SE424676B - DEVICE FOR READING A RADIATOR REFLECTING RECORDER - Google Patents

Description

7803138-2 2 the details of the information sheet must be very small. For example, if a television program of 30 minutes in length is stored on one side of a disk-shaped, round record carrier in an annular area with an outer radius equal to about 15 cm and an inner radius equal to about 6 cm, then the track width is about 0.5 / um while the average length of the areas and intermediate areas will a fi up to about 1 I.

To enable reading of such small details, a lens system with a relatively large aperture must be used. However, the depth of field of such a lens system is small. Because in the reading device the distance between the plane of the information strip and the lens system can vary by an amount greater than the depth of field. measures must be taken to enable these variations to be detected and the focus to be corrected.

According to the said German patent specification, a beam is made for this purpose which has been re-selected by the record carrier astigmatically by arranging a cylinder lens in the beam path for the beam behind the objective system. Between the focal lines of the astigmatic system, which is formed by the objective system and the cylindrical lens, a radiation-sensitive detector, consisting of four sub-detectors, is arranged. When the plane of the information structures changes relative to the objective system, the shape of the image generated on the subdetectors also changes. This shape change can be detected by combining the output signals of the subdetectors in a suitable manner.

When using the known reading device, practical problems can arise.

The radiation distribution over the composite detector also depends on the firing of the beam through the details of the information source. In the first instance, refraction in the longitudinal direction of a track is to be read due to the sequence of areas and intermediate areas. The variations in the radiation distribution over the composite detector as a result of this refraction have a high frequency compared with the focusing errors, whereby the effect of this refraction on the focusing control signal can be eliminated electronically. In addition, refraction occurs in a direction transverse to the tracer.

This refraction depends on the position of the radiation spot formed on the record carrier relative to the center of a track to be read. During the installation of the reading device, the focusing error detector device must be adjusted so that when the center of the radiation spot coincides with the center of a track to be read * and when the focus is correct, the focusing error signal is equal to zero. However, during reading of the record carrier, the reading spot is moved from the center of a track to be read towards its edge, the radiation distribution over the composite detector will change regardless of the focus. This gives rise to an incorrect focusing error signal, whereby the focus of the lens system changes incorrectly. The reading apparatus may also comprise a position error detector device for determining a deviation between the centers of a. radiation spot formed on the record carrier and the center of a track to be read, and a servo device for correcting the center of the reading spot. The position error signal also depends on the focus of the lens system. In case of incorrect focusing, the position of the radiation spot will also be corrected incorrectly. As a result, the focusing error increases again. It may then occur that both the servo device for focusing and the servo device for correcting the position of the reading spot relative to the track to be read end up outside the control area.

V As the optical reading unit on its way to a certain determined passage in the stored program moves radially over the record carrier at high speed, the edges of each track that is crossed will give rise to a change in the focusing error signal. The servo device for focusing then intervenes unnecessarily and with high frequency. When the focusing of the objective system is corrected with respect to the movement of the system, the high-frequency control signals supplied to the drive means of the objective system give rise to a troublesome acoustic "rattle". In addition, the drive means consume extra power.

Since the width of a track is smaller than the distance between the tracks, the reading spot will on average be shorter at the tracks than between the tracks when the reading unit is moved quickly across the track direction. This means that the average focusing error cycle is also not zero in the case of correct focusing. It follows that the focusing will, on average, be corrected incorrectly. The effect of refraction of the beam across the track direction is particularly noticeable when the projection of a track section to be read on the surface of the subdetectors, hereinafter referred to as "effective track direction", forms an angle. equal to 450 with the X and Y axes of the composite detehorn.

The object of the invention is to provide an embodiment of the known reading apparatus in which refraction across the track direction does not affect the focusing error signal.

To achieve this, the apparatus according to the invention is characterized in that one of the axes of the coordinate system in whose quadrants the subdetectors are located is arranged parallel to the effective track direction, and that the astigmatic focal lines are arranged to form an angle equal to with 450 with the effective track direction.

The invention will be described in more detail in the following with reference to the drawing, in which: g shows the reading apparatus according to the invention; and Figs. 2a, 2b and 2c show how the shape of the spot formed on the detector varies as a function of the focusing.

In the apparatus of Fig. 1, a round, disc-shaped record carrier is denoted! The information structure is, for example, a phase structure and comprises a large number of concentric or quasi-iconoentric grooves 7, which grooves consist of a series of areas g and intermediate areas t. The areas may, for example, be located at a different level in the record carrier. than the intermediate areas. The information may, for example, consist of a (false) television program, but may alternatively consist of. of other information, e.g. a large number of different images, or digital information.

The record carrier is illuminated by a reading radiation map 3, which is obtained from a radiation source 3, which can for instance be constituted by a cw laser. A lens system, shown for simplicity by a simple lens 5, focuses the reading beam mp to a reading spot V on the plane of the grooves 2. The focal length of the auxiliary lens 6 has been chosen in such a way that the objective system pupil is adequately filled. The reading beam is reflected by the record carrier and is then modulated in accordance with the stored information in a track section to be read. In order to separate the incident (unmodulated) and the reflected (modulated) reading beam flip-flops, the beam path comprises a radiation splitter 8, e.g. in the form of a translucent mirror. The radiation divider directs the modulated reading beam to a radiation-sensitive detector 9. This detector is connected to an electronic circuit 10, which derives a high-frequency information signal Si and, as will be described below, a focusing error signal Sf of lower frequency.

In order to enable detection of focalisation errors, the beam path behind the radiation splitter 8 comprises an astignatic element 11. This element can, as shown in Fig. 1, be constituted by a cylindrical lens. It is also possible to cause astigmatism in other ways, e.g. through a flat transparent plate which is arranged obliquely in the beam or through a lens which is inclined relative to the beam. Instead of a focal point, an astigmatic system has two astignatic focal lines, which, viewed in an axial direction, have different positions and form a straight circle with each other.

The objective system and the cylinder lens thus supply two focal lines 12 and 13 to the reading spot V. The radiation-sensitive detector 9 is now arranged in a plane which, viewed along the optical axis, is located between the lines 12 and 13, and preferably at the place where the dimensions in two mutually perpendicular directions of the image spot superimposed on the reading spot V are equal as far as possible with correct focusing.

To enable detection of the shape of the leakage V 'and thereby the degree of focus, the detector 9 comprises four sub-detectors, which are located in the four quadrants of a Kil coordinate system. Figures 2a, 2d and 2c show a top view of the four subdetectors A, B, C and D along the line 2,2 'in Fig. 1, with the different shapes of the spot V' projected thereon for different distances between the lens system and the track plane. The X and Y axes form the angle 459 with the axis 15 of the cylinder lens, i.e.

I with the astigzrzatic focal lines 12 ooxh 13, while the X-axis is now parallel to the effective groove direction. 7803138-2 Fig. 2a shows the position when the distance between the lens system and the track plane is correct. If this distance is too large, the focal lines 12,13 are closer to the cylinder lens 11. The detector 9 is then closer to the focal line 13 than the focal line 12. The spot V 'then has the shape shown in Fig. 2b. If the distance between the objective system and the track plane is too small, the focal lines 12 and 15 are further away from the cylinder lens and the focal line 12 is located closer to the detector 9 than the focal line 13.

The spot V 'then acquires the shape shown in Fig. 2c.

If the signals emitted by the subdetectors A, B, C and D are represented by SA, SB, SC and SD, then the focusing error signal Sf is given by the expression sf = (SA + sC) _ (sBJfsD) It is realized that in the state according to Fig. 2a SA + SC = SB + SD, which means that Sf = O. In the state according to Fig. 2b and Fig. 2c, Sf is negative and positive, respectively. By adding the signals SA and SC as well as the signals SB and SD and then subtracting the thus formed smmasigrxals from each other, an unambiguous focalization error signal is obtained. This signal can be processed electronically in a previously known manner so that a focusing control signal is obtained by means of which the focusing of the objective system can be corrected, e.g. by moving the objective system relative to the track plane by means of an electromagnetic coil.

As the reading spot V is moved across the track direction, the amount of radiation towards, for example, detectors A and B will increase compared with the incident radiation on detectors C and D, regardless of the focus. However, since the focusing error signal Sf is derived by subtracting the signals SA and SB, the effect of said movements on the signal Sf becomes negligible.

Finally, it is emphasized that the beam b can also be used for reading the information on the record carrier. The information signal Si can be obtained, for example, by adding the signals from the four subdetectors. Variations in the radiation distribution over the subdetectors as a result of a movement of the radiation spot V in a direction across the track direction then have a significantly lower frequency than the variations in the radiation distribution due to the sequence of areas and intermediate areas in a track. By allowing the signal SA + SB + SC + SD to pass through a high-pass filter, the effect of this movement across the track direction e1 on the signal Si is eliminated.

Claims (1)

An apparatus for reading a radiation-reflecting record carrier (1) on which information is stored in an optically readable, track-arranged information structure (g, t), which apparatus comprises a radiation source (Ä) which generates a reading beam (3), an objective system (5) for transmitting the beam to a radiation sensitive detector device (9) via the record carrier, which device performs conversion of the reading beam modulated by the information structure into an electrical signal (Si), and a opto-electronic focusing detector device for determining deviation between the desired and actual position of the focusing plane of the objective system, which focusing detector device comprises an astigmatic element (II) and a radiation-sensitive detector (9), which detector comprises four subdetectors (A, B, C, D) a which are located in four different quadrants | an imaginary XY coordinate system, wherein the X and Y axes are arranged to form an angle equal to ÅBO with the astigmatic focal lines (12,13) of the astigmatic element, characterized in that one of the axes (X, Y) of the coordinate system The warning detectors (A, B, C, D) are located, are arranged parallel to the effective track direction (7), and that the astigmatic focal lines (12, 13) are arranged to form an angle equal to # 50 with the effective track direction. REQUEST PUBLICATIONS: SE patent application 7607643-9 (GHB 7/08)