DE1270863B - Arrangement for periodic or one-time digital speed, speed ratio, period duration, speed measurement or the like. - Google Patents

Description

Arrangement for periodic or one-time digital speed, speed ratio, Period duration, speed measurement or the like.

For measuring speeds, speed ratios, period durations, Speeds or the like, it is known, electronic digital counting methods to use. The respective measurement is based on the counting of pulses of a Encoder within a certain time or given number of pulses of a second encoder returned.

In the case of digital speed measurement, for example, there is a pulse generator appropriately assigned to the examination subject. The by the rotary motion The pulse sequence of the encoder generated by the examination object is transmitted via a logical Gate fed to an electronic counter. The logical gate will as well driven by pulses of known frequency (frequency standard). The measuring section is respectively determined by the opening of the logic gate, so that a section-by-section count the pulses generated by the encoder takes place.

When measuring the speed ratio, each examination object is one Assigned to encoder. The pulse sequence of one of the encoders is again via a logical Gates given to an electronic counter while the logic gate is related its opening now from the possibly stocky pulse train of the other Encoder is controlled.

When measuring the period, a pulse train of known frequency is used given via a logic gate to the electronic counter, the gate with regard to its opening from the impulses of the associated with the examination subject Encoder is controlled.

When measuring the speed, the pulses are counted of the transmitter connected to the examination object again by means of a logical Gate and a downstream counter, now the logic gate within of a given period of time.

In the case of the electronic ones previously used for the above measurements Counting fields can occur in counters with capacitive coupling between the counting levels if the pulses driving the counters do not meet certain conditions, such as for example, sufficient edge steepness. In a great many cases, these will Donors' demands not met. Special pulse shapers must then be given to the donors be connected downstream, which steepen the encoder pulses.

Another disadvantage of only responding to impulses of a certain shape Electronic counters then also have external electrical interference pulses counting fields can evoke. The location of the installation for such meters must therefore be carefully chosen chosen , and thus such meters are by no means without regard to local Conditions can be used.

This is particularly disadvantageous in connection with mobile devices, such as vehicles that have their own power generation and distribution systems have in limited space.

There is also the fact that, for example, by bouncing the encoder or incorrect impulses can occur due to mechanical vibrations, which get on the counters and thus also cause counting errors.

The invention results in a measuring arrangement which the above avoids the disadvantages mentioned.

Only the Requirement for a sufficient amplitude. The slope and shape No demands are made on the pulses, so that previously necessary pulse shapers omitted. For example, incorrect impulses from the encoder caused by vibrations, such as this one can occur especially in mobile systems, have no influence on the measurement result.

As already indicated above, the arrangement according to the invention is Can be used with advantage in connection with mobile systems. Here is often next to the Speed measurements also require a speed measurement. A measure of speed is the number of pulses generated by an encoder within a certain Time. The encoder is in vehicles in a suitable manner with a vehicle wheel or also be coupled with a special encoder wheel.

The encoder can, for example, be an inductive gear encoder known per se be designed, which is rigidly connected to the vehicle or transmitter wheel. The invention enables any changes that occur in the diameter of the vehicle or encoder wheel to consider. Changes in the diameter can be caused, for example, by wear or regrinding the Running surface occur. These changes of the diameter would be included in the measurement result.

The diameter is taken into account by changing the measuring time.

The invention allows a periodic or one-time measurement. at of the periodic measurement, the result in a storage group is accepted and used for display or control.

The invention relates to an arrangement for periodic or Unique digital speed, speed ratio, period duration, speed measurement od. The like. Using a measurement object encoder and measurement object counter. The invention is that means for periodic or one-time generation of a first measuring section representing signal are provided, its beginning and end with respect to the signals of the device under test is arbitrary, and that by means of a a measuring section former consisting of a memory arrangement in a second measuring section representing signal is generated so that this with a after the emergence of the first Measuring section signal occurring signal of the test object encoder occurs and with a after the disappearance of the first measuring section signal occurring signal of the test object encoder disappears and that within the second measuring section signal, the signals of the test object transducer are counted by the measurement object counter, and that in the periodic measurement the Duration of the interruption of the first measuring section signals from the frequency of the signals of the measurement object counter is made dependent. Corresponding to further training is to form the first section Messab a measuring section transmitter and a measuring section counter provided and in a measuring section former consisting of a memory arrangement the signal representing the first measurement section is generated, and from this point in time the measuring section counter counts the signals to determine the duration of the signal of the measuring section encoder, and after reaching a certain count of the measuring section counter a signal is generated by a tail unit which influences the measuring section generator in such a way that that the measuring section signal is deleted and the measuring section counter is blocked as a result will. The tail unit expediently generates for periodic measurements after the expiry of the second measuring section a signal for storing the measurement result and opposite This signal is offset in time by a further signal to delete the measurement result and the blocking signal, so that a new measuring section can be formed. One Corresponding to a further training is a DC-coupled measurement object counter used by the signals to be counted and associated signals generated by the device under test Auxiliary counting signals that do not change their state at the same time are activated and counts the signals as long as the second measuring section signal acting as counting release is present, and this measuring section signal is from the first measuring section signal formed in a memory array so that it appears with an auxiliary counting signal and disappears.

