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Description  |
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The present invention relates to the optical read-out of information stored
in a flexible or rigid information carrier or record, and arranged along a
track comprising a succession of diffractive elements. Generally speaking,
the diffractive elements constituting the track take the form of hollows
or projections which can be produced by transferring an impression to a
carrier which is either simply transparent or coated with a reflective
layer. Although the diffractive track may be of substantially constant
width, its elements have non uniform length and/or spacing, in order,
along the longitudinal axis of the track, to create a square waveform
angularly modulated by the information which is to be read out. In
accordance with one known embodiment, the read-out of the information
requires a light source associated with a projection objective lens which,
at the surface of the carrier, forms a light spot of dimensions comparable
with the constant width of the track. To read out the recorded
information, the read-out spot must be centered on the track and since
there is no kind of mechanical tracking system at all, it is necessary to
have recourse to an optical sensor associated with a servo-motor which
continuously corrects the position of the projection objective lens. Those
skilled in the art will be aware that it is possible to simultaneously
carry out read-out of the information recorded along a track and
measurement of its eccentricity in relation to a read-out spot, by means
of an assembly of photo-electric transducers connected to transmission
circuits which, by a sum and difference procedure, furnish the read-out
signal and the instantaneous value of said eccentricity. However, if a
single read-out spot is being used, it turns out that the eccentricity
signal tends to undergo a inadvertent change in sign and this renders the
feed back positional control system unstable. This drawback is due to the
lack of uniformity in the illumination received by the photo-electric
transducers. This lack of uniformity is due to the interference between
the light waves diffracted by the track and those responsible for
producing the read-out spot. The anomalies observed are also ascribable to
the fact that the track exhibits certain defects such as variation in the
depth of engraving; they are due also to transfer irregularities in a
situation where the read-out spot is concentrated in a plane other than
the surface containing the track.
To provide an optical read-out device for reading out a diffractive track
with a wider tolerance via a vis anomalies in the process of generation of
the eccentricity signal, the invention provides for the read-out spot to
be doubled in order to simultaneously illuminate the two edges of the
diffractive track. Two illuminating beams which are decoupled from one
another, are then necessary but these can be furnished by one and the same
projection objective lens. The invention likewise provides for the
addition of a third beam. The invention likewise provides for the addition
of a third beam illuminating the track over the whole of its width in
order to extract the optical information which it carries, without using
the other two beams.
In accordance with the present invention there is provided an optical
read-out device for the read-out of a data-carrier having a read-out
surface wherein is formed a succession of diffractive elements building up
a track of predetermined width, said optical read-out device including an
optical read-out assembly comprising: a source of radiant energy for
illuminating said read-out surface, optical projection means arranged
between said source and said data-carrier for concentrating said radiant
energy upon said read-out surface, and photoelectric means arranged for
collecting radiant energy emerging from the portion of said read-out
surface illuminated by said source; said optical projection means being
capable of forming at said read-out surface at least two collateral
read-out spots respectively formed by elementary beams supplied from said
optical projection means; said read-out spots being aligned along an axis
intersecting the longtudinal axis of said track for scanning said surface
during the course of read-out over a width interval greater than said
predetermined width; said photoelectric means being subdivided into at
least two groups respectively sensing any spread of said elementary beams
arising from the scattering action of anyone of said diffractive elements;
said photoelectric means being associated with substractor means having
two inputs respectively coupled to said groups.
For a better understanding of the present invention and to show how the
same may be carried into effect, reference will be made to the following
description and the attached figures among which:
FIG. 1 schematically illustrates a device for the optical read-out of a
diffractive track, which utilizes a single spot;
FIG. 2 schematically illustrates an optical read-out device with two spots,
in accordance with the invention;
FIG. 3 is an explanatory figure relating to the device shown in FIG. 2;
FIGS. 4 and 5 illustrate details of the device shown in FIG. 2;
FIG. 6 is an isometric view of an embodiment of the device in accordance
with the invention;
FIG. 7 is an isometric view of a first variant embodiment of the device in
accordance with the invention;
FIG. 8 is an isometric view of a second variant embodiment of the device in
accordance with the invention.
FIG. 1 schematically illustrates in a manner known per se, a device for
effecting optical read-out of a diffractive track. In this figure, a
transparent data carrier 1 has been shown at the surface 2 of which there
has been formed a hollow impression of a diffractive track 3 whose
longitudinal axis is perpendicular to the plane of the figure. The track
performs a transfer motion along said axis, at constant velocity. It is
made up of diffractive elements which successively encounter the
concentrated beam of radiant energy delimited by the contour 4. In passing
through the carrier 1, the beam projects a read-out spot and in the
absence of any diffractive elements in its path, the radiant energy is
contained within the interior of the dotted contour. The wavefront 5 which
characterizes this non-diffracted energy, exerts a weak influence upon the
two lateral photo-electric transducers 14 and 15. The subtractor 20 in
this case supplies no voltage due to the equality between the detected
illuminations.
When a diffractive element 3 is illuminated by the read-out spot, the
radiant energy is diffracted and this causes it to spread in directions of
emergence 6 which reach the sensitive faces of the photo-electric
transducers 14 and 15. The wavefront 7 of the radiation fraction subjected
to this spread, is centred on the diffraction element 3 and should
intersect the wavefront 5 of the undiffracted portion of the radiation as
soon as there is any eccentricity on the part of the element 3 in relation
to the centre of the read-out spot. The result is that the interference
pattern of the wavefronts 5 and 7 art the transducers 14 and 15, has a
morphology which varies as a function of the eccentricity of the read-out
spot vis a vis the diffractive track 3. The integration of these
non-uniform illumination by the transducers, normally results in the
appearance at the output of the subtractor 20 of a differential voltage
which translates in terms of magnitude and sign, the eccentricity.
However, since we are concerned with interference between two wavefronts 5
and 7, the phase difference at the level of the transducers may reach a
value such that the direction of variation of the eccentricity signal may
locally undergo an unpredictable reversal. This operating anomaly produces
instability in the positional control whose function is to maintain the
read-out spot centred in relation to the diffractive track 3.
In FIG. 2, there has been schematically illustrated an optical read-out
device in accordance with the invention. The device differs from the
preceding one by the fact that the read-out beam 4 is doubled to give two
separate elementary beams whose respective contours are indicated by the
broken lines 9 and the chain dotted lines 8. At the surface 2 of the
carrier 1, two offset read-out spots are obtained which touch the edges of
the diffractive track 3 when the latter is centred. For convenience as far
as the drawing is concerned, the dimensions of the read-out spots have
been exaggerated and the photo-electric transducers 16-17 and 18-19, have
been shown at different distances from the data carrier although they
could equally well be located in the same detection plane.
As FIG. 2 shows, a group of photo-electric transducers 16-17 is assigned to
the measurement of the disturbances introduced into the beam 9 by the
diffractive element 3 plus another group of photo-electric transducers
18-19 which performs the same function in relation to the beam 8.
The eccentricity of the diffractive element 3, as shown in FIG. 2, places
it beyond the read-out spot projected by the elementary beam 8. The result
is that the wavefront 10 shown in chain dotted fashion and centred on this
spot, has little influence upon the transducers 18 and 19. By contrast,
the diffractive element 3 produces a substantial diffraction in the
elementary beam 9 and this increases the illumination of the transducers
16 and 17.
It will be observed from a consideration of FIG. 2 that the waves whose
wavefronts 12 and 11 are respectively centred on the element 3 and on the
centre of the read-out spot projected by the beam 9, are practically
coincidental with one another and this contributes to the uniformity of
the illuminations picked up by the transducers 16 and 17. Under these
conditions, the differential amplifier supplies an eccentricity voltage
whose value depends primarily upon the voltages furnished by the
transducers 16 and 17. This voltage is less affected by the anomaly
referred to earlier. In a similar way, when the diffractive element 3 is
located beyond the spot projected by the beam 9 and is under the influence
of the other read-out spot, the voltage furnished by the amplifier 20
depends primarily upon the illumination picked up by the transducers 18
and 19. Accordingly, the translation of an eccentricity on the part of the
diffractive track, into an electrical signal, is effected with a wider
tolerance in terms of the possible reversal referred to earlier in respect
of optical read-out devices using only one spot.
In FIG. 3, at (a) an explanatory diagram can be seen relating to FIG. 2 and
illustrating, as a function of the transverse displacement Y of the
diffraction track 3 vis a vis the two read-out spots, the values I of the
voltages respectively applied to the inputs + and - of the amplifier 20.
The graph 21 corresponds to the voltage furnished by the transducers 16
and 17; its peak 22 corresponds to the position of the track 3 in which
the latter is centred vis a vis the read-out beam 9. The graph 24 relates
to the voltage furnished by the transducers 18 and 19; its peak 23
corresponds to the position occupied by the track 3 when centred vis a vis
the beam 8. The point of intersection between the graphs 21 and 24
indicates the intermediate position of the track 3, in respect of which
the servo system need not produce any guidance correction. At (b), there
has been shown the eccentricity signal 25 which is obtained at the output
of the amplifier 20; this signal has a value .DELTA. I which changes in
sign when the track passes through the intermediate position. The
effecitve control range extends between the maxima 22 and 23 and between
these limits there is no unpredictable reversal in the direction of
variation of the signal 25.
In accordance with the invention, the doubling of the read-out spot shown
in FIG. 2, can be achieved using a single light source and a single
projection lens.
In FIG. 4, a divergent beam of radiant energy 28 can be seen emanating from
a source of radiant energy (not shown) and a projection objective lens 26
whose optical axis Z is located in the plane of the figure. That portion
of the beam 28 located in front of the plane of the figure, is incident
directly on the objective lens 26 and constitutes therefore the elementary
beam 8 of FIG. 2, which is concentrated on the surface 2 of the data
carrier 1, slightly to the right of the axis Z. That portion of the beam
28 located behind the plane of the figure passes through a refractive
plate with parallel faces, 27, before reaching the objective lens 26,
where it constitutes the elementary beam 9 of FIG. 2 which, in its turn,
is concentrated very close to the surface 2 and slightly to the left of
the axis Z. Since we know that the plane of the figure is traversed by the
longitudinal axis of the diffractive track, the optical system of FIG. 4
will thus give rise to two offset read-out spots which straddle the track
when it passes through the point of intersection between the surface 2 and
the axis Z. By combining FIGS. 2 and 4, we obtain a complete system of two
read-out spots, to which there can be added the positional control system
which exploits the eccentricity signal in order for example to correct the
positional deviations of the projection objective lens 26 in relation to
the track.
In FIG. 5, a variant embodiment of the optical system of FIG. 4, has been
shown. The system of FIG. 5, also utilizes a plate 29 with parallel faces
in order to double the beam 28, but it is cut from a double-refracting
material and extends both before and behind the plane of the figure. The
beam 28 incident upon the plate 29 is linearly polarized in a direction
such that it splits into two fractions which are differently refracted,
with polarization components orientated in the same direction as the
principal axes of the plate 29. Thus, once again, the read-out spots are
obtained at the surface 2, but the elementary beams 8 and 9 which have
formed them are substantially coincidental with one another to either side
of the surface 2. In order to separately detect the fractions of radiant
energy contained respectively in the beams 8 and 9, it is necessary to
equip the groups of transducers with suitable orientated polarization
analysers.
FIG. 6 is an isometric view of a read-out device in accordance with the
invention, in which the doubling of the read-out beam is effected by means
of a prism. The read-out radiation 28 is furnished by a source 30 whose
phase centre is located slightly off the axis YZ perpendicular to the
longitudinal axis X.sub.1 of the diffractive track 31. A convergent lens
34 whose focus is on the axis Z at the height of the point 0, converts the
incident radiation into a parallel beam which is slightly obliquely
directed in relation to the axis Z. A mask 35 with two windows 36 and 37
is arranged in the neighbourhood of the projection objective lens 26, in
order, from the plane XY, to delimit two square-section light beams which,
due to the presence of the prism 27, have equal obliquities and opposite
signs in relation to the optical axis Z of the objective lens 26. The
surface 2 of the data carrier 1 which is located in the focal plane
X.sub.1 Y.sub.1 of the objective lens 26, receives from the windows 36 and
37 light beams 9 and 8 which are concentrated in order to respectively
form the read-out spots 33 and 32. The spots 33 and 32 are aligned in the
direction Y.sub.1 and normally straddle the axis X.sub.1 of the
diffractive track 31. The light beams 8 and 9 pass through the carrier 1
and, in the detection plane X.sub.2 Y.sub.2, illuminate square zones
respectively covered by the photoelectric transducers 18-19 and 16-17. The
two photoelectric transducers are under the influence of the beam 9 and
the read-out spot 33; they have their outputs connected to an adder
circuit 40. The two photo-electric transducers 18 and 19 are under the
influence of the beam 8 and the read-out spot 32; they are also connected
to an adder circuit 39. The adder circuits 39 and 40 respectively supply
the inputs of a further adder circuit 38 which furnishes the voltage V,
and those of a subtractor circuit 20 which furnishes the eccentricity
signal .epsilon.. There is nothing to prevent each group of transducers
from comprising just a single element, directly connected to the inputs of
the circuits 20 and 38. In this case, however, it is necessary to mask off
the central zone of each group or to quite simply discard one of the
transducers of the two composing each group. In FIG. 6, it can be seen
that the track 31 can be split into several equidistant portions separated
by cross hatched, completely smooth zones of the surface 2 of the carrier
1. This case occurs in particular if the carrier 1 is a disc on which the
track 31 has been recorded in the form of a spiral; the successive turns
of the spiral have their radii struck from the axis Y.sub.1 defining the
centre of the rotation of the disc.
The interval between the two read-out spots in the read-out plane X.sub.1
Y.sub.1 is adjusted so that they they overlap onto the track portion
passing between them in the direction X.sub.1. However, the interval must
not have such a value that the spots can overlap onto adjacent tracks. The
operation of the device shown in FIG. 6 as far as the formation of the
eccentricity signal .epsilon. is concerned, has already been described.
This signal is substantially zero when the two spots symmetrically
straddle the diffractive element 3 of the portion of the track 31 being
read out. It acquires a positive or negative value depending upon whether
the diffractive element moves off center in or the other sense, in the
direction Y.sub.1 of the read-out plane. It is not necessary for the line
joining the centres of the two spots to be perpendicular to the
longitudinal axis X.sub.1 of the track in order for the eccentricity
signal to be properly produced, since all that is necessary is that the
spots should not be aligned on the diffractive track 31. The advantage of
choosing a transverse orientation of the light spots, resides in the
possibility which thus affords to effect fine read-out of the stored
information. In other words, from the point of view of information
read-out, the two spots are equivalent to one read-out spot of elongated
shape, whose narrowest dimension is in the direction of transfer of the
track. If the surface 2 is illuminated in a smooth zone, the radiation
being undiffracted, the volatge V is higher because none of the
transducers is illuminated. When the illumination of the surface 2
involves a diffractive element, the diffraction which results spreads the
radiation transmitted towards the detection plane and the voltage V
acquires a higher value. The increase in the voltage V takes place when
the diffractive element 3 reaches the zone illuminated by the objective
lens 26, and is maintained until the element quits this zone.
In FIG. 7, an isometric view can be seen, of a variant embodiment of the
device shown in FIG. 6.
In this version, to read out a diffractive track 31 of width L, an assembly
of three spots is used; one of them is assigned to the read-out of the
information and the other two serve to produce the eccentricity signal 2.
As in FIG. 6, the spots 53 and 54 are projected to either side of the
diffractive track 31 in order to partially overlap onto same.
Preferentially, they will be given an elongated shape in the direction of
transfer since their function is simply to detect transverse movements of
the track 31. The spot 55 designed to read out the information carried by
the track is projected in such a way as to completely cover the track 31
and, preferentially, this spot will have an elongated shape which overlaps
the track portion being read out without, ever, reaching the neighbouring
track portions; the narrow shape of the spot 55 makes it possible to
effect fine information read-out. Grouping these various forms, the
illuminated zone of the read-out plane resembles the letter H with its
legs disposed parallel to the longitudinal axis X.sub.1 of the track 31.
FIG. 7 shows how this configuration of spots can be produced. The read-out
beam 28, after having been rendered parallel, is incident upon a
refractive plate 27 which, in the central zone 43, has parallel faces and
in the marginal zones 42 and 44 non-parallel faces designed to locally
change the orientation of the parallel light rays; the centre beam is
codirectional with the axis Z and the two others are slightly oblique in
attitude, in mutually opposite directions. The beams are delimited by
three rectangular windows 36, 37 and 52 formed in the mask 35 which is
arranged in the neighbourhood of the projection objective lens 26. Since
the projection of the spots 54, 53 and 55 takes place in the focal plate
X, Y, of the objective lens 26, and in view of the diffraction phenomena
occuring in the neighbourhood of the focus of an objective lens, it will
be seen that it is necessary for the major axis of the window 36 to be
parallel to the axis Y.sub.1 so that the radiation emerging from it can
produce the elongaged spot 54 whose major axis is parallel to the axis
X.sub.1 ; the same applies to the orientation of the two other rectangular
windows 52 and 37, the emergent radiations from which form the elongated
spots 55 and 53.
Considering projection onto the detection plane X.sub.2 Y.sub.2, of
radiation giving rise to the spots 53, 54 and 55, it will be seen that in
the absence of any diffractive element in the path of the three read-out
beams 8, 9 and 51, the radiant energy is projected onto the detection
plane X.sub.2 Y.sub.2 at three zones which are the pseudo images of the
windows located in the XY plane. The zone illuminated by the beam 8 is
straddled by the photo-electric transducers 45 and 46 in order to pick up
the spread radiation due to coincidence between a diffractive element of
the track 31, and the spot 53. The photo-electric transducers 49 and 50
perform the same function vis a vis the beam 9 and the spot 54. By
combining the voltages produced by the transducers 45, 46, 49 and 50, with
the help of circuits 39, 40 and 20, the eccentricity signal which is
required to guide the read-out device is obtained. The photo-electric
transducers 47 and 48 which straddle the zone illuminated by the read-out
beam 51, are designed to read out the information stored in the
diffractive track 31; to this end, they are connected to an adder circuit
38 which produces a square waveform V characteristic of the distribution
of the diffractive elements along the track 31. It is not necessary to
provide two transducers for each read-out beam, instead it is equally
possible to utilize in each group a single transducer whose central
portion has been masked off in order to render the latter insensitive to
the undiffracted radiation fraction.
In FIG. 8, another embodiment of the read-out device in accordance with the
invention can be seen. It is distinguished from the other embodiments
already described, by its use of a double-refracting prism 29. The
radiation source 30 and the optical system formed by the lens 34 and the
polarizer 56, make it possible to project onto the prism 29 a parallel
read-out radiation 28 whose polarization P is disposed obliquely in
relation to the two principal axes 64 and 65 of the material from which
the prism 29 is cut. The exit face of the prism 29 supplies two oblique
radiation fractions 8 and 9 which pass through the window 57 in the mask
35 and are then concentrated by the projection of objective lens 26 in the
read-out plane X.sub.1 Y.sub.1 which contains the diffractive track 31 of
width L. Because of the double-refracting property of the prism 29, two
read-out spots, 32 and 33, are obtained in the read-out plane X.sub.1
Y.sub.1 and since the window 57 has its major axis arranged in the
direction X, these two elongated spots have their major dimension in the
direction Y.sub.1 , intersecting the longitudinal axis of the track 31.
The spots 32 and 33 straddle the track 31 and can therefor be used both to
read out the track and to measure its eccentricity. After having projected
the two spots 32 and 33 onto the read-out planes, the beams 8 and 9,
respectively illuminate, in the detection plane X.sub.2 Y.sub.2, the
rectangular zones 67 and 68 which overlap substantially more than FIG. 8
would suggest where the distance between the spots 32 and 33 has been much
exaggerated. Outside these illuminated zones 66 and 67, which are the only
ones to receive light in the absence of any diffractive elements in the
path of the beams 8 and 9, two photo-electric transducers 60 and 59 are
arranged. These receive the diffracted radiation fractions occurring in
the presence of a diffractive element, and since these fractions have
crossed polarizations the transducers 60 and 59 are associated with
polarization analysers 61 and 58. The transducers 60 is sensitive only to
spread in the beam 9 whose polarization direction 62 is determined by the
double-refracting prism 29, whilst the transducer 59 is sensitive only to
spread in the beam 8 whose polarization direction 63 is perpendicular to
the direction 62. Thus, due to the polarization analysers 58 and 61, it is
possible to provide two groups of transducers which are respectively
sensitive to the diffractions occuring in the read-out beams 8 and 9. This
comes back to the same kind of processing of the signals furnished by the
transducers 59 and 60, as far as the formation of the eccentricity signal
.epsilon. and the read-out signal proper, V, is concerned. It should be
pointed out that the space between the transducers 60 and 59 may contain a
photo-electric transducer designed to directly furnish the read-out signal
V, because the spread in a read-out radiation under the effect of a
diffractive element, brings about a reduction in luminous intensity in the
zone which is illuminated in the absence of any diffractive element.
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