JPH03505942A - electromechanical data storage device - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed description of the invention] electromechanical data storage device The present invention is an electromechanical data storage device! , depending on the respective driving device. a first memory unit and a second memory unit having an adjustable storage medium; It is equipped with a drive control device and a writing/reading device assigned to the storage medium, in which case , relating to the type of memo placed in the frame of each memo.

From European Patent Application No. 69 545 (EP-A-69545) Data storage devices of the above-mentioned type that are already known are functionally separate and closed themselves. It has two memory units. One memory unit is a hard disk drive. The other memory unit is the frame of the hard disk drive mechanism. This is a cassette tape drive mechanism that can be completely inserted into the system.

Both memory units can be functionally coupled to each other via suitable interfaces. be. However, these two memory units are each sterically and functionally complete. It is constructed as an independent unit and can also be produced separately from each other. The space requirements for both units are still quite large. The functional characteristics of these memory units that must be This is equivalent to two arbitrary storage media that can be connected to each other at the same interface.

A more advanced straw structure in two memory units has been published in a European patent application. Data storage device disclosed in EP-A-201761 This is realized by This known example also has a Yabari hard disk drive mechanism. The tape drive mechanism is unitized, and in this example, the tape drive mechanism The write/read drum used for the magnetic tape in the structure is the chassis of the hard disk drive mechanism. It is placed on the floor. In this case, a device that functionally connects both memory units is required. A memory unit is provided that allows the connection from one memory unit to the other memory unit. It is made possible to transmit data to the unit. According to this embodiment For example, a memory unit device having a three-dimensionally dense and compact arrangement can be obtained.

However, a functional flaw in this implementation is that each memory unit is narrowly spaced from each other. The problem is that it cannot be activated at any time. Therefore, the memory unit The possibilities of application and thus the performance of the data storage device as a whole are severely limited. become.

The object of the present invention is to improve the data storage device of the type mentioned at the beginning. Make sure that the height of the device does not exceed the value of 41.3 - (so-called half size). In that case, the point is that the performance of the data storage device is not limited.

According to measure 1 of the present invention proposed to solve this problem, two memory units are placed on both sides of the base plate in the frame common to both! and less At least the electronic control circuit parts are located on a common printed circuit board. Ru. According to this configuration, a common base plate connects one memory unit to another. The hollow space in one memory unit is used to accommodate the components of the other memory unit. This makes it possible to create extremely compact data storage devices. It shows that it is possible. Therefore, in the present invention, one hard disk drive The live mechanism and, for example, one cassette drive mechanism are placed at a height of 41.3 cm, so-called – a single hard disk drive mechanism. It can fit into an insertion section of a size that can only accommodate a small amount of tissue. Skein Instead of a separate tape drive mechanism, it is possible to freely exchange storage media each time. A replaceable disk drive mechanism (floppy disk drive mechanism), or It is also possible to use a device that stores data optically.

Both memory units are placed in a narrow three-dimensional space, and both memory units are Reuniting electronic circuitry on a common printed circuit board Therefore, it is possible to make these memory units functionally closely related to each other in a particularly simple manner. This will require that both memory units be connected internally. are connected to each other by a bus, and at the same time are connected to an interface common to both. through which the data storage device connects to the data processing device. one common flow control device for both memory units. In this case, data transmission via the internal bus and both memory units are access to an intermediate memory device located between the internal bus and the flow control device. can be controlled by a bus controller with

The main advantage of this measure is that each memory unit can be Each memory unit can be accessed individually via an internal bus. It is also possible to exchange data between There is no need to transmit data over the . In this case, the bus controller and By using a flow control device common to both memory units, between the interface and individual memory units, between memory units, and between provided for data transmission between the interface and the bus controller This allows you to use your time most effectively.

The difference between the internal bus and the interface is to disconnect the interface from the internal bus. It is advantageous to have 10 bus-to-column units in place. bus-protoco For example, the role of the rule unit is to first handle all instructions coming from the interface. After complete modification and setup, the commands can be bus-controlled via the internal bus. wave! This allows the internal bus to perform internal data transmission. The goal is to maintain a free state for as long as possible. As an interface, For example, it is possible to use a 5CSI-interface.

It is advantageous if a write/read memory is connected to the internal bus, which write/read The memory is capable of storing data that is continuously output from the memory unit or written to the memory unit. It is used for intermediate memory of the data to be processed. Such measures have been taken data transmission from one memory unit to the other memory unit. It becomes possible to implement it without any problems.

The hard disk drive mechanism is primarily background-based due to its short access time. Each memory unit is used as a ground memory, whereas each other memory unit is Securing the data of the hard disk drive mechanism via the memory carrier or is used to transfer data records and programs to a hard disk drive mechanism. Both memory units can be used via the internal bus. A functional connection is achieved reliably with extremely short transmission times and eliminates computer bus clutter. I won't let you down.

