DE1296189B - Circuit arrangement for a multi-stage electronic magnetic core counter with adjustable counting capacity - Google Patents

Description

The invention relates to a circuit arrangement for a multi-stage Electronic magnetic core counter with in particular between the value 1 and a maximum value adjustable counting capacity, which is one per counting stage, in particular by a counting core Contains formed, multistable storage element and which also has to be quantized Counting pulses can be controlled by setting pulses.

For the purpose of setting the counting capacity, one can use a Provide counters as primary windings of counting cores with switchable partial windings. In a known frequency divider of this type, the count rate is a stage with a Switches and taps on an input winding can be switched over. Here you can however, successive counting levels do not optimally adapt to one another.

A presettable counter is also known from Transistors and magnetic cores is composed. With this counter you can Preset decadic counting levels by adding one in each of the counting levels Voltage source with adjustable voltage and a gate circuit for applying the Voltage source is provided on a winding of the magnetic core. One of those However, counter requires too much effort for different applications, especially when there are special requirements for operational safety will.

The object of the invention is to provide a circuit arrangement for a counter to create with memory elements, its counting capacity with high operational reliability is easily adjustable.

According to the invention, the circuit arrangement for the counter is used This object is achieved in such a way that the counter is one with control pulses controllable setting unit common to several counting levels to form at least contains one type of setting pulses and that each type of setting pulses and counting stage Switching means for selecting the counting levels to be set by the setting pulses are provided.

By means of these measures, the counting volume of a counter with counting levels of fixed counting scope with high operational reliability within of a wide setting range before the start of counting and during the Count can be decreased or increased. Such counters can in particular in control, monitoring, remote control and / or measuring technology equipment use advantageously. The counter cores become automatic before setting reset, the counting process can advantageously be in any Position of the counter are canceled, the counting volume being independent of the last counter reading before initiating the setting process.

In a further embodiment of the invention, the counter is designed in such a way that that the stages for presetting each by several, from a plurality of Output pulses, in particular different voltage time values, different Setting levels of the setting unit selectable setting pulses are adjustable. With such a counter, a setting pulse can be sent to several counting cores at the same time act. In addition, several setting pulses can be fed to each counter core.

These measures result in a circuit arrangement for one Counter in which the counting levels are particularly advantageous due to the setting pulses Way in an integer multiple of the voltage time value of the Set the quantized counting pulses to an adjustable voltage time value. In the number of times for a specific change in the counting volume is advantageous The required setting levels are particularly low.

The setting pulses can be sent to several outputs of the setting unit are present in succession. A particularly simple time control can be used achieve in that a control pulse supplied to a first setting stage continuously is passed on from one setting to the next, so that the setting pulses of all setting levels are automatically output one after the other if the setting unit triggered by a control pulse. It is advantageously used for Control of the setting process no auxiliary cycle required. The setting levels can however, they can also be controlled independently of one another.

In a further development of the invention, the voltage-time areas of the setting pulses in binary graduation are equal to 2R times the voltage-time area of a counting pulse (n = 0 ... number of setting levels). Such a binary staggering of the voltage-time areas of the setting pulses emitted by the individual setting levels has the advantage that any changes in the counting volume within the maximum counting range can be implemented with the least amount of setting levels.

The counter cores to be influenced by the setting pulses can can be selected by switches or solder bridges. One adjustable this way Counters can be used advantageously in an electronic remote control system for wide area networks use a single bus line that connects all stations with one another switched channel for signal transmission. Each substation contains a multi-level magnetic core counter, the set counting scope of the address corresponds to the station. This magnetic core counter selects from a cyclically repeated one Sequence of, for example, a maximum of two hundred identical call pulses Count the call pulse assigned to the substation in question, which the Station granted permission to transmit. It is of particular advantage that all Counters are constructed in the same way and that only for setting their counting range Solder bridges need to be inserted. To get each station to one responds to another call pulse, every counter is counted before the start of a call cycle reset to another initial counter reading permanently assigned to the station. First the content of all counting levels is deleted; then the Digits of the initial count in the form of setting pulses of a defined voltage-time area entered in parallel in the individual counting levels. Each counter receives the call and synchronization characters on different inputs. In this mode of operation the high operational reliability of the meter is of particular advantage.

The invention is illustrated with reference to the FIGS. 1 to 3 shown Exemplary embodiments explained in more detail: F i g. 1 shows a block diagram of a presettable Counter with three counting levels, each of which has a maximum counting capacity of 8; F i g. 2 shows a block diagram of a presettable, eight-stage binary counter; F i g. 3 shows a circuit diagram of a binary counter according to FIG. 2.

The in F i g. 1 contains the three counting stages 15, 16 and 17 connected in a chain, each of up to eight counting stages, the pulse shaper stage 10 upstream of the counting stage 15 for outputting quantized counting pulses and the three setting stages 34, 32 and 31, which are essentially structured like the pulse shaper stage 10 , which emit quantized setting pulses for presetting the counter stages 15, 16 and 17, respectively.

A control pulse triggers a process that brings the magnetic core counter into the state that corresponds to a certain preselectable number of counting pulses. The remaining number of counts per level can be any number between 1 and the maximum level capacity. With the aid of a blocking oscillator (not shown in detail) and with a driver core, the pulse shaping stage 10 delivers a counting pulse for each pulse entered at the counting input 21. This counting pulse has the value 1, ie it magnetizes the following counting core by one of eight possible steps. The initially empty counting stage 15 stores seven of these counting pulses in its counting core (not shown in detail) and passes the eighth as a counting pulse to the counting stage 16 when the counting core is reset. This second counting stage 16 works like the first counting stage 15 and forwards the 64th pulse to the third counting stage 17 , which finally outputs the 512th pulse (83 = 512).

If you do not start with empty counting stages 15, 16 and 17 , but rather with defined, preset counting stages, the last counting stage 17 emits its output pulse earlier. In order to be able to obtain any desired counting range between 1 and 512, each of the counting stages 15, 16 and 17 is set to multiples of the change in flow caused by a counting pulse between the value 0 and the value corresponding to the maximum counting capacity reduced by 1 per counting stage, ie to values of 0 to 8 can be preset. These values are distributed with 4 on setting level 34, with 2 on setting level 32 and with 1 on setting level 31. The presetting stages 34, 32 and 31 are connected in a chain. Triggered by a control pulse, the presetting stages 34, 32 and 31 automatically deliver a reset pulse at output 41, which sets all counting cores to zero, and then at outputs 42, 22 and 12 setting pulses that are separated in time and whose voltage Time surfaces are graduated in binary. The temporal separation of the setting pulses can be achieved in that the setting stages emit a pulse derived from the trailing edge of the setting pulse to control the setting stage connected downstream in the chain. Each of the counting stages 15, 16 and 17 can be supplied with one or more preset pulses by the switches 18, 19 and 20. They cause in the in F i g. 1 counter cores, not shown in detail, a magnetization which corresponds to a certain number of counting pulses. Since the setting pulses emitted by the setting stages 34, 32 and 31 are separated in time, an optional addition of the values in the counting stages 15, 16 and 17 is possible in a particularly simple manner.

Presetting is triggered by a synchronization pulse applied to input 22 of setting stage 34. First, a blocking oscillator contained in the setting stage 34 sets the counting cores of the counting stages 15, 16 and 17 to the zero position via the output 41 and then sends a setting pulse of value 4 from a driver core of the setting stage 34 via the output 42. This setting pulse can be fed to each of the three counting stages 15, 16 and 17 via the switches 18 assigned to the counting stages 15, 16 and 17. After the end of the zeroing pulse emitted by the setting stage 34 , a blocking oscillator (not shown) of the setting stage 32 responds. When this blocking oscillator is switched off, the driver core of the setting stage 32 emits a setting pulse of value 2, which can be fed to each of the counting stages 15, 16, 17 via the switch 19. Finally, the same applies to setting stage 31 with its setting pulse of value 1.

In the case of the counter according to FIG. 1 can be any count between 1 and 512 can be set. The principle is not on three counting levels and not limited to the specified count of eight per level.

Every number D can be broken down according to the following equation: D = c.Un + b # Un-1 ... + a.Un-n, where the base number U is equal to the counting range of a level and n is the highest integer The power of the base number that D can contain is.

The following applies to levels: n = s -1. The coefficients a, b, c are whole numbers smaller than U, which indicate the weight measure with which the individual powers are contained in the number D.

Let it be in the case of the counter according to FIG. 1 z. B. U = 8 and n = 2.

It should z. B. a count of 169 can be set. The largest counting range is US = 83 = 512. The setting of the counting levels 15, 16 and 17 is made as if D = 512 - 169 = 343 pulses had already been counted. The number 343 is the complement of 169. So the decimal number D = 343 is broken down according to the given formula in such a way that the coefficients a, b and c of the polynomial are found (q = remainder): 343 = c-8z + q c = 5 q = 23 23 = b.81 + q b = 2 q = 7 7 = a-8 () a = 7 Solution: c = 5 b = 2 a = 7 That means: The counting stage 17, which corresponds to the exponent 2 receives a presetting pulse with a value of 5 corresponding to 4 -I-- 1. For this purpose the contacts 18 and 20 of the counting stage 17 are closed. At the counting stage 16 , the contact 19 and at the counting stage 15 , the contacts 18, 19 and 20 are closed. The results are compiled in a table: step A j B 1 C Exponent ........... 0 1 2 Presetting ....... from C Value ........... 7 2 5 Division . . . . . . . . . . . 4 -E- 2 -t- 1 2 4 -f- 1 Closed commitment ........... 18.19 19 18 and 20 and 20 F i g. 2 shows a block diagram of a binary counter with an adjustable counting capacity. The setting stage 9 is controlled by a control or synchronization pulse given to terminal 25 and supplies a square pulse on line 30, which Decimal binary number Counting level ................ .... 1 2 f 3 4 5 6 '7 8 Binary digit. . . . . . . . . . . . . . . ... . . . . 0 1 2 3 4 5 6 7 Complement ................... 92 0 0 1 1 1 0 1 0 N - 1 ......................... 163 1 1 0 0; 0; 1 0 1 Total ....................... 255 1 1 1 1 i 1 (1 1 1 Closed contacts .......... 1 53 54 55 11 57 The result in binary form means that the contacts 53, 54 and the one shown in FIG. 2 contacts 55 and 57, not shown in detail, of the fifth and seventh counting stage are closed in order to enter the number 92 into the counter. The binary sum 20 + 21-f-22 + ... 27 = 255 is the largest number that can be preset in such a counter. It also explains why you can read the number N - 1 instead of N in binary form on switches 51 to 58.

The numbers 92 and 163, written in binary form, show the relationship between complement and counting range. It is therefore possible at any time to convert the desired counting range N directly into a binary number if you take the number N - 1 instead of N and write a "1" for "open" and a "0" for "closed".

The binary counter retains its high counting accuracy even with larger ones Fluctuations in the operating temperature or the supply voltage at and is against larger scatter of the component parameters, in particular of the meter core scatter to a large extent insensitive.

The counter according to FIG. 2 can be used as an evaluation for systems that are output in binary form. The output of the system, the z. B. consists of relay or cam contacts or of flip-flops, correspondingly coupled to switches 51 to 58. At the time of the query with a synchronization pulse, the binary result is entered in the counter. The counter then records a certain number of pulses until the first output pulse interrupts the process. This pulse sequence already represents the decimal number. B. be done with a mechanical counter, since you can choose the repetition frequency arbitrarily. The pulses can be fed to all counting levels 1 to 8 at a higher level. All memory cores or counter cores are thereby brought into the negative remanence position. The contacts 51 to 58 determine which of the counting stages 1 to 8 receives the presetting pulse on the line 31 after the rectangular pulse on the line 30 has ended. This presetting pulse causes the same magnetization in the counting cores of counting levels 1 to 8 as a counting pulse. The “open” state of contacts 51 to 58 corresponds to a “0” in the binary code, while a 1 stands for “closed”. This binary number indicates the initial state in which the counter is set.

It should z. B. a counting range of N = 164 can be set. There eight Binary levels have a maximum counting range of 28 = 256, the complement is to 164 the number D = 92. The number 92 can be converted into a Binary number can be converted. Also integrate frequency and number with a pointer instrument Show. This also applies analogously to the counter according to FIG. 1. One can use the counter according to the invention thus as a converter between the decimal system and systems that are based on any basic number. Is used in the counter instead the counter cores formed by toroidal cores or magnetic cores the blocking circuit of Transfluxors, the current status of the meter can be read continuously.

The value of the presetting levels can be determined by a turn ratio determine and change this ratio by switching. But you can Set the value of a preset level by letting the driver core through Impulse is partially magnetized. Three impulses then correspond to the value 3 or - if implementation is desired - another corresponding value. When the driver core is reset, a pulse is then given to the counting stages Added value.

It is also possible to use the counting levels of a counter as a presetting level to use for a second meter. The resulting cascade connection offers along with the other possibilities, a variety of links.

Since the driver core depends on current, voltage, resistance or magnetize other physical quantities, the presetting and thus the counting range can be a measure of these quantities. Two counters in a kind of compensation circuit make it possible to compare two variables, especially in the case of control arrangements.

The setting pulses can move the counter cores in the same direction of magnetization affect how the counting pulses or in the opposite direction of magnetization. These types of settings enable the counting capacity to be reduced or increased. the Setting pulses can also set the counter cores saturated at the end of counting to a defined value Reset initial magnetization. The adjustment pulses can, however, on the other hand after resetting the counter cores to the magnetization state a, a defined initial magnetization cause.

The switches for selecting the counting cores can also be electronic Switches are formed. With such a counter, the counting volume easily change through control circuits.

The setting levels can be used as a quantization element for the voltage-time area of the setting pulses to be emitted contain a monostable circuit.

The counting volume of the meter can easily be influenced from the outside by that the setting steps as a quantization element for the voltage-time area of the The setting pulses to be emitted have a magnetic core with a rectangular hysteresis loop contain. Such a counter can be used to calculate the voltage-time area digitally measure a pulse input into the quantization element. Included it is useful to partially magnetize the quantization magnetic core in a defined manner. The quantization magnetic core can also be defined by an output hole in Way adjusted transfluxors be formed.

The quantization magnetic cores can also be replaced by the counting cores of others Magnetic core counter be formed. The electrical switches can also have additional Counter can be controlled. If you control the assignment of the setting levels in this way to the counter cores by other counters, so multiplications or divisions can be made carry out. The counting cores of a counter can also be used as quantization cores for several other meters can be used. The status of a counter can be monitored Enter in one or more other counters, in which (which) then continue counting can be. In this way it is possible to query the counter without the counter reading is lost. In addition, this arrangement can be used to add or subtract or be recoded. If the counting nuclei are formed by transfluxors, then the state of the circuit can be read permanently non-destructively.

In Fig. 3 is a circuit diagram of the one shown in FIG. 2 shown in the block diagram of the binary counter. Of the eight counting levels that are identical to one another, only the first two levels 1 and 2 are shown. Similar parts are provided with the same reference numerals.

In this binary counter, the pulse shaper stage 13 connected upstream of the first counting stage 1 contains the magnetic core 62, which serves as a quantization core for the magnetic core 63 of the first counting stage 1, which is operated as a counting throttle. The magnetic core 63 operated as a counting throttle acts as a quantization core for the downstream magnetic core 64 of the second stage 2. In the coupling elements, which are each arranged between two successive magnetic cores or counting cores, a counting choke and a quantization core are arranged in each case in two line branches connected in parallel and decoupled by diodes. In each case, the winding 84 of the quantization core with the diode 95 connected in series with it lies in one branch of the line, while the other branch of the line is formed by the winding 80 of the counting choke and the diode 97. Each counter stage 1, 2, ... is assigned to one of the switches 51 to 58, of the adjustment stage 9 via the provided in each counter stage diode 96 sets the output 31 either to the winding 80 of the respective magnetic core 63, 64 ....

This counter, in which all stages as multipliers of the same type are designed, allows a high counting speed and loads the supply current source only slightly. Its input circuit allows control with short pulses. Furthermore, the meter can be used in a remote control system at any time within of a call cycle synchronized, d. H. at the same time as the other meters in the initial position are brought.

The one in counting levels 1, 2. . . magnetic core 63, 64 contained in each case. . . carries the windings 80, 81, 82, 83 and 84. The winding 80 is located in a line branch of the coupling element connected upstream of the magnetic core 63, 64. The winding 82 is led on one side via the resistor 92 and the capacitor 93 connected in parallel therewith to the base of the transistor 74 and from there via the capacitor 94 to earth; on the other hand, it is due to the positive potential Uv.

The collector of the transistor 74 is connected to the negative potential UB via a series circuit comprising the resistor 95, the winding 83, the diode 95 and the winding 84. In addition, the magnetic core 63 carries the winding 81, which corresponds to the similar windings 81 of all other magnetic cores 64 ... of counting levels 2 . . . is connected in series.

The presetting stage 9 and the pulse shaper 13 are formed by identically constructed pulse shaper stages. They each contain a blocking oscillator 65 or 66, a toroidal core 61 or 62 and one as in counting levels 1, 2 ... switched reset transistor 67. The pulse shaping stages differ from the counting stages in this way; that they do not contain a wired reset winding 81 and that the input winding 80 is led via the resistor 75 and the series-connected winding 78 of the transformer 68, bridged by the diode 79, to the collector of the transistor 74 , the base of which is passed through the further, through the Resistor 72 bridged winding 73 is connected to the positive voltage.

Before counting, the counter is synchronized, ie deleted and preset. For this purpose, a control pulse is applied to the control input 25 , which is fed via the capacitor 69 and the diode 70 to the winding 71 of the blocking oscillator 65 contained in the presetting stage 9. The resistor 72, which is parallel to the other winding 73 of the blocking oscillator 65, is used to evaluate the applied pulse according to its energy. A pulse can only trigger the blocking oscillator 65 if its energy is greater than the quotient of the square of the voltage U 1 and the value of the resistor 72.

If the blocking oscillator 65 has been triggered, the collector current of the transistor 74 drives the core 61 of the presetting stage 9 far into saturation. Since the collector current is passed not only through core 61 but also through windings 81 of all counter cores 63, 64 ... , all counter cores 63, 64 ... are brought into the negative remanence position. If the transistor 74 switches off again, the magnetization of the core 61 falls back from saturation to the remanence point. This creates a voltage pulse in the winding 82 of the core 61 , which makes the transistor 67 conductive via the resistor 76 and the capacitor 77 connected in parallel therewith. In terms of alternating current, parallel to the base-emitter path of the transistor 67 is the capacitor 68, which reduces the spread of the input capacitance of the transistor 67. The collector current of the transistor 67 magnetizes the magnetic core 61 via the windings 83 and 84 of the magnetic core 61 into the positive remanence point. This process is fed back. The voltage-time area over the winding 84 of the core 61 is a measure of the flux excursion caused in the core 61. When the contact 51 is closed, the same voltage-time area is applied to the winding 80 of the magnetic core 63 of the first counting stage 1. The flux stroke of the magnetic core 61 is now in the magnetic core or counting core 63 according to the winding ratio of the winding 84 of the magnetic core 61 and the winding 80 of the magnetic core 63 stepped down. It is expedient to select the ratio of 2: 3 as the ratio of the number of turns of the output winding 84 to the input winding 80 for all toroidal cores or magnetic cores. This means that the magnetic core 63 is remagnetized from the negative remanence point up to 67% of its entire flux stroke, provided that the magnetic cores 61 and 63 are the same. The pulse shaper stage 13, which is identical to the counting stage 9, works in the same way. The first pulse applied to the counter input 24 magnetizes the counter core 63 to 67%, the second drives it safely into saturation, whereby the fallback pulse in the magnetic core 63 with the transistor 74 as well as in the magnetic core 61 causes the immediate reverse magnetization. These advantageous conditions are retained with all settings of the meter.

As long as the transistor 67 of the pulse shaper stage 13 is blocked, the magnetic cores 62 and 63 are decoupled by the diodes 95 and 97. The same applies to the magnetic cores 61 and 63, since the diodes 98 and 96 are blocked when the transistor 67 of the presetting stage 9 is blocked. It is therefore ensured that the presetting process and the counting do not interfere with each other, provided they are not carried out at the same time.

Claims (19)

Claim: 1. Circuit arrangement for a multi-stage electronic Magnetic core counter with adjustable, in particular, between the value 1 and a maximum value Counting capacity, which, for each counting stage, is formed in particular by a counting core, contains multi-stable storage element and which in addition to quantitative counting pulses can be controlled by setting pulses, d a d u r c h g e - indicates that the counter one with control pulses controllable, several counting stages (15, 16, 17) common Setting unit for forming at least one type of setting pulses contains and that depending on the type of setting pulses and counting stage (15, 1C, 17) switching means for selection the counting stages to be set by the setting pulses are provided. 2. Circuit arrangement according to claim 1, characterized in that the counting stages (15, 16, 17) for presetting in each case by several, out of a plurality of output pulses, in particular different ones Voltage time value, different setting levels (34, 32, 31) of the setting unit selectable setting pulses are adjustable. 3. Circuit arrangement according to claim 2, characterized in that the setting pulses at several outputs (42, 22, 12) the setting unit are applied consecutively in time. 4. Circuit arrangement according to claim 3, characterized in that the setting stages (34, 32, 31) of the Adjustment unit can be controlled in such a way that the one fed to a first adjustment stage (34) Control pulse is continuously passed on from one setting level to the next, so that the setting pulses of all setting levels (34, 32, 31) automatically one after the other are issued. 5. Circuit arrangement according to one of claims 2 to 4, characterized characterized in that the voltage-time areas of the setting pulses in binary graduation are equal to 2 "times the voltage-time area of a counting pulse. 6. Circuit arrangement according to one of claims 1 to 5, characterized in that the setting pulses to be influenced counter cores (63, 64) can be selected by switches or solder bridges. 7. Circuit arrangement according to one of claims 1 to 6, characterized in that that the voltage time value to which the particular before setting to the Value 0 or 1 resettable counting levels (15, 16, 17) are adjustable between the value 0 and that of the maximum counting capacity reduced by 1 per counting level Value is adjustable. B. Circuit arrangement according to one of Claims 1 to 7, characterized characterized in that the setting pulses move the counter cores (63, 64) in the same direction of magnetization affect how the counting pulses. 9. Circuit arrangement according to one of the claims 1 to 7, characterized in that the setting pulses the counter cores in other Influence direction of magnetization than the counting pulses. 10. Circuit arrangement according to claim 9, characterized in that the setting pulses are those at the end of counting Reset saturated counter cores to a defined initial magnetization. 11. Circuit arrangement according to Claim 8, characterized in that the setting pulses after resetting the counter cores to the magnetization state zero a defined Cause initial magnetization. 12. Circuit arrangement according to claim 6, characterized characterized in that the switches for selecting the counting cores as electronic switches are trained. 13. Circuit arrangement according to one of claims 1 to 12, characterized characterized in that the setting stages as a quantization element for the voltage-time area of the setting pulses to be emitted contain a monostable circuit. 14th Circuit arrangement according to one of Claims 1 to 12, characterized in that the setting levels as a quantization element for the voltage-time area of the output Adjustment pulses contain a magnetic core with a rectangular hysteresis loop. 15. Circuit arrangement according to claim 14, characterized in that the quantization magnetic core is partially magnetizable in a defined manner. 16. Circuit arrangement according to claim 14, characterized in that the quantizing magnetic core is through an exit hole a transfluxor that can be set in a defined manner is formed. 17. Circuit arrangement according to claim 14, characterized in that the quantization magnetic cores by the counting cores of other magnetic core counters are formed. 18. Circuit arrangement according to Claim 12, characterized in that the electronic switches have further Counter can be controlled. 19. Circuit arrangement according to one of the preceding Claims, characterized in that the counting cores are formed by transfluxors are.