JPS62120644A - Optical memory substrate - Google Patents

Abstract

PURPOSE:To enlarge a reproducing signal of address information and to stabilize a control signal even near a border between a guide track part and an address part by providing marks constituting address information with the same physical shape in respective guide tracks. CONSTITUTION:In the address part 3 for reproducing address information, the mark parts 3b... are formed not like pits, but like flat parts and grooves 3c... having the same width and depth as that of the guide tracks 2a are formed between respective mark parts 3b.... Thereby, the physical shape of the groove 3c between respective mark parts 3b coincides with the physical shape (interval or the like) of respective guide tracks 2a. The length of respective grooves 3c is determined in accordance with the address data. The interval between respective flat parts 3b is detected by a reproducing circuit to demodulate the detected signal.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a formatting method for an optical memory board for an optical storage device that records, reproduces, or erases information by irradiating a storage medium with laser light.

(Prior Art) Optical memory devices are attracting attention as high-density, large-capacity memory devices. The reason why this optical memory has a high density and a large capacity is that the size of a bit, which is a unit of recording information, can be narrowed down to about 1 μmφ with relative ease.

However, this requires many strict conditions for the optical memory device. For example, in order to record information at a fixed location or to reproduce information recorded at a fixed location, the light beam must be positioned very precisely.

In an optical memory for recording, reproducing, or erasing information, which is the object of the present invention, in order to position a light beam at a desired location, the optical memory board 1 generally includes, as shown in FIG. 5(a), for example. Track 2 for guiding the light beam in advance
a s 2 a l . . . and pins) 3 a, 3 a, . . . indicating address information are formed according to a predetermined format.

As shown in FIGS. 4 and 5(a), the guide track portion 2 and the address portion 3 have a general shape with a depth of λ/8n (n: refractive index of the substrate material, λ). :Laser light wavelength) front and rear continuous grooves 2a.

2a, . . . and the address section 3 is constructed as a row of pins 3a, 3a, . . . having the same depth.

(Problems to be Solved by the Invention) In order to stably scan the guide track portion 2 and the address portion 3 with the light beam as described above, seven focusing control and tracking control are normally performed. The control signals used for both controls are normally the guide tracks 2a, 2a, . . .
Detection is performed using an information beam subjected to a diffraction effect by the address bits 3a, 3a, . . . .

However, since the guide track section 2 and the address area 3 necessarily have different diffraction patterns and diffraction efficiencies on the control signal detector, the control signal is disturbed to some extent. In particular, if a steady offset occurs in the control signal due to either optical or circuit factors, fluctuations at the boundary between the guide track section 2 and the address section 3 will become large, and control may become unstable. arise. For this reason, it takes time for the servo state to settle into a steady state, which may cause problems in reproducing address information and the data head area immediately after the address.

tIS5 (b) shows the guide track unit 2 when the tracking control signal is obtained by the known push-pull method.
An example of a control signal obtained when the light beam 4 traverses the address section 3 formed in the conventional format as shown by the arrow in FIG. 3(a) is shown. When moving from the guide track section 2 to the address section 3, the control signal is disturbed.

In the address area 3, the sensitivity of the control signal is greatly reduced compared to the guide track section 2 because there are few areas that are subject to the diffraction effect by the pins 3a, 3a, . . . . Furthermore, if the mark length in the address area 3 is approximately the same as the reproduction beam diameter, even if the light beam 4 scans over the marker 23a, it will be subject to diffraction effects from both sides of the mark and diffraction effects from the front and back of the mark. The diffraction pattern itself is also different from that of the guide track section 2, and it is expected that the sensitivity will further decrease.

The purpose of the present invention is to stably obtain a light beam control signal for the optical memory as described above, and by slightly changing the formatting method of the optical memory board, discontinuous guide tracks and address areas can be eliminated. The purpose is to reduce the influence of the control signal when it exists.

(Means for Solving the Problems) An optical memory board according to the present invention is an optical memory board having a format including a guide track and marks constituting address information, and is configured such that address information is reproduced by mark intervals. , the space between the marks is formed to have the same physical shape as each guide track.