The present invention will now be described in detail with reference to the embodiments shown in the accompanying drawings.

FIG. 1 is a system configuration diagram of a data storage device according to the present invention, and section 2 is a diagram of the first embodiment of the present invention. 3 is a cross-sectional view of the data storage device according to the invention taken along the line ■-■ in FIG. 3; 3 is a plan view of the device shown in FIG. 2 as seen in the direction of arrow A, and FIG. 4 is a plan view of the device shown in FIG. 5 to 7 are plan views of the device viewed in the direction of arrow B, and FIGS. Figures illustrating the second embodiment of the device in the same manner as Figures 2 to 1, respectively; 8 to 10 show a third embodiment of a data storage device according to the present invention, respectively. The diagram shown similarly to In Figure 1, two memory units are each represented by a rectangular block (not drawn with a dashed line). 10 and 12. One of them, memory unit 1o, is For example, the other memory unit 12 is a hard disk drive mechanism, and the other memory unit 12 is, for example, a hard disk drive mechanism. A disk or diskette replaceable drive mechanism (floppy disk drive mechanism) ), a tape drive mechanism or an optical storage device, This point will be discussed in more detail below in connection with Figures 2 to 10. The ports 10.12 are connected to each other via an internal bus 14 and, for example, Nearby bus via interface 15, which can be configured as a C8I-bus. It is also connected to the bus 16. In this case, the connection between the internal bus 14 and the peripheral bus 16 is , to automatically receive commands using auxiliary parameters and store them in intermediate memory. This is done via a bus-protocol unit 18 that can The bus 14 is isolated from the peripheral bus 16 by a bus protocol unit 18. ing. Data transmission via the internal bus 14 is carried out by a bus controller with an intermediate memory function. 20 (buffer controller). The bus controller is a processor connected to a microprocessor 24 via a bus 22; Processor 24 is required to provide overall flow control of the data storage device. It is. Microprocessor 24 has a small internal write/read memory and is Instructions from a read-only memory 26 are received via a processor bus 22. Processor bar By keeping bus 22 separate from internal bus 14, this operation can be performed simultaneously. It is possible to implement it by means of the internal bus 14 independently of the data transmission.

Each memory unit 10.12 has one formatting device 28 to 12. 30 are provided, and these formatting devices communicate with the internal bus 14. The data format on the internal bus 14 is changed to the storage medium. used to convert data formats to and vice versa. data to or from the data channels 32 to 34 in each case. can be received. Each data channel 32-34 each encodes data. encode or decode the NRZ-format (non-return-to-zero) and write on the storage medium. 6 data channels 32 and 34 for switching between The writing/reading devices 36 to 38 write the encoded data to the respective storage medium. reading from a storage medium, in which case the storage medium is connected to its respective control unit. The movement is imparted by a mechanism having positions 40 to 42, and the control device itself The command t! is transmitted from the microprocessor 24. Receive via 44.46 , received from the microprocessor 24 via transmission lines 44 and 46, and Sends a status message to the processor 24.

When an instruction from peripheral bus 16 begins to arrive, this instruction is The data is temporarily stored in the bus protocol unit 18 as an intermediate memory. this middle During storage operations, internal bus 14 and microprocessor 24 perform other tasks. He has been released to take over the job. When the command has completely arrived, this Process commands and, if necessary, commands for mechanism control waves W4o and 42. 0 peripheral bus 16 prompted by microprocessor 24 to send the code. This peripheral bus 16 is used for data storage while remaining open for as long as possible. In order to be as undisturbed as possible by the internal processes of the device, When writing information to a storage medium, first the write/reader connected to the internal bus 14 The memory 48 is filled and then each storage medium is written from its write/read memory 48. be included. In the opposite case, the data read from the storage medium is written/read first. is filed in memory 48 and then bus-protocol-unified at maximum speed. The data is transferred to peripheral bus 16 via bit 18.

If access is skillfully organized by the bus controller 20, new The incoming instructions are routed from the bus-protocol unit 18 into the microprocessor 24. At the same time, almost simultaneously, data is transmitted into the write/read memory 48. Alternatively, data transmission from the write/read memory 48 is formatted by the formatting device 1F2. It is even possible to have either one of 8 and 30 do it.

Data paths 18.14.20 and 4 common to both memory units 10 and 12 The structure of the hard disk drive mechanism according to the type is known per se and therefore Therefore, the explanation will be limited to a general one. diskette supplement Original copy and translation) Article 184-8 of the Patent Law submitted on May 28, 1991 Commissioner of the Patent Office Wataru Fukasawa 1. Display of patent application PCT/EP89100601 , name of invention electromechanical data storage device 3. Patent applicant Address: Day-4790 Paderborn Fuyuastenale, Federal Republic of Germany 7 Name: Siemens Nixdorf Informazionessteme ・Akchen Gesellschaft 4, agent Postal code 105 1-6-7 Atago, Minato-ku, Tokyo 5. Date of submission of written amendment May 14, 1990 6. List of attached documents Copy and translation of amendment) 1 copy (1) Claim 1 Correct as shown below.

1. an electromechanical data storage device, each comprising one storage medium and one storage medium; assigned to the drive device, drive control device (40, 42) and storage medium to adjust the a first and a second memory unit (having a write/read device (36, 38); 10, 12), in which case one side of the memory unit is a sealed hard Disk drive mechanism, separate memory units that can be driven independently of each other (10, 12) are arranged in a common frame, each frame is Mori unit (50, 52; 50, 88; 50° 100) was common to this Both memory units are arranged on both sides of the base plate 52 in the frame. (50,52; 50.88; 50.100) at least electronic It is noted that the parts of the control circuit are located on a common printed circuit board 84. Data storage device with characteristics.

Corrected translation) Copy and translation of amendment) Submitted Article 184-7, Paragraph 1 of the Patent Act) May 2, 1991 8th day Toshi Ueki, Commissioner of the Patent Office 1. Display of patent application PCT/EP8910O601 , name of invention electromechanical data storage device 3. Patent applicant Address: Day-4790 Paderborn Fuyuastenale, Federal Republic of Germany 7 Name: Siemens Nixdorf Informazionessteme ・Akchen Gesellschaft 4. Agent Postal code 105 1-6-7 Atago, Minato-ku, Tokyo Atagoyama Attorney Building (14) and data transmission to both memory units (10, 12). ) Claim 1 is amended as follows.

1. t% mechanical data storage! each with one storage medium and this record. a drive device for adjusting the storage medium, a drive control device (40, 42) and a storage medium; a first and a second memory unit (10, 12), in which case one side of the memory unit 7 is a sealed hard disk. There are 81 memory units (10, 12) on a common frame. Each memory unit (50, 52; 5( 1,88; 50.1oo) Ka,:? LG: Common 1j: 7 frames 4 units Located on both sides of the base plate (52), both memory units (50°52 ;50.88;50. +00) at least the electronic control circuit characterized in that the parts are arranged on a common printed circuit board (84) data storage device.

(2) Claims 2 to 4 shall remain as they are without amendment.

2. The data storage device according to claim 1, wherein the second memory unit comprises a magnetic tape. A data storage device characterized in that it is a double-flop storage device (52).

3.i*Data storage device according to claim 1! with the second memory unit connected to the disk A data storage device characterized in that it is a replaceable drive mechanism (88).

4. The data storage device according to claim 1, wherein the second memory unit comprises an optical It has a storage medium (106) and an optical writing/reading device (+08,110 ) through which data can be transferred to or retrieved from a storage medium. A data storage device characterized by:

(3) Claims 5 to 7 are newly added.

5. The data storage device according to any one of claims 1 to 4, (to, 12>) to each other and to the data storage device by an internal bus (14). A common interface for both memory units that can be connected to a data processing device. (15), and common to both memory units (10°12). flow control bag! (24) is assigned, and in this case, internal bar access is Bus control device (20) arranged between the bus (14) and flow control bag W (24) A data storage device characterized in that it can be recovered by.

6. The data storage device according to claim 5, wherein the internal bus (14) and the interface bus (15) which isolates the interface from the internal bus (14). A data storage device, characterized in that a protocol-unit (18) is arranged.

7. The data storage device according to claim 5 or 6, wherein one of the memory units ( 10, 12) or one memory unit (12°10) A write/read memory (48 ) is connected to an internal bus (14).

international search report 1----Tsumugiichi---・PCT/εp 89100601 International Search Report SA 29200

Claims (4)

[Claims] 1. Electromechanical data storage device, each adjustable by a drive First and second memory units (10, 12) having storage media and a drive control device. and a writing/reading device (36, 38) assigned to the storage medium. In this case, each memory unit (10, 12) is arranged in a common frame. In the type in which each memory unit (50, 52; 50, 88 ;50,100) of the base array (52) in the common frame. Both memory units (40, 42: 50, 88; 50, 10 At least parts of the electronic control circuit in 0) are on a common board (84). A data storage device characterized in that: 2. 2. The data storage device of claim 1, wherein the second memory unit comprises a magnetic tape. A data storage device characterized in that it is a double-flop storage device (52). 3. 2. The data storage device of claim 1, wherein the second memory unit is a disk. A data storage device characterized in that it is a replaceable drive mechanism (88). 4. 2. The data storage device of claim 1, wherein the second memory unit comprises an optical It has a storage medium (106) and an optical writing/reading device (108, 110). It is possible to transfer data to or retrieve data from a storage medium via A data storage device characterized by: