DE19962758A1 - Optical disk drive with optical arrangement allowing a read- write head to read diametrically opposed sides of the disk simultaneously to greatly improve read or write speeds - Google Patents

Abstract

Optical disk drive has a read-write head with its functioning end surrounded by the data storage medium. The read-write head is arranged so that light transmitted or received travels in two diametrically opposed directions. This is achieved using a beam splitter that divides light from a laser light source so that the intensity of each beam is approximately the same. The storage medium is in the form of a helically coiled body with the read-write head and the hollow cylinder of the media arranged to rotate around each other in opposite directions. The storage medium is arranged so that the read- write head reads or writes along an inner path in one direction and in a second direction on the outer region of the coil.

Description

The present invention relates to an optical data run work according to the preamble of the independent claim.

Data storage on optical media per se is known; data is stored on CD-Roms, DVD media etc. saved. Optical data has also been proposed to store on a generally round information carrier, which is optically transparent and designed such that the Information carrier through several information carrier layers is readable by, this information carrier spiral is wound up properly, see DE-GBM 298 168 02.2.

Such data storage devices can be a transparent support of the winding body provided by an internal one Optics can be read or written. To Le This is done with a laser light, for example source like a diode laser generated light beam that on  directed a certain area of the information carrier is determined whether a strong Re flexion or absorption is present or not, in with a photo sensor from the scanned area return amount of incident light is determined.

In optical data drives, there is now generally the Er demand data at high speed but still high Read precision, i.e. low error rates.

The object of the present invention is to create something new to provide for commercial use.

The solution to this problem is claimed independently. Before preferred embodiments can be found in the subclaims.

According to a first essential aspect of the invention with an optical data drive with a read and / or Print head that has a function that is surrounded by the storage medium has end, proposed, it being provided that the Read and / or write head for receiving light off and / or the broadcast in two generally diametrically opposed set directions is formed.

This will significantly increase the writing relationship approximate reading speed in which the memory medium is scanned simultaneously in two directions. There the reception or the transmission of light in two is generally diametrically opposite directions the least possible interference in the returned signals through crosstalk on or in the storage medium expect.  

The storage medium can be generally hollow cylindrical and preferably realized in particular by a winding body become. A suitable medium is in DE 298 16 802.2 wrote.

The functional end and the generally hollow cylindrical spoke medium can rotate against each other. It is possible here Lich and preferred that the function end on a driven benen shaft is arranged. This allows the optical Da drive with a fixed optical disk, such as a winding body made of PMMA or the like without having to balance it with high precision, because it is sufficient, a static optical storage medium to use; only the function end respectively the read and / or write head is once again precise to balance.

If the generally hollow cylindrical storage medium as a winding body or with several concentric layers one above the other is preferably formed with the first part of the reading and / or write head a winding position lying further inside be scanned while in the generally diametrically opposite opposite direction of the winding layers lying further out area is detected. In this way, time becomes the focus reduced to different winding layers. It is mentions that with such an arrangement, large data block to be saved as a whole on both internal and external winding layer areas divided can be.

Even with an arrangement with which the diametrically ent against opposite directions winding positions in different Depths are scanned, it is possible and preferred that  the end of the function is generally balanced. It is be preferred if the existing focusing optics on the functional ends are identical.

The read and / or write head preferably comprises a source for the reading and / or writing light, in particular a laser diode or the like, which preferably non-colinear, esp emits special divergent light. When ordering a Beam splitter between the focusing optics for the general diametrically opposite directions with a back reflection gate on the passage side of the through the beam splitter The current beam can then by the path difference of the two diametrically opposed rays of light be achieved that identi with such an arrangement cal lenses can be used for the two directions and the arrangement is nevertheless initially approximately balanced is when in both directions in different diametra len distances are read and / or written.

If a beam splitter is used, it is preferred if this is the incident light from the reading and / or Writing light source in an intensity ratio of approximately 50: 50 on the two diametrically opposite Splits directions.

The beam splitter is preferably a reflector for the through subordinate this current beam, being between beam divider and back reflector in particular a λ / 4 plate can be seen to the polarization of the running through Rotate light and the signal-to-noise ratio by Ver wrestle to improve crosstalk.  

Furthermore, the beam splitter is preferably tilted slightly, so that the two are generally diametrically opposed current rays less affected by crosstalk rivers.

In a preferred embodiment, the Beam splitter, and preferably the lenses, the λ / 4 plate and the back reflector together on a rotary drive.

The light received back from the storage medium is preferred with two separate, belong to the read and / or write head the, but possibly outside of the functional end ordered photo detectors. These photo detectors are preferably arranged so that the light from the first the generally diametrically opposite directions on the first photo detector is focused while light from the second direction is collected on the second photodetector. If, as preferred, this focus is sufficiently strong and the light from the other direction is sufficient is weakly focused is irrelevant if on each of the Photo detectors still light from both directions falls because si Significant signal components only from the focused light beam are expected. It can preferably be between two photo detectors Ren a beam splitting element can be provided to the ge entire, from the end of the function and thus the optical data storage back medium to both photodetectors divide.

The invention is described below only by way of example Drawing described. In this shows:

Fig. 1 shows an optical data drive according to the present invention.

According to Fig. 1 comprises with a generally. 1 designated optical data drive, a read head 2 , which has a function end 4 surrounded by a storage medium 3 and a light source 5 and a photo detection unit 6 .

The storage medium 3 consists of a winding body of, for example, 90 layers of PMMA, which are adequately bonded to one another by a suitable adhesive. Suitable materials for PMMA and connecting intermediate layers can be realized as with "Tesafilm crystal clear".

The light source 5 of the reading head 2 comprises a laser diode 5 a with suitable control (not shown), and a slightly defocusing scattering lens 5 b to produce a defocused reading light beam 7 th

The defocused light beam 7 is directed to the functional end 4 , which comprises a beam splitter 8 , a λ / 4 plate 9 arranged in the passage direction behind the beam splitter 8 and a back reflector 10 . The beam splitter 8 has a beam splitter surface 8 a, by means of which half of the incident light in the beam 7 is directed onto a first displaceably mounted lens 11 a. The focal length of the lens 11 a is chosen so that it focuses the light on egg ne of the inner layers 12 a.

In the passage direction, the λ / 4 plate 9 , like a back reflector 10, is provided behind the beam splitter for the light passing through the beam splitter surface 8 a to rotate its direction of polarization. The back reflector 10 is aligned so that the light comes back, reflected at the interface 8 b and directed to the slidably mounted fo kussierlinse 11 b. This lens 11 b is at the diametrically opposite direction to lens 11 a angeord net and the focal length of the lens 11 b is selected so that the light in the starting position is directed to the outer layer of the wound storage medium 3 . The focal lengths of the lenses 11 a, 11 b are identical.

The lenses 11 a, 11 b are arranged on an actuating unit (not shown) in order to enable their displacement. The adjustment range is so large that at least half of all winding layers can be overwritten with the respective focal point of the light, namely the inner half with lens 11 a and the outer half with lens 11 b.

The function end 4 is arranged with the beam splitter 8 , the λ / 4 plate 9 , the back reflector 10 , the two lenses 11 a, 11 b and the associated focusing units on a rotary drive (not shown), which rotates the beam splitter at high speed can rotate the axis defined by the light beam 7 . The function end 4 is balanced.

The end of the function can also be moved axially. The lens 11 a is further designed to collect the light reflected from the storage medium 3 at the point 12 a and so irradiate into the beam splitter 8 that it strikes a steel splitter 13 , from which it is reflected on the photodetection unit 6 .

The lens 11 b is designed to collect the back-reflected light from the focus point 12 b, so that it reflects on the surface 8 b of the beam splitter 8 in the direction of the λ / 4 plate 9 and after passing through it is reflected on the reflector 10 is, after which it is thrown back through the λ / 4 plate 9 and the beam splitter 8 back towards the laser light source 5 , wherein it is directed by the beam splitter arranged in front of the laser light source onto the photo detection unit 6 .

The photodetection unit 6 comprises a beam splitter 13 , which is arranged in the beam path between the beam splitter cube 8 and the defocusing render upper lens 5 b in order to direct the light received by the areas 12 a and 12 b in the direction of two photodetectors 16 a, 16 b.

The beam splitter 13 is another beam splitter 14 arranged with which light is directed onto a lens 15 a, which is connected upstream of the first photodetector 16 a. The lens 15 a and the photodetector 16 a are arranged such that the light from the storage medium area 12 a is focused on the photodetector 16 a. Behind the beam splitter 14 , a lens 15 b is provided in the direction of passage, with which light is focused on a photodetector 16 b. Lens 15 b and Fo todetektor 16 b are arranged so that the light from the storage medium area 12 b is focused on the photodetector 16 b.

The optical data drive 1 of the present invention operates as follows:
First, a described storage medium 3 is placed in its position around the functional end 4 of the read head 2 and a cover is closed if necessary (not shown). The function end 4 is then set in rotation within the storage medium and moved into a desired axial position.

The laser light source 5 a is excited and sends a beam 7 through the beam splitter 13 in the direction of the beam splitter 8 . The lens 11 a is focused on a desired winding position. A first part of the beam 7 is directed at the beam splitter 8 in the direction of the lens 11 a, which kisses the beam onto the axially desired storage area 12 a fo.

The other part of the complementary light beam 7 comes with further expansion through the beam splitter 8 , the λ / 4 plate 9 , with reflection on the reflector 10 , with renewed passage through the λ / 4 plate 9 in the beam splitter 8 , in which this part of the beam 7 is directed at the surface 8 b onto the lens 11 b, which defocuses the beam onto a focused outer winding layer area.

The light received from the inner winding layer area 12 a on the lens 11 a passes through the beam splitter 8 under reflection at the beam splitter 13 into the photo detection unit 6 . There, part of the light is directed through the steel splitter 14 onto the lens 15 a and from there onto the photodetector 16 a. This results in a precise focus in the photo detector 16 a. Another part of the light originating from the area 12 a runs through the beam splitter 14 into the lens 15 b and is directed by the latter into the photodetection unit 16 b. However, due to the divergence of the incident beam 7 , which affects the entire beam path, there is no sharp focus point for the light from the storage area 12 a at the photodetector 16 b.

The light from the inner winding bearing area 12 b also reaches the beam splitter 13 after passing through the functional end 4 and is partially reflected on the beam splitter 14 , while at the same time it is partially transmitted. This results due to the divergence of the beam 7 at the photodetector 16 a no sharp focus of the light originating from the area 12 b, while this light originating from the area 12 b of the storage medium 3 is sharply focused on the photodetector 16 b through the lens 15 . This results in a sharp image of the light received back from the winding layer area 12 a only on the photodetector unit 16 a, while a sharp image of the light returned from the winding layer area 12 b only results on the photodetector 16 b.

The modulation of the received light signals is then determined at the photodetectors 16 a, 16 b. This modulation is dependent on the data stored and sequentially read out in the storage medium, which are stored in binary form by changing the optical properties of the storage medium, in particular its refractive index. The detection of the light signals received for the storage of the data changed reflection properties of the storage medium 3 thus allow the decoding and evaluation of the information stored in the storage medium 3 .

It should be mentioned that it can be determined by appropriate design of the photo detectors 16 a, 16 b and / or the evaluation circuits assigned to them, whether the allocated and currently read-out memory area 12 a or 12 b is in the focus of the lens 11 a or 11 b be found. For this purpose, track information can also be saved or, for media still to be written, formatted. There is a control circuit known per se, which is known in the prior art and is based on an optimization of the signal received by the respective area. If the storage layer area is to be changed from a further inner to a further outer winding position or vice versa, it is easily possible by appropriate changes tion of the focus position per lens 11 a, 11 b.

Claims (16)

1. Optical data drive with a read and / or write head, which has a function end surrounding the storage medium, characterized in that the read and / or write head for the reception of light and / or the emission of light in two generally diametrically opposite directions is formed. 2. Optical data drive according to claim 1, characterized records that the function end for arrangement in one generally hollow cylindrical storage medium is. 3. Optical data drive according to the preceding claim, characterized in that the functional end and generally hollow cylindrical storage medium for rotation are trained against each other.   4. Optical data drive according to the preceding claim, characterized in that the functional end on a Rotary drive is arranged in particular axially movable. 5. Optical data drive according to one of the preceding An sayings, characterized in that the general hollow cylindrical storage medium through a winding body is realized and the read and / or write head is formed one along the first direction inside and along the second direction a white the outer wrapping layer area. 6. Optical data drive according to one of claims 4 or 5, characterized in that the functional end is balanced. 7. Optical data drive according to one of the preceding An sayings, characterized in that the reading and / or Write head a light source, especially laser light source, from which a non-colinear, esp special divergent beam of light at the end of the function is sent. 8. Optical data drive according to one of the preceding An sayings, characterized in that the reading and / or Print head includes a beam splitter, with which is radiated light from the light source into the first be drawing second of the diametrical directions in progress Light is split. 9. Optical data drive according to the preceding claim, characterized in that the beam splitter the light divided approximately in the intensity ratio of 50:50.   10. Optical data drive according to one of the preceding An Proverbs 8 or 9, characterized in that the beam divider a reflector for the non-reflected beam share is subordinate. 11. Optical data drive according to the preceding claim, characterized in that between the beam splitter and Re a λ / 4 plate is arranged in the reflector. 12. Optical data drive according to one of claims 8 to 11, characterized in that between the beam splitter and Storage medium a lens arrangement is provided. 13. Optical data drive according to the preceding claim, that for the two diametrically opposite directions separate lenses are provided and relate to the lenses approximately lens arrangements in diametrically opposed set directions have the same focal lengths. 14. Optical data drive according to the preceding claim, characterized in that the reading and / or writing head for the detection of light at least two photodes Tectors, which are arranged so that the light from the first of the generally diametrically opposed Directions on the first photo detector and light from the second of the generally diametrically opposite Rich tion is collected on the second photo detector. 15. Optical data drive according to the preceding claim, characterized in that on each of the photodetectors Light falls from both directions.   16. Optical data drive according to one of claims 14 or 15, characterized in that between the two photodes tectors a beam splitting element is provided.