(Function) Since the marks constituting the address information are formed so as to have the same physical shape between the marks and between the guide tracks, the reproduction signal of the address information is weakened and the guide track portion and The control signal is stabilized even near the boundary with the address part.

(Example) Hereinafter, an example of an optical memory board according to the present invention will be described in detail using the drawings.

FIGS. 1(a) and 1(b) are a plan view and a sectional view taken along line A-A of an optical memory board having a format based on the present invention. Here, the guide track portion 2 is a guide track 2a which is a group (groove) as in the conventional case.

Consists of 2a+... On the other hand, in the address section 3 for reproducing address information, the mark sections 3b, 3b, . A group (groove) 3c having the same width and depth as the guide track 2a between...
, 3c, ... are formed. Therefore, the physical shape of the group 3c between each mark portion 3b, 31), . . . is the same as the physical shape (interval, etc.) of each guide track 2a, 2a, . The length of each group 3c is determined corresponding to address data (conventional bit interval).

The spacing between the flat portions 3b, 3b, . . . is determined by detecting and demodulating the spacing using the reproducing circuit shown in FIG. The reproduced signal 11 is first differentiated by a differentiating circuit 12. Next, the zero cross detection circuit 13 generates a signal that changes from a high level to a low level when the differential signal crosses zero in a negative progression. Ikegata, the reproduced signal 11 is the level slice circuit 1.
Shape the waveform in step 4. AND date 15 is the output signal of zero cross detection circuit 13 and level slice circuit 14
is ANDed with the output signal of the reproduced signal 10 to obtain a pulse signal that progresses negatively at the peak of the reproduced signal 10. The demodulation circuit 16 uses the negative progression of this pulse signal to obtain the interval between the mark portions.

When the light beam 4 crosses the above optical memory board along the path shown in Figure 3 (,), the tracking control signal shown in Figure 3 (b) is obtained under the same reproduction conditions as in Figure 5 (b). It will be done. Compared to the conventional format, there are more group areas in the address area 3 that have the same properties as the guide track 2a, and as a result, the decrease in sensitivity of the track control signal is reduced. As a result, the guide track 7 area 2 and the address area 3
The influence of optical and circuit offsets on the control signal is reduced even near the boundary with the control signal, and the stability of tracking control is increased.

The degree of this improvement is determined by the DSV (Digital Sum Val
In other words, this is particularly effective when the DC component is large, and it is possible to suppress the amount of variation not only in the above-mentioned tracking control signal but also in the focus control signal and the change in reflectance in the address section.

(Effects of the Invention) According to the present invention, it is possible to make the servo control signal more stable by only slightly changing the format signal when forming the format on the optical memory board. Thereby, a highly reliable information recording and reproducing system can be provided.

[Brief explanation of drawings]

FIGS. 1(a) and 1(b) are a plan view and a cross-sectional view taken along line A-A of an optical memory board according to the present invention, respectively. FIG. 2 is a diagram of a reproducing circuit for reproducing address information from an optical memory board according to the present invention. FIGS. 3(a) and 3(b) are diagrams showing the relationship between the optical memory board and the tracking control signal according to the present invention. FIG. 4 is a partial perspective view of the optical memory board. FIGS. 5(a) and 5(b) are diagrams showing the relationship between the positional relationship between the reproduction light beam and the conventional optical memory board and the tracking control signal. DESCRIPTION OF SYMBOLS 1... Board, 2... Guide track part, 2a, 2a... Guide track, 3... Address part, 3b, 3b,... Mark part, 3c+3c+... group. Patent Applicant: Sharp Co., Ltd. Agent Patent Attorney: 2 people mentioned above 10th Figure 2 - Kazuyaichi Rin 3rd = 4th F! 1 Figure 5(b)

Claims (2)

[Claims] (1) In an optical memory board having a format including guide tracks and marks constituting address information, the address information is configured to be reproduced by mark intervals, and the spaces between the marks have the same physical shape as each guide track. An optical memory substrate characterized in that it is formed so as to be held. (2) The optical memory board according to claim 1, wherein a groove is provided between the guide track and the mark representing address information, and the mark portion is a flat portion.