JPH02218031A - Optical tape medium - Google Patents

Abstract

PURPOSE:To prevent sticking of dust to the optical tape medium which records or reproduces information by a light spot converged by an optical system and to improve the recording and reproducing characteristics thereof by previously forming a thin film for electrostatic prevention on the tape surface. CONSTITUTION:A recording layer 102 consisting of a thin Te film is deposited at about 300Angstrom thickness on one surface of a base film 101 consisting of polyethylene terephthalate, etc., and is protected by an SiO2 layer 103 having about 1,000Angstrom thickness. A carbon film 104 formed to 50Angstrom is deposited on the other corner to form the DRAW type optical tape medium. The tape medium is irradiated with the laser light from the carbon film 104 side while the light is converged to evaporate the recording layer 102 in this part and to generate a hole, by which the information is recorded. The sticking density of >=2mum dust on the surface of the conductive film 104 after the tape formed in such a manner is rested for 24 hours in an ordinary environmental chamber is about 10 pieces/cm<2> and is much smaller than about 10<3> pieces/cm<2> when the conductive film 104 is not provided.

Description

Detailed Description of the Invention (a) Industrial Application Field The present invention relates to an optical tape medium on which information can be recorded and/or reproduced using a light beam. (b) Conventional technology in which information can be read using light. Examples of media used include optical discs such as compact discs and video discs. In such an optical disk, the laser beam is focused at 1 μm by the objective lens.
The information track on the disk is scanned by this spot, and the information recorded on the disk is read by the reflected light.

FIG. 6 is a diagram showing the mechanism. In the figure,
The disk (20) is composed of a substrate (21) made of transparent plastic, a reflective film (22), and a protective layer (23). Here, the information is the reflective film (
22) are recorded as pits on the side surface.

(24) is an objective lens that directs the laser beam (25) to the substrate (
21) to converge on the interface between the substrate (21) and the reflective film (22) as a spot with a diameter of about 1 μm. (26
) is an actuator that controls the objective lens (24).
The objective lens (24) is moved to correctly position the spot on the interface. The information is read by causing the resensor to receive the reflected light from the reflective film (22) by a desired means.

Since the reflected light is modulated by the bit, the sensor outputs a signal according to this modulation. still,
Such a mechanism is described, for example, in "Illustrated Compact Disc Reader" published by Ohmsha Co., Ltd. (published November 25, 1980).

Such an optical reproducing system has the advantage of not causing damage to the medium due to wear or the like because information is read without contact using light. However, on the other hand, if there is dust on the readout surface, this dust will block the light.
There is a problem that errors occur when reading information.

In an optical disc, as shown in FIG. 6, the thickness of the substrate (21) is relatively large, so the diameter of the beam on the reading surface (28) of the disc is large. Since the beam is not obstructed by dust to the left, errors in reading information do not occur. Therefore, if the reading surface of an optical disc is wiped with a cloth before playback, reading errors will not occur as much.

Incidentally, in recent years, an optical tape system using an optical tape medium as a medium has been studied. This type of optical tape system is disclosed, for example, in Japanese Patent Application Laid-Open No. 57-64333 (
GIIB 7100) discloses 6. In such an optical tape system, an information signal is obliquely recorded on the optical tape by winding the optical tape diagonally around a rotating drum having an optical head and scanning the laser spot helically. The optical tape medium used in such optical tape systems must be highly flexible because it is wound around a rotating drum. It must be very thin, approximately 10-20 μm. However, if the substrate is thin like this, the diameter of the beam on the readout surface will be very small.
Even small pieces of dust can cause reading errors.

Moreover, such dust has a habit of blocking the beam and causing errors in information recording.

(c) Problems to be Solved by the Invention The present invention solves the following problems when recording or reproducing information on an optical tape.
This is intended to solve the problem of errors occurring in recording or reproduction due to dust present on the beam incidence surface.

(d) Means for Solving the Problems In view of the above problems, the present invention has a structure in which an antistatic thin film is formed on the surface of an optical tape.

