CH685172A5 - Position-measuring device. - Google Patents

Description

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description

State of the art

The invention is based on a position measuring device according to the type of the independent patent claim, as is known from EP-B1 116 636. This has an encoder with markings in the form of a sequence of code elements and a device for recognizing these code elements. The code elements arranged on the encoder form a pseudo random sequence with a characteristic word length. A bit sequence with at least word length must be read out for position detection. The detection device is designed such that it always reads out at least the number of bites required to form a word. A disadvantage of this arrangement is the relatively large width of the detection device, which must correspond at least to the physical length of a word in the pseudo-random sequence. This width increases, the higher the desired spatial resolution, and thus the higher the order of the pseudo-random sequence used.

From FR-A 2 551 203, an arrangement for determining the angle, consisting of two sensor disks and a detection device, is known. A sensor disk has digital markings which generate an irregular square-wave signal in the state of movement, the rising edges being at regular intervals and the falling edges being at variable intervals. With the help of the clock signal emitted by the first encoder disk, the irregular square-wave signal can be clearly assigned to the second encoder disk. The disadvantage of this arrangement is that two encoders must be provided.

From the German patent application file number P 3 942 800.1 an arrangement for recognizing the position of a camshaft is known, the essential components of which are a sensor disc marked with a pseudo random sequence and a device for detecting the markings. The document also makes the suggestion to design the markings on the transmitter so that the pseudo-random sequence signal that is emitted during movement is produced in a phase-modulated form. In this way, the width of an individual bit required for position determination within the output signal can be obtained directly from the measurement signal without using a clock signal. A phase-modulated marking increases the information density to be transmitted. This places increased demands on the production effort - more markings have to be made per unit length - and also on the detection sensor to be used.

From the document IEEE, Transactions, IM 36, No. 4, 1987, pp. 950-955, the proposal is also known to use a transmitter with two marked pseudo random sequences, which are arranged in parallel, in order to achieve a higher resolution.

The invention has for its object to provide a position measuring device that delivers good measurement accuracy with the simplest possible structure.

The object is achieved by an arrangement with the features of the independent claim. A measuring arrangement according to the invention only requires a single sensor marking track. Additional markings for the generation of the clock are not necessary. The space available for the arrangement of the sensor markings can be used completely in favor of the most accurate possible marking.

A device according to the invention requires a detection device in the form of a sensor or the like, which only has to be suitable for bit-wise detection of the sensor marking. As a result, the detection device can be designed to be very space-saving. Furthermore, only one detection device is required. On the one hand, this brings cost advantages over solutions with multiple encoders, and on the other hand, it reduces the number of possible sources of error in a measuring arrangement.

An embodiment of the invention is explained in more detail in the following description with reference to the drawing.

drawing

Show it:

1 is a block diagram of the proposed position measuring device,

2 shows an optical coding with an associated electrical binary signal,

3 shows the clock signal T for FIG. 2,

4 shows a possibility for the generation of an information signal about the phase shift,

5 shows a control strategy in order to achieve synchronization of the signals.

Description of an embodiment

The arrangement shown in FIG. 1 is divided into three main components: the encoder 17, the detection device 11, and the evaluation arrangement 12 to 15 with position determination device 16.

In the example of FIG. 1, the encoder 17 is a rotary encoder designed in the form of a disk, which is firmly connected to a rotating object, such as the rotor of a motor. Markings 10 in the form of code elements are arranged on an upper or outer side of the encoder disk 17, arranged on a track running in a ring around the axis of rotation. The markings 10 form an arbitrarily selectable sequence of bit sequences, which are arranged in such a way that they allow the position to be determined as accurately and quickly as possible. They can be designed both optically, for example as a barcode, and magnetically or geometrically, for example by means of elevations, depressions, incisions, etc. All individual code elements have the same angular width 22 and appropriately match their base area. Each individual code element corresponds either to the value logically

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I or the value logical 0, the values 0 and 1 are arranged in an apparently irregular sequence one after the other.

