Source: https://patents.google.com/patent/JP3469699B2/en
Timestamp: 2020-08-05 08:33:07
Document Index: 415728884

Matched Legal Cases: ['Application No. 05', 'Application No. 06', 'art 210', 'art 210', 'art, 331', 'art, 350']

JP3469699B2 - Docking device for portable computer - Google Patents
Docking device for portable computer
JP3469699B2
JP3469699B2 JP03169996A JP3169996A JP3469699B2 JP 3469699 B2 JP3469699 B2 JP 3469699B2 JP 03169996 A JP03169996 A JP 03169996A JP 3169996 A JP3169996 A JP 3169996A JP 3469699 B2 JP3469699 B2 JP 3469699B2
JP03169996A
JPH09230959A (en
田 一 彦 前
澤 貴 柳
村 健 俊 除
1996-02-20 Priority to JP03169996A priority Critical patent/JP3469699B2/en
1997-09-05 Publication of JPH09230959A publication Critical patent/JPH09230959A/en
2003-11-25 Publication of JP3469699B2 publication Critical patent/JP3469699B2/en
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a docking device for a portable computer, which is mechanically integrated with a so-called portable computer and electrically connected to extend various functions of the portable computer. More specifically, the present invention relates to a docking device for a portable computer, which can be configured by selecting a function required by a user.
2. Description of the Related Art With the recent technological innovation, various types of personal computers such as desktop type and notebook type have been developed and put on the market. Of these, notebooks
The computer is a battery-powered personal computer designed with portability in mind.
Since notebook computers place importance on small size and light weight, there is no room for accommodating peripheral devices. In some cases, the expandability of the device cannot be relied on solely by the PC card. Also, because the surface area is small,
The number of bus slots is severely limited. While it is not uncommon to find products with more than 10 bus slots in desktop computers, laptops /
Notebook computers have no bus slots at all, or at most one or two. In addition, the notebook computer
The most important feature is portability, but it is very troublesome to attach and detach cables (eg printer cable, monitor cable, communication cable, etc.) between office use and portable use. Yes, this will impair usability.
So-called "docking station"
(Docking Station: "Expansion Box"
(Also referred to as an "expansion unit") is for giving the notebook computer the same working environment as that of the desktop computer when used in the office, without impairing the portability of the notebook computer. The main function of the docking station is the "port proxy function"
And "Bus Expansion Function"
Is. Of these, the port proxy function is realized by the docking station having extended connection ports of a notebook computer. In other words, if a cable is connected to each port on the docking station side in advance, the user can use the printer, external monitor, and network immediately by simply incorporating the notebook computer into the docking station. It is a translation. From the viewpoint of collectively managing the connection of cables, it is also called "cable management function". On the other hand, the bus expansion function is realized by the docking station expanding the bus of the notebook computer and having one or more bus slots. When the notebook computer is docked with the docking station, this allows the desired adapter cards and devices to be available through the docking station. The user is no longer subject to the tight space constraints of a notebook computer.
Regarding the docking station itself, for example, Japanese Patent Application No. 05-
No. 181593 (Internal reference number: JA9-93-02
7) and the specification of Japanese Patent Application No. 06-134124 (internal reference number: JA9-94-030).
FIG. 16 shows typical configurations of the notebook computer 100 and the docking station 200. Notebook computer 100
Has a connector for docking (hereinafter referred to as a docking connector) on its rear surface (not shown). The docking connector is usually composed of tens to hundreds of connector pins, and each connector pin is assigned to a port signal or a bus signal in the notebook computer 100. The bus assigned to the docking connector by the notebook computer 100 side (that is, the bus to be expanded) is generally an ISA (Industry Standard Arch) which is an input / output bus.
itecture) bus. This is because ISA has long been a standard in the industry, so ISA devices, ISA
This is also because there are a wealth of past assets that can be inherited, such as applications. Also, recently, a PC that is positioned as a local bus for the CPU instead of the ISA bus
Notebook computers of the type that assign an I (Peripheral Component Interconnect) bus to the docking connector (ie, expand the PCI bus) have also appeared. This is for graphics, PC cards, etc.
The number of devices that require high-speed data transfer operations has increased, the number of devices that can be connected to one PCI bus is limited, and expansion is required. It seems that the bus can be extended, etc.
On the other hand, the docking station 200
Is composed of a main body having a built-in electric circuit system, a mounting portion for mounting the notebook computer 100 on the upper surface of the main body, and a protrusion protruding upward at the rear end of the mounting portion. A connector for joining with a docking connector on the rear surface of the notebook computer 100 is provided on the front surface of the protruding portion. The surface of this connector may be covered with an openable / closable lid for protection when not in use. Further, a pair of linear projections for guiding the mounting of the notebook computer are provided on both side edges of the mounting portion.
By the way, the docking station
From a relatively small-scale storage device that has only a port proxy function to a fixed or removable storage device (HDD, FDD, C
It has multiple storage spaces (also called "media bays") for mounting D-ROM drives, etc.,
There are various product forms, up to relatively large ones that can accommodate multiple adapter cards. However, each of them has essentially the following drawbacks.
(1) As a product lineup of docking stations, it is necessary to support the type of docking connector (N) and the type of configuration (M) such as the contents and number of expandable devices. Therefore, the manufacturer has to develop and manufacture N × M kinds of products, and also have an inventory. Also, depending on whether the bus to be expanded is a PCI bus or an ISA bus,
Since the configurations are different, we will increase the number of items accordingly.
(2) On the other hand, the user selects a docking station having a desired configuration from among the docking stations whose electrical and mechanical specifications match the docking connector provided on his or her notebook computer. Select and purchase. If, over time, you need more bus extensions or configuration changes, you will have to buy the docking station again. Further, the ISA bus expansion type notebook computer cannot be used on a docking station compatible with the PCI bus. Conversely, a PCI bus expansion type notebook computer cannot be used on a docking station compatible with the ISA bus. Further, the connector mechanically and electrically coupled to the notebook computer and its peripheral portion remarkably depend on the product standard such as the form factor on the notebook computer side, and sometimes the diversion is not effective. Therefore, a troublesome situation may occur in which the docking station must be replaced with the replacement of the notebook computer.
An easy solution to enhance the bus expansion function of the docking station, that is, to prepare extra bus slots and media bays, in anticipation of future system configuration version upgrades. A method could be considered. However, providing a function with limited users and conditions as a standard imposes a heavy financial burden on the user.
A typical usage of the docking station is that a plurality of users (multi-users) are alternately connected in an office (or office). However, even within the same office, notebook computers possessed by each user are divided into PCI bus expansion type, ISA bus expansion type and the like. Therefore, if the docking station has a fixed compatible bus type, it becomes difficult to realize a multi-user environment.
The need for the port proxy function of the docking station is more common than that of the bus expansion function. Nevertheless, if the configuration of the bus expansion function no longer meets your needs, you may replace the entire docking station.
I have to say that there is a lot of waste.
SUMMARY OF THE INVENTION It is an object of the present invention to provide an excellent portable computer that is mechanically integrated with and electrically connected to a portable computer to extend the functions of the portable computer. It is to provide a docking device for use.
A further object of the present invention is to provide an excellent docking device for a portable computer, which allows the user to select and configure the necessary functions.
The present invention has been made in consideration of the above problems, and a first aspect thereof is a portable computer which is mechanically integrated with and electrically connected to a portable computer. Docking device for
(A) It has a first connector that can be mechanically integrated with a portable computer and that is electrically connected to the portable computer side, and each port signal in the first connector has a connection port. And a bus signal in the first connector that passes through to the second connector as it is,
(B) A third unit that can be mechanically combined with the first docking device and that is electrically connected to the second connector.
Connector, a space for accommodating a peripheral device connected to the bus expanded via the third connector, and an expansion adapter card connected to the bus expanded via the third connector. And a second docking device including one or more bus slots for storing the docking device for the portable computer.
A second aspect of the present invention is a docking device for a portable computer, which is mechanically integrated with and electrically connected to the portable computer, and a mounting portion for mounting the portable computer, and a portable unit. Type connector for electrically connecting to the computer type computer side,
One or more connection ports given to each port signal in the first connector, and a second connector that passes through the bus signal in the first connector as it is. A docking device for a portable computer, which is a feature.
The third aspect of the present invention is capable of being mechanically combined and separated from the docking device for a portable computer according to the second aspect, and is electrically connected to the second connector. A space for accommodating a third connector, a peripheral device connected to the bus extended through the third connector, and an expansion adapter card for the bus extended through the third connector. One for connecting
A docking device for a portable computer, comprising the above bus slot.
1, 2 and 3 are high level conceptual diagrams of a notebook computer embodying the present invention and a docking station for the computer.
The docking station according to the first aspect of the present invention comprises a first docking device 200 and a second docking device 300. The first docking device 200 corresponds to the docking device according to the second aspect of the present invention, and the second docking device 300 corresponds to the docking device according to the third aspect.
The notebook computer 100 includes a printed circuit board (not shown) on which various electric circuits such as a CPU and a main memory are mounted. Docking connector 1 by collecting various port signals and bus signals extending from the printed circuit board
It appears as 30 outside. Examples of the port signal here include serial signals, parallel signals, and video signals. The types of port signals that are output to the outside are
It is relatively common between computers. On the other hand, the bus signal assigned to the docking connector 130 varies depending on the model such as an expansion bus (for example, ISA bus) or a local bus (for example, PCI bus). Also,
The type and number of peripheral devices to be added to the bus (that is, the configuration on the docking station side) vary depending on the needs of each user, and it is difficult to share them.
The first docking device 200 has a mechanism capable of being mechanically combined and separated from the notebook computer 100. Further, the docking device 200 is physically fitted with the docking connector 130 on the side of the notebook computer 100, and is provided with a first connector 221 whose electrical specifications match. The first connector collectively receives port and bus signals extending from the notebook computer 100 via the docking connector 130. Then, each signal line included in the first connector is again separated into a port signal and a bus signal inside the docking device 200. Of these, each port signal is electrically connected to a corresponding port provided on the surface of the housing of the docking device 200. Examples of ports here include serial and
Ports, parallel ports, CRT ports and the like. On the other hand, the separated bus signal is passed through to the second connector 222 as it is. The second docking device is a unit having only a relatively common part of the functions required of the docking station, and can be said to be the minimum docking station. From another point of view, the first docking device 200 absorbs the difference in the form factor on the notebook computer side and the mechanical / mechanical specifications of the docking connector to allow the second docking device 30 to operate.
It is also a unit to make it invisible from 0. The ports and the second connector 222 are the same as the first connector 2
It is arranged on the surface facing 21.
On the other hand, the second docking device 30
Reference numeral 0 is a unit for supplementing a portion of the functions required for the docking station, where the needs of each user (or each notebook computer) are not commonly shared. The product lineup of the second docking device 300 is diverse, and the configuration thereof greatly differs depending on which bus in the notebook computer 100 is expanded.
FIG. 2 schematically shows one embodiment of the second docking device 300, that is, the hardware configuration of the PCI bus expansion type docking device 300.
The second docking device 300 physically fits with the second connector 222 on the second docking device 200 side, and is provided with a third connector 321 whose electrical specifications match. Inside the second docking device 300,
A bay for accommodating various peripheral devices, a PCI bus received via the third connector AFU, and this PCI
The bus includes an ISA bus connected by a bridge circuit. Bay has one or more PCIs connected to a PCI bus
Device or one or more I's connected to the ISA bus
The SA device is housed. The end of the PCI bus is
It is electrically connected to a PCI bus slot 322 provided on the surface of the housing of the docking device 300. Also, I
The end of the SA bus is electrically connected to the ISA bus slot 323 provided on the surface of the housing of the docking device 300.
Further, FIG. 3 shows the second docking device 3
00, that is, the hardware configuration of the docking apparatus 300 of the ISA bus expansion type is schematically illustrated. The second docking device 300 physically fits with the second connector 222 on the second docking device 200 side, and is provided with a third connector 321 whose electrical specifications match. Inside the second docking device 300, a bay for accommodating various peripheral devices and a third docking device are provided.
ISA bus received via connector 321 of At least one IS connected to the ISA bus in the bay
A device is accommodated. The end of the ISA bus is electrically connected to the ISA bus slot 323 provided on the surface of the housing of the docking device 300.
As will be reiterated, the needs for the bus expansion function of the docking station are less common among the users than for the port proxy function. Further, the connector for connecting to the notebook computer and its peripheral portion largely depend on the product standard such as the form factor on the notebook computer side, and diversion is not so effective. According to the invention,
It implements the port proxy function that directly contacts the notebook computer and the bus expansion function with various needs as independent devices. Therefore, even when the user wants to change or add the expansion contents, the user only needs to replace the second docking device while leaving the port proxy function (that is, the first docking device). Also, if you replace your notebook computer,
Conversely, only the first docking device needs to be replaced while leaving the second docking device.
Further, as long as the mechanical and electrical specifications of the docking connector, the first, second, and third connectors are unified, the first docking device has various types of second
It can be integrated with the docking device. Therefore, from the manufacturer's point of view, M + is a combination of the type of configuration (M) such as the content and number of expandable devices and the type of connector (N) of the notebook computer.
All you have to do is develop and manufacture N types of docking devices. That is, it is possible to significantly reduce the burden of product assortment and inventory.
Still other objects, features and advantages of the present invention are as follows.
It will be clarified by a more detailed description based on embodiments of the present invention described below and the accompanying drawings.
A. External Configuration First, the external configuration of an apparatus embodying the present invention will be described.
FIG. 4 shows the appearance of a docking station according to an embodiment of the present invention. The docking station is composed of two independent devices, a first docking device 200 and a second docking device 300, which can be physically combined and separated. The first docking device 200 corresponds to the “first docking device” according to the first aspect of the present invention or the “docking device for a portable computer” according to the second aspect of the present invention. In addition, the second docking device 300
Corresponds to the "second docking device" according to the first aspect of the present invention or the "docking device for a portable computer" according to the third aspect of the present invention.
A-1. Notebook Computer The notebook computer 100 is a personal computer including a shallow-bottomed main body 110 and a lid 120 rotatably attached to a substantially rear edge portion of the main body 110. Notebook computer 100
For example, it has a footprint of about A4 size. Generally, a keyboard unit 115 is provided on the top surface of the main body 110.
And a liquid crystal display (LCD) 125 is arranged on the inner surface of the lid 120.
The notebook computer 100 according to the present embodiment is provided with a docking connector 130 (not shown) on its rear surface, and a pair of linear projections (described later) on its bottom surface. There are formed a pair of linear grooves (not shown) for inserting the holes, and an opening (not shown) for engaging with a hook 215 (described later) on the second docking device 200 side. Further, on the left side surface of the main body of the notebook computer 100, there is provided a card exchange opening 118 for attaching / detaching / exchange of a PC card.
Such a notebook computer 1
An example of "00" is "IBM ThinkPad 760"("Think
Pad "is a trademark of IBM Corp. of America. However, the configuration of the notebook computer itself is not the gist of the present invention.
A-2. First Docking Device The first docking device 200 includes a mounting part 210 for mounting the notebook computer 100 as a “portable computer” and a protruding part projecting behind the mounting part 210. 220 and 220.
The mounting portion 210 is a thin and rigid structure having a width and a depth corresponding to the footprint of the notebook computer 100. A side wall 211 is formed at the left end of the mounting portion 210, and a security link cover 212 is provided at the right end. Security link cover 212 has security key 21
3 is a member for covering a transmission mechanism (not shown) for transmitting the rotation operation of 3 to each part. This transmission mechanism
It is for setting the devices 200 and 300 in a predetermined security mode. For example, the hook 215 provided substantially in front of the mounting portion 210, the link cover 21
The first shutter 216 erected on the upper surface of the second docking device, the second shutter 333 vertically installed on the right side surface of the second docking device 300, etc. are adapted to receive the transmission of the rotational operation (described later).
The distance between the side wall 211 and the inner wall of the link cover 212 is kept substantially the same as the width of the notebook computer 100 along the depth direction. In addition, a pair of linear projections 214a and 214b, which are spaced at predetermined intervals along the depth direction, are provided on both left and right sides of the upper surface of the mounting portion 210 so as to project. When the notebook computer 100 is mounted on the first docking device 200 (dashed line in FIG. 4), the notebook computer 100 has the side wall 21.
The movement direction is restricted by 1 and the inner wall of the link cover 212, and is guided by the pair of linear projections 214a and 214b so that the link cover 212 can be mounted smoothly.
The rear projection 220 is located on the right side of the front surface of the projection 220.
A first connector 221 for connecting to the notebook computer 100 is embedded. The electrical and mechanical specifications of the first connector match the docking connector 130 on the notebook computer 100 side. The first connector 221 is composed of, for example, 240 pins, and various port signals and bus signals are included therein.
An electric circuit is mounted inside the protrusion 220 (not shown). This electrical circuit is mainly
Is to separate each signal pin included in the connector 221 into a port signal, a bus signal, and the like. The reason why each signal pin is treated separately is that the first docking device 200 itself acts as a port function while the bus expansion function is delegated to the second docking device 300.
FIG. 5 shows a perspective view of the first docking device 200 separated from the second docking device 300 as viewed from the upper left rear side thereof. However, in order to make ports (described later) appear, a part of the rear edge of the upper surface of the protrusion 220 is cut out and drawn.
Each bus separated inside the protrusion 220
The signal is passed through to the corresponding pin of the second connector 222 provided on the back surface. On the other hand, the separated port signals are electrically connected to the ports provided on the back surface and the side surface. The first docking device 200 of the present embodiment uses the FDD port 23 as ports.
1, CRT port 232, serial port 233
Parallel port 234, keyboard port 235,
Each has a mouse port 236. Each port 2
31, 32, 233, 234, 235, and 236 have an external FDD, external CRT, modem, and
A printer, an external keyboard, and a mouse (not shown) can be attached. These external devices can be always attached regardless of the operation of joining and separating with the notebook computer 100. Besides this, DC
It also has a DC inlet 237 for receiving power and an audio line out 238 for outputting an audio signal.
A-3. Second Docking Device FIG. 6 shows an example of the second docking device 300 separated from the first docking device 200 as viewed from the front. However, in order to avoid complication of the drawings, various cables, mounted circuits, etc. are not depicted in detail.
The housing of the second docking device 300 is composed of a bottom cover 310 for accommodating various electric circuits and storage media, and a rear cover 320 for covering the back surface.
The potom cover 310 is a relatively robust structure having a shallow bottom shape. Bottom cover 310
An LCD panel 351 for displaying the status of the device 300 and the like, and a storage medium (mainly a CD-ROM
A bezel 352 is provided to close the exchange port of a floppy disk or a floppy disk.
The left half of the bottom cover 310 includes the second docking device 300 itself and the first docking device 20.
0, and a power supply circuit 311 capable of supplying power to the notebook computer 100. A printed circuit board 312 is screwed to the lowermost layer of the right half of the bottom cover 310.
A space approximately in front of the right half of the bottom cover 310 is a "media bay" capable of accommodating any one storage device of a CD-ROM drive, an FDD, and an HDD. In front of the printed board 312, a connector 31 to which a CD-ROM or FDD can be connected
IDE (Integrated Dri) that can connect 2a and HDD
ve Electronocs) connector 312b is mounted.
In the rear of the media bay, a PC card
Slots 313 are installed. The PC card slot 313 has, for example, a relatively thin type 1/2.
Two cards or one relatively thick type 3 card can be inserted.
A riser card 314 is erected at a substantially rear end of the printed board 312. Bottom cover 31
A protrusion 340 for accommodating the riser card 314 is integrally formed with the bottom cover 310 at the rear of 0. A third connector 321 is mounted on the front surface of the riser card, and various bus slots such as a PCI slot 322 and an ISA slot 323 are provided on the back surface thereof, as well as a SCSI port 324 and a MIDI port 3.
25 are mounted (not shown in FIG. 6). The third connector 321 is for receiving a pass-through bus signal from the first docking device 200, and has electrical and mechanical specifications that match those of the second connector 222. Also, bus slots 322, 323
The SCSI port 324, the MIDI port 325, and the audio line-out jack 326 are exposed on the back surface of the second docking device 300, and P and P respectively.
It is possible to connect a CI compatible expansion adapter card, an ISA compatible expansion adapter card, a SCSI bus, and a MIDI device.
Further, on the right side surface of the bottom cover 310, an overhanging portion 330, which originally bulges out of a rectangular footprint, is formed. On the surface of the overhanging portion 330, P
An exchange port 331 for attaching and detaching the C card is provided. Further, on the upper surface of the overhanging portion 330, the interlocking means 332 that receives the transmission of the rotation operation of the security key 213 from the first docking device 200, and the second interlocking means 332 that can slide forward and backward integrally. Shutter 333
FIG. 7 shows the back surfaces of the first docking device 200 and the second docking device 300 in a combined state.
The rear surface of the second docking device 300 is covered with a rear cover 320. The rear cover 320 has bus slots 322, 323 and SCSI port 3
24, each opening for exposing the MIDI port 325 to the outside is provided.
The substantially central portion of the protruding portion 340 is formed to have a low height. Therefore, the first docking device 200
Even when the second docking device 300 and the second docking device 300 are combined, each port 231, 232, 233, 234, 23
5, and 236 do not mechanically interfere with the housing of the second docking device 300. Therefore, the external device connected to each port can always be attached, and it is not necessary to remove it when combining and separating. On the other hand, if the sound source function and the power feeding function that can be expanded by the first docking device 200 are combined, the second docking device 30
The function is absorbed by 0, which is unnecessary. Therefore, D
C inlet 237 and audio line out 238
Are hidden by the third docking device 300.
A-4. Security Mechanism Docking Devices 200 and 300 Shown in FIGS. 4-7
Has a security mechanism to protect the system from theft and the like. The security mechanism includes a security key 213, a transmission mechanism built in the security link cover 212, a hook 215 driven by transmission of a rotation operation of the security key 213, a first shutter 216, and It is configured with the second shutter 333. The security mechanism itself is not the subject of the present invention. In this section, only the operation of each unit that appears in appearance will be briefly described.
Rotation position of security key (key
The security key 213 provided on the rear of the left side surface of the first docking device 200 has an "eject position" and an "unlock position" in order from the right as shown in FIG.
It has three key positions, "position" and "lock position". Each key position is
It corresponds to the operation status of the device. That is, the eject position is the notebook computer 1 equipped with
00 is the key position for removing, and the unlock position is the notebook computer 100.
Can be mounted, but is a key position for not locking, and the lock position is a key position for prohibiting removal of the mounted notebook computer 100, PC card, and the like. The rotation operation of the security key 213 is performed by the link cover 21.
2 is transmitted to each part via a transmission mechanism (not shown) in the device 2, and each part of the devices 200 and 300 performs a predetermined operation. In addition, at the right end of the upper surface of the protrusion 220,
Indicator 223 for displaying key position
Eject Position: FIG. 9 shows a state in which the security key 213 is placed in the eject position.
Unlock the security key 213
A pair of ejectors 250a and 250b project from the left and right of the front surface of the projecting portion 220 in conjunction with further clockwise rotation from the position. Ejectors 250a, b
Is a built-in notebook computer 100 (see FIG. 9).
(Not shown), and then pushes it forward.
Note that the security key 213 always has a restoring force for returning from the eject position to the unlock position. This is because the eject operation itself is only a temporary state and should normally be placed in an unlocked state in which the notebook computer 100 can be mounted. Further, in the eject position and the unlock position, the security key 213 cannot be removed from the key hole. This is because it is necessary to operate the key except in the locked state. The constant keying allows multiple users to share the docking device (multi-user environment).
Unlock Position: Security
The unlocked position is the state where the key 213 is substantially upright. The unlocked state is a neutral state between the eject position and the locked position, and while the notebook computer 100 and PC cards can be freely attached, no protection is provided against their removal.
Locked Position: Further rotation of security key 213 from the unlocked position counterclockwise causes devices 200 and 300 to enter the locked position.
One effect associated with the transition to the locked position is the inhibition of removal of the notebook computer 100 by the hooks 215. In the unlocked state, the hook 215 can be retracted from the mounting portion 210 (see FIG. 10). However, in conjunction with the lock position,
It is fixed in the appearance state and is prohibited from being drawn into the placing section 210. As a result, as shown in FIG.
Remains engaged in an opening formed in the corresponding portion of the bottom surface of the notebook computer 100, and the removal of the notebook computer 100 is prohibited.
Further, another operation associated with the transition to the lock position is the PC of the notebook computer 100.
It is prohibited to remove the PC card from the card slot. As mentioned above, the notebook computer 1
00 is provided with a card exchange port 118 substantially rearward of its left side surface. On the other hand, in the first docking device 200, the first shutter 21 is provided on the upper surface of the link cover 212.
6 are erected. As shown in FIG. 12, the first shutter 216 is adapted to slide in the front-rear direction in conjunction with the rotation operation of the security key 213. In the unlocked position (A), the first shutter 216 is located rearward (A ′), and the card exchange opening 118 of the notebook computer 100 is fully opened. However, in the lock position (B), the first shutter 216 slides forward to block (B ') at least a part of the card exchange port 118, and as a result, the removal of the PC card is preferably prohibited. .
Another action associated with the transition to the lock position is prohibition of removal of the PC card from the PC card slot of the second docking device 300.
As described above, the second docking device 300 is provided with the card exchange port 331 substantially behind the left side surface thereof. Further, a second shutter 333 is vertically provided at the substantially center of the left side surface of the second docking device 300. 12
As shown in, the second shutter 333 is adapted to slide in the front-rear direction in conjunction with the rotation operation of the security key 213. In the unlocked position (A), the second shutter 333 is located substantially in the center (A ′), and the card exchange port 331 of the second docking device 300 is fully opened. However, in the lock position (B), the second shutter 333 slides backward to block (B ') at least a part of the card exchange opening 331, and as a result, the removal of the PC card is appropriately prohibited. .
Another action associated with the transition to the lock position is prohibition of separation of the first docking device 200 and the second docking device 300. By prohibiting the separation of the two, peripheral devices in the docking device 300 (for example, HDDs and CDs housed in the media bay)
It is possible to prevent unauthorized removal of ROM, FDD, etc.
In the lock position, unlike the other key positions, the security key 213 can be removed. This is to prevent an unauthorized user from operating the key without permission, and to ensure the security state.
B. Hardware Configuration FIG. 13 schematically shows the internal hardware configurations of the notebook computer 100 and the first docking device 200 used for implementing the present invention. 14 and 15 each schematically show an example of the internal hardware configuration of the second docking device 300. Hereinafter, each part will be described.
Notebook computer 100: The CPU 11, which is the main controller, executes various programs under the control of an operating system (OS). The operating clock is an oscillator (OS
C) Supplied from 12. The CPU 11 is, for example, In
"Pentium / 1xxMHz" marketed by tel may be used. The CPU 11 has a processor bus 12 directly connected to its own external pin, and a PCI (Peri) as a local bus.
pheral comonent interconnect (BUS) 17 and ISA (Industry Standard Architectur) as an input / output bus
e) Each device is interconnected via a three-level bus called a bus.
The processor bus 12 and the PCI bus 17 are connected by a bridge circuit (host-PCI bridge) 14. The bridge circuit 14 of this embodiment is
A memory controller for controlling an access operation to the main memory 15 and a data buffer for absorbing a speed difference between the buses 12 and 17 are included. The main memory 15 is composed of a writable memory such as a DRAM, and is used as a storage area for each program and a work area for a program being executed. The L2-cache 16 is composed of a high-speed accessible memory element such as SRAM, and holds the minimum necessary data in order to absorb the difference between the processing speed of the CPU 11 and the access speed to the main memory 15. Used for. The ROM 18 includes a control code (BIOS) for operating the hardware and a test program (P
It is a non-volatile memory for permanently storing (OST) and the like.
The PCI bus 17 is a high-speed bus that originated from the proposal by Intel Corporation of the United States, and has a bus width of 32 bits, an operating frequency of 33 MHz, and a maximum transfer rate of 132 Mbp.
s is the main performance. Another feature of PCI is via a bridge circuit (eg blocks 22, 23, 365),
The point is that it can be interconnected with other independently driven buses. PC
The I-bus 17 has a graphic controller 19 and a C
A device such as the ArdBus controller 20 that requires relatively high-speed data transfer is connected.
The graphic controller 19 uses the CP
It is a peripheral controller for actually processing the drawing command from U11, and the processed drawing information is stored in the screen buffer (V
The RAM 21) is temporarily written, the drawing information is read from the VRAM 18, and is output to a liquid crystal display (LCD) 125 that is equipped as standard.
Further, the graphic controller 19 can convert the video signal into an analog signal by an attached DA converter. The analog video signal is
It is output to the CRT port 41 via the signal line 19a. In addition, the signal line 19 a branches toward the docking connector 130.
The CardBus controller 20 is a PC
A controller for outputting a bus signal on the I-bus 17 to the PC card slot 118. The card slot 118 contains "PC Card Specific
A PC card capable of high-speed operation conforming to the "ation 95" is installed.
A bridge circuit (PCI-PCI bridge) 22 is provided at the end of the PCI bus 17. The bridge circuit 22 is for exchanging data between the PCI bus 17 and the PCI bus 371 on the local side (that is, in the second docking device 300). Further, the bridge circuit 22 is adapted to disable each signal pin on the local side when there is no PCI bus on the local side.
The PCI bus 17 and the ISA bus 35 are interconnected by a bridge circuit (PCI-ISA bridge) 23. The bridge circuit 23 of this embodiment has a D
The configuration includes an MA controller, a programmable interrupt controller (PIC), and a programmable interval timer (PIT). Furthermore, the bridge circuit includes an IDE interface for connecting a hard disk drive (HDD) (IDE is originally a standard for directly connecting an HDD to an ISA bus), and the interface is provided as standard equipment. Built-in IDE_HDD 24a and built-in IDE_CD-ROM2
4b is connected. The two bridge circuits 14 and 23 described above are defined by PCI and are generally commercially available in the form of a single chip set. An example of a chipset is "Trito" marketed by Intel Corp.
On the ISA bus 35, an I / O controller 25, a key board / mouse controller (KMC)
26, Digital Signal Processor (DSP) 27
A device such as the one that requires relatively slow data transfer is connected.
The I / O controller 25 is a floppy
It is a controller for controlling access to the disk drive (FDD) 28 and serial and parallel data input / output with an external device (for example, a modem or a printer: not shown). Signal line 25 for FDD
In addition to going to the built-in FDD 28, a also branches to extend to the docking connector 130. Also, serial
The signal line 25b extends toward the docking connector 130 as well as toward the serial port 45 on the rear surface of the housing. The parallel signal line 25c goes to the parallel port 46,
It also branches and extends to the docking connector 130. It should be noted that, due to the volume limitation of the note hook computer 100, only one of the FDD 28 and the IDE_CD-ROM 24b can be accommodated in the media bay.
The KMC 26 is a keyboard or mouse /
Track Point ("TrackPoint" is US IBM
It is for controlling data input / output by the trademark of the company. The mouse signal line 26a and the keyboard signal line 26b are directed to the mouse port 43 and the keyboard port 44, respectively, and are branched to extend to the docking connector 130.
The DSP 27 is a dedicated processor for processing digital signals and is mainly used for processing audio data. DPS27 is MIDI (Musi
calInstrument Digital Interface) data can also be processed. The MIDI signal line 27a is
It is assigned to a part of the docking connector 130. Also, the audio output signal line 27b is
In addition to heading to audio line-out 42, branch off,
It also extends to the docking connector 130.
The analog switch 30 is the ISA bus 3
It is for connecting or disconnecting the terminal of 5 and the docking connector 130. That is, analog
The switch 30 either energizes the end of the ISA bus 36 to electrically connect to a corresponding pin in the docking connector 130, or deenergizes its end to disconnect it from the docking connector 130. Analog switch 3
0 acts in cooperation with the bridge circuit 22 described above. When the PCI bus is directly connected to the local side of the docking connector 130 (FIG. 14: described later)
The bridge circuit 22 drives the local bus pin and the analog switch 30 is de-energized.
On the other hand, the IS on the local side of the docking connector 130
When the A bus is directly connected (FIG. 15: described later), the bridge circuit 22 deactivates the bus pin on the local side and the analog switch 30 activates. That is,
Only one of the PCI bus 35 and the ISA bus 35 can be assigned to the docking connector 130.
The DC / DC converter 31 is for reducing the DC power supply voltage supplied via the DC inlet 47 or the docking connector 130 and stably supplying power to each device inside the computer 100.
As shown in the figure, the PCI bus 17 or the ISA bus 35, the branched port signals 25a, 25b,
25c, 26a, 26b, ... And the power line 31a is 1
They are gathered in a bundle. Each connector pin of docking connector 130 is assigned to each of these aggregated signal and power lines. The mechanical and electrical specifications of the docking connector 130 match those of the first connector 221 on the first docking device 200 side.
The line segment P-P 'corresponds to the back surface portion of the casing of the notebook computer 100. docking·
The connector 130 and other ports 41, 42, 43, 44, 45, 46, which are not gathered in the connector 130,
47 is disposed at a position substantially corresponding to the line segment P-P '. While not combined with the first docking device 200,
The rear part P-P 'is exposed, and each port type 41, 4
2, ... are corresponding external devices (for example, external C
An RT display, an external keyboard, etc. (not shown) can be connected. On the other hand, when combined with the first docking device 200, the back surface portion PP ′
Comes into close contact with the front surface of the protrusion 220. As a result, the docking connector 130 mechanically and electrically joins with the first connector 221. Also, other ports 41,
42, ... Are unusable because they are blocked by the union, but instead are replicated by the first docking device 200.
The notebook computer 100
The configuration itself is not the essence of the present invention. For example, it is not always necessary to provide a two-level bus of a PCI bus and an ISA bus. Further, it is not necessary to have a function of selectively connecting either one of the PCI bus and the ISA bus to the docking connector 130, and only one bus is fixedly connected to the docking connector 130. May be. The minimum requirement for the notebook computer 100 to contribute to the present invention is to have a docking connector 130 that meets the electrical and mechanical specifications of the first connector.
First Docking Device 200: The first connector 221 on the first docking device 200 has the same mechanical and electrical specifications as the docking connector 130.
In the first docking device 200, the bundle of signal lines 260 received collectively by the connector 221 is a bus signal (PCI bus or ISA).
Bus) 260a and audio output signal line 2
60b, power line 260c, FDD signal line 260e, CRT signal line 260f,
It branches into a serial signal line 260g, a parallel signal line 260h, a keyboard signal line 260i, and a mouse signal line 260j. These branched buses, port signal lines, etc. are respectively connected to the second connector 222,
Audio line-out 238 and DC inlet 2
37, FDD port 231, and CRT port 23
2 and serial port 233 and parallel port 2
34, a keyboard port 235, and a mouse port 236.
The second of these connectors and ports
The connector 222, the DC inlet 237, and the audio line-out 238 are connected to the line segment Q-
It is arranged in the part of Q '. The portion corresponding to the line segment Q-Q 'is brought into close contact with the second docking device 300 by uniting. The second connector 222 is the second
The third connector 321 on the docking device 300 side is mechanically and electrically joined. On the other hand, the DC inlet 23
7 and the audio line-out jack 238 are blocked by the union and cannot be used. This is supplied with power from the side of the third docking device 300 while being combined,
In addition, the audio line-out is replicated on the side of the third docking device 300 and becomes unnecessary.
Other FDD port 231 and CRT
The port 232, the serial port 233, the parallel port 234, the keyboard port 235, and the mouse port 236 are arranged in the line segment RR ′ on the surface of the housing. The line segment RR ′ corresponds to a portion that does not mechanically contact the second docking device 300 even if they are combined. Therefore, an external FD connected to each port
External devices (not shown) such as D, an external CRT display, a modem, a printer, an external keyboard, and an external mouse can always be attached regardless of whether they are combined or separated. In other words, the cable connection to these ports can be managed collectively by the first docking device 200.
Second docking device 300: The second docking device 300 shown in FIG. 14 is of a type that expands the PCI bus.
The second docking device 300 has a third connector whose electrical and mechanical specifications match those of the second connector 222.
The connector 321 is provided, and the bus signal, the port signal, and the like are collectively received via the connector 321.
The CPU 360 is a processor for controlling the operation of each unit in the device 300 associated with the combination and separation. CPU 360 and notebook computer 100
By communicating with the CPU 11 inside, the uniting / separation (also referred to as “hot docking” or “warm docking”) at the time of power-on or power saving operation can be performed. However, the hot dock and the warm dock themselves are not related to the gist of the present invention, and thus will not be described here.
The CPU 360 further includes a notebook
It also controls the drive of the eject lock 361 for electrically prohibiting the removal of the computer 100, the beeper 362 for issuing a warning sound at the time of joining and separating, and the LCD panel 351 for indicating the state of the device 300. Has become.
The EEPROM 380 is a rewritable nonvolatile memory. The EEPROM 380 is the device 3
00, serial number, password, device configuration information, etc. used to store small amount of data required for security at the time of uniting / separation and guaranteeing system operation,
The stored contents can be read by the CPU 360 and the CPU 11 on the notebook computer 100 side.
The AC / DC adapter 311 is an external AC
This is for rectifying and smoothing an AC voltage supplied from a power source (for example, a commercial power source) to obtain a predetermined driving DC voltage. The AC / DC adapter 311 receives power from the outside via the AC inlet 368. Power line 311a
Are integrated with the bus 371 toward the third connector 321.
The MIDI port 325 is an external MIDI port.
It is a port for receiving MIDI data from a device, and the MIDI signal line 325a is a bus 371.
Integrated into a third connector 321.
The audio output signal line 326a included in the third connector 322 branches off from the bus towards the audio line out jack 326.
FD included in third connector 322
The D signal line 367a branches from the bus,
It is facing the connector 312a (see FIG. 6). The FDD 367 can be attached to the connector 312a.
On the PCI bus 371 extended in the second docking device 300, a CardBus controller 363 and a SCSI (Small Computer System Interfac) are provided.
e) A device such as the controller 364 that requires relatively high-speed data transfer is connected. In addition, PCI
A PCI bus slot 322 is provided at the end of the bus 371. PCI bus slot 322 has a P
A CI compatible expansion adapter card can be installed.
Like the hardware block 20, the CardBus controller 363 is a controller for outputting a bus signal on the PCI bus 371 to the PC card slot 331.
The SCSI controller 364 is a controller for performing protocol conversion between the PCI bus 371 and the SCSI bus 364a. SCSI bus 364
a goes out through the SCSI port 324. S
Up to eight SCSI devices can be daisy chained to the CSI port 324. An example of a SCSI device is H
These are DD, CD-ROM drive, and MO disc drive.
The second docking device 300 is further
It includes an SA bus 372. At the end of the ISA bus 372, an ISA bus slot 323 for mounting an ISA compatible expansion adapter card is provided. IS
The significance of expanding the A bus is to inherit the rich assets of ISA. The PCI bus 371 and the ISA bus 372 are interconnected via a bridge circuit (PCI-ISA bridge) 365.
The structure of the bridge circuit 365 is substantially the same as that of the hardware block 23 and also includes an IDE interface. HD for IDE interface
An IDE device such as a D or a CD-ROM can be attached. However, in the case of the second docking device 300 of the present embodiment, due to the restrictions on the volume, the FDD3 is placed in the media bay.
67 or IDE device (HDD or CD-ROM) 3
Only one of 66 can be accommodated.
The above-mentioned bus slots 322, 3
23, card slot 331, ports 324, 32
5. The AC inlet 368 is arranged on the surface of the housing of the docking device 300 (line segment S-S 'in the figure).
On the other hand, FIG. 15 schematically shows the internal hardware configuration of another type of second docking device 300 '. The docking device 300 'has a configuration in which only the ISA bus 372 is expanded instead of the PCI bus.
A bridge circuit (PCI-ISA bridge) or PCI bus
It has no slots. Also, instead of having a CardBus controller, a PCMCIA (Person) for sending the signal on the ISA bus 372 to the card slot is used.
al Computer Memory Card International Associatio
n) The controller 369 is used. The other hardware blocks are substantially the same as those shown in FIG.
If the electrical and mechanical specifications of the third connector 321 match the second connector 222, then FIG.
And that any type of FIG. 15 can be used with the first docking device 200.
Incidentally, these devices 100, 200, 300
In order to configure the above, many electric circuits and the like other than those shown in FIGS. 13 to 15 are necessary, but these are well known to those skilled in the art and are not related to the gist of the present invention. ,
Description is omitted in this specification.
C. Addendum The present invention has been described in detail above with reference to specific embodiments. However, it is obvious that those skilled in the art can modify or substitute the embodiments without departing from the scope of the present invention. That is, the present invention has been disclosed in the form of exemplification, and should not be limitedly interpreted.
In order to determine the gist of the present invention, the section of the claims described at the beginning should be taken into consideration.
It is possible to provide an excellent docking device for a portable computer, which allows the user to select and configure the necessary functions.
FIG. 1 is a conceptual diagram of a docking device for a portable computer according to the present invention and a portable computer that can be combined with the docking device, and more specifically, a notebook computer 100 and a first docking device. 2 is a high level block diagram of apparatus 200. FIG.
2 is a high-level block diagram illustrating one aspect of a second docking device 300, and more specifically, a block diagram of a PCI bus expansion type docking device 300. FIG.
3 is a high-level block diagram illustrating one aspect of a second docking device 300, and more specifically, a block diagram of an ISA bus expansion type docking device 300. FIG.
FIG. 4 is an external perspective view of a docking device for a portable computer according to an embodiment of the present invention.
FIG. 5 is a perspective view of the first docking device 200 separated from the second docking device 300 as viewed from the upper left rear side thereof.
6 is a front perspective view of the second docking device 300 separated from the first docking device 200. FIG.
FIG. 7 is a rear view of the first docking device 200 and the second docking device 300 in a combined state.
FIG. 8 is a diagram showing keys of a security key 213.
It is the figure which showed the position.
FIG. 9 is a diagram showing a state in which a security key 213 is placed at an eject position.
FIG. 10 is a diagram showing how the hook 215 provided on the upper surface of the mounting portion 210 is operated.
FIG. 11 is a diagram showing a state where the hook 215 locks the notebook computer 100.
FIG. 12 is a state in which the first shutter 216 prohibits the removal of the PC card of the notebook computer 100, and the second shutter 333 prohibits the removal of the PC card of the second docking device 300. It is the figure which showed the situation.
FIG. 13 shows a notebook computer 10.
FIG. 20 is a diagram schematically showing an internal hardware configuration of 0 and the first docking device 200300.
FIG. 14 is a diagram schematically showing an internal hardware configuration of a second docking device 300 according to an embodiment.
FIG. 15 is a diagram schematically showing an internal hardware configuration of a second docking device 300 according to another embodiment.
FIG. 16 is a diagram showing a typical form of a docking station.
11 ... CPU, 12 ... OSC, 13 ... Processor bus, 14 ... Bridge circuit, 15 ... Main memory, 16
... L2-cache, 17 ... PCI bus, 18 ... RO
M, 19 ... Graphic controller, 20, 363
... CardBus controller, 21 ... VRAM, 22
... Bridge circuit, 23,365 ... Bridge circuit, 24 ...
IDE device, 25 ... I / O controller, 26 ... K
MC, 27 ... DSP, 28 ... FDD, 29 ... Pointing device, 30 ... Analog switch, 31 ... D
C / DC converter, 35 ... ISA bus, 41 ... CRT
Port, 42 ... Audio line-out, 43 ... Mouse port, 44 ... KBD port, 45 ... Serial port, 46 ... Parallel port, 47 ... DC inlet, 100 ... Notebook computer, 115 ...
Keyboard, 118 ... Card slot, 125 ... LC
D, 130 ... Docking connector, 200 ... First docking device, 210 ... Mounting portion, 211 ... Side wall, 212
… Link cover, 213… Security key, 21
4 ... Linear projection, 215 ... Hook, 216 ... First shutter, 220 ... Projection portion, 221 ... First connector, 22
2 ... second connector, 223 ... indicator, 231 ...
FDD port, 232 ... CRT port, 233 ... Serial port, 234 ... Parallel port, 235 ...
Port for KBD, 236 ... Port for mouse, 237 ... D
C inlet, 238 ... Audio line-out jack, 300, 300 '... Second docking device, 3
11 ... Power supply device, 312 ... Printed circuit board, 313 ... Card slot, 320 ... Bottom cover, 321 ... Third
Connector, 322 ... PCI bus slot, 323 ...
ISA bus slot, 324 ... SCSI port, 32
5 ... MIDI port, 326 ... Audio line-out jack, 330 ... Overhang part, 331 ... Card exchange port, 332 ... Interlocking means, 333 ... Second shutter, 3
40 ... Projection part, 350 ... Bezel, 351 ... LCD panel, 360 ... CPU, 361 ... Beeper, 362 ... Eject lock, 364 ... SCSI controller, 36
6 ... IDE device, 367 ... FDD, 368 ... AC inlet.
─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Kazuhiko Maeda 1623 Shimotsuruma, Yamato-shi, Kanagawa 14 Yamato Works, IBM Japan, Ltd. Shimazuruma 1623 14 Japan IBM Japan, Ltd. Yamato Works (56) Reference JP 5-80901 (JP, A) JP 7-306737 (JP, A) JP 8-6668 (JP, A) (58) Fields surveyed (Int.Cl. 7 , DB name) G06F 1/16-1/18 G06F 3/00
1. A docking device for a portable computer, which is mechanically integrated with and electrically connected to a portable computer, comprising: (a) a mechanical integration with the portable computer, and an electrical connection with the portable computer side. A first connector for connection is provided, each port signal in the first connector is provided with a connection port, and the bus signal in the first connector is directly passed to the second connector. A first docking device that passes through, (b) a third connector that can be mechanically integrated with the first docking device, and that is electrically connected to the second connector; and the third connector. A space for accommodating a peripheral device connected to the bus extended through the connector, and an extension adapter for the bus extended through the third connector Portable computer docking device characterized by comprising the one or more bus slots for connecting a card, and a second docking apparatus including, a.
2. A docking device for a portable computer which is mechanically integrated with and electrically connected to the portable computer, and a mounting portion for placing the portable computer on the docking device and electrically connected to the portable computer side. A first connector for connection, one or more connection ports given to each port signal in the first connector, and a second connector that directly passes through the bus signal in the first connector. A docking device for a portable computer, comprising: a connector.
3. A third connector which can be mechanically combined with the docking device for a portable computer according to claim 2 and which is electrically connected to the second connector, and the third connector. A space for accommodating a peripheral device connected to the bus extended via the bus, and one or more bus slots for connecting an expansion adapter card to the bus extended via the third connector; A docking device for a portable computer, comprising:
4. The connection port is an FDD port, C
RT port, serial port, parallel port,
The docking device for a portable computer according to claim 1, further comprising at least one of a keyboard port and a mouse port.
5. The connection port is an FDD port, C
The docking device for a portable computer according to claim 2, further comprising at least one of a keyboard port and a mouse port.
6. The docking device for a portable computer according to claim 1, wherein the bus signals include signals of a PCI bus.
7. The docking device for a portable computer according to claim 2, wherein the bus signals include signals of a PCI bus.
8. The docking device for a portable computer according to claim 3, wherein the bus signals include a PCI bus signal.
9. The docking device for a portable computer according to claim 1, wherein the bus signals include an ISA bus signal.
10. The docking device for a portable computer according to claim 2, wherein the bus signals include an ISA bus signal.
11. The docking device for a portable computer according to claim 3, wherein the bus signals include an ISA bus signal.
JP03169996A 1996-02-20 1996-02-20 Docking device for portable computer Expired - Fee Related JP3469699B2 (en)
JP03169996A JP3469699B2 (en) 1996-02-20 1996-02-20 Docking device for portable computer
TW85103989A TW296443B (en) 1996-02-20 1996-04-01 Docking device for portable computer
US08/741,586 US5805412A (en) 1996-02-20 1996-10-31 Multiple stacked docking stations and portable computer
KR1019960055503A KR100245966B1 (en) 1996-02-20 1996-11-15 Docking station for a portable computer
EP19970300480 EP0793164B1 (en) 1996-02-20 1997-01-28 Docking station for portable computer
DE69721106T DE69721106D1 (en) 1996-02-20 1997-01-28 Docking station for portable computers
JPH09230959A JPH09230959A (en) 1997-09-05
JP3469699B2 true JP3469699B2 (en) 2003-11-25
JP03169996A Expired - Fee Related JP3469699B2 (en) 1996-02-20 1996-02-20 Docking device for portable computer
TW (1) TW296443B (en)
JP3383489B2 (en) * 1995-09-29 2003-03-04 株式会社東芝 Expansion unit and computer connectable to this expansion unit
KR100310100B1 (en) * 1996-07-10 2001-12-17 윤종용 Power supply apparatus for portable computer and dc input selection circuit adapted to same
JP3248712B2 (en) * 1996-11-05 2002-01-21 富士通株式会社 Function expansion device for information processing device
JP2938049B1 (en) * 1998-07-02 1999-08-23 新潟日本電気株式会社 Hot-swap controller for extended I / O device to computer
WO2000017733A1 (en) * 1998-09-22 2000-03-30 Sanyo Electric Co., Ltd. Accessory of electronic device
EP1470493A2 (en) * 2002-01-19 2004-10-27 Incorporated Technologies (Holdings) Limited Kiosk technology kit
JP4632857B2 (en) * 2004-10-05 2011-02-23 オリンパスイメージング株式会社 Information processing device
JP5782963B2 (en) * 2011-09-28 2015-09-24 富士通株式会社 Expansion device, information processing device, information processing system, and information processing system security processing method
TWI475394B (en) * 2012-10-15 2015-03-01 Aopen Inc Transmission port module for expanding transmission capacity of a host module and computer system therwith
CN107003953A (en) 2014-09-30 2017-08-01 惠普发展公司，有限责任合伙企业 Manage the access to ancillary equipment
WO2016170790A1 (en) * 2015-04-23 2016-10-27 パナソニックＩｐマネジメント株式会社 Mounting device
JP6677244B2 (en) * 2015-04-23 2020-04-08 パナソニックＩｐマネジメント株式会社 Mounting device
DE69031705T2 (en) * 1989-11-29 1998-04-02 Toshiba Kawasaki Kk Computer system suitable for connecting an expansion unit
JP2576837B2 (en) * 1994-06-20 1997-01-29 インターナショナル・ビジネス・マシーンズ・コーポレイション Docking device for portable computer
1996-02-20 JP JP03169996A patent/JP3469699B2/en not_active Expired - Fee Related
1996-04-01 TW TW85103989A patent/TW296443B/en active
1996-10-31 US US08/741,586 patent/US5805412A/en not_active Expired - Fee Related
1996-11-15 KR KR1019960055503A patent/KR100245966B1/en not_active IP Right Cessation
1997-01-28 DE DE69721106T patent/DE69721106D1/en not_active Expired - Lifetime
1997-01-28 EP EP19970300480 patent/EP0793164B1/en not_active Expired - Lifetime
EP0793164A3 (en) 1998-12-23
KR100245966B1 (en) 2000-03-02
US5805412A (en) 1998-09-08
EP0793164A2 (en) 1997-09-03
EP0793164B1 (en) 2003-04-23
DE69721106D1 (en) 2003-05-28
KR970062859A (en) 1997-09-12
TW296443B (en) 1997-01-21
JPH09230959A (en) 1997-09-05
EP0689690B1 (en) 1997-01-08 Hardware protection control for computer storage devices
US6883055B2 (en) 2005-04-19 Hot swap method
US6661654B2 (en) 2003-12-09 Computer having option card module latching and drive bay pivot structures