(E) Function: The static electricity present on the optical tape becomes extremely small, making it difficult for dust to adhere to the optical tape.

(F) Example Hereinafter, an example of the present invention will be described with reference to the drawings.

FIG. 1 is a sectional view of the optical tape according to this embodiment. In the figure, (101) is a base film, (102) is a recording layer, (1o3)+i protective layer, and (104) is a conductive film. The base film (101) is made of PET (polyethylene terephthalate) material and has a thickness of 10 μm.
m is set. The recording layer (102) is formed of a Te (tellurium) thin film, and its thickness is set to 300. The protective layer (103) is 5iO1 (silicon dioxide>p
The film thickness is set to 1000 people. The conductive film (104) is made of a carbon film, and its thickness is set to 50. Here, Te thin film, 54
The 0g film and the carbon film are each formed by vacuum evaporation. Note that such a tape is used as a write-once type, and the recording layer (102) is evaporated by convergent irradiation with laser light, thereby forming holes in the recording layer (102) to record information. is to be carried out.

After forming the optical tape in this manner, it was left in a normal environmental chamber for 24 hours, and then the condition of the conductive film surface was examined, and the adhesion density of dust particles with a diameter of 271 m or more was approximately 10 pieces/m'. Met. In addition, as a comparative example, an optical tape was formed by removing the film from the inner guide 1 of the optical tape structure, and when it was left at the same time and at approximately the same position as the tape of the above example, no dust with a diameter of 2 μm or more was attached. Density is approximately 108 pieces/ll1
It was 1111. The experimental results confirmed that the optical tape of this example can prevent dust from adhering more effectively than that of the comparative example. This is thought to be largely due to the fact that static electricity generated on the tape surface during tape manufacture or when the tape is left is grounded through an object that comes into contact with the conductive film and removed from the tape surface.

Next, experimental results when information was actually formed on the optical tapes of the above-mentioned examples and comparative examples will be explained. Incidentally, in such an experiment, an optical tape having the same structure as in the above-mentioned example was used, and as a comparative example, an optical tape having the same structure as in the above-mentioned comparative example was also used. In this experiment, predetermined information was recorded on an optical tape and then played back.
The pit error rate during such reproduction is measured. Recording and reproduction of information is performed by the apparatus shown in FIG. In the figure, (1) is a bottomed cylindrical rotating drum made of aluminum alloy, and (2) is a concave portion (1a) of the rotating drum (1) aligned with the center of rotation of the rotating drum (1).
), (3) is a rotating drum (1).
), a transparent hole is placed at a position facing the reflective prism (2) on the side surface, (4) is an objective lens placed in this transparent light (3), and (5) is a rotation of the rotating drum (1). A rotary shaft fixed to the bottom of the rotary drum (1) coincident with the center, (6) a motor that applies driving force to this rotary shaft, and (7) a motor arranged above the rotary drum (1) and its output. A laser diode whose optical axis of emitted light coincides with the rotation axis of the rotating drum (1), (8) a beam splitter that splits the laser light from the laser diode (7), and (9) a beam splitter (8). A collimator lens converts transmitted light into parallel light, and (10) is a photosensor that receives reflected light from the beam splitter (8).

According to such an apparatus, an optical tape (T) is wound obliquely around the outer periphery of a rotating drum (1) as shown in the figure, and recording and reproduction are performed thereon. At this time, the optical tape (T) is fed at a constant speed along the outer peripheral surface of the rotating drum ( ) by a feeding device (not shown). Also, the rotating drum (1) is a motor (6)
It is sent at a constant rotational speed. Optical tape (
By operating the optical tape T) and the rotating drum (1), the laser beam focused by the objective lens (4) obliquely scans the optical tape (T). Such a recording/reproducing apparatus is generally referred to as a helical scan type recording/reproducing apparatus, and its details are explained in, for example, Japanese Patent Laid-Open No. 149036/1985 (GIIE 71085).