It is advisable to use a DC-coupled measuring section counter, the signals to be counted generated by the measuring section encoder and the associated auxiliary counting signals, which do not change their state at the same time, is activated and the signals counts as long as the first measuring section signal, which acts as a counting release, is present is, and this Measurement section signal is generated in a memory array and appears after initiating a measurement or automatically after completing a measurement with a Auxiliary counting signal and disappears depending on the count of the measuring section counter with an auxiliary counting signal. A further training is to be completed accordingly of the first measuring section at a certain count of the measuring section counter (for example when changing from the highest count to zero) in a storage element of the tail unit, the locking signal is set, and a single measurement remains stored until a clear signal is given, and takes place during a periodic measurement the deletion of the blocking signal and the measurement object counter by one from the control unit clear signal formed in a logic stage, the lock signal being generated of the takeover signal is used in a further logical level. Appropriate the takeover signal occurs when the second measuring section is terminated The counter reading of the measurement object counter and disappears during the periodic measurement before clearing the DUT counter. In order to change the measuring section, there are means for Setting of the desired number of counting steps of the measuring section counter provided. According to a further embodiment, the measuring section counter is set to an initial number presettable, and a signal required to enable presetting is momentary generated before the occurrence of the first measuring section signal by means of a logic stage, which is controlled by the memories of the first measuring section generator. Appropriate Preselection means are provided for the measuring section counter, and if they match of the count of the measuring section counter with the one set in the preselection means Number is a coincidence signal generated to terminate the first measurement section is used. According to a further training is in the memory element of the timer used the coincidence signal to set the blocking signal, and in a subsequent logic stage there is a time-shifted cancellation signal formed for the measuring section counter. Controls according to further training the device under test, the measuring section counter and the measuring section generator on and the Measuring section transmitter, the measuring object counter and the measuring section generator and also on the tail unit the DUT and measuring section encoder signals have been interchanged. Appropriate the device under test and measuring section encoder signals are interchanged by logical ones Circuits made by these signals and a toggle signal and its negated Form are controlled. A changeover signal influences a further training the tail unit in such a way that the measuring arrangement works either periodically or once.

The arrangement according to the invention thus makes use of two static ones Counters, one of which can preferably be preset. By the use of static meters and the direct galvanic coupling of these meters with all of them further electronic circuit parts is when using the invention Procedure is largely insensitive to mechanical and electrical Interference reached.

The invention is shown schematically with reference to in the drawing Embodiments explained in more detail. In the figures, the same elements carry the same Reference number.

F i g. 1 shows a circuit for the first four binary digits of a static dual counter; F i g. 2 shows a circuit for the lowest decade a static decimal counter, which is in the natural binary coded decimal system is working; F i g. 3 shows the measuring principle according to the invention and the structure of an arrangement to carry out the procedure; F i g. 4 shows the more precise design of the arrangement according to FIG. 3 for a periodic measurement; F i g. 5 shows a signal diagram for the arrangement according to FIG. 4; F i g. 6 shows the more precise design of the arrangement according to FIG. 3 for one-time measurement; F i g. 7 shows a signal diagram for Arrangement according to FIG. 6; F i g. 8 shows circuits for the counters after the F i g. 1 and 2 guided signals 1 e and 2 e; F i g. 9 to 13 show partial circuits for the measuring arrangements according to FIGS. 4 and 6; Fig. 14 shows a switch for the encoder pulses; F i g. 15 shows one of the FIGS. 3 corresponding arrangement that instead of presetting means contains preselection means; F i g. 16 shows the more detailed training the arrangement according to FIG. 15 for a periodic measurement; F i g. 17 shows a the F i g. 16 associated signal diagram; F i g. 18 shows a possible circuit for the preselection means; F i g. 19a to 19d show partial circuits for the arrangement according to FIG. 16.

In the F i g. 4, 6, 16 are storage elements for one bit through one small black corner square marked. Multiple storage element icons also have a small black triangle. The memory symbols have two outputs. The "affirmative" exit is through a white, the "negative" exit through one shown in black bars.

The static counters according to FIGS. 1 and 2 are by patent 1 170 001 is known per se. Let us therefore only briefly refer to the counters after the F i g. 1 and 2 of the present invention.

Each counting stage consists of a main memory SA and an auxiliary memory SH. All components are galvanically coupled. Except for the signals to be counted - in FIG. 1 with tl, in FIG. 2 labeled Y1 - are used for control Auxiliary counting signals required - in the fig. 1 with t2, in FIG. 2 labeled Y2 -, which are offset in time with respect to the counting signals, appropriately against each other gaping. The counting result is taken from the outputs of the main memory - in the F i G. 1 with 1A, in FIG. 2 labeled 2A - output. The deletion via memory takes place by a delete signal in FIG. 1 with 11, in FIG. 2 with 21.

By means of preset signals 1k or 2k (for example from switches or save out) can if a special preset release signal is present If or 2f any starting number can be preset. The signals 1zl, lz2 or 2zl, 2z2 are used to enable counting. The counting signals are only counted when the signal 1 z2 or 2z2 is present. The signals 1 e and 2e are introduced, so that all counting levels are identical in structure. Circuits for generating the signals 1e and 2e show the F i g. 8 a and 8 b. Through the in the figures on the right to the A- Letter combinations written down in the corridors indicate that the individual Signals are combined in AND stages and the output of these AND stages at the input connected.

The static counters are characterized by a high level of counting reliability the end. The signals acting on such a counter can be of any form. the Interposition of a trigger is not necessary. Whether a signal as present (L) or non-existent (0) depends only on its amplitude.

Repeated disappearance and reappearance of a signal like this for example, can be caused by bouncing during signal generation no interference; because there are several between two auxiliary counting signals t2 (or Y2) t1 pulses (or yl pulses) are evaluated as a counting signal t1 (or yl), several 4 pulses (y2 pulses) occurring between two t1 signals (yl signals) are effective correspondingly as a 4 signal (y2 signal).

The measuring principle according to the invention and a simplified design a measuring arrangement is shown below with reference to FIG. 3 explained in more detail.

The arrangement consists of a Meßobjektgeberl, which is suitable Way is coupled to the test object. This encoder 1 generates on two separate Lines two pulse trains Yl, Y2 which occur in gaps with one another, as in the Figure indicated. For the sake of simplicity, only one line is shown. The duration the impulses and the pauses between the impulses do not need to be the same. The pulses y control a measurement object counter 2, one consisting of storage elements Measuring section builder 6 and the tail unit 7 on. The measurement object counter 2 is a dual counter according to FIG. 1 trained. (It can also be a decimal counter as shown in Fig. 2 Presetting means can be omitted. The measuring section builder 6 controls the DUT counter 2 and the tail unit 7 on.

The arrangement also consists of a measuring section transmitter 3, for example can be a frequency standard or another device under test. The measuring section transmitter 3 generates signals t1, t2, which also occur with gaps from one another, as in FIG the figure is indicated. The pulse sequences t1, t2 also occur again each at one Line on. The pulses t of the measuring section transmitter 3 control a measuring section counter 4, a measuring section former 5 consisting of storage elements and the tail unit 7 at. The measuring section counter 4 is a decimal counter according to FIG. 2. (He can also like a dual counter according to FIG. 1.) He controls the tail unit 7 at. The measuring section generator 5 controls the measuring section counter 4, the counter 4 associated presetting means 9 and the measuring section generator 6. The tail unit 7 controls the measuring section former 5, the measuring object counter 2 and one to the measuring object counter connected display device 8. (In the case of a one-off measurement, the control is of the measuring object counter and the display device from the tail unit are not necessary.) The Display device 8 consists of storage elements, converters and suitable display means.

Before starting a measurement, all storage elements of the system are by a in the F 1 g. 3 operating clear signal IB, not shown, deleted.

A measurement is given by a to the measuring section former 5 Signal initiated; it can also be applied to the measuring section generator 5 effective signal to be switched off. Instead of signals Ze, Za can of course also be switched on and off with a switch take place. A measurement that has already started will end after switching off guided. The measuring section generator 5 forms using the signals t of the measuring section generator 3 a first measuring section signaliz2 of selectable duration, which the measuring section counter 4 for counting the pulses t1 of the measuring section encoder 3 releases.

The duration of the first measurement section can be set at the presetting means9 can be set. The presetting means have, for example, switches for setting a number lk. In the presence of one of the presetting means before the start of a Count of the preset enable signal 1f generated becomes 1k as the initial number in the counter entered. The measuring section counter 4 starts counting from this initial number of the measuring section signal 1z2 up to a certain count, for example his highest.

When this count is reached, the measuring section counter 4 a signal iHn is generated and sent to the tail unit 7. The tail unit thus forms a locking signal Sp acting on the measuring section forming device 5, which the first Signal lz2 representing the measuring section deletes and thus the measuring section counter 4 for the further counting of signals tl blocks.

Using the first measurement section signal 1z2, Signals 7 of the measurement object encoder 1 through the measurement section generator 6 a second measurement section formed, which is offset in time from the first. The second measurement section is represented by a signal 2z2. The signal 2z2 gives the counter 2 to be measured for the duration of the second measuring section to count those coming from the measuring object transmitter 1 Signal Y1 free.

The second measuring section signal 2z2 also acts on the tail unit 7 a. If the measurement section given by the signal 2z2 has ended, the Tail unit 7 a given to the storage elements of the display device 8 takeover signal ü generated, so that the output signals 2A of the measured object counter, the count forming the measurement result is accepted. The count result is if applicable decrypted and displayed. Should the measurement result only be used for control purposes an advertisement can of course be omitted.

Forms after the counting result has been transferred to the display device the tail unit 7 a temporarily occurring clear signal 21, which the measurement object counter 2 clears. Furthermore, the blocking signal output by the tail unit is activated by the signal 21 Sp deleted so that a new measurement time can be created.

In the case of a periodic measurement, measurement sections are continuously generated and measured values determined. The display in the device 8 only changes upon completion of a measuring section.

The storage group for taking over the measurement result is for periodic Measurements always required. In the case of a one-time measurement, this can be are omitted and the count of the measurement object counter 2 is used immediately for display will.

The F i g. 4 shows a detailed arrangement for a periodic Measurement. As in FIG. 3, the measurement object encoder is again at 1, the measurement object counter with 2, the measuring section transmitter with 3 and the measuring section counter with 4. In FIG. 4 it is indicated that the device under test, in addition to the "affirmative" signals Y1, γ2 also generate the "negated" signals y1, y2 and, accordingly, the measuring section transmitter in addition to the signals 4, t2, the signals t1, t. For understanding how it works however, this is irrelevant.

The remaining parts of the measuring arrangement according to FIG. 3 are in the F i g. 4 broken down. The first measuring section former 5 consists of the storage elements 5.1, 5.2 and 5.3; they generate the signalsz, 1zl and 1z2. The second measuring section builder 6 consists of the storage elements 6.1 and 6.2; they generate the signals 2z1 and 2z2. The tail unit 7 contains a storage element 7.1 for generating the signal Sp and two logic stages 7.2 and 7.3, which form the signals u and 21. The display device has a group of storage elements 8.1, converters 8.2 and display elements (lamps) 8.3. The presetting means include a presetting register (e.g. switch) 9.2, which outputs signals, and a logic stage 9.1 for forming the signal if.

The circuits for parts 5.1, 5.2, 5.3, 6.1, 6.2, 7.1, 7.2, 7.3 and 9.1 are shown in FIGS. 10 to 13 reproduced. The following are the switching functions compiled for these circuits: Z = (Ze & Za & lB) V (Z & Za & 7E), 1z1 = (z & tl & V & Sp) V (1z1 & lB & Sp), z2 = (1z1 & t2 & lB) V (1z2 & 1z1 & lB) V (1z2 & t2 & lB), if 1z1 & 1z2, 2zl = (1z2 & γ1 & lB) V (2z1 & 1z2 & lB) V (2z1 & γ1 & lB), 2z2 = (2z & 2 & T) V (2z2 & 2z1 & lB) V (2z2 & γ2 & lB), Sp = (t1 & 1Hn & 2l) V (Sp & 21), ü = 72 & 2Z1 & Sp, 21 1EV (2z2 & yt) -The mode of operation of the measuring arrangement according to FIG. 4 becomes the periodic measurement in connection with the signal diagram according to FIG. 5 explained.

In the signal diagram there are different frequencies for the impulses and t assumed so that two different, independent grids are used for the display result whose vertical lines are not aligned with each other. In the diagram are the Pulses 4, t2 selected so that they have a shorter duration than the pulses 71, γ2 to have. The circumstances can of course also the other way around be. For the sake of clarity, the respective negative impulses are, for example tl, not shown in the diagram. This also applies to all other signals of the diagram. The signals can assume the state L or O, as is the case with the Impulse tl is indicated.

Before starting a measurement, all storage elements of the system are cleared with the operation clear signal 113. The signal 113 can, for example, be composed be from a cancel signal triggered by a key at any time is and a further clear signal IA, for example, forcibly after switching on of the entire system is generated. A circuit arrangement for this is shown in FIG. 9. The one for the measuring section counter in FIG. 1 marked 11 clear signal is identical to signal 113. The one for the measurement object counter in FIG. 2 with 21 marked clear signal occurs with the signal 113 and - as explained below - at other times.

A measurement is initiated by a count command signal z. That Signal z can be generated with the aid of a switch; but it can also - how it in the fig. 4 is shown - in a storage element 5.1 from a switch-on signal Ze and a switch-off signal to be formed. A circuit for this memory element FIG. 10a. The output signal z of the memory element is with occurrence of the signal is set and deleted when the signal zu or lu occurs. The signals Ze, Za can be triggered, for example, by keys. One press of a button, for example for generating the switch-on signal, can take longer than determining one Measurement result. In the signal diagram there is a cross for the signals Ze, Za Period indicated in which the state of these signals is arbitrary.

The counting command signal z becomes a signal in the memory element 5.2 1 z1 and from this the first measuring section signal 1 z2 is formed in the memory element 5.3.

The circuits for this memory element are shown in FIG. 10b and 10c. As is also the case in the signal diagram according to FIG. 5 is shown, occurs, after the signal z = L, the signal 1 z1 with a signal tl of the measuring section transmitter 3 on and with the following signal t2 of the measuring section transmitter the signal 12. The Signal 1 z1 disappears when the locking signal generated by the tail unit is present Sp, the signal 1 z2 with the subsequent signal t2 of the measuring section transmitter 3. (The signals 1zl, 1z2 can also be deleted by the signal 113.) The Signal 1z2 therefore always occurs with the beginning of an auxiliary counting signal ta of the measuring section encoder and also disappears with the beginning of a single glass 12.

The time shift between the occurrence of signals 1zl and 1z2 is used in logic level 9.1 to generate the preset enable signal 1f is used for the measuring section counter 4. The circuit for stage 9.1 shows the F i g. 11. The signal 1f occurs when the signal 1z1 = at the same time L and the signal 1z2 = 0.

Level 9.2 can, for example, be a register of switches, at which any number - represented by signals 1k - can be set can.

If the preset release signal lf = L is present, the Signals 1k are stored in the measuring section counter 4. The presetting of the measuring section counter takes place immediately before the counting enabled by the measuring section signal 1z2 corresponding to L. In the signal diagram, the presetting is a 7 by the presetting signals lko, 1k1 and 1k2 corresponding to L.

A four-stage counter is used as the measuring section counter for the signal diagram Dual counter according to FIG. 1 accepted. The output signals of the main memory of its Counting levels are with 1A, to 1A3, the auxiliary memory of the counting levels with 1 H0 to 1H3. After the measuring section signal 1z2 occurs, the measuring section counter counts continue from the preset number (in the example from 7 with the first counting signal t1 of the measuring section encoder to 8, with the following signal t1 to 9 etc.) up to its highest count (in the example to 15) and presents itself with the following Counting step to zero.

The signal lHn of the auxiliary memory that is present at this point in time the counting level with the highest value - denoted in the signal diagram with 1 H2 - controls the storage element 7.1 of the tail unit 7. The tail forms how it also shows the signal diagram at the time of transition of the measuring section counter from the highest count to zero the locking signal Sp. The signal Sp clears that Signal 1 z1 generating memory element 5.2; with the subsequent signal t2 des Measuring section transmitter also disappears the signal forming the first measuring section 1 z2. The measuring section counter 4 is then used to count further signals 11 the measuring section encoder 3 locked and remains in its zero position.

Since the measuring section counter 4 after reaching the highest count with the following signal in itself to zero does not need at this point in time special extinguishing signal to be triggered. The measuring section counter is only forward Start of the measuring process (which can include many individual measurements) by means of the operating clear signal 113 deleted.

Is the number of possible counting positions of the measuring section counter equal to N and if it is preset to the number 1k, it makes N-lk counting steps, to count to zero. In the example, the four-stage dual counter has sixteen possible Counting positions (0, 1, 2 ... 15); after presetting the number 7, it arises after 16-7 = 9 counting steps to zero. However, this number of counting steps the duration of the first measurement section signal 1z2 is determined. As from the signal diagram As can be seen, in the example it has one of the nine counting steps of the measuring section counter corresponding duration of nine periods of the signals t of the measuring section transmitter. at predetermined frequency of the measuring section encoder signals can therefore be the duration of the first Measurement section can be varied by selecting the presetting.

With the aid of the storage elements, the first measurement section signal 1 becomes Z2 6.1, 6.2 in the second measuring section builder 6 that representing the second measuring section Signal22, formed. The circuits for the storage elements 6.1, 6.2 show the F i g. 12a and 12b. The memory element 6.1 generates from the measuring section signaliz2 first a signals, and the storage element 6.2 from the signals, the signal 2z2. After the first measurement section signal 1z2 is L, the first then the count signal 71 of the test object encoder 1, the signal 2zl and with the the following auxiliary counting signal 72 of the device under test, the signal 22, set; after this the first measuring section signal is again corresponding to 0, will with the first subsequent signal 7i the signal 2z1 and with the then following signal 72 the signal22 deleted. (The signals 22, 2z2 can also be activated by the operating signal 113 can be deleted.) By the way in which the second measuring section signal is formed 2z2 it is ensured that with the beginning of a signal 72 from the device under test occurs and disappears with the beginning of a signal 72 of the device under test.

During the duration of the second measurement section signal 2z2, the measurement object counter is on 2 released for counting the signals 7i of the device under test 1. For the signal diagram is for example a counter according to Fig. 2 with one decade (four counting levels) accepted. The output signals of the main memory of the counting stages are with 2A, O to 2A3 °, which the auxiliary memory of the counting levels designates with 2H, O to 2 H30.

Since no presetting means are required for the measuring object counter, can the in the F i g. 2 drawn input and stages of the main memory for the signals 2k, 2f output by presetting means are omitted.

In the example shown in the signal diagram, the DUT counter, while the second measuring section signal 2z2 = L, corresponding to that within this The pulses 7i emitted by the measuring object transmitter are counted to 5. (On disappearance of the first measuring section signal 1Z2 is still in the DUT counter in the signal diagram the count 4.

When the second measuring section signal disappears, it is at 5, da Another pulse yt occurred between the disappearance of the signals lz2 and 2z2 is.) The count reached by the measurement object counter, which is represented by the signals 2A (in the example the number 5), is of the memory elements 8.1 of the display device when a takeover signal generated by level 7.2 of the tail unit occurs ü taken over. The measurement result determined in the 8-42-1 code can be stored in the converter 8.2 (every decimal digit naturally-binary-coded) converted into the 1-out-of-10 code so that a display with number lamps 8.3 can take place.

After the measurement result has been transferred to the memory group of the display device the measurement object counter 2 is formed by one of the stage 7.3 of the tail unit Clear signal 21 cleared. So that the measuring object counter as well as the measuring section counter is deleted before the start of a measuring process, this delete signal also occurs Appearance of the operation cancel signal 113. The clear signal 21 also clears the DUT counter the locking signal Sp. This can be done again in the manner described a new measuring section signal 1z2 for the measuring section counter and from this a new one Measurement section signal 2z2 for the measurement object counter are formed and thus a new one Measurement take place.

The circuits for the system consisting of parts 7.1, 7.2 and 7.3 The tail unit is shown in FIGS. 13a, 13b and 13c. This becomes the control below of the measurement process required tail unit explained in summary.

As has already been stated, the blocking signal Sp should occur, if the measuring section counter has reached the highest count with the sets the following signal t1 of the measuring section encoder to zero. At this point only is both the signal t and the output signal of the auxiliary memory of the counting stage with the highest value 1 Hn (in the Example the SignalHD according to L. That simultaneous presence of the signals elHn and t1 is used to set the signal Sp generating storage element 7.1 exploited. While the measuring section counter sets to zero, the signal Sp clears the signal 1z1. With the following Signal t2 of the measuring section transmitter, the signal 1Z2 disappears and blocks the measuring section counter. After the signal 1z2 is correspondingly 0, des disappears with a signal y1 DUT the signal 2z1 and with the following signal 72 of the DUT the signal 2z2. The count of the measured object counter reached at this point in time represents the measurement result and is stored in the memory elements 8.1 of the display device accepted. The signal ü that triggers the takeover is in stage 7.2 of the tail unit educated. It occurs with a signal 72 from the DUT, during the lock signal Sp corresponds to L and the signal 2z, (or 2z2) corresponds to 0.

After the measurement result has been transferred, the following signal 7i of the device under test generates the clearing signal 21 in stage 7.3 of the tail unit (The one shown in dashed lines for stage 7.3 in the circuit according to FIG. 13c Input is not required for the periodic measurement described here.) The Signal 21 occurs when signal 22, corresponding to 0, and signal 7i, corresponding to L is and also in the presence of the delete signal 113. With the signal 21 the measurement object counter and the locking signal Sp are cleared. After the Signal Sp is - as shown in the signal diagram - with the following signal t1 of the measuring section transmitter in the memory element 5.2 again the signal 2z1 and with the signal 1 Z2 is set to the subsequent signal t2 in the memory element 5.3 and thus, if the signal z is still present, a further first measuring section initiated. After the presence of the signal, the occurrence of a signal of the device under test 1 the signal, and with the following signal 72 the signal 25 is set and thus again the measurement object counter for counting the signals Y1 des DUT released.

In the signal diagram according to FIG. 5 is believed to be during the second measurement terminates the counting command signal z by a switch-off signal za will. The measurement that has already been started will still be completed, as this will Signal 1 z2 representing the first measurement section remains set. After setting the Signals 1z1, 1z2 disappears - apart from the operating clear signal 113 - the signal 1z2 only with a signal t2 after the signal 1 Z1 is correspondingly 0, which in turn is only deleted by the signal Sp, so the measurement should take place at any point in time are ended, for example, a key is pressed through which the signal Za is generated according to L. However, the current measurement will come to an end as indicated in the diagram. The from the display device 8 after the F i g. 4 then remains visible until a final Cancellation by signal 113 takes place. If a measurement is interrupted 6011, in this way, the operation cancel signal 113 can be brought into effect immediately.

The periodic measurement will in practice be longer than two Cycles extend. The speed of the output of the count of the DUT counter 2 adapts itself automatically to the frequency of the encoder pulses 7. Is the pulse frequency high, the duration of the interruption between two measurement times is small. Is the pulse frequency low, there is a correspondingly longer interruption duration. In each Case this is sufficient so that the described synchronization of the measurement time signals 1 Z2,2Z2 can take place with the encoder signals t2 or y2. In general, the Interruption (duration during which a measuring section signal is 0) very small compared to the Measuring time (duration during which a measuring section signal is L).

For speed measurements on moving land vehicles A change in the wheel diameter can occur through appropriate presetting the measuring section counter 4 are corrected; the measurement times are useful here selected so that the measurement result is displayed in the desired unit (e.g. km / h) will.

Of course, the counters used generally have more than four counting levels.

An arrangement for a one-off measurement is shown in FIG.

Compared to the arrangement for a periodic measurement according to FIG the arrangement according to FIG. 6 in that the tail unit 7 is modified is. The step 7.3 required for the periodic measurement is superfluous. at of the one-time measurement, only a single cycle occurs, at the end of which the measurement object counter is activated 2 shows the final result.

The arrangement according to FIG. 6 is used in conjunction with the signal diagram according to FIG. 7 explained in more detail.

As can be seen from the diagram, the initiation of the cycle is correct with the introduction in the signal diagram according to FIG. 5 completely matched.

(A special switch-off signal is superfluous.) It will Signal 1z2 formed, which represents the first measurement section. While the signal 12 = L, the measuring section counter counts the signals t1 from the measuring section transmitter. To the Time of transition of the measuring section counter 4 from the highest count to zero a signal Sp, which is the first measuring section signal, arises in turn in a storage element 7.1 1 Z2 clears and thus locks the measuring section counter.

The memory element 7.1 of FIG. 6 differs from that of the fig. 4 only in that it instead of the signal 21 by the signal 113 is deleted. As in the case of the periodic measurement, the first measurement section signal becomes 1 Z2 derives the signal 2z2 representing the second measurement section. While that Signal 2Z2 is L, the DUT counter counts the signals 7i of the DUT. When the signal disappears, a signal u is again formed, for which a Step 7.2 according to FIG. 6 is provided. It can be just like level 7.2 after the F i g. 4 be formed. The two input signals 72 and 2T can also through the signal2z2 are replaced. The signal ü opens the display device 8 for acceptance of the count of the measurement object counter 2. This count can now be of any length queue. Only when an operating signal 113 occurs is the signal Sp deleted, which previously resulted in a renewed setting of the signal after the transition of the Measuring section counter 4 prevented from peaking to zero. After deleting the Signal, a new cycle can be initiated when a signal z occurs.

The memory of the display device can be used for the single measurement also omitted, since the measurement result remains stored in the measurement object counter.

The storage element 7.2 for forming the signal u can then also be omitted. A display device connected to the measurement object counter is provided in this case the current status of this counter during a measurement and after completion of the Measure the result.

In order to be able to choose between periodic or one-time with a single arrangement To carry out measurements, a switching signal is used in the arrangement for periodic measurements A introduced into the tail unit.

This signal also controls stage 7.3 of the F i expediently G. 4 at. In the circuit of stage 7.3 according to FIG. 13 c this is indicated by the dashed line Input for signal A indicated.

If A = L, a single measurement is carried out; because then the signal is correct 21 corresponds to signal 113, the locking signal is not automatically deleted, and only after a clear signal 113 has been generated does the locking signal disappear, and a new measurement can be initiated. If AQ = 0 there is a periodic Measurement; because in this case the signal 21 remains as it was for the periodic Measurement has been described.

For a period measurement, for example, the number of Pulses from the measuring section encoder (frequency standard) within a certain number of pulses from the DUT are counted by the DUT counter. The measurement section is then given by a certain number of pulses from the DUT, the are counted by the measuring section counter. This procedure is appropriately used when the frequency of the target transducer signals is low.

