NL8403689A - Memory unit with twin optical or magnetic disc drives - controls selection of disc to achieve shorter search time - Google Patents

Abstract

The unit (6) contains two identical recording discs (5,6) which may be magnetic or optical types. The axial tracking of the read heads (7,8) is controlled by a central unit (1) via a read control unit (2). The signal from the central unit is fed in real (3) and inverted (4) form to the tracking devices (7,8), in such a way that if the head on one disc is at a particular distance from the centre (9) of the disc, the other head will be at the same distance from the circumference of the other disc. If after reading data from an address inside the central zone (B) of one disc, the following address is within the same zone, data will be read from the same disc. If however the following address is in the outer zone (A), data will be read from the other disc.

Description

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Memory device containing an information carrier containing at least two complementary readable memories with identical information,

The invention relates to a memory device comprising an information carrier and a reading device, which information carrier contains at least two memories on which identical information is stored in track on substantially corresponding tracks of the memory surfaces, which reading device has a reading device for each memory with identical information as well as positioning means for separately positioning each memory and its reader on offered track addresses.

Such a memory device is known from an English translation of Japanese patent application no. 55-135955. The data carrier of the known memory device contains two memory disks which can rotate independently of each other on their respective spindle. Both memory disks contain identical information stored on corresponding track addresses. Each memory disk has its own reader for reading the information stored in the memory disk. When the memory device now performs a read operation on a offered memory address containing a track address and a sector address, the two readers are activated and moved to the offered track address. As soon as each of the readers individually arrive at the offered memory address, they each transmit an acknowledgment signal to a control unit. The reading device from which the acknowledgment signal has first been received obtains the order to carry out the reading operation. This reduces the access time to a specific address in the memory disk.

A drawback of the known memory device is that moving the two reading members each time costs extra energy and that if the reading operation only extends over a limited number of addresses, the two reading members will be in substantially the same place during a subsequent reading operation. Furthermore, it is necessary to provide the known memory device with means which, after receiving an acknowledgment signal, transmit the read command to the relevant reader. In addition, moving the two readers each time causes an additional load on the drive mechanism of each 840368®

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PHN 11.222 2 reader.

The object of the invention is to realize a memory device in which the access time to a offered track address of the memory is reduced without it being necessary to move all readers 5 simultaneously.

For this purpose, a memory device according to the invention is characterized in that the surface of each of the memories with identical information is subdivided into at least two subsurfaces and in which each reader is assigned an exclusive subsurface from its associated memory, and that the memory device has a selection unit which has an input for receiving at least one bit of a track address offered and wherein each reader is connected to the selection unit provided to select the sub-surface and the reader within which the track address 15 is located. Since, in a reading operation, each reading member now only covers its assigned sub-surface, the average distance traveled by a reading member has been considerably reduced, and thus also the access time. Selecting the partial area takes hardly any time (for example 1 gate time or only a few micro-instructions) and so the entire access operation to a offered track address can take considerably less time.

It is advantageous that said bit presented to the selection unit is the most significant bit of the track address. This allows a simple realization of the selection unit.

A preferred embodiment of a memory device according to the invention is characterized in that the memories are formed by optical or magnetic disks. With optical or magnetic memory disks, the seek time is relatively large, so that a decrease in the seek time obtained by applying the invention significantly reduces the access time required to read such a memory disk and thus a more efficient use of the memory device.

The invention will now be explained in more detail with reference to the drawing.

In this drawing: figure 1 shows a first embodiment of a memory device according to the invention; Figure 2 shows a simple embodiment of the selection unit 8403889

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ΡΗΝ 11,222 3 see; figure 3 shows a second exemplary embodiment of a memory device according to the invention; Figure 4 shows a flow chart illustrating an example of a processing program for selecting a reader; Figure 5 shows a graph illustrating the advantage offered by a memory device according to the invention.

The invention will be described by means of two embodiments. In both embodiments, the transformation medium is formed by two memory disks. It will be understood, however, that the invention is applicable to any memory device containing memories on which identical information is stored in track on substantially corresponding spears of the memory surfaces. Such memories are, for example, disc-shaped or drum-shaped t5 memories as well as slide-shaped (magneto-optical) memories.

Figure 1 shows a first exemplary embodiment of a memory device according to the invention. This memory device (G) contains a reading device and an information carrier which, in this exemplary embodiment, contains two memory disks 5 and 6. The memory disks are, for example, formed by two optical or magnetic disks on which the information is stored in a track-wise manner. The memory disks 5 and 6 contain identical information in corresponding memory locations, so-called shadow disks (shadow or mirrored disc). The use of shadow disks is known per se and is used, inter alia, for error tolerance. Because identical information is stored on two different disks, the chance that erroneous information is delivered by the memory device is considerably reduced. Memory disk 5 and 6, respectively, are mounted on spindle 9 and TO, respectively. Each of the spindles 9 and 10 forms part of a drive device (not shown in Figure 30). Thus, each disc is driven by its own drive device. This is important due to the fact that the information on both disks must be accessible independently of each other and because a failure on one memory disk should not affect the other.

The information stored in memory disk 5 and 6, respectively, is read by a reading member 7 and 8, respectively, which is connected to the reading device 2 via a connecting line 3 and 4, respectively.

The reading device 2 is connected to a central unit 1. The central

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fiv <T5 PHN 11.222 4 unit 1 is, for example, part of a data processing system whose memory device is a peripheral station. Among other things, the central unit sends read commands to the memory device in order to retrieve and further process information stored in the memory disks.

The reader 2 controls the readers 7 and 8 and includes a selection unit 20 for determining which of the readers reads the information from the memory disc. In order to significantly reduce the radial direction of the readers (seek time), the readers are moved in only a part of their respective memory disks in the radial direction. For example, in a reading operation, only the hatched sub-surface A of memory disk 5 is covered by reading member 7 and only the hatched sub-surface B of memory disk 6 is covered by reading member 8.

A read command issued by central unit 1 contains an address, usually composed of a track address and a sector address, for which information is to be read. When receiving such a read command, the reading device 2 examines whether the attached address is located in the sub-surface A or the sub-surface B of a memory disc 20. If the track address points to one of the tracks located in sub-surface A, reader 7 is activated, and if the track address relates to a track from sub-surface B, reader 8 is activated. Thus, each of the readers covers only a maximum of half the radius of the memory disk and the time to find a particular memory location is reduced. The partial surfaces A and B are mutually exclusive and together form the entire surface of the memory disk provided for storing information.

Suppose that the track address of a track from a memory disk is formed by a six-bit-wide address word and that the 30 tracks with track address between 000000 and 011111 are in section B of the memory disk and the tracks with track address 100000 to 111111 are in section A are located.

With such a division of the track addresses, the selection unit 20 is simple to design. Figure 2 shows such a simple embodiment of the selection unit 20, which is part of the reading device 2. The most significant address bit of the track address is applied to an input 23 of the selection unit. This input is connected to a first output 24 via a connection 22 and an inverter 21 to a second output 25 of the selection unit via 8403689 PHN 11.222. Connecting lines 3 and 4 are connected to the first and second outputs, respectively.

If now the most significant bit of the track address 5 equals "1", a "1" is output at the first output 24 of the selection unit, and thus the reading 7 covering part A via connection line 3 is activated. the most significant bit of the track address is "O", then, by means of inverter 21, this "O" is converted into a "1" and 10 is output at the second output 25. Thus, the reader 8 covering the portion B is activated.

Figure 3 shows a second exemplary embodiment of a memory device according to the invention. In this exemplary embodiment, the reading device is substantially entirely contained in the central unit 1. (Corresponding elements to those of figure 1 have the same reference numeral in figure 3.) The selection of one of the memory discs is now carried out by the central unit itself. This is done, for example, under the control of a dedicated processing program which is stored in a memory of the central unit and which is handled under the control of the central unit when addressing the memory device.

Figure 4 shows an example of such a processing program by means of a flow chart. The processing program is started (50) when the central unit addresses the memory device and performs a reading period. The track address of the information to be read is then retrieved (51). Again, it has been assumed that the track address is six bits wide and that the format between sections A and B is as described above. The central unit now examines (52) the value of the most significant track address bit (MSB). When this 30 is equal to 1 (MSB = 1) then reader 7 is activated (53) and when this MSB = 0 then reader 8 is activated. After activating one of the reader passages, the processing program is terminated (55).

It will be clear that the invention is not limited to the exemplary embodiments given in Figures 1 and 3. For example, the memory device may contain down to two memory disks containing all identical information at corresponding memory locations.

In case there are N (N ^ 2) such a memory disks, each 8403889 PHN 11.222 6 each of the N read heads 1 / N cover part of the surface of their respective memory disk.

If N = 2 ^ then the selection unit is easy to carry out, since the selection is then made on the basis of the p most significant 5 bits of the track address.

Figure 4 illustrates the advantage of the invention by means of a graph. The percentage of read operations from the total number of access operations in the memory disk is shown along the apse (x direction) and the average number of 10 tracks traversed along the ordinate (y direction) during a radial movement of a read (write) organ over the memory disc. 0% reading equates to 100% writing.

The horizontal line C represents the graph when using a memory device with only one memory disk. Line D represents the graph using two memory disks with identical information. It follows from graph D that already when the operations with the memory device consist of 60% read operations, the average number of tracks traversed during a radial movement of the reader across the disk decreases when using two memory disks relative to only one disk.

20 This trend continues as a larger percentage of operations are reading operations. In the event that the memory device would only serve as a dead memory (100% read) then only half of the number of tracks is traversed by a radial movement of the read head when using two disks in a memory device according to the invention in proportion to use only a single memory disk. As a result, the seek time is reduced by half when reading only.

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Claims (4)

Memory device comprising an information carrier and a reading device, which information carrier contains at least two memories on which identical information is stored in track-wise on substantially corresponding tracks of the memory surfaces, which reading device 5 contains a reading member for each memory with identical information, and also contains positioning means for positioning each memory and its reader separately on worshiped track addresses, characterized in that the surface of each of the memories with identical information is divided into at least two subsurfaces and each reader is assigned an exclusive subsurface from its associated memory, and in that the memory device includes a selection unit which has an input for receiving at least one bit of an offered track address and each reader is connected to the selection unit provided for selecting the sub-area and the le the organ within which the railway address is located. Memory device according to claim 1, wherein the data carrier contains two memories, characterized in that said bit presented to the selection unit is the most significant bit of the track address. Memory device according to claim 1 or 2, characterized in that the memories are formed by optical or magnetic disks. 4. Read device to be used in a memory device according to claim 1 or 2