According to such an apparatus, information is recorded on the optical tape (T) by intermittently generating a high-output laser beam according to the bit of information to be recorded. At this time, during the laser beam emission period, the recording layer (102) of the optical tape (T) is erased by the laser beam spot as described above, and a hole is formed in that portion. FIG. 4 shows the recording tracks (11) (11) formed on the optical tape (T) in this manner.
)... is a diagram showing. At the time of playback, the optical tape (T) is similarly fed by rotating the rotary drum (1) and scanning each recording track (11), (11), etc. with a light beam. The recorded information is read.

At this time, the intensity of the reproduction beam that scans each recording track (11), (11), etc. is much smaller than the intensity of the recording beam described above, and the reproduction beam is used to scan the optical tape (T ) is set to such an extent that even if the recording layer (1, 02) of the tape is irradiated, the irradiated portion of the tape will not be erased. Information is read by receiving a reflected beam from the optical tape (T) with a sensor (10) and converting the level change of the reflected beam into an electrical signal. On this occasion,
Since the intensity of the reflected beam is binary modulated by the holes (bits) on the recording trunk (11), the electrical signal is
It becomes a bit signal with a value.

Now, in the experiment, a monotonous bit string was recorded on the optical tape of the experimental example and the comparative example using such a recording/reproducing apparatus with a bit pitch of 2 μm and a laser power of 1.0 mw, and then recorded in this manner. The information was read using a laser beam with a laser power of 0.5 mw, and the pit error rate generated at that time was measured.

Table 1 is a table showing the results of such an experiment. Optical tape (T
) In a comparative example in which no carbon film was formed on the base film surface, the pit error rate was 10-' to 10-t.
That is, bit errors were detected at a rate of 1 bit in 10 bits to 1 bit in 100 bits. In contrast, in an example in which a carbon film was formed on the surface of the base film of the optical tape (T), the bit error rate was io
-' to 10-4, and bit errors were detected at a rate of 1 bit in 1000 bits to 1 bit in 10000 bits. As is clear from these experimental results, it is found that forming a carbon film on the surface of the base film of the optical tape (T) can significantly reduce the rate of bit errors that occur during recording and reproduction. One of the reasons for this effect is that static electricity generated on the surface of the base film (1) is transferred from the carbon film to the rotating drum (1),
It is thought that the dust was grounded and removed via the motor (6) and the chassis inside the player, thereby preventing dust from adhering to the base film due to charging.

In addition, when the base film is formed of PET material, which is an organic polymer, when the base film comes into sliding contact with the rotating drum (1), static electricity is very likely to be generated due to friction. On the other hand, if a carbon film is formed on the surface of the base film, the inorganic carbon film will come into sliding contact with the rotating drum (1), which will generate more static electricity than when the organic base film itself comes into sliding contact with the rotating drum (1). is less likely to occur. Therefore, the possibility that the optical tape (T) will be charged during recording and reproduction is reduced, and in this respect as well, dust is less likely to adhere to the optical tape. Furthermore, when a carbon film is formed by vacuum deposition, it has self-lubricating properties, so when a carbon film is formed on a base film, it has the effect of smoothing the sliding contact between the base film and the rotating drum. It can be played.

FIG. 3 shows an apparatus in which the recording/reproducing apparatus used for measuring the pit error rate has been slightly modified. That is, in such a device, a conical transparent material (12
) is embedded, and the apex of this transparent material (12) protrudes outward from the outer peripheral surface of the rotating drum (1). still,
In such a device, the apex of the transparent material (12) is rounded to prevent the transparent material (12) from damaging the optical tape when it slides into contact with the optical tape during recording and reproduction. There is. In such a device, as shown in FIGS. 3 and 5, the recording/reproducing beam focused by the objective lens (4) is focused slightly further away than the apex of the transparent material (12). The positions of the objective lens (4) and the transparent material (12) have been adjusted.

During recording and reproduction, the transparent material (12) comes into sliding contact with the optical tape (T) while bending the optical tape (T), so that the objective lens (
4) and the distance between the optical tape (T) is always constant. As mentioned above, the focus of the beam is set slightly farther from the apex of the transparent material (12), so the optical tape (T)
12), the beam focuses on the optical tape (
T) is set in the recording layer (102). Therefore, the recording/reproducing beam is always focused on the recording layer (102) of the optical tape (T) without performing focus control of the objective lens (4).

In this type of recording/reproducing device, the objective lens (4)
This has the effect of eliminating the need for a focus servo device, but in addition, since the sliding contact distance of the transparent material (12) with respect to the optical tape (T) is high, the transparent material (12) Dust and the like attached thereto are scattered, and as a result, the pit error rate in the measurement described above can be reduced. Table 2 shows the measurement results of the pit error rate using such a recording/reproducing apparatus. As is clear from the measurement results, it can be seen that the pit error rate is improved in both the example and the comparative example compared to the measurement results in Table 1, but especially in the case of the example, the pit error rate is significantly improved. Improvement was observed.

In this example, a carbon film was used as the antistatic thin film, but since such a carbon film has self-lubricating properties as described above and also has the effect of a protective film, the second
When using an optical tape in a recording/reproducing device in which a rotating drum (1) and an optical tape (T) come into contact as shown in Figures 3 and 3, tape running properties are good, and the base film is scratched. It can also have the effect of preventing the entry of

Further, although vacuum evaporation using an electron beam is used as the method for forming the carbon film, other manufacturing methods such as the CDV method or the sputtering method may also be used.

Further, the grounding thin film is not limited to the carbon film described above, and other conductive materials such as copper and aluminum can also be used. However, as mentioned above, the carbon film produced by vacuum evaporation has excellent lubricity and is characterized by very low resistivity, so even if the film is thin, it cannot sufficiently exhibit the static electricity removal effect of the present invention. , is suitable for the recording and reproducing apparatus shown above.

(G) Effects of the Invention According to the present invention, since an antistatic thin film is formed on the optical tape to prevent the optical tape from being charged, it is possible to prevent dust from adhering to the optical tape. Therefore, information can be recorded and reproduced on the optical tape in a good manner.

Furthermore, if the antistatic KM is made of a conductive thin film, the static electricity generated on the tape can be grounded through the rotating drum, internal chassis, etc., and thus the static electricity generated on the tape can be removed.

Furthermore, if the antistatic thin film is formed of an inorganic material, static electricity generated when the tape slides on the rotating drum can be suppressed.

In addition, if the antistatic thin film is a carbon thin film formed by vacuum evaporation, the sliding movement of the tape against the rotating drum can be made smooth, and since the resistivity is extremely low, the film thickness can be reduced. Also, a sufficiently large static electricity removal effect can be achieved.

[Brief explanation of the drawing]

FIG. 1 is a sectional view of an optical tape according to an embodiment of the present invention, FIGS. 2 and 3 are diagrams showing an example of an optical tape recording and reproducing device, and FIG. 4 is a diagram showing information on a tape by this recording and reproducing device. FIG. 5 is a side view of the main parts of the recording/reproducing apparatus shown in FIG. 3, and FIG. 6 is an example of an optical disk and an optical system used in the optical disk system. The side view, Tables 1 and 2 are diagrams showing the measurement results of the pit error rate, respectively. (T)...Optical tape, (101)...Base film, (102)...Carbon film (thin antistatic material. Table 1 Table 2 Figure 8 Figure 4 Figure 6

Claims (4)

[Claims] (1) An optical tape medium for recording and/or reproducing information using a light spot narrowed down by an optical system, characterized in that an antistatic thin film is formed on the surface of the tape. (2) The optical tape medium according to claim 1, wherein the antistatic thin film is a conductive thin film. (3) The optical tape medium according to claim 1, wherein the antistatic thin film is made of an inorganic material. (4) The optical tape medium according to claim 1, wherein the antistatic thin film is a carbon thin film formed by vacuum deposition.