Should one and the same arrangement without change for both measuring possibilities (Frequency and period measurement) are used, additional circuits can be used according to FIG. 14 the measuring section and measuring object encoder are connected downstream. the Circuits of FIG. 14 consist of input and stages with downstream Or-not stages, which are controlled by the encoder signals and a switchover signal u will. In the arrangements according to FIGS. 4 and 6 replace the output signals 1G ,, g the signals tan t2, the output signals 2Gl, 2G, the signals 7i, Yl, the Output signals 2 2G2 the signals 72, 72 If the switchover signal u = 0, then 1 G1 = t1, 1G2 = t2, 2G1 - y ,, 2G, = yz; so there is a frequency measurement or a measurement of the same type as shown in FIGS. 4 and 6 is shown. Is this Switchover signal p ^ L, then 1 G1 = Y1, 1 pa = 72, 2G1 = t1, 2G2 = t2; it takes place thus a period measurement.

Both in the above-described method for periodic as Even for a one-off measurement, the first measurement section is selected by setting a number alk on the presetting means. The duration of the first measurement section is then given by the number of counting steps that the measuring section counter makes, to count to zero. The number of these counting steps is, however, equal to the complement the preset number alk for the number of possible counting positions of the counter.

Used as a measuring section counter instead of an up counter a down counter and sets this to the number by the presetting means 1k a, so he makes 1k counts to count to zero.

The duration of the first measurement section is then directly through the preset number given.

Should be used when using an up counter as a measuring section counter the number of counting steps determining the duration of the first measuring section Counter can be given directly by a set number, so you can use the counter Count from zero to the set number. The F i g. 15 shows a Arrangement for this procedure.

A comparison of FIGS. 15 with FIG. Figure 3 shows that the presetting means 9 according to FIG. 3 have been omitted. The measuring section counter 4, which is shown in FIG. 1 can be designed, therefore does not require the input AND stages for the from Presetting means output signals, If. Instead of the presetting means are at the arrangement according to FIG. 15 pre-selection means 10 have been added.

Generated after initiation of a measurement by the switch-on signal Ze the measuring section generator 5 the signal 1z2 representing the first measuring section, the enables the measuring section counter 4 to count the measuring section encoder signals. the control output signals 1A of the measuring section counter indicating the respective count the preselection means 10 on.

If the count of the measuring section counter agrees with the generate the desired number of counting steps set in the preselection means the preselection means 10 a coincidence signal os, which (instead of the signal lHn after the F i g. 3) controls the tail unit 7. The tail unit forms a cancellation signal 11 for the Measuring section counter and a blocking signal Sp, which interrupts the measuring section signal 1z2. After the signal is 0, the measuring section counter for the next Counting of signals from the device under test blocked; after solving the measuring section counter by means of the signal 11, this remains in the zero position.

As already in connection with FIG. 3 is described from the first measuring section signals, in the measuring section generator 6 the opposite of the signal 1z2 time-shifted second measuring section signal 2z2 is formed. During the through the signal, given duration of the second measurement section counts the measurement object counter 2 the signals of the device under test 1. As has also been described, the If necessary, the measurement result is displayed, the measurement object counter and the locking signal Sp cleared. After the signal Sp has been deleted, the signal 1z2 can be formed again and thus a new measurement time formation will take place.

16 shows a more detailed design of the circuit according to F i g. 15 for periodic measurements. How a comparison with the F i g. 4 shows contains the arrangement according to FIG. 15 instead of presetting means the preselection means 10.1 and 10.2; the tail unit also contains stage 7.4 for generating the signal 1 L The stage 10.1 can, for example, be a register of switches with which any number w can be set. Level 10.2 is a coincidence term, that when the number w coincides with that of the signals 1A of the measuring section counter The count shown forms a signal os F i g. 18 shows an embodiment for the preselection means for four counting levels of the measuring section counter. It is believed that by closing the switches wO and w2 a 5 is set. As the switch in Are connected in series to the outputs of the measuring section counter, are the input signals JBO and jBa of the AND stage connected downstream of the switches are equal to 1A and 1A2, respectively. the Input signals j Pa act on the AND stage because of the open switches lvl, w3 like signals according to 2. If the measuring section counter has counted to 5, are the signals 1A, and 1A2 corresponding to L. Since then all input signals of the AND stage L, the signal corresponding to L.

The F i g. 19a to 19c show the circuits of stages 5.2, 5.3 and 7.1 according to FIG. 16, which compared to the corresponding stages according to F i G. 4 are modified; the F i g. 19 d shows the opposite of the arrangement according to F i g. 4 added level 7.4.

The temporal position of the with the arrangement according to F i g. 16 generated Signals is in the signal diagram of FIG. 17 shown.

After the arrangement according to FIG. 4 using the signal diagram according to FIG. 5 has been explained in detail, this should be according to the arrangement the F i g. 16 associated signal diagram according to FIG. 17 easily understandable be.

If only a single measurement is to be made instead of the periodic measurement, can in the arrangement according to FIG. 16 levels 7.3 and 7.4 are not applicable. the Clear signals 11 and 21 for the counters 4 and 2 are then with the operation clear signal 113 identical. Furthermore, the storage elements 8.1 and the stage 7.2 can be omitted.

If one wants to use the arrangement according to FIG. 16 for both periodic as well as one-off measurements, it is analogous to the arrangement according to FIG. 4 introduced a switching signal A in stage 7.3.

Claims (14)

Claims: 1. Arrangement for periodic or one-time digital Speed, speed ratio, period duration, speed measurement or the like. using a measurement object encoder and measurement object counter, characterized in that that means for the periodic or one-time generation of a first measuring section representing signal (1z2) are provided, the beginning and end of which with respect to the signals (y) of the test object encoder (1) is arbitrary, and that by means of one off a memory arrangement existing measuring section former (6) a second measuring section representing signal (2z2) is generated so that this is with a after the emergence of first measuring section signal (1z2) occurring signal (y) of the measuring object encoder (1) occurs and with one that occurs after the first measuring section signal (1z2) has disappeared Signal (7) of the measurement object encoder (1) disappears and that within the second measurement section signal (2z2) the signals (y) of the measurement object encoder (1) are counted by the measurement object counter (2) and that in the periodic measurement the duration of the interruption of the first Measuring section signals (1z2) of the frequency of the signals (8) of the measuring object counter (2) is made dependent. 2. Arrangement according to claim, characterized ge. indicates that to education of the first mass. from a measuring section transmitter (3) and a measuring section counter (4) are provided and ir one consisting of a memory array Measuring section former (5) generates the signal (1z2) representing the first measuring section is and from this point on the measuring section counter (4) to determine the duration of the signal (12) the signals of the measuring section encoder (3) counts and after reaching a certain count of the measuring section counter (4) by a tail unit (7) a signal (Sp) is generated which influences the measuring section generator (5) so that the The measuring section signal (12) is deleted and the measuring section counter (4) is blocked will. 3. Arrangement according to claim 1 and 2, characterized in that for periodic measurements of the tail unit (7) after the end of the second measuring section (2z2) a signal (ü) for storing the measurement result and in relation to this signal (ü) staggered in time a further signal (21) to delete the measurement result and of the blocking signal (Sp) generated so that a new measuring section can be formed. 4. Arrangement according to claim 1 to 3, characterized in that a DC-coupled measurement object counter (2) is used by the measurement object encoder generated signals to be counted (7i) and associated auxiliary counting signals (72) that are not change their state at the same time, is activated and the signals (7i) counts as long as the second measuring section signal (2z2) acting as counting release is present is, and that this measuring section signal from the first measuring section signal (lZ2) in a memory arrangement (6.1, 6.2) is formed so that it is provided with an auxiliary counting signal (72) appears and disappears. 5. Arrangement according to claim 1 to 4, characterized in that a DC-coupled measuring section counter (4) is used by the measuring section encoder (3) generated signals to be counted (t1) and associated auxiliary counting signals (t2), the do not change their state at the same time, is activated and the signals. (ti) counts as long as the first measuring section signal acting as counting release is present is, and that this measuring section signal (1z2) in a memory arrangement (5.1 to 5.3) is generated and after initiation of a measurement or automatically after completion a measurement with an auxiliary counting signal (ta) appears, and depends on the count of the measuring section counter (4) with an auxiliary counting signal (t2) disappears. 6. Arrangement according to claim 1 to 5, characterized in that for Termination of the first measuring section (1z2) at a certain count of the measuring section counter (4) (for example during the transition from the highest count to zero) in a storage element (7.1) of the tail unit (7) the locking signal (Sp) is set and for a single measurement remains stored until a clear signaling (113) and a periodic one Measure the solution of the blocking signal (Sp) and the measurement object counter (2) by a from the tail in one logical stage (7.3) formed erase signal (21) takes place, wherein the blocking signal (Sp) for generating the takeover signal (ü) in a further logic Level (7.2) is used. 7. Arrangement according to claim 1 to 6, characterized in that the Acceptance signal (ü) when the count is given by the termination of the second measuring section of the measurement object counter (2) occurs and in the periodic measurement before deletion of the target counter disappears. 8. Arrangement according to claim 1 to 7, characterized in that for the purpose Measuring section change Means for setting the desired number of counting steps of the measuring section counter are provided. 9. Arrangement according to claim 8, characterized in that the measuring section counter (4) can be preset to an initial number and that a preset release required signal (1 shortly before the first measurement section signal occurs (dz2) is generated by means of a logic stage (9.1), which is generated by the memories of the first measuring section generator (5.2, 5.3) is controlled. 10. The arrangement according to claim 8, characterized in that for the Measuring section counter preselection means (10) are provided and when the Count of the measuring section counter with the one set in the preselection means Number a coincidence signal (oc) is generated that to terminate the first measurement section is used. 11. The arrangement according to claim 10, characterized in that in the Storage element (7.1) of the tail unit the coincidence signal (o) for setting the blocking signal (Sp) is used and in a subsequent logical stage (7.4) in terms of time offset a clear signal (11) is formed for the measuring section counter (4). 12. Arrangement according to claim 1 to 11, characterized in that the measuring object transmitter (1) the measuring section counter (4) and the measuring section generator (5) and the measuring section generator (3) controls the measuring object counter (2) and the measuring section generator (6) and also on the tail unit (7) an interchanging of the measurement object and measuring section encoder signals is made. 13. Arrangement according to claim 12, characterized in that one Interchange of the target and measuring section encoder signals by logic circuits takes place by these signals and a toggle signal (u) and its negated Form to be controlled (Fig. 14). 14. Arrangement according to claim 1 to 13, characterized in that a switching signal (A) influences the tail unit (7) in such a way that the measuring arrangement is optional works periodically or once (Fig. 13c). ~~~~~~~ Publications considered: German Auslegeschriften No. 1 119 025, 1 163 446.