DE2020393A1 - Error protection with incremental measuring systems - Google Patents

Description

Error protection in incremental measuring systems The invention relates to a method and an arrangement for error protection in incremental measuring systems for direction-dependent distance measurement by means of phase-shifted electrical Scanning signals.

Incremental position measuring systems are known to be based on the Pulse increment method, each change in the value of the measurand in pulses counts.

In the case of incremental measuring systems, there is therefore no fixed relationship to the original starting position.

As a result, a measurement error that occurs once also all subsequent measurements falsified.

There are already arrangements for error protection with incremental Measuring systems become known. These are interspersed in a transmission path Interference pulses suppressed, in such a way that the pulses to be transmitted as complementary pulses of the same phase position on different channels one logical Network on the receiving end. Via the network output Only then are pulses emitted, two transmission channels occur at the same time complementary signals arrive.

With arrangements of this kind, however, none can be caused by faulty Measurement errors caused by phase positions of the scanning signals are determined.

However, incorrect phase positions of the scanning aials can, for example, be caused by soiling the measuring graduation of the incremental measuring system.

A largely constant phase position and possibly also A certain amplitude level of the scanning signals are a prerequisite for a perfect measurement.

In the case of incremental measuring systems, the invention aims to use simple means create a reliably working error protection that allows faulty Phase positions and possibly also incorrect amplitude levels of the down signal to display.

The invention solves the problem in that the at Measuring process generated scanning signals a control of the phase angle and / or the Amplitude level is carried out, and that with certain deviations of the scanning signals an error message is issued from their target phase position and / or target amplitude level.

In one possible arrangement for performing the method according to the invention becomes one of the mutually phase-shifted scanning signals in a known manner Trigger and subsequently a differentiator of a directional discriminator and counting circuit supplied, which supplies pulses each time the trigger is toggled The other no @ transformed departure signal, the one in front of the directional discriminator - and counting circuit is branched off, controls a so-called window trigger, the in contrast to the first-mentioned trigger, a certain output switching state Area around the mean value of the input signal and the opposite output switching state assigns the extreme ranges of the input signal. The output of the differentiator as well as the output of the window tri.ggers are placed in a control circuit that for example, determines whether the respective pulse emitted by the differentiator coincides in time with the switching state of the window trigger, which is the Eftrembbereich assigned to its input signal. is.

If the respective pulse emitted by the differentiator falls over time does not coincide with the aforementioned switching status of the window trigger, then an alarm device set in motion.

In this way, incorrect phase positions of the scanning signals - which can be caused, for example, by soiling of the measuring parts - immediately determined and after checking the measuring system also be remedied, To increase the safety the arrangement described above can also be provided in duplicate.

Each of the phase-shifted scanning signals controls own window rigger. Each window trigger has its own control circuit assigned, at their inputs the output of the associated window trigger as well as the output of one controlled by the other scanning signal via a trigger Differentiatom are placed.

Each control system checks for itself whether the respective The pulse emitted by the differentiator is timed to a switching state of the associated one Window trigger coincides with the extreme ranges of its input signal assigned.

In a further possible arrangement for exercising the invention The method in turn controls each of the mutually phase-shifted scanning signals its own window trigger. Also are the electrical signals whose Phase position is to be checked, taken again directly from the branch, the leads to the electronic direction discriminator and counting circuit of the measuring system.

However, deviating from the arrangement described above only the outputs of the window triggers are fed to a control circuit which e.g. checks whether the switching states of the window triggers coincide with those of the central areas are assigned to their respective input signals.

With arrangements of this type, both a phacer angle control as well as an amplitude control of the scanning signals can be carried out. A phase angle and amplitude control is particularly important for high-resolution measuring systems, in which a signal multiplication is effected in the known way of phase interpolation shall be. Precondition for a perfect signal multiplication through phase interpolation is not only a largely constant phase position, but it is also important that the amplitude of the scanning signals does not fall below a certain minimum value sinks.

Further features of the invention emerge as the following Description in connection with the drawing, in the embodiments of the invention are shown schematically.

In the drawing, FIG. 1 shows an arrangement for practicing the invention Method, FIG. 2 shows a signal curve for FIG. 1, FIG. 3 shows a further arrangement for carrying out the method according to the invention, FIG. 4 shows a signal curve for FIG 3.

Figure 1 shows a known photoelectric grating scanner for direction-dependent distance measurement. A grid scale 1 and one sliding over it Grating scanning plate 2 are illuminated by means of a lamp 3 via a circular sensor 4. Lenses 5 and 6 form the light beams penetrating grids 1 and 2 on photo elements 7 and 8. The output signals of the photo elements 7 and 8 are fed into amplifiers 9 and 10 reinforced. The electrical output via the amplifier outputs 11 and 12 Signals S11 and S12 are converted into square-wave signals in pulse shaping stages (triggers) 13 and 14 TIS and T16 reshaped. The square-wave signals T15 and T16 are transmitted via the trigger outputs 15 and 16 in the usual way of an electronic directional discriminator and counting device 17, the logical network of which contains a differentiator, which is included in Figure 1 for better understanding outside.

this switching arrangement is provided in the line branch 15/19. Of the Differentiator 18 in the branch 15/19 delivers during the tipping process of the trigger 13 pulses 119 The amplified output signal S12 is according to the invention a window trigger 20 supplied, which in contrast to the triggers 13 and 14 a certain output switching state a range around the mean value of the input signal and the opposite output switching state is the extreme range of the input signal assigns.

The window trigger 20 can consist of two triggers 13 and 14 corresponding to each other Triggers 21 and 22 and an exclusive ODET2 gate 29 exist. The switching levels NO or N1 and N2 (Figure 2) of triggers 13 and 14 or 21 and 22 can be set. The output .24 of the window trigger 20 and the output 19 of the differentiator 18 are connected to a control circuit 25 which, in the exemplary embodiment, determines whether the respective pulse I19 (FIG. 2) supplied by the differentiator 18 is temporal in the area X (FIG. 2) of the square-wave signal supplied by the window trigger 20 T24 falls.

The control circuit 25 contains two AND gates in the exemplary embodiment 26 and 27 and an OD-R gate 28. At the inputs of the first AND gate 26 is the Output 19 of differentiator 18 and output 24 of window trigger 20 are applied.

At the inputs of the second AND gate 27, the output 191 is one Inverter 29 for the pulses I19 supplied by the differentiator 18 and the output 24 of the window trigger 20 connected.

The phase position of the signals S11 and 512 is correct if as in FIG 2 the respective from Differentiator 18 delivered pulses I9 in the area X of the square wave signal U24 fall. The time duration of the switching range X can be varied by changing the switching levels N1 and N2 of the triggers 21 and 22 will. 1) The alarm device, which for example can contain a warning lamp 31, is then switched on when the respective pulse 119 supplied by the differentiator 18 is timed does not fall within the switching range X of the window trigger 20. That way you can Incorrect phase positions of the scanning signals S11 and S12, e.g. due to contamination at the grid division 1 and 2, determined and after elimination the source of the error must be corrected.

In Figure 3, each of the mutually out-of-phase scanning signals is 511 and S12 are placed on their own window trigger 201, which is activated at switching level N3 or N4 responds and is constructed in accordance with the trigger 20 shown in FIG can be. The square-wave signals emitted via the outputs 32 and 33 of the window trigger 201 T32 and T33 (Figure 4) control a control circuit consisting of an AND gate 34, A warning lamp 31 is actuated via the output 35 when an error occurs. The control circuit 34 checks whether the switching states of the window trigger 201 coincide, which are assigned to the central areas of their respective input signals are. Contrary to the illustration in FIG. 4, the respective switching areas Y the window trigger 201 together, 3.) Arrangement according to claim 2, characterized in that one of the mutually phase-shifted scanning signals (S11) in a known manner a trigger (13) and then a differentiator (18) is supplied, which each time the trigger (13) is tilted, pulses (I19) supplies, and that the other Abtaatsignal (S12) is applied to a window trigger (20) is, and that also the output (24) of the window trigger (20) and the output (19) of the differentiator (18) are connected to a control circuit (25) which e.g. determines whether the respective pulse (I19) emitted by the differentiator (18) is timed coincides with a switching state (X) of the window ~ Uriggers (20), which corresponds to the extreme areas is assigned to its input signal.

4.) Arrangement according to claim 2, characterized in that each of the phase-shifted scanning signals controls its own window trigger, and that each window trigger is assigned its own control circuit whose inputs are the output of the associated window trigger and the Output of a differentiator controlled by the other sampling signal via a trigger are placed, and that each control circuit checks for itself whether the respective The pulse emitted by the differentiator is timed with a switching state of the associated one Window-Uriggem coincides5 with the extreme

Claims (2)

areas of its input signal is assigned. 5.) Arrangement according to claim 2 to 4, characterized in that the Control circuit (25) contains two AND gates (26 and 27) and an OR gate (28), the output (19) of the differentiator being connected to the inputs of the first AND gate (26) (18) and the output (24) of the window trigger (20) and to the inputs of the second AND dores (27) the inverted output (191) of the differentiator (18) and the Output (24) of the window trigger (20) are set, and that the output of the AND gates (26 and 27) is placed on the OR gate (28), via its output (30) an alarm device (31) is controlled. 6.) Arrangement according to claim 2, characterized in that the phase angle and / or amplitude control of each of the scanning signals (S11 and S12) its own Window trigger (201) controls and that outputs (32 and 33) the window trigger (201) are connected to a control circuit (34) which, for example, checks whether the switching states the window triggers (201) coincide with the central areas of their respective Input signals are assigned. then the warning lamp is via the output 35 of the control circuit 34 31 switched on. This arrangement with two window triggers 201 does not only allow a phase angle control of the signals S11 and S12, but it allows at the same time also a control of the amplitude of the signals jS11 and S12. The amplitude decreases of the signal S11 or S12 below the switching level of the window trigger 201, then this error is indicated by the warning lamp 31 lighting up. Deviating from the exemplary embodiments shown, this can be done according to the invention Find procedures also for error checking in measuring systems use in which the two mutually shifted scanning signals, which are further processed by means of a push-pull circuit are generated in which, as is known, four offset from one another Photo elements are provided, each of which by half a lattice constant staggered in pairs are electrically connected together. The error check according to the invention is of course also included magnetic, capacitive, inductive incremental measuring systems applicable. Claims 1. A method for error protection in incremental measuring systems for direction-dependent distance measurement by means of phase-shifted electrical Abtaatsignale, characterized in that the scanning signals generated during the measuring process (S11 and S12) a check of the phase angle tnd / or the amplitude level is carried out is, and that with certain deviations from the target phase position and / or target amplitude level an error message occurs. 2.) Arrangement for performing the method according to claim 1, characterized characterized in that to control the phase angle and / or the amplitude level at least one of the scanning signals (S11 and S12) is a so-called window trigger (20 or 201) is supplied, which has a certain output switching state Area around the mean value of the input signal and the opposite output switching state assigns the extreme ranges of the input signal. L e r s e i t e