JP2004133542A - Information processor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an information processor capable of transferring data to a transfer destination without starting the entire processor in becoming the transfer source of the data. <P>SOLUTION: When the power source of a PC 10 is turned off and when a power saving mode is set, a hard disk device 21 and an optical disk device 22 are connected to an interface bridge control part 42 and an external drive function mode is set. Then, when the supply of power is instructed by the operation of an HDD button 44 or the main body of the PC 10 is inserted to the frame body 57 of a relay unit 52, the power of the hard disk device 21 and the optical disk device 22 is supplied and direct access and control from an external PC 61 to the hard disk device 21 and the optical disk device 22 are made possible. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an information processing apparatus such as a personal computer or a PDA (Personal Digital Assistants) having an internal device such as a hard disk.
[0002]
[Prior art]
Personal computers (hereinafter referred to as PCs) include a desktop type and a notebook type. In general, desktop PCs are low-cost and high-performance, but not portable. Laptop PCs are portable because they are powered by a battery, but they are desktop-based in terms of performance. Does not reach.
[0003]
This is because a notebook PC uses a battery as a power source and employs low power consumption components that are disadvantageous in terms of performance. It can be said that the laptop PC pursues portability in exchange for performance. In particular, in the case of pursuit of further portability and designed with “always carrying” in mind, the importance of small size, light weight and long battery life is extremely important, the main body itself is light and thin and small, and its performance Could not be expected to improve.
[0004]
For this reason, if the user desires both the performance and the portability of the PC, the user uses the desktop PC in the office or at home, and uses the laptop PC when going out. . In addition, there are situations in which a plurality of PCs are properly used. For example, there is a situation where each user shares one PC and each user owns a PC, and a situation where each PC is used properly according to each work content.
[0005]
By the way, when a plurality of PCs are properly used, data migration between the PCs is frequently performed. For example, data created on a notebook PC when going out may be transferred to a desktop PC, or data created on a desktop PC may be transferred to a notebook PC.
[0006]
Conventionally, in order to transfer data between PCs, a recording medium such as a removable disk medium (floppy disk, MO disk, etc.) or a memory card (compact flash, smart media, etc.) has been used. The method of using this recording medium is to record data on the recording medium on the data transfer source PC side, carry this recording medium from the data transfer source PC to the data transfer destination PC, and execute the data transfer on the data transfer destination PC side. Data is read from the recording medium.
[0007]
There is also a method of linking two PCs and directly transferring data from a transfer source PC to a transfer destination PC. The data transfer between the PCs can be performed by using a communication using a serial cable, a serial communication using infrared rays, a communication conforming to IEEE 1394, a wired LAN, a wireless LAN, Bluetooth (Bluetooth), or the like. By applying these techniques, flexible data transfer becomes possible.
[0008]
Further, there is a method in which the transfer source PC directly accesses the memory of the transfer destination PC, and the transfer destination PC transfers data from the memory of the transfer source PC (see Patent Document 1). When the transfer source PC is connected to the data transfer destination PC via the bus, the bus connection means and the arbitration means disconnect the storage device from the arithmetic device upon the connection of the bus, and connect the storage device to the bus. The processing device of the transfer-destination PC is connected to the storage device via the transfer-destination PC.
[0009]
Here, an example of a conventional PC is shown in FIG. In the PC 100, a CPU (Central Processing Unit) 101 executes various programs, and controls a system memory 102, a display control unit 103, an I / O control unit 104, and the like via a core logic (Core Logic) 105. . The CPU 101, the system memory 102, the display control unit 103, the I / O control unit 104, the core logic 105, and the like are connected via a bus.
[0010]
The bus is a remarkable part of technological progress, and the FSB (Fast Side Bus) related to the CPU 101, the DDR (Double Data Rate) memory interface bus related to the system memory 102, and the AGP related to the display control unit 103 centering on the core logic 105. (Accelerated Graphics Port) bus and Hub-Link related to the I / O control unit 104. Here, a bus related to the CPU 101 is referred to as a processor bus 106a, a bus related to the system memory 102 is referred to as a memory bus 106b, and a bus related to the display control unit 103 and the I / O control unit 104 are referred to as a system bus 106c. In addition, there are a disk bus 106d, an I / O bus 106e, and the like.
[0011]
The system bus 106c is also connected to other devices requiring high-speed operation, such as the LAN control unit 107 and the card bus control unit 108, via the I / O control unit 104. Further, the specifications of the system bus 106c may be different from the boundary of the I / O control unit 104. For example, a Hub-Link is used from the core logic 105 to the I / O control unit 104, and a PCI (Peripheral Component Interconnect) bus is used from the I / O control unit 104 to other devices such as the LAN control unit 107 and the card bus control unit 108. However, the I / O control unit 104 can incorporate a bridge function so that the difference between the specifications of the buses can be absorbed by the I / O control unit 104.
[0012]
The system memory 102 stores various programs and subroutines, a work area, and the like. The CPU 101 executes various programs and subroutines, and the CPU 101 uses the work area.
[0013]
The display control unit 103 receives the display data written by the CPU 101, controls the display device 110 via the display interface in response to the display data, and displays an image indicated by the display data on the screen of the display device 110. The display device 110 is a CRT (Cathode Ray Tube), an LCD (Liquid Crystal Display), or the like. The display interface is a specification corresponding to the type of the display device 110. If the display device 110 is a CRT, it is an analog RGB interface, and if it is an LCD, it is an LVDS interface or the like.
[0014]
The I / O control unit 104 accesses the hard disk device (Hard Disk Drive) 111 and the optical disk device (Optical Disk Drive) 112 via the disk bus 106 d in accordance with the data read request and the data write request from the CPU 101. Of the optical disk of the optical disk device 112 (CD: Compact Disk, DVD: Digital Versatile Disk, etc.).
[0015]
The I / O control unit 104 accesses the LAN control unit 107 and the card bus control unit 108 via the system bus 106c, and instructs these devices to read or write data. Further, the I / O control unit 104 is connected to the keyboard / mouse control unit 113 and the power supply control unit 114 via an I / O bus (ISA: Industry Standard Architecture bus, LPC: Low Pin Count bus, etc.) 106e.
[0016]
The LAN control unit 107 controls connection with a LAN (Local Area Network), and transmits and receives data to and from another terminal device via the LAN.
[0017]
The card bus controller 108 handles a computer system expansion card (a PC card such as a memory card, a modem card, or a LAN card) which is removably inserted into the card socket 115. Perform connection control.
[0018]
The keyboard / mouse control unit 113 is connected to the keyboard 116 and the mouse (pointing device) 117, and outputs input data from the keyboard 116 and the mouse 117 to the CPU 101. Further, the keyboard and mouse control unit 113 plays a role of instructing the power supply control unit 114 to return from the power saving mode in response to the operation of the keyboard 116 and the mouse 117 in the power saving mode.
[0019]
The power control unit 114 is connected to the I / O bus 106e, the power button 118, and the power control unit 119, controls the power control unit 119 in response to the operation of the power button 118, and turns on and off the power of the PC 100. