sequences to allow different from the one shown here. Furthermore, each flip-flop has complementary outputs 142, 144, 146, 148, 150, 152, 154 and 156, with the Lines 144, 148, 152 and 156 to multiple lines 36, 38, 40 and 42 (F i g. 1) are summarized, which are dependent on the respective counting level with the digit scanner 32 are connected.

F i g. 3 shows a schematic representation of the unit memory 28, of the similar to the description of FIG. 2 only one of the like Circuits to be discussed in detail. For storing the ones in the units place 18, four separate flip-flops are used, their respective State of a corresponding flip-flop of stage 18 by means of the complementary outputs is downstream. Note that the outputs 142 and 144 of the circuit shown in FIG. 2 shown Flip-flops 70 with the base electrodes of two cross-connected transistors 168 and 170 via the inputs of two "And" gates, generally with 172 and 174 and are described in detail below, and the diodes 176 and 178 are connected. If z. B. in the "0" state of the flip-flop 70 the transistor 82 is conductive, line 142 carries a potential of minus 12 volts the transistor 168 conducts and thus sets the flip-flop 160 to the "0" state.

On the other hand, when the "1" state of flip-flop 70 is on the line 144 negative potential, which makes transistor 170 conductive and flip-flop 160 is switched to state »1«. So you can see that each of the flip-flops of the One memory 28 normally shows the state of that flip-flop in the one's place 18 assumes it is associated with.

As stated above, a coding device for the intended here Be able to use the receiving part of a circuit from the transmitting part isolate. This property is in the storage tier 28 mediated by the fact that from the counter suppression circuit 30 on line 184 a suppression pulse arrives. This negative pulse is applied to the base of a transistor 186 and switches it from its normally non-conductive state to saturation, wherein the potential of a suppression line 188 is raised from minus 12 volts to zero will. The line 188 is with the two "And" gates 172 and 174 in the entrance of the Flip-flops 160 and with similar pairs of "and" gates in the inputs of the flip-flops 162, 164 and 166 connected, and the value potential applied thereby causes during a read operation that the state of the flip-flops regardless of whether or not during During this time, the state of the assigned flip-flop changes, is "frozen". As can be easily seen, this is accomplished by having diodes 190 and 192 keep connection points 194 and 196 at ground potential and thereby prevent that a negative pulse arriving on lines 142 or 144 changes the conductivity state of transistors 168 or 170 influenced. At the end of a read process, the suppression signal away from line 184, the potential of line 188 drops back to minus 12 volts back, the diodes 190 and 192 cancel their blocking effect and allow that the state of the flip-flop 160 via the lines 142 and 144 is controlled. This ensures that the flip-flops of the memory unit 28 have the state of those of the ones digit 18, regardless of whether the state of the latter changed during the reading process.

Finally, it should be noted - and this is another important one Characteristic of the invention - that the unit counter 18 just starts from the digit 9 the number 0 switches and thereby generates a transmission signal that corresponds to the correct Storage of the number located in the counter 16 must be scanned.

This important task is performed in the storage unit 28 as follows solved in a simple yet effective way. Table 1 shows that the position with the value 7, which is indicated by the flip-flop 76 in FIG. 2 represents will only switch from state »1« to state »0« when the The value in the counter changes from 9 to 0, i.e. i.e., when generating a transmission signal must become. This state causes the memory unit 28 to send a transmission signal to be delivered to the counter of the tens digit 20, both during normal Counting steps as well as at the end of a reading process, provided the counter is the ones digit 18 has switched from 9 to 0. The output 154 of flip-flop 76 (Fig. 2) is via a differential network consisting of a capacitor 202 and a Resistor 204, with the input of another flip-flop, which the transistors 198 and 200 contains connected. At the beginning of a counting segment or when the counter 16 has been reset to 0, transistor 200 is turned on via line 206 made conductive by a pulse, the collector voltage being raised to 0 volts will. Diode 208 holds connection point 210 at this level and causes in that the transistor 212 for the carry output becomes non-conductive. if then the ones digit 18 counts from 9 to o, arises on the line 154 as tSbertragssignal a negative wave caused by the Capacitor 202 and the Resistor 204 is differentiated, makes transistor 198 conductive and thereby puts transistor 200 in the non-conductive state. Because the collector voltage of transistor 200 drops to minus 12 volts, connection point 210 is released, and the base voltage of transistor 212 is now given by the ratio of the resistors 214, 216 and 218 determines the transistor becomes conductive and gives on the line 220 from a positive carry pulse. It should be noted that the carry pulse is applied to the base of the transistor 198 via a line 222 and an isolating diode 224 to reset the flip-flop and the connection point 210 to keep it on earth potential again. Results during normal counting steps hence any carry indication on line 154 in a positive output pulse on line 220.

As stated above, however, are allowed during a read process no carry signals are added into any of the digits that are currently being made is read so that serious errors do not occur at the output of the encoder can. This is achieved by a diode 226 connecting the suppression line 188 connects to node 210. Since the line 188 Leads to ground potential, the diode 226 pulls the connection point 210 to this potential and thus prevents the generation of a carry signal regardless of the Collector voltage of transistor 200. When the reading process is finished, the Diode 226 has no effect with respect to the connection point 210, and the formation of a Carry pulse is in the manner described above only by the state of transistor 200 is determined. Although there is a carry-over indicator on the line 154 occurs during a read process is output until the end of this process the in F i g. 2 no carry pulse is generated.

In summary, the ones memory 28 follows during normal Counting steps the value stored in the counter of the units digit 18 and initiates Carry signal generated by counting stage 18 to stage 20. During a reading process the storage unit 28 isolates both the value present in the counting stage 18 as well as the carry signal that may arise and prevents any influence on the data read from the counter 16.

After the reading process has been completed, the value in the output circles of the counter 16 corrected to the amount that takes into account all the pulses during of the reading process from the flow meter 10 via the line 14 were issued.

4 is a schematic representation of the location scanner 32; in which again identical parts are shown as a block diagram. The four binary output signals from the storage unit 28, the counting stages 20, 22, 24 and 26 and the code generator 44 are in "and" gate fashion with the inputs of the four Connected "neither-nor" gates 240, 242, 244 and 246, of which only gate 240 is shown as a complete circuit. Another entrance to these "and" gates is used by the sequence of K-time signals Kl to K6, which are used by the K-time generator 56 are supplied via line 60. Since each counting stage has identical circuits used, are the input lines in Fig. 1 coming from these circuits. 4 with double Designated reference numerals, the first of which is the multiple cable between the concerned Counter stage and the digit scanner, the second the single output line shown in Fig.2 indicates. For example, the input labeled 42-156 refers to the Output 156 of counting stage 26 to cable 42, input 40-156 to the output 156 of the counting stage 24 with the cable 40 etc. A similar numbering is for the Outputs of the storage unit are selected with the cable 34, while the outputs of the Data code generator 44 over the cable 46 by the reference numerals 1 to 4 are, the generator 44 from a group of transistor stages or the like There are circuits that are optionally in different states.

As shown, the four "neither-nor" gates are driven by the K-time signals controlled one after the other on the six control lines of the multiple cable 60 appear. This means that only one of these control lines is excited during the individual K-time segments and that the corresponding signal from such a line causes the state of the four flip-flops to be scanned Position is passed on via outputs 248, 250, 252 and 254. Normally all K control lines are positive and thereby separate all flip-flop output lines from the outputs of the "neither-nor" gates through diodes 256, 258, 260, 262, 264 and 266. For example, however, during a K time period the corresponding Control line negative and connects input 42-156 to output 248, the Input 42-152 with output 250, input 42-148 with output 252 and the Input 42-144 with output 254. In this way, a specific K control line at the outputs of the “neither-nor” gates 240, 242, 244 and 246 generates a signal indicating the state of the four flip-flops of the Level. Since the K control lines have a negative potential one after the other are applied, 4-bit signals are used one after the other to display the in the individual Digits stored digits generated. Although the circuit in FIG. 4 shown like this is that the individual places are scanned in increasing order, it is It goes without saying that either the order of the K control signals or the inputs of the counter could be modified so that the sampling in ascending order of posts takes place.

To transfer the data from the encoder in series over a single line to the The four output lines of the position scanner 32 must be scanned one after the other, and the 7-4-2-1 code must also be sent to the control panel reconciled 7-4-2-1-0 or 2-out-of-5 codes can be converted. These two functions an output scanner 48 takes over from which FIG. 5 shows a circuit diagram. In this are the output lines of the digit scanner 32, these are the lines 248, 250, 252 and 254, each connected to one of the amplifiers 270, 272, 274 and 276, the outputs of which appear on corresponding lines 278, 280, 282 and 284. For example from the mutual linking of transistors 286, 288 and 290 of the amplifier 270 it can be seen that the polarity of the Output of everyone Amplifier corresponds to the polarity of the input signal, i.e. i.e., a negative input signal (a binary 1) causes a negative output, and a relatively positive one Input signal (earth potential corresponding to a binary 0) generates a relatively positive one Output signal. The outputs of amplifiers 270, 272, 274 and 276 become the series according to the time pulses generated by the B-time generator 58 via the multiple line 62 B1 through Bg sampled with each of the B timing pulses, B through BS, during each K timing interval occurs. Analogous to the circuit used in the location scanner 48 are all B control lines are usually positive and are in the desired scan sequence excited. If z. B. during a period BJ the output line 278 of the amplifier 270 is relatively positive, this potential is at the base of a transistor 350, and there all other potentials appearing at transistor 350 at the same time are also relatively positive, as will emerge from the further description, thus transistor 350 remains in the non-conductive state, and those connected in series therewith Transistors 352 and 354 remain conductive, putting a on output line 50 relatively positive signal is generated. However, if line 278 is during a Time segment B1 negative, a negative occurs at the base of transistor 350 Signal that alone is sufficient to put transistor 350 in the conductive state to switch and thereby generate a negative voltage on the output line 50. This will make it understood that the lines on lines 248, 250, 252 and 254 are in parallel present data over the line 50 one after the other by the successive excitation of the control lines B1 to B4 appear.

Referring again to Table 1, it should be noted that the desired 2-out-of-5 Check Code uses a representation of the decimal value 0 in the 7-4-2-1-0 code requires the binary number 11000. In the circuit of FIG. 5 this will be based on the following achieved in a new way: As I said, the output data are created in descending order Order of positions. Because of this, the signal corresponds to during the time segment B1 has place value 7, during section BO has place value 4, etc. So it must a binary 1 appears on output line 50 during periods B and B2, if all input lines contain a binary 0 at the same time, i.e. i.e. if the Decimal value is zero. The amplifier outputs 278, 280, 282 and 284 are additional connected in parallel to the base of a transistor 292. You can see that during one Time interval K, in which all these lines according to a decimal value 0 im 7-4-2-1 codes are relatively positive, transistor 292 is non-conductive and its Collector voltage is at minus 12 volts. A diode 296 prevents this Potential at a node 294 appears. By energizing the control line B1 negative potential is applied to the base of transistor 350 via diode 298, which thereby becomes conductive and a negative potential on output line 50 (a binary 1) is generated. Similarly, transistor 350 is energized the control line B made conductive via a diode 300 and generated during this B-time period a binary 1. If, however, during another B-time period one or more input lines contain a binary 1, a from zero different decimal value before; appears at the base of transistor 292 at least a negative potential, the collector voltage rises to relatively positive or Ground potential, and during this period the diode 296 pulls the node 294 to this potential and prevents the control lines B1 and B2 from the state of transistor 350 affect. Let on by controlling transistor 292 in this way the control signals B1 and B2 during the time segments for the place values 7 and 4 at the output a binary 1 appear if the sampled decimal value is the Digit is zero.

In addition, the generation of a check bit is necessary, if one and only an output line carries a binary 1, which corresponds to the decimal values 7, 4, 2 or 1. If necessary, the check bit is provided with a transistor 203 and five "and" gates the diode pairs 304-306, 308-310, 312-314, 316-318 and 320-322. Note that these diodes are connected to those combinations in which decimal values for which no check bit should be generated. For example is the diode 304 with the line 278, which carries the place value 7, and the diode 306 connected to the line 282, which carries the place value 2, so that the combination gives the decimal value 9; the diode 308 is also connected to the line 278 and the Diode 310 connected to line 284, which carries the value 1, so that the combination results in the decimal value 8; the other pairs of diodes are similar for the decimal values 6, 5 and 3 connected. If now during a certain Time interval K a decimal value 7, 4, 2 or 1 is sampled, the transistor 302 placed in its non-conductive state. This occurs when only one of the Lines 278, 280, 282 or 284 carry negative potential, so that at least one The diode of each "and" gate remains continuous, and if, in addition, the collector of the As explained above, transistor 292 is at a relatively positive potential. In this combination, line 324 remains positive and transistor 302 is off. The excitation of the control line B5 leads the base of the transistor 350 negative Potential to and generates a binary 1 on line 50, but if during one other time interval a decimal 3, 5, 6, 8 or 9 is sampled, are both Diodes in the appropriate "and" gate are blocked, so line 324 is on negative potential drops and makes transistor 302 conductive. A diode 325 pulls a node 326 to ground potential and prevents the excitation of the Line B5 supplies a binary 1. In addition, no check bit is generated if a binary 0 is sampled, since during this time the collector of transistor 292 is at negative potential and thus the transistor 302 is independent of the "And" gates described above remain conductive.

In summary, the subject of this disclosure is an improved one Electronic coding device, which receives input pulses in a random sequence counts and saves. The stored information is then used in series during a selected period during which the information is protected against change and still further information is accepted and counted.

Finally, means are provided for the saved Information, as described above, to be implemented in a specific code sequence. You can see that all set goals among those evident from the foregoing description, can be achieved in an effective way. Everything in this description and in the drawings is included only by way of example and not restrictive; therefore, changes are possible to the above embodiment without the range to leave the invention.

Claims (8)

Claims: 1. Electronic coding device with one of several in series connected decadic steps existing counter, in any order incoming impulses accumulated, as well as with one to read out the accumulated Additional decadic storage level for the units level, which is used for numerical values, the content of which usually changes with that of the counter, which is marked, that the decade storage stage (28) is connected downstream of the first decade stage (18) and during one of it and the subsequent decade stages (20 ... 26) Reading process by an inhibition circuit (30) against changes in your count is protected, while the first Zähidekade (18) uninterrupted on incoming Signals. 2. Coding device according to claim 1, characterized in that the memory stage (28) has a gate circuit which is one during the reading process from the first Counting stage (18) stores the transmitted signal and stores it after completion of the reading process forwards to the second counting stage (20). 3. Coding device according to one of the preceding claims, characterized in that that each of the decade counting stages has four flip-flops connected in series, a first "neither-nor" gate (108), via which the counting steps kick the seventh count can be set according to the selected code, and on second "neither-nor" gate (110), which counts when the tenth pulse occurs resets to zero and sends a carry signal to the next higher level. 4. Coding device according to claim 3, characterized in that the memory stage (28) has four flip-flops that are parallel to the flip-flops of the first counting stage are connected and their inputs (142 to 156) via two diodes (190, 192) each Occurrence of a count suppression signal at a switching transistor (186) on Blocking potential are drawn. 5. Coding device according to claim 4, characterized by a test bit generator (48), the 7-4-2-1 code used in the counting stages for information transmission into a 2-out-of-5 code. 6. Coding device according to one of the preceding claims, characterized by a time generator (56), the several time intervals during the reading process (K) defines, during which the individual counting levels are scanned one after the other. 7. Coding device according to claim 6, characterized by a data code generator (44), which during a first time interval (K1) a binary signal for identification the type of information transmitted. 8. Coding device according to claim 7, characterized by a second Time generator (58) which divides each time interval (K) into several time segments (B), during which the individual bit positions of each counting stage by an output scanner (48) read in succession and transmitted in series over a single output line (50) will. Publications considered: German Auslegeschriften No. 1 172 307, 1176196.