JPH08161862A - Magnetic storage device - Google Patents

Abstract

PURPOSE: To obtain the device to be portable with good handleability and extensibility and high reliability by portably constituting an information storage part including a magnetic disk, its rotation drive part and an actuator, etc., and a circuit part including their control circuits and circuit boards, etc., in separated bodies. CONSTITUTION: A magnetic disk device consists of an information recording part and a circuit part constituted in a case having 3.3mm thickness, 54mm width and 106.8mm length. The storage part and the circuit part are both independently portable respectively, each have their connectors corresponding to PCMCIA, and one sheet of disk can be inserted to a PCMCIA type 1 slat, two sheets of disk to the type 2 and three sheets of disk to the type 3 at most. When a PDA is used as a computer main body, by inserting the information recording part and the circuit part into two PCMCIA type 1 slots provided in juxtaposition in a side of a PDA main body respectively, the magnetic disk device can be used as an external storage device of the PDA. Consequently, the thickness of the computer main body can be reduced to <=5mm.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a portable, compact and thin hard magnetic disk storage device, and more particularly to a magnetic storage device which complies with the PCMCIA standard.

[0002]

2. Description of the Related Art Conventionally, magnetic storage devices using hard disk media include magnetic heads, magnetic disks, spindles,
A circuit unit including an information storage unit including an actuator and the like, a controller for controlling the information storage unit, an LSI for demodulating a servo signal, an LSI for performing signal processing, a cache, an interface terminal, a circuit board, and the like. And are built in the same housing or integrated, and they cannot be used separately. It is considered that this conventional magnetic disk device has the following problems.

Since the circuit system and the mechanical system cannot be separated from each other, it is not possible to change the configuration of the circuit system according to the purpose of use or application, and to select an arbitrary recording capacity as necessary.

The thinning of the device has been realized by reducing the number of disks, reducing the thickness of the head slider, and thinning the actuator and the spindle motor, but the thickness of the LSI constituting the circuit system is limited, and the bare chip is used. Extreme thinning cannot be achieved without mounting. For example, a PCMCIA-type 3 card type memory device currently on the market has a floor projected area of 10.8 mm ×
It is 54 mm, which is the same as a credit card or the like, but the thickness is very thick, 10.5 mm, and the weight is about 60 g, which is inconvenient to carry.

Since the head / medium system and the circuit system are combined, it is difficult to reduce the cost of the device.

[0006] Recently, a magnetic storage device in which only a hard magnetic disk medium can be removed has been released from Psychst. However, this device has a problem that the risk of head crash is very high because dusts are more likely to adhere to the surface of the medium when the medium is replaced. Therefore, it is basically difficult to realize high density recording by narrowing the spacing between the head media.

On the other hand, an example in which an information storage unit composed of a head, a medium, and an R / W IC and a controller unit are independently used is also disclosed in, for example, Japanese Patent Laid-Open No. 5-210962. However, in this conventional example, since the controller is incorporated in the computer main body, it is impossible to replace it, change its function, or use it additionally.

[0008]

SUMMARY OF THE INVENTION An object of the present invention is to realize an ultra-thin portable magnetic disk device which is easy to use, has good expandability, and is extremely reliable and low in cost.

[0009]

The above problems are caused by an information storage unit, an interface terminal, and a magnetic head positioning in the information storage unit, each of which includes at least one head / medium, a spindle, an actuator, etc. The controller for controlling the recording / reproducing of the data, the LSI for demodulating the servo signal, the LSI for performing the signal processing, and the circuit unit including the circuit board are configured in separate casings according to the intended purpose and application. This is solved by configuring a magnetic storage device by combining an arbitrary circuit unit and a mechanical unit.

The first feature of the present invention is: (1) In a magnetic storage device, a magnetic head for performing a recording / reproducing operation, a magnetic disk for storing information, a rotary drive unit for the magnetic disk, and a desired magnetic head on the magnetic disk. An information storage unit that has at least an actuator for moving on a radius of
A circuit for controlling the positioning of the magnetic head in the information storage unit, a controller for controlling recording / reproducing of information,
LSI for demodulating servo signals, L for signal processing
The SI and the circuit unit including at least one of the circuit boards are configured in separate housings, and the magnetic storage device can be carried independently.

In the above (1), the following (2)-
It is preferable to do (11). (2) The information storage unit and the circuit unit are connected by a connector attached outside the magnetic storage device.

(3) The information storage section and the circuit section are connected by a connector attached to the mechanism section or the circuit section.

(4) The case forming the circuit section drives at least one case forming the information storage section.

(5) The case forming the information storage section is driven by at least one case forming the circuit section.

(6) A cache memory is built in the case forming the information storage unit.

(7) A cache memory is built in a case forming the circuit section.

(8) It is possible to use the IC memory as a cache.

(9) The circuit section has a function other than magnetic storage.

(10) Having the above (9), the circuit section has a communication function.

(11) In addition to the above (9), the circuit section has a function of compressing and expanding the stored information.

The second feature of the present invention is that, in the above (1) to (11), (12) the dimensions of the housing constituting the information storage section and the circuit section are 5 mm or less in thickness and 54 mm or less in width, respectively. , A magnetic storage device having a length of 85.6 mm or less.

A third feature of the present invention is that, in the above (1) to (12), (13) the information storage unit constituting the magnetic storage device includes at least one magnetic disk and at least one actuator. There is at least one magnetic head and at least one R / W IC in a magnetic storage device.

A fourth feature of the present invention is that, in the above (1) to (12), (14) at least two spindles, at least two magnetic disks, and, in the information storage section constituting the magnetic storage device, The magnetic storage device has at least two actuators and can perform parallel transfer of data by at least two magnetic disks.

A fifth feature of the present invention is that, in the above (1) to (12), either (15) the circuit section or the information storage section constituting the magnetic storage device is a PCMC.
In a magnetic storage device having an IA interface.

A sixth feature of the present invention is that, in the above (1) to (12), (16) the information storage section and the circuit section constituting the magnetic storage device are recorded / reproduced even when an impact of 200 G or more is applied. It is in a magnetic storage device that does not cause an obstacle in its operation.

A seventh feature of the present invention is that, in the above (1) to (16), (17) the connector for inserting the circuit section is not shared with the connector for inserting the information storage section, and the information storage section and the circuit are not shared. There is at least a structural difference in the parts, and it is in a magnetic storage device in which it is impossible to erroneously connect the circuit part connector to the information storage part connector.

An eighth feature of the present invention is that, in the above (1) to (16), (18) the connector for inserting the circuit section is also used as the connector for inserting the information storing section, and The magnetic memory device has no structural difference in the connector for the circuit unit.

A ninth feature of the present invention is that, in the above (1) to (16), (19) the information storage section also has 68 pins having the same dimensions as the PCMCIA connector like the circuit section. , A magnetic storage device that uses pins that are not used in the circuit section to connect to the mechanism section.

A tenth feature of the present invention is the magnetic storage device according to any one of (1) to (16), in which (20) the size of the case forming the information storage unit is different from that of the case forming the circuit unit. It is in.

An eleventh feature of the present invention is that, in the above (1) to (16), (21) at least an LSI provided in the housing forming the information storage unit or the housing forming the circuit unit. One is in a magnetic storage device using a flexible LSI.

[0031]

At present, the purpose and use of magnetic disk devices are very wide, and they are no longer used only as external storage devices of computers as before.

For example, it is assumed that the information storage unit composed of the head medium system realizes a storage capacity of 650 MB. By connecting this information storage unit to a cache having a capacity of 256 kB and a circuit unit having a PCMCIA interface, it can be used as an external storage device such as a workstation. Also, 65
An information storage unit having a storage capacity of 0 MB is used, for example, in EMP.
By combining with a circuit unit having a circuit system of EG1 standard, it becomes possible to use it as a memory for handling a moving image file of about 70 minutes. If the storage capacity is 80MB but the cache capacity is 120kB, use a circuit system with a large cache capacity.
This application can be satisfied by combining with a mechanism system of 80 MB which is composed of an inexpensive head medium system having a low realized recording density. Conversely, the storage capacity is 600MB
It has excellent expandability such that it can respond to a request such as a desired cache capacity of 32 kB, etc., by using an arbitrary combination of the information storage unit and the circuit unit.

If the information storage section and the circuit section are formed in separate housings, the information storage section and the circuit section are separated from each other, and, for example, carry only the information storage section in which confidential information is stored. It is also possible to use it by leaving the circuit part in the slot. In such a case, the information storage unit and the circuit unit are made thin, which is very convenient for carrying. PCMCIA type 2 (thickness 5.0
mm) compatible slot is provided, but here is a PC
MCIA type 1 (thickness 3.3 mm) information storage unit and F
By inserting the circuit section having the AX modem function at the same time, the usability can be significantly improved. Furthermore, since the head medium system is always stored in a closed space, high reliability can be ensured regardless of the usage environment. Further, since the information storage unit configured by the head medium and the like is stored in a housing different from the circuit unit, the temperature rise of the atmosphere surrounding the head medium due to the heat generation of the LSI can be suppressed low. As a result, a magnetically and mechanically stable magnetic memory device can be constructed.

[0034]

【Example】

(First Embodiment) A first embodiment of the present invention will be described with reference to FIGS. First, as shown in FIG. 1, the magnetic disk device according to the present invention has a thickness of 3.3 mm and a width of 54 m.
An information storage unit and a circuit unit, which are configured in a housing of m and a length of 106.8 mm. Both the information storage unit and the circuit unit can be carried independently, and both have PCMCIA compatible connectors.
One for A type 1 slot, or two for type 2
Up to 3 cards can be inserted into Type 3.

FIG. 2 shows a PDA as a computer main body.
(P ersonal D igital A sistan
It is a figure for demonstrating how to use the magnetic disk unit of this invention when t) is used. As shown in FIG.
By inserting the information storage unit and the circuit unit into two PCMCAI type 1 slots provided side by side on the DA body side, the magnetic disk device according to the present invention can be used as a PDA.
Can be used as an external storage device. FIG. 2
As shown in Figure 2, by installing two PCMCAI type 1 slots side by side, the thickness of the computer main body is 5 m.
It is possible to make it very thin as m or less.

The sectional structures of the information storage section and the circuit section are
This is as shown in FIGS. 3 (a) and 3 (b). First, one magnetic disk (1) having an outer diameter of 1.89 inches is contained in the information storage unit housing, and two magnetic heads (2) are provided so that the front surface and the back surface of the medium can be accessed. If only one side of the disk is accessed, only one head is needed.
The magnetic disk (1) has a thickness of approximately 0.386 mm, and the head slider (2) has a thickness of 0.3 mm. The cover (6) has a thickness of approximately 0.4 mm. In the information storage unit, an R / W IC (5) is mounted in addition to the head / medium, the spindle (3), and the actuator (4).
By mounting the R / W IC (5) in the vicinity of the head in this way, noise can be reduced and at the same time good high frequency characteristics can be maintained. In addition, R / W IC
When (5) is composed of a flexible LSI and mounted on the actuator (4), the high frequency characteristics can be further improved. Further, a connector (7) for PCMCIA is attached to the end of the circuit part, which is used for connection with the circuit part through a slot (8) incorporated in the computer main body. Only the terminals necessary for connecting to the circuit system are used.

On the other hand, the sectional structure of the circuit portion is as shown in FIG. Like the information storage unit, the circuit unit has a thickness of 3.3.
mm, width 54 mm, length 106.8 mm. This circuit part is the same as a normal disk device
It has a function of controlling the information storage unit, and includes an LSI for servo signal demodulation, an LSI for signal processing, a cache, and the like. The printed circuit board (9) has a thickness of approximately 0.4.
There are two layers of wiring in mm, and here is the signal processing LSI.
(10), servo signal detection LSI (11), head positioning control LSI (12), controller LSI (1
3), spindle and VCM drive LSI (1
4) etc. are attached. The thickness of the cover (15) of the circuit section is approximately 0.4 mm, as in the information storage section, and the thickness of the base (16) is also approximately 0.4 mm. A PCMCIA connector (17) is also used at the end of the circuit section, but this has the same function (68 pins) as a normal PCMCIA connector. However, since it is necessary to connect to the information storage section through the slot (8), the unused pins of the 68 pins are used for this. The circuit part and the mechanism part have a common ground. The information storage unit and the circuit unit can be used as a magnetic disk device by inserting them into the slots (8) attached to the computer main body, but as shown in FIG. The shape of the insertion part is different. Therefore, it is prevented that the circuit portion is mistakenly inserted into the slot for inserting the information storage portion. Also, when the disk device falls into the circuit, the disk becomes eccentric and the
The impact resistance can be improved to 200 G or more by adding the eccentricity follow-up servo function for preventing the failure.

During the recording / reproducing operation, the rotation speed of the disc (1) is set to 3200 rpm and the recording frequency is set to 16 MHz. The recording film used in the magnetic disk (1) is CoCrPt, the coercive force is 2800 Oe, and the product Br · t of the residual magnetization and the recording layer thickness is 75 G · μm.
On the other hand, the magnetic head (2) is a recording / reproducing separated type head using an inductive element for recording and a magnetoresistive effect element for reproducing.
An areal recording density of 2 Gb / in by combining this head medium
² has been realized, and the storage capacity of the information storage unit is 650 MB.
Is.

On the other hand, although the cache capacity of the circuit unit used in this embodiment is set to 256 kB, it is possible to use any cache capacity having an arbitrary capacity in consideration of device performance and cost. Further, in the present embodiment, it is premised that the magnetic disk device is positioned and used as an external storage device of a computer, but the information storage unit (storage capacity 650 MB) according to the present embodiment is, for example, MPEG1.
By combining with a circuit section having a standard data compression / decompression function, it becomes possible to use a moving image as an image file capable of handling about 70 minutes.

FIG. 4 is a diagram for explaining the outline of the circuit configuration of the magnetic disk device according to the present invention. In the present invention,
Since the information storage unit and the circuit unit are connected via the PCMCIA connector, signal exchange between them is converted into digital. Further, in this embodiment, 68 P
Of the CMCIA pins, 15 are used to connect the information storage unit and the circuit unit. PCMCIA slot No. 1 and No. 2 to use as a magnetic disk
ce ID is set to Hi and No. 1 and No. It is designed to connect two unused pins. On the other hand, Device
e When the ID is Low, No. 1 and No. 2 is Op
It becomes "en" and can be used as it is as a slot of PCMCIA. Also, A / D, D / A
Is not always necessary, and the information storage section and the circuit section can be exchanged with an analog signal.

(Second Embodiment) A second embodiment according to the present invention will be described with reference to FIG. Similar to the first embodiment, the outer dimensions of the information storage unit and the circuit unit according to this embodiment are 3.3 mm in thickness, 54 mm in width, and 106.8 in length, respectively.
mm. However, the outer diameter of 1.
It contains one 3-inch magnetic disk (18), and two magnetic heads (19) for accessing the front and back surfaces of the medium. Needless to say, only one side of the disc may be accessed. The magnetic disk (18) has a thickness of 0.386 mm and the head slider (1
The thickness of 9) is 0.3 mm. The cover (2
0) and base (21) each have a thickness of 0.4 m
m. In the information storage section, in addition to the head / medium and the actuator (22) as in the first embodiment, the R / W is used.
An IC (23) is mounted. A shock absorbing cover (24) is attached around the information storage unit. The cover (24) is elastically deformed when an impact is applied from the outside, and thus has a structure in which the impact is hard to be transmitted to the information storage unit including the head medium. As a result, this information storage unit is designed to withstand a shock of 1000 G. On the other hand, the circuit section has the same performance as that of the first embodiment. The circuit system is originally 1000 Gs
Designed to withstand the impact of.

During the recording / reproducing operation, the number of revolutions of the disk is set to 3200 rpm and the recording frequency is set to 8 MHz. The recording film used in the magnetic disk (18) is CoCrPt as in the first embodiment and has a coercive force of 2800.
The product Br · t of Oe, remanent magnetization and recording layer thickness is 75 G ·
μm. The magnetic head (19) is also a recording / reproducing separated type head using an inductive element for recording and a magnetoresistive effect element for reproducing, as in the first embodiment. An areal recording density of 2 Gb / in ² is achieved by combining this head medium,
The storage capacity of the mechanical unit is 325 MB.

(Third Embodiment) In this embodiment, an example will be described in which two 1.3-inch disks are used for the information storage section and data is transferred in parallel between the disks. FIG. 6 is a diagram for explaining a third embodiment according to the present invention. The external dimensions of the information storage unit are 3.3 in thickness.
mm, width 54 mm, and length 106.8 mm. Two magnetic disks each having an outer diameter of 1.3 inches are contained in the housing of the information storage unit, and four magnetic heads are provided so that the front surface and the back surface of each medium can be accessed.
The magnetic disk has a thickness of approximately 0.386 mm, and the head slider has a thickness of 0.3 mm. The cover has a thickness of 0.4 mm. One R / W IC is attached to each disc. The disk rotation speed during recording / reproducing operation is 3200 rpm, and the recording frequency is 8 MHz.
Is set to CoCr is used for the magnetic film of the magnetic disk.
Pt is used, the coercive force is 2800 Oe, and the product Br · t of the residual magnetization and the recording layer thickness is 75 G · μm.
On the other hand, the magnetic head element is a recording / reproducing separated type head using an inductive element for recording and a magnetoresistive effect element for reproducing. With this combination of head media, an areal recording density of 2 Gb / in ²
Has been realized. The storage capacity is 325 MB. The data transfer rate is 5 MB / s, which is twice as fast as the second embodiment. Further, this disk device can also be used as a disk device having a storage capacity of 650 MB and a transfer speed of 2.5 MB / s without performing parallel data transfer in combination with a circuit system. Further, in the information storage unit according to the present embodiment, the rotation speed is reduced to 1600 rpm,
It can also be combined with a low power consumption compatible circuit unit that records data at 4 MHz. The power consumption in this case is about 1 when the disk rotation speed is 3200 rpm.
/ 4.

(Fourth Embodiment) FIG. 7 shows a fourth embodiment according to the present invention. FIG. 7A shows a case where one circuit portion is inserted into the slot for PCMCIA type 3 and two information storage portions are inserted into the remaining portion to operate. in this case,
Depending on the selection of the circuit section, the storage capacity can be used as twice as large as that of one information storage section, or the transfer rate can be used as twice as large as that of one information storage section. Further, FIG. 7B shows a case in which one information storage unit and two circuit units are connected to the slot for PCMCIA type 3, but if such usage is used, for example, the cache capacity is increased and the performance is improved. It is also possible. The external dimensions of the information storage section and the circuit section shown in this embodiment are 3.3 mm in thickness and 54 m in width, respectively.
Although the length is m and the length is 106.8 mm, the outer dimensions of the information storage unit and the circuit unit do not necessarily have to be the same.

[0045]

As described above, according to the present invention, it is possible to realize an ultra-thin portable magnetic disk device which is easy to use, has good expandability, and is highly reliable and low in cost.

[0046]

[Brief description of drawings]

FIG. 1 is an information storage unit of a magnetic disk device according to the present invention,
FIG. 3 is an external view of a circuit unit.

FIG. 2 is an external view of a computer body, an information storage unit of a magnetic disk device according to the present invention, and a circuit unit.

FIG. 3 is a diagram showing a cross-sectional structure of an information storage unit and a circuit unit.

FIG. 4 is a circuit diagram of a magnetic disk device according to the present invention.

FIG. 5 is a configuration diagram of a magnetic disk device having an information storage unit using a magnetic disk having an outer diameter of 1.3 inches.

FIG. 6 is a configuration diagram of a magnetic disk device having an information storage unit using two magnetic disks having an outer diameter of 1.3 inches.

FIG. 7 is a device configuration diagram when a PCMCIA type 3 slot is used.

[Explanation of symbols]

1 ... magnetic disk, 2 ... magnetic head, 3 ... spindle,
4 ... Actuator, 5 ... R / W IC, 6 ... Cover,
7 ... Connector, 8 ... Slot, 9 ... Printed circuit board, 10
... signal processing LSI, 11 ... servo signal detecting LSI, 1
2 ... Head positioning control LSI, 13 ... Controller L
SI, 14 ... Spindle, VCM driver LSI, 1
5 ... Cover, 16 ... Base, 17 ... Connector, 18 ... Magnetic disk, 19 ... Magnetic head, 20 ... Cover, 21 ...
Base, 22 ... Actuator, 23 ... R / W IC,
24 ... Cover.

 ─────────────────────────────────────────────────── --- Continuation of the front page (72) Inventor Ryo Suzuki 1-280, Higashi Koikekubo, Kokubunji, Tokyo Metropolitan Research Laboratory, Hitachi, Ltd. (72) Takashi Yoshida, 502, Kintatemachi, Tsuchiura, Ibaraki Nitate Manufacturing Co., Ltd. Mechanical Research Laboratory (72) Inventor Hiroshi Nishida 2880 Kozu, Odawara-shi, Kanagawa Hitachi Storage Systems Division (72) Inventor Akira Saito 2880 Kozu, Odawara, Kanagawa Hitachi Storage Systems Division

Claims (21)

[Claims] 1. In a magnetic storage device, a magnetic head for performing a recording / reproducing operation, a magnetic disk for storing information, a rotary drive unit for the magnetic disk, and an actuator for moving the magnetic head to a desired radius on the magnetic disk. At least an information storage unit, a circuit for controlling positioning of the magnetic head in the information storage unit, a controller for controlling recording / reproducing of information, L for demodulating a servo signal
A magnetic storage device characterized in that an SI, an LSI for performing signal processing, and a circuit portion including at least one of circuit boards are configured in separate housings and can be carried independently of each other. 2. The magnetic storage device according to claim 1, wherein the information storage unit and the circuit unit are connected by a connector mounted outside the magnetic storage device. 3. The magnetic storage device according to claim 1, wherein the information storage unit and the circuit unit are connected by a connector attached to the mechanism unit or the circuit unit. 4. The magnetic storage device according to claim 1, wherein the case forming the circuit section drives at least one case forming the information storage section. 5. The magnetic storage device according to claim 1, wherein the housing forming the information storage unit is driven by at least one housing forming the circuit unit. 6. The magnetic storage device according to claim 1, wherein a cache memory is incorporated in a housing forming the information storage unit. 7. A magnetic storage device according to claim 1, wherein a cache memory is built in a case forming the circuit section. 8. The magnetic storage device according to claim 1, wherein the IC memory can be used as a cache. 9. The magnetic storage device according to claim 1, wherein the circuit section has a function other than magnetic storage. 10. The magnetic storage device according to claim 9, wherein the circuit section has a communication function. 11. The magnetic storage device according to claim 9, wherein the circuit section has a function of compressing and expanding stored information. 12. A magnetic storage device comprising a magnetic head for performing a recording / reproducing operation, a magnetic disk for storing information, a rotary drive unit for the magnetic disk, and an actuator for moving the magnetic head over a desired radius on the magnetic disk. At least an information storage unit, a circuit for positioning control of the magnetic head in the information storage unit, a controller for controlling information recording / reproduction, and an LS for demodulating a servo signal
I, an LSI that performs signal processing, and a circuit unit including at least one of the circuit boards are configured in a different housing,
In a magnetic storage device that can be carried independently of each other, the dimensions of the housings forming the information storage unit and the circuit unit are 5 mm or less in thickness and 54 mm or less in width, respectively.
A magnetic storage device having a length of 85.6 mm or less. 13. A magnetic storage device comprising a magnetic head for performing a recording / reproducing operation, a magnetic disk for storing information, a rotary drive unit for the magnetic disk, and an actuator for moving the magnetic head on a desired radius on the magnetic disk. At least an information storage unit, a circuit for positioning control of the magnetic head in the information storage unit, a controller for controlling information recording / reproduction, and an LS for demodulating a servo signal
I, an LSI that performs signal processing, and a circuit unit including at least one of the circuit boards are configured in a different housing,
In a magnetic storage device that can be carried independently of each other, an information storage unit that constitutes the magnetic storage device includes at least one magnetic disk, at least one actuator, at least one magnetic head, and at least one magnetic disk. A magnetic storage device characterized by the presence of an R / W IC. 14. A magnetic storage device comprising: a magnetic head for performing a recording / reproducing operation; a magnetic disk for storing information; a rotational drive unit for the magnetic disk; and an actuator for moving the magnetic head to a desired radius on the magnetic disk. At least an information storage unit, a circuit for positioning control of the magnetic head in the information storage unit, a controller for controlling information recording / reproduction, and an LS for demodulating a servo signal
I, an LSI that performs signal processing, and a circuit unit including at least one of the circuit boards are configured in a different housing,
In a magnetic storage device that can be carried independently of each other, at least two spindles, at least two magnetic disks, and at least two actuators are present in the information storage unit that constitutes the magnetic storage device, and at least 2 A magnetic storage device characterized in that data can be transferred in parallel by a single magnetic disk. 15. A magnetic storage device comprising: a magnetic head for performing a recording / reproducing operation; a magnetic disk for storing information; a rotary drive unit for the magnetic disk; and an actuator for moving the magnetic head to a desired radius on the magnetic disk. At least an information storage unit, a circuit for positioning control of the magnetic head in the information storage unit, a controller for controlling information recording / reproduction, and an LS for demodulating a servo signal
I, an LSI that performs signal processing, and a circuit unit including at least one of the circuit boards are configured in a different housing,
A magnetic storage device which can be carried independently of each other, characterized in that either one of a circuit portion and an information storage portion constituting the magnetic storage device has a PCMCIA interface. 16. A magnetic storage device comprising: a magnetic head for performing a recording / reproducing operation; a magnetic disk for storing information; a rotary drive unit for the magnetic disk; and an actuator for moving the magnetic head to a desired radius on the magnetic disk. At least an information storage unit, a circuit for positioning control of the magnetic head in the information storage unit, a controller for controlling information recording / reproduction, and an LS for demodulating a servo signal
I, an LSI that performs signal processing, and a circuit unit including at least one of the circuit boards are configured in a different housing,
In a magnetic storage device that can be carried independently of each other, an information storage unit and a circuit unit that make up the magnetic storage device do not cause a trouble in performing a recording / reproducing operation even if an impact of 200 G or more is received. A magnetic storage device characterized by the above. 17. A magnetic storage device comprising a magnetic head for recording / reproducing operation, a magnetic disk for storing information, a rotary drive unit for the magnetic disk, and an actuator for moving the magnetic head to a desired radius on the magnetic disk. At least an information storage unit, a circuit for positioning control of the magnetic head in the information storage unit, a controller for controlling information recording / reproduction, and an LS for demodulating a servo signal
I, an LSI that performs signal processing, and a circuit unit including at least one of the circuit boards are configured in a different housing,
In a magnetic storage device that can be carried independently of each other, the connector for inserting the circuit unit is not shared with the connector for inserting the information storage unit, and there is at least a structural difference between the information storage unit and the circuit unit, A magnetic storage device characterized in that it is impossible to erroneously connect the circuit connector to the information storage connector. 18. A magnetic storage device comprising: a magnetic head for performing a recording / reproducing operation; a magnetic disk for storing information; a rotary drive unit for the magnetic disk; and an actuator for moving the magnetic head to a desired radius on the magnetic disk. At least an information storage unit, a circuit for positioning control of the magnetic head in the information storage unit, a controller for controlling information recording / reproduction, and an LS for demodulating a servo signal
I, an LSI that performs signal processing, and a circuit unit including at least one of the circuit boards are configured in a different housing,
In a magnetic storage device that can be carried independently of each other, the connector for inserting the circuit unit is also used as the connector for inserting the information storage unit, and there is a structural difference between the information storage unit and the connector for the circuit unit. A magnetic storage device characterized by the absence thereof. 19. A magnetic storage device comprising: a magnetic head for performing a recording / reproducing operation; a magnetic disk for storing information; a rotary drive unit for the magnetic disk; and an actuator for moving the magnetic head to a desired radius on the magnetic disk. At least an information storage unit, a circuit for positioning control of the magnetic head in the information storage unit, a controller for controlling information recording / reproduction, and an LS for demodulating a servo signal
I, an LSI that performs signal processing, and a circuit unit including at least one of the circuit boards are configured in a different housing,
In a magnetic storage device that can be carried independently of each other, the information storage unit has 68 pins having the same dimensions as the PCMCIA connector like the circuit unit,
A magnetic storage device characterized in that pins not used in the circuit section are used for connection with the mechanical section. 20. A magnetic storage device comprising a magnetic head for performing a recording / reproducing operation, a magnetic disk for storing information, a rotary drive unit for the magnetic disk, and an actuator for moving the magnetic head to a desired radius on the magnetic disk. At least an information storage unit, a circuit for positioning control of the magnetic head in the information storage unit, a controller for controlling information recording / reproduction, and an LS for demodulating a servo signal
I, an LSI that performs signal processing, and a circuit unit including at least one of the circuit boards are configured in a different housing,
In a magnetic storage device that can be carried independently, a magnetic storage device characterized in that a housing forming an information storage unit and a housing forming a circuit unit have different sizes. 21. A magnetic storage device comprising a magnetic head for performing a recording / reproducing operation, a magnetic disk for storing information, a rotary drive unit for the magnetic disk, and an actuator for moving the magnetic head to a desired radius on the magnetic disk. At least an information storage unit, a circuit for positioning control of the magnetic head in the information storage unit, a controller for controlling information recording / reproduction, and an LS for demodulating a servo signal
I, an LSI that performs signal processing, and a circuit unit including at least one of the circuit boards are configured in a different housing,
In a magnetic storage device that can be carried independently of each other, a flexible LSI is used as at least one of the LSIs provided in the housing forming the information storage unit or the housing forming the circuit unit. A magnetic storage device characterized by the above.