WO1993023849A1 - Device for imparting curvature across the width of an optical recording medium - Google Patents

Abstract

A device for imparting curvature across the width of an optical recording medium (30) includes a form (26) that is provided with a guide portion (28). The guide portion (28) has a front guiding surface (32) against which the optical recording medium (30) is guided. The guide portion (28) of the form (26) is convex while the front guiding surface (32) of the guide portion (28) is concave. The concave shape of the front guiding surface (32) causes the optical recording medium (30) to curve concavely across its width as the optical recording medium (30) is guided along the front guiding surface (32).

Description

DEVICE FOR IMPARTING CURVATURE ACROSS THE WIDTH

OF AN OPTICAL RECORDING MEDIUM

Technical Field

The present invention generally relates to a device for use in an optical recording system and, more particularly, to a device for use in, for example, an optical video tape,

record and playback system.

Background Art

It is known that storage of data on a recording tape can be accomplished by using magnetic storage techniques in which the recording tape is moved into contact with a

read/write head for purposes of writing information on the tape and reading the stored information. By way of example, such a system is shown in Figure 1. As shown in that drawing, a tape 10 is brought into engagement with a read/ write head 12 by way of several movable tape engaging guides 14. The read/write head 12 writes information on the tape 10 and also reads information that is stored on the tape 10.

Recently, attention has turned to optical recording technology as an alternative to

magnetic storage techniques for storing data on a recording tape. In optical recording technology, a beam of light (e.g. , a laser beam) is directed at and scans across the width

of a moving data storage medium, such as a flexible optical tape, to produce unique domains on the tape that represent binary data bits. This technology is described in more

detail in, for example, United States Patent Nos. 4,719,615 and 4,912,696, the disclosure of which is incorporated herein by reference.

Generally speaking, optical recording technology involves the use of a source of

light which directs a light beam at a mirror or other reflective surface, whereupon the light beam is reflected and directed at the optical tape. Typically, the mirror is connected to a suitable operating device (e.g., a motor and control system) that causes the mirror to rotate slightly back and forth. The rotation of the mirror causes the light beam to scan back and forth across the width of the tape as the light beam is reflected off the mirror. In this way, information can be stored on the tape in the form of unique domains, and information already stored on the tape can be read.

As a result of the foregoing arrangement and operation, the light beam reflected from the reflecting device moves in an arcuate path that defines an arc of a circle. If the portion of the optical tape being scanned possesses a relative flat configuration, the focal point of the light beam must be continually adjusted as the beam scans across the width of the tape. This is so because the focal point of the light beam when the beam is directed at, for example, the middle of the optical tape is different from the focal point of the light beam when the beam is directed at, for example, the edge of the tape. In order to ensure proper focusing of the beam at all times, it would be necessary, therefor, to employ relatively complicated focusing optics.

Disclosure of The Invention

Generally speaking, the present invention provides an optical video tape record and playback system that would eliminate the need for complex focusing optics and thereby simplify the overall design of the system. More particularly, the present invention provides a device that imparts curvature across the width of an optical recording medium. The device includes a guide portion that has a front guiding surface along which the optical recording medium is guided. The front guiding surface is concave to cause the

optical -recording medium to curve across its width as the optical recording medium is guided along the guide portion of the form. In accordance with a preferred embodiment of the present invention, the guide

portion of the form can be convex to help ensure that the optical recording medium is forced against the front guiding surface, Also, the device can include an extension that

is connected to the form and that extends away from the front guiding surface to help guide the optical recording medium across the front guiding surface.

In accordance with another aspect of the present invention, a system for writing and reading data on an optical recording medium includes a light source for providing a light beam, an arrangement for focusing and directing the beam of light from the light source onto the optical recording medium to produce spots on the optical tape

representing bits of data and to read stored data on the optical tape, and a form around which the optical tape is to be guided. The form includes a guide portion having a front

guiding surface against which the optical recording medium is to be guided. The guiding surface is concave that the optical tape is curved across its width as the optical tape is guided along the guide portion of the form. In accordance with a preferred embodiment of the system, the form can be convex

to help ensure that the optical tape is pressed against the front guiding surface as the optical tape is guided past the guide portion. The system can also include two spaced apart guide rollers, each of which is positioned at one end of the guide portion of the form. In accordance with a still further aspect of the present invention, a method of

storing data on an optical recording medium and reading stored data on the optical

recording medium includes the steps of withdrawing an optical tape from a feed reel, imparting a curvature across the width of the optical tape by guiding the optical tape

along a concave front guiding surface of a guide portion of a form, scanning a light beam back and forth across the width of the optical recording medium, and winding the optical tape onto a take-up reel. In the preferred embodiment, the optical recording medium is

guided across a convex guide portion in order to help ensure that the optical tape is pressed against the front guiding surface as the optical tape is guided past the guide

portion.

Brief Description of The Drawings

The present invention can be further understood with reference to the following

description in conjunction with the appended drawings, wherein like elements have been

provided with the same reference numerals. In the drawings: Figure 1 is a front view of a known read/write head used in systems which store data on a recording tape by way of magnetic storage techniques;

Figure 2 is a perspective view of the form according to the present invention, illustrated in conjunction with a portion of an optical video tape record and playback

system; and Figure 3 is a schematic illustration of a portion of an optical video tape record and

playback system incorporating the form according to the present invention.

Best Mode for Carrying Out The Invention

Figures 2 and 3, generally speaking, show a portion of a system for optically recording data on an optical recording medium and for reading stored data on the optical

recording medium. The system can, for instance, form a portion of an optical video tape

record and playback unit. Preferably, the optical recording medium is a flexible optical tape. While the system includes additional features, those additional features have not

been described or illustrated herein. As shown in Figure 3, the system includes a light source 20. a focusing mechanism 22, a reflecting device 24 and a guide member 26, all of which are preferably

mounted within a housing (not shown) of the optical video tape record and playback unit.

The light source is adapted to produce a light beam 21 , preferably a laser light beam.

The light beam 21 produced by the light source 20 is directed at the focusing mechanism

22. The focusing mechanism 22 can be any suitable and known mechanism for use in focusing the light beam from the light source 20.

The focused light beam emerging from the focusing mechanism 22 is then directed at the reflecting device 24. The reflecting device 24 can be a mirror or any other suitable device capable of reflecting light. The reflecting device 24 is mounted for rotation and

is connected to a suitable control device 25. The control device 25 controls operation of a motor or other suitable apparatus (not shown) for rotating the reflecting device 24 in

the manner represented by the arrow A. The rotation of the reflecting device 24 causes the beam of light 21 to move up and down as shown in Figure 3. In that way. the light beam 21 can scan back and forth across the width of the optical tape as the tape is

moving in a direction parallel to its length. Thus, the amount of rotation of the reflecting device should be sufficient to permit the light beam 21 to scan the entire width of the optical tape.

The light beam 21 that is reflected from the reflecting device 24 is directed at the guide member 26. As is shown most clearly in Figure 2, the guide member or form 26

includes a guide portion 28. This guide portion 28 faces in the general direction of the reflecting device 24. For reasons that will become apparent from the description that

follows, the guide portion 28 is convex as seen from above the form 26. Specifically, the

guide portion 28 of the form 26 is convex toward the reflecting device 24.

As most clearly illustrated in Figure 3, the guide po.rtion 28 is provided with a front guiding surface 32 that faces in the direction of the reflecting device 24. The front guiding surface 32 of the guide portion 28 is concavely curved from the top surface 33 of the form 26 to the bottom surface 35 (i.e., as seen from the side of the form 26). More particularly, the front guiding surface 32 is concavely curved away from the reflecting device 24. 5 As shown in Figure 2, the system can be provided with two reels 34, 36 which, depending upon the direction of movement of the flexible optical tape 30, define a take- up reel and a feed reel. The tape 30 is unwound from one of the reels (e.g. , reel 34), is guided along the front guiding surface 32 of the guide portion 28 of the form 26, and is then wound on the other reel (e.g., reel 36).

10 As the optical tape 30 is guided along the front guiding surface 32, the concave curvature of the front guiding surface 32 imparts a similar concave curvature across the width of the optical tape 30. Preferably, the radius of curvature of the front guiding surface 32 is selected such that it is equal to or substantially equal to the distance between the reflecting device and the front guiding surface 32 (as measured along the light beam

15 30). As a result, the light beam 30 reflected from the reflecting device 24 traces an arc of a circle that substantially corresponds to the circular arc defined by the concave front guiding surface 32. Stated differently, the distance between the concave front guiding surface 32 and the reflecting surface of the reflecting device 24 (as measured along the light beam that is reflected from the reflecting device 24) is the same or substantially the

20 same, regardless of whether the light beam is directed at the middle of the optical tape 30, the edges of the optical tape 30, or some other point on the optical tape 30. Due to the foregoing correlation, it is not necessary to provide complex focusing optics because the focal point of the light beam 21 relative to the optical tape 30 remains substantially

constant as the light beam 21 scans the width of the optical tape 30.

25 To ensure that the advantages associated with providing a concave guiding surface 32 are fully realized, the optical tape 30 should preferably be in contact with or substantially in contact with the front guiding surface 32 of the guide portion 28 as the optical tape 30 is guided past the guide portion 28 of the form 26. So long as sufficient tension is applied to the optical tape 30, that objective can be achieved.

5 Although the optical tape 30 isάn tension as it is wound onto one of the reels 34,

36, that tension may not be sufficient to force the optical tape 30 against the front guiding

surface 32 of the guide portion 28. To further facilitate the tensioning, the guide portion

28 of the form 26 is convex. In addition, the guide portion 28 of the form 26 is positioned slightly forwardly of the reels 34, 36 (i.e. , slightly forwardly in the direction

10 of the reflecting device 24). That is, the guide portion 28 of the form 26 is positioned

slightly forwardly of an imaginary line extending between the rotational axes of the reels

34, 36.

The combination of the aforementioned two features helps ensure that the optical

tape 30 is pulled sufficiently to force it against the front guiding surface 32 of the guide

15 portion 28. The extent to which the guide portion 28 of the form 26 is positioned forwardly of the reels 34, 36 and the amount of curvature of the convex guide portion

28 can be selected to ensure that sufficient tension is applied to the optical tape.

To help guide the optical tape 30 and further ensure that the tape is sufficiently in tension, guide rollers 40, 42 can be provided. The guide rollers 40, 42 are preferably

20 positioned at opposite ends of the guide portion 28 of the form 26.

Additionally, as best shown in Figure 3, a guide element 46 is provided to help guide the tape and prevent it from sliding upwardly along the front guiding surface 32,

The guide element 46 can be in the form of an extension member that is connected to the

guiding portion 28 of the form 26 and that extends away from the front guiding surface

25 32. Of course, other suitable arrangements could be employed for serving substantially the same purpose as the guide element 46.

In operation, the optical tape 30 is unwound from one of the reels (e.g., reel 34), is guided behind the guide roller 40, is guided along the guiding portion 26, is passed behind the other guide roller 42 and is wound on the other reel 34. The optical tape 30 is in a flat configuration as it moves from the take-off reel 34 and around the guide roller

40. The optical tape 30 begins to curve across its width as it is forced against the front guiding surface 32. As it leaves the form 26, the optical tape 30 once again returns to its flat configuration as it moves behind the guide roller 42. As a result of the foregoing mode of operation, the optical tape 30 is forced against the front guiding surface 32 so that the optical tape 30 is concave across its width.

While the optical tape 30 tape is moving past the guiding portion 28 of the form 26, the light beam 21 (e.g. , laser beam) that is reflected off the reflecting device 24 scans back and forth across the width of the optical tape 30 (through suitable rotation of the reflecting device) to either write information on the optical tape 30 or to read information that has already been stored on the optical tape 30. Because the curvature of the front guiding surface 32 matches or substantially matches the arc traced by the scanning light beam 21, the focusing optics, as well as the entire focusing system, can be greatly simplified.

The foregoing has described the principles, preferred embodiments and modes of operation of the present invention. However, the invention should not be construed as limited to the particular embodiments discussed. Instead, the above-described embodiments should be regarded- as illustrative rather than restrictive, and it should be appreciated that variations and changes may be made by workers skilled in the art, and equivalents employed, without departing from the scope of the present invention as defined by the following claims. Industrial Applicability

The present invention cab be adapted in an optical recording system, that is, an optical video tape record and playback system, to thereby provide a device that imparts curvature across the width of an optical recording medium.

Claims

What is Claimed is:

1. A device for imparting curvature across the width of an optical recording medium, comprising:

a form having a guide portion along which the optical recording medium is to be guided, the guide portion being curved convexly and having a front guiding surface against which the optical recording medium is to be guided, the front guiding surface having a concave shape to cause the optical recording medium to curve concavely across its width as the optical recording medium is guided along the guide portion surface.

2. The device according to claim 1, including means for guiding the optical reading medium along the guide portion.

3. The device according to claim 1 , wherein the means for guiding includes an extension connected to the form and extending away from the front guiding surface.

4. A device for guiding an optical recording medium and for causing the optical

recording medium to curve across its width, comprising: a form having a guide portion along which the optical recording medium is to be guided, the guide portion having a

front guiding surface against which the optical recording medium is guided, the front

guiding surface having a concave curvature to impart a concave curvature across the

width of the optical recording medium as the optical recording medium moves along the guide portion, and including means for ensuring that as the optical recording medium moves along the guide portion the optical recording medium is forced against the front

guiding surface to thereby cause the optical recording medium to curve across its width.

5. The device according to claim 4. wherein the means for ensuring that the

optical recording medium is forced against the front guiding surface includes the guide

portion being curved convexly.

6. The device according to claim 4, including an extension connected to and extending away from the form at an upper portion of the form.

7. The device according to claim 4, including two spaced apart guide rollers, one of the guide rollers being positioned at each end of the form.

8. A system for writing and reading data on an optical recording medium,

comprising: a light source for providing a beam of light that can be used to store information on the optical recording medium and to read store information; means for focusing and directing the beam of light from the light source onto an optical recording medium; and

a form around which the optical recording medium tape is guided and towards which the light beam from the light source is directed, the form having a guide portion,

the guide portion having a front guiding surface against which the optical recording medium is guided, the front guiding surface being concave so that the optical recording medium is concave across its width when the optical recording medium is guided along the guide portion.

9. The system according to claim 8, including means for helping to ensure that the optical recording medium is pressed against the front guiding surface when the optical recording medium is guided past the guide portion.

10. The system according to claim 9, wherein the means for helping to ensure that the optical recording medium is pressed against the front guiding surface includes the guide portion being convex.

11. The system according to claim 8, including an extension connected to and extending away from the form at an upper end of the guide portion.

12. The system according to claim 11 , including two. spaced apart guide rollers, each of which is positioned at one end of the guide portion of the form.

13. The system according to claim 8, wherein the means for focusing and directing the beam of light from the light source onto an optical recording medium includes a rotatably mounted reflecting device having a reflecting surface so that a light beam which strikes a point on the reflecting surface when the reflecting device is in a first position strikes a point on the optical recording medium.

14. The system according to claim 8, wherein the radius of curvature of the front guiding surface is substantially equal to the distance between the point on the optical recording medium and the point on the reflecting surface when the reflecting device is in the first position.

15. The system according to claim 8, including two reels onto which the optical recording medium is wound and from which the optical recording medium is unwound, the means for focusing and directing the beam of light from the light source onto an optical recording medium including a reflecting device, at least a part of the guide portion of the form being positioned beyond, in the direction of the reflecting device, an imaginary line extending between axes of the reels.

16. A method for storing data on an optical recording medium and for reading stored data on the optical recording medium, comprising the steps of: unwinding an optical recording medium from a feed reel; imparting curvature across the width of the optical recording medium by guiding the optical recording medium along a concavely-shaped front guiding surface of a guide portion of a form; scanning a light beam back and forth across the width of the optical recording

medium; and winding the optical recording medium onto a take-up reel.

17. The method according to claim 16, wherein the optical recording medium is guided across a convexly-shaped guide portion in order to help ensure that the optical recording medium tape is pressed against the front guiding surface.

18. The method according to claim 16, including the step of passing the optical recording medium behind a guide roller before guiding the optical recording medium along the concavely-shaped front guiding surface of the guide portion of the form, and passing the optical recording medium over a guide roller after the optical recording medium has been guided along the concavely-shaped front guiding surface of the guide portion of the form.