On the second part of the arrangement, which is at rest relative to the transmitter 17, there is a detection device 11 for detecting the markings 10 made on the transmitter. It is designed as an optical, magnetic or mechanical scanner to match the markings 10 used on the transmitter 17. The detection device 11 is arranged in such a way that the markings 10 arranged on the transmitter 17 move past it serially in the moved state. It recognizes the binary code element that is guided past it in the movement state and converts the detected value of the read code element into a binary electrical signal w suitable for further processing in the evaluation circuit.

Downstream of the detection device 11 is a control loop with a summing point 12, a controller 13, a clock generator 14 and a signal generator 15. The reference variable of the control loop 12 to 15 is that of the detection device

II output binary signal w, controlled variable is a clock signal T with the dimension of a frequency, hereinafter briefly referred to as clock, which allows the binary code signal originating from the detection device 11 to be broken down into its individual code elements. The clock signal T on the control loop output side and the binary signal w emitted by the detection device 11 are also fed to a position determination device 16 via corresponding branches. By superimposing the two supplied signals, this determines the instantaneous angular position or position P of the encoder disk 17.

The function of the arrangement 10 to 16 is explained in more detail below. Encoder 17 and detection device 11 interact in a manner known per se. The encoder markings 10 are preferably applied as an optically readable line pattern, in this case the detection device 11 is an optical scanner. In the moving state, that is, the encoder disk rotates, the line pattern runs through the detection field of the scanner 11. This creates a light-dark signal, which the scanner 11 converts into the binary signal w, which is expediently in the form of a square-wave voltage signal a high and a low voltage level, one voltage level corresponding to the logic value 1, the other to the logic value 0, at the output of the scanner. FIG. 2a shows an example of an optical line pattern, FIG. 2b an associated square-wave voltage signal w, as would be generated by the line pattern according to FIG. 2a at the output of the scanner 11.

As shown in FIG. 2b, the signal w generally consists of a series of uneven rectangular pulses in an apparently irregular sequence. The width of the individual rectangular pulses depends on the one hand on the number of successive bits of the same value read out, and on the other hand on the speed of movement of the encoder disk 17. In order to be able to use the information contained in the signal w at all, it is necessary to know the number of bits for each rectangular pulse which determine its width. This is expediently done with the aid of the clock signal T superimposed on the signal w, which in each case marks the beginning or the width 22 of each individual bit of the signal w.

Such a clock signal T shown in FIG. 3 is obtained by means of the control circuit 12 to 15 as follows. A signal generator 15 continuously generates a second binary signal u, the bit pattern of which corresponds identically to that marked on the encoder disk 17, but which is initially based on an arbitrary clock frequency. The clock frequency is supplied by the clock generator 14. The signal generator 15 supplies the binary signal u to the summing point 12, where it is compared with the measured binary signal w coming from the detection device 11. The summing point 12 is expediently designed in the form of a phase controller which, as intended, examines the two signals u and w for possible phase deviations. If the two compared signals u and w do not match, the phase controller 12 outputs a signal with corresponding information to the controller 13. This determines from the information from the phase controller 12 whether the frequency of the binary signal u generated by the signal generator 15 has to be increased or decreased. In accordance with the result found, the controller 13 transmits a signal to the clock generator 14, which causes the clock generator 14 to increase the frequency of the clock signal T when the speed of the binary signal u generated by the signal generator 15 lags behind the binary signal w measured by the detection device 11 and reduced when the generated binary signal u leads the measured binary signal w.

The control mechanism described above is explained in more detail below. The phase controller 12 compares the speeds of the two binary signals u and w, for example by checking which of the two signals u and w has a falling edge first. This can be done by means of a logic circuit with two inputs, at which the signals u and w are present, and with two outputs, at which signals ai and a2 are present, with information about a possible phase shift between the input signals. An example of a possible mode of operation of such a circuit is shown in FIG. 4. In Fig. 4a, the edges of the signal u fall before the edges of the signal w, the output signal al is therefore constantly at the logic value 1, the output signal 2 changes between the appearance of successive falling edges of the signals u and w its polarity. 4b shows the reverse case, the signal u lags behind the signal w here. In this case, a signal appears at output ai, the polarity of which alternates between the appearance of successive falling edges, while the signal present at output a2 has a constant level. The in the two initial

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gnalen information contained ai and az is supplied to the controller 13.

On the basis of the signal coming from the summing point 12, that is to say from the phase controller in the present case, the controller 13 can decide whether and which of the two binary signals u or w leads the other. If the edges of the binary signal u generated by the signal generator 15 run in later than those of the binary signal w measured by the scanner 11, the controller 13 causes the clock generator 14, the clock frequency T, on which the binary signal u generated by the signal generator 15 is based and which determines its speed increase.

The clock frequency T is expediently not increased linearly, but rather according to the scheme shown in principle in FIG. 5a. Thereafter, the clock frequency T is first increased very significantly at a point in time ti in order to cause the binary signal u generated by the signal generator 15 to move past the binary signal w measured by the scanner 11. After a short time, at time t2, the clock generator 14 then reduces the clock frequency T again in such a way that the finally set clock frequency T is above that set before the start of the control process. If the generated binary signal u is still faster than the measured binary signal w after the control process, the control process is repeated.

If the controller 13 determines that the edges of the binary signal u generated by the signal generator 15 run in faster than those of the binary signal w measured by the scanner 11, the controller sends a signal to the clock generator 14, on the basis of which the latter reduces the frequency of the clock signal T. The frequency reduction is expediently analogous to the increase, but in the opposite direction. As shown in FIG. 5b, the frequency of the clock signal T is initially greatly reduced briefly at time t3. The binary signal w measured by the scanner 11 thus passes the binary signal u generated by the signal generator 15. After a short time, at time t4, the clock frequency is then increased again somewhat, the clock frequency finally set being below the clock frequency present before the control process. If after the control process the binary signal w measured by the scanner 11 is still faster than that generated by the signal generator 15, the control process is repeated.

The procedure for changing the clock frequency illustrated with reference to FIGS. 5a and 5b reflects the basic idea of a control strategy, which specifically consists in providing an overshoot which has an effect in a phase jump of the controlled variable. Control functions selected for practical implementations can deviate significantly from the diagram shown in FIG. 5. In particular, it can be expedient to provide several stages or to introduce softer transitions between the individual stages. The selectable control parameters height of the levels, i.e. how much the clock frequency is initially increased or decreased, and switching times ti to t4 should at least be verified in practice by previous tests in order to rule out the possibility of unstable vibration states.

A controller which at least approximately shows the behavior shown in FIG. 5 is a PI controller if a square-wave signal is supplied as the input signal, the width of the square-wave pulses indicating the size of the phase shift and the polarity indicating the direction of the phase shift.

If the edges of the signals arriving in the phase controller 12 match, the controller 13 does not emit a clock-changing signal to the clock generator 14. The signal T present at the output of the clock generator 14 is then the clock on which the signal measured by the detection device 11 is based. In this case, the controller 13 outputs a signal to the position determination device 16, whereupon the latter detects the value of the clock signal T present at the output of the clock generator. At the same time, the position determination device 16 detects the measured binary signal w applied to the detection device 11 via a corresponding signal line. By suitably superimposing the signal w with the clock signal T, the position determination device 16 can read the information contained in the binary signal w and thus determine the exact angular position P of the encoder disk 17. The position signal P is present at the output of the position determination device 16.

The signal sequence coded on the encoder disk 17 is expediently a pseudo random sequence. Pseu-do random sequences are machine-generated sequences of numbers with the properties of random sequences. The pseudo-random sequences are represented as a sequence of binary characters in the form of logical variables 0 and 1. They differ in terms of their order and their length. For a given order N, the maximum length is 2N ~ 1 bit. The characteristic of a pseudo random sequence for the measurement arrangement according to the invention is the structure of the arrangement of the individual bits. A pseudo-random sequence of the order N is constructed in such a way that every possible bit combination of N bits occurs exactly once within the pseudo-random sequence. The markings 10 of the encoder disk 17 in FIG. 1 show an example of a pseudo random sequence of order four with the bit combinations of four bits contained therein. Hatched segments correspond to the value logical 1, white segments to the value logical 0. As a practical addition, as will be explained below, an additional code element of significance was added between the bit combinations of three code elements of logical value 0 and those of four code elements of logical value 1 logical 0 inserted. If at least four consecutive bits of this pseudo-random sequence are known, the local position of this bit combination within the pseudo-random sequence is also known with an accuracy of 4/15. In general, for a pseudo-random sequence of order N, exactly N consecutive bits must be scanned for a unique localization of a bit combination with N bits.

An introduction to the theory of pseudo-random sequences can be found, for example, in W.D.T. Davis, system recognition for adaptive control, oil

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denbuchverlag Munich 1973. These publications can also be found in electronic circuits for generating pseudo-random sequences, as can be used in the signal generator 15.

To simplify the handling and, above all, the production of pseudo-random sequences, it is expedient to extend the pseudo-random sequence by an additional bit, so that its total length is 2N, instead of 2N-1, bits. This is advantageously done by inserting a bit of logic 0 value into the bit combination within the pseudo-random sequence which consists of N-1 identical bits of logic 0 value. All properties of the pseudo-random sequence, insofar as they are important for the proposed measuring device, are thereby preserved.

The proposed measuring arrangement is of course not restricted to use in rotary movements. It can also be used to record translatory movements.

Claims (8)

Claims 1. Position measuring device for determining the relative position of two parts that are movable relative to one another, with an encoder that has markings in the form of a sequence of code elements that, when read in the direction of the relative movement, result in a non-regular bit pattern, which detects and detects a detection device Binary signal is implemented, characterized by a device (12-15) which generates a clock signal (T) from the binary signal w of the markings emitted by the detection device (11), which allows the binary signal w to be broken down into its individual code elements. 2. Position measuring device according to claim 1, characterized in that the sequence of the code elements are arranged in the form of a pseudo random sequence. 3. Position measuring device according to claim 2, characterized in that in the longest occurring in the pseudo-random bit combination of code elements of logic 0 logic an additional code element of 0 security is inserted. 4. Position measuring device according to claim 1 or 2, characterized in that the device for obtaining the clock signal (T) comprises: a summing point (12) which generates the binary signal w emitted by the detection device (11) with a signal generator (15) compares the second binary signal u, a controller (13) which influences a clock generator (14) on the basis of the difference between the signals u and w measured in the summing point (12), a clock generator (14) which on the basis of the signal received from the controller (13) Signals influences a signal generator (15) for generating a predetermined bit pattern, and a signal generator (15) for generating a binary signal u with a predetermined bit pattern which corresponds to the bit pattern of the markings (10) on the transmitter (17). 5. Position measuring device according to one of the preceding claims, characterized in that the detection of the markings (10) arranged on the transmitter (17) takes place optically. 6. Position measuring device according to claim 4 or 5, characterized in that the summing point (12) is a phase controller. 7. Position measuring device according to one of claims 4 to 6, characterized in that the device for obtaining the clock signal (T) (12-15) the frequency of the clock signal (T) in the presence of a phase difference at the summing point (12) initially strongly in the direction changes the phase difference found, and then adjusts it to a value that differs only slightly from the originally applied value. 8. Position measuring device according to one of claims 4 to 7, characterized in that the controller (13) is a PI controller. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 5