CH412357A - Device for determining the relative displacement of an object - Google Patents

Description

  

  



  Device for determining the relative displacement of an object
The invention relates to a device for determining the relative displacement of an object, in which a grid is used which is shifted together with the object, of which grid the lines are practically perpendicular to the displacement direction, wherein a light source is present, the light of which Raster and an associated optical system passes through once or several times and falls on two photoelectric elements, in each of which a signal is generated when the raster is shifted, which are a periodic function of the shift and mutually have a phase difference that of one is different from whole multiples of 180,

   the magnitude and direction of the shift being measured by recording the periodicity of these signals in a counter.



   In known devices of this type, the luminous flux incident on the photoelectric elements consists of a more or less constant part, the background, on which a substantially sinusoidal part dependent on the grid position is superimposed and the photocurrent has a corresponding shape. The periodicity of the signals is then recorded by using the zero crossings of the sinusoidally variable part of the photocurrent. This. is made more difficult, however, by the fact that the background of the luminous flux can exhibit undesirable changes and, in addition, in the case of the usual semiconducting photosensitive elements, the background is additionally reinforced by the so-called dark current of the element. which is strongly dependent on the temperature.



     Measures undesired changes can be comparable to or even greater than the or the amplitude of the sinusoidally variable part, whereby the determination of zero crossings becomes uncertain or even impossible.



   This interfering direct current component must not be removed by filters because the frequency of the alternating current component can approach zero at low displacement speeds.



   In the applicant's British patent specification No. 928 564 it is described how a sinusoidal phase-modulated signal is obtained by a vibratory movement of one of the elements of the optical system belonging to the grid, which in combination with one derived from the vibration, sinusoidally with of the time-elapsed signal has all the information to determine the direction and magnitude of the shift, the DC portion of the photoelectric signal being harmless.



   A disadvantage of this known method is that it is difficult to measure at high displacement speeds. Namely, the maximum allowable rate of translation is limited by a number of circumstances.



   In the first place, the maximum number of shift periods that can be covered per second is half the modulation frequency.



  Realizing a sufficiently high modulation frequency can present mechanical disadvantages.



   Furthermore, the maximum displacement speed is determined by the maximum frequency (cut-off frequency) to which the photoelectric element still reacts, namely the theoretical maximum of the number of displacement periods per second is only one fifth of this cut-off frequency, since in the phase-modulated signal at maximum displacement speed a frequency of 2.5 times the modulation frequency occurs, so forfeited by the photoelectric element who must be able to, because the number of displacement periods per second is a maximum of half the modulation frequency.



   The aim of the invention is to create a device of the type mentioned in the introduction in which the subsurface has been rendered harmless in the manner described and yet can easily be measured, even if the displacement speed is relatively high.



   The device according to the invention is characterized by means for modulating the phase of the two signals in the same way by vibration of the same part of the optical system and means for deriving unmodulated signals from the modulated signals.



   In the first place there is the possibility to give the modulation frequency a higher value than was previously the case. It is also possible to make better use of the cut-off frequency of the photosensitive elements used while maintaining the possibility of the advantage that an alternating voltage coupling remains in the amplifier at low speeds or at standstill of the grid.



   An exemplary embodiment of the subject matter of the invention is shown in the accompanying drawings.



   Fig. 1 shows the device.



   Fig. 2 shows a quartz plate in front of the grid.



   FIG. 3 shows a cross section of the quartz plate according to FIG. 2.



   Figs. 4, 5, 6 show means for converting the signals.



   A device with which two mutually 90 mutually different photoelectric signals of the form:
A = sin ((,) x + b sin ss t) + const.



   B = cos (co x + b sin Q t) + const. can be derived is shown in Fig. l. The direction of movement of the grid lies in the plane of the drawing and is denoted by x.



   The light from a light source B is collimated by a lens L1 and is incident on a partial mirror 52 via a plane mirror Ss. The reflected bundle falls through lenses L9 and L3 onto the grid R, which forms part of the body, the displacement of which is measured with respect to the optical system, which is assumed to be stationary.

   The light is split by the grid R into coherent partial bundles, which fall through the quartz plate K, which will be described further below. Via the lens L4, the bundles then fall onto the concave mirror S3, which is located in the focal surface of L4 and is set in vibration about an axis parallel to the grid lines. This takes place here in that the mirror S is attached to the end of a rod made of magnetostrictive material, which is provided with an asymmetrical incision close to the end on which the mirror is arranged.

   The rod ends carry coils in which, in a known manner, an amplifier with feedback generates electrical oscillations at a frequency equal to the natural frequency of the rod. The angular frequency of the oscillation is denoted by ss. In Fig. 1 of the drawing, the path of the rays is indicated, which cause the bending maxima of the order 0, -1 and +1. These are labeled Mo, M 1 and M 1 on the mirror Sz ,,. The mirror Sa is made non-reflective at the point of Mo by a black covering, and the dimensions of the mirror are chosen so small that maxima of higher order are not absorbed.

   In this way, only the bundles of order-1 and + 1 are thrown back and these fall back onto the grid R via the lens L4 and the quartz plate K. Of the backward exiting, coherent bundles S formed by the grid R, only two are used, namely first the bundle of order +1 formed by the grid R from the light originating from M 1, and second the bundle of the order +1 formed by the grid the bundle of order -1 formed by M + + 1 light. These coherent bundles, which coincide in the direction of each other, fall through the lenses L and L-7 and the mirror Se onto the partial prism P, which consists of two parts Pi and P2,

   which are cemented to the diagonal plane W, which is perpendicular to the plane of the drawing. The cemented surface of Pi is provided with a mirror coating of thin layers of alternating high and low refractive index, which are vapor-deposited in a vacuum. It will be evident that if the angle of incidence y is chosen in such a way that the light is incident on the boundary between the layers of high and low refractive index at approximately the Brewster angle and, in addition, if the thickness of the layers is selected appropriately, it can be achieved that Due to the above-mentioned mirroring of the light in the wavelength range used, most of the part oscillating perpendicular to the plane of the drawing is reflected back to the lens L5,

   of which it is noticed on the photodiode Fi. Most of the part vibrating in the plane of the drawing is let through and falls over the lens L,; on the photodiode Fo.



   FIG. 2 shows the quartz plate K in front of the grid in the direction of the optical axis of the imaging system Lu, as seen below. Fig. 3 shows a cross section of the quartz plate after the main section. The optical axis of the quartz forms an angle of about 45 with the plane of the plate. In FIG. 2 it is assumed that the direction of the grid lines includes an angle p with the perpendicular on the plane of the drawing from FIG. 1. The main section H encloses an angle a with the direction of the grid lines.



   The point O of the grid lying on the optical axis of the imaging system L4 S3 is imaged onto itself as O in the usual> beam path. The direction of vibration (perpendicular to the main section) is indicated in FIG. 2 by the double arrow. The unusual figure Oe is, however, shifted along the main section in the raster plane with respect to 0. at a distance that can be approximately given as OoOe = 2dne-no / no. In the formula, d = thickness of the quartz plate, Ko = ordinary refractive index, n ,. = exceptional refractive index.



   It is noted that in FIG. 2 the shift is shown exaggerated for the sake of clarity.



   The direction of vibration of Oo is perpendicular to and that of Oe is parallel to the main section. They are indicated in Fig. 2 with double arrows.



   In the direction perpendicular to the grid lines, the mutual distance between the two images Oo and 0 .. is therefore equal to 2 d sin a no
If is not too large and the grid lines, with the exception of a small angle ¯, are perpendicular to the direction of movement of the grid R, the signals supplied by Fi and Fä will have the following form as a first approximation:

  
EMI3.1


<tb> <SEP> 2 <SEP> x <SEP> cos <SEP>
<tb> A <SEP> = <SEP> const. <SEP> + <SEP> sin <SEP> (2Rp <SEP> ss <SEP> x <SEP> + <SEP> b <SEP> sinDt)
<tb> <SEP> C <SEP> i / 4p
<tb> B <SEP> = <SEP> const. <SEP> + <SEP> sin <SEP> (2 <SEP>% <SEP> p <SEP> s <SEP> fl <SEP> x <SEP> + <SEP> b <SEP> sinqt <SEP> + < SEP> approx)
<tb> <SEP> \ <SEP> /
<tb> in which b = 2a-e in which r = the radius of S3, &commat; the angular amplitude of the oscillation of S3 and
C = 2d (ne-no) /1/2pno.2? Members of an order higher than the first order in a and / 3 are neglected here.



   By suitable choice of d it can be achieved that z. B. c is greater than- .. so that the angle a required for a phase difference of 2 is not greater than approximately 5. Since in practice l; is also not more than a few degrees, we may use the above form for the signal from F2. The angle a required for a phase difference of? / 2 then becomes? = Pno?
16d (ne-no) The desired value of a can be set in that the quartz plate is mounted in a mount V (see FIG. 1) that can be rotated around the optical axis of L4 and S3.

   The main section of the plate is thus rotated so much out of the raster line direction by means of this rotatable mount until the phase difference of 2 mentioned is reached.



   The following applies to quartz: no-no? = 0.006 Ho
If one chooses further: d = 2 mm p = 16Á (steps 1 Á) then α = 16.10-3? = 1? radial = 5¯ 16. 2. 0, 006 12 Dile thickness d of the quartz plate must not be too small because complications arise with larger values of a, namely a reduction in the amplitude of the alternating current components of the two signals. On the other hand, it is desirable not to choose d too large, since then the setting of a becomes too critical. The voltages obtained in the photosensitive elements are thus of the form:
A = sin (oo x + b sin 92 t) + const.



   B = cos (co x + b sin Q t) + const.



   A display can then be obtained from these voltages in the following manner to be described with reference to FIG. The modulation angle b is chosen to be small, e.g. B. 0, 2. The above expressions can then by
B = const + sin cv x + b cos a) x sin Q t
B = const + cos? x-b sin? x sin O t can be approximated.



   The signals mentioned occur at I and II and are fed to devices A and A2, which are also fed with voltages derived from the mirror vibration and proportional to sin Q t. In the devices r1 and r2, each z. B. can have a Hall generator, the product of the two voltages is formed. The mixed products are fed to the low-pass filters Bt and B2, which e.g. B. the frequencies to 1/2. Q dWrcht. Voltages cos co x and sin x then arise at the output, which can be treated further in a known manner.



   Since b is small, S2 can be high and thus also the highest permissible displacement speed
EMI3.2

A second method is proposed in Fig. 5, in which the drive system for the mirror is also provided. The signals that appear at I and II can be written in the following way:

   A = const + sin co x [JO (b) + 2J2 (b) cos 2 Q t + 2J4 (b) cos 4 ss t + ...] + cos oi x [2T1 (b) sin Ot + 2J3 (b ) sin 3 Q t + ...] B - const + cos co x (Jo (b) + 2J2 (b) sin Ot + ...] sin co x (2Jl (b) sin Q t + 2J3 (b ) sin 3 Q t + ...]
If b is chosen to be approximately equal to 2.5, then Jo (b) is approximately equal to zero, so that at a standstill the elements Jo (b) sin oi x and JO (b) cos oo x do not cause any difficulties.



   In device A, the zero crossings of the alternating voltage parts of voltages A and B are used in the usual way to form counting pulses forwards and backwards. When the raster is at a standstill, the counting is always back and forth as a result of the phase modulation b sin Qt, but this need not be disadvantageous.



   If, however, the difficulty of moving the grid is such that dx 0 dt m ', the element with the amplitude Jl (b) has a frequency of zero. In order to avoid complications from this, it is desirable to take the following precaution: in device B, the counting pulses forwards and backwards are calculated positively or negatively, integrated and rectified, so that when moving quickly, device B supplies a DC voltage that The gain of the amplifier C is decreased, whereby the amplitude of the vibrating mirror is set to a lower value and the term? J1 (b) becomes insignificant.



   Another device for converting the signals is shown in FIG. The first signal is mixed multiplicatively in the device A, again with a voltage proportional to sin, whereupon the resulting voltage is passed through the low-pass filter B1, which allows the frequency below 1/2 S2, whereupon the signal obtained is proportional to cos? x is fed to the device Et.



     At the same time, the second signal is supplied to Et via a phase compensator C2. As far as the zero crossings are concerned, this signal behaves essentially like the function cossox, since b is chosen so small that Jo (b) is large compared to Ji (6) (e.g. b = 0, 2).



   E2 receives its signals in a similar way. The incoming signals are combined linearly in Et and E2. The signals emerging from Et and E2, which are essentially proportional to cos and sin cu x, are fed to F, in which pulses for forward and backward are formed in a known manner.



   The pulses are fed to device D, which calculates the pulses for positive forward and negative for reverse, integrates them and rectifies them. The DC voltage obtained is fed to Et and Ez to control the mixing ratio of the signals linearly com bined in El and E2. At a low speed of the raster, only the signals emerging from Bi and B are coupled into Et or E2. As the speed increases, these are decoupled and the signals emerging from Ci and C2 are coupled in.



   The phase compensators Ci and C2 are used to compensate for the phase shift occurring in Bt and B2 to some extent so that the signals emerging from Bt and BS and C2 and Ci will be approximately in phase when tY is taken over.

 

Claims (1)

PATENT CLAIM Device for determining the relative displacement of an object, in which a grid is used which is shifted together with the object, of which grid the lines are practically perpendicular to the direction of displacement, a light source being present whose light is the grid and an associated one passes through the optical system one or more times and strikes two photoelectric elements, in each of which a signal is generated when the raster is shifted, which are a periodic function of the shift and have mutually a phase difference different from an integer multiple of 180 , the magnitude and direction of the shift being measured by recording the periodicity of these signals in a counting device, characterized by means for modulating the phase of the two signals in the same way by vibration of an equal part of the optical system and means for deriving unmodulated signals from the modulated signals. SUB-CLAIMS 1. Device according to claim, characterized in that the optical system has means for reversing the image of the grid onto itself, and a mirror which can be set in vibration about an axis which extends practically parallel to the grid lines. 2. Device according to claim and dependent claim 1, characterized in that the optical system also has an element by which two images of the grid polarized with respect to one another are formed, which are shifted in the direction of displacement and that an analyzer is present which the with respect to each other perpendicularly polarized bundles of rays separates and that means are available to throw the bundles of rays onto an associated photo element. 3. Device according to dependent claim 2, characterized in that the analyzer is a partial prism (P) with two parts (Pi, P2) which are cemented to a diagonal plane (W) and there are provided with layers of alternating low and high refractive index. 4. Device according to claim, characterized by such a design that the diffraction maxima of the order + 1 and -1 are used for the imaging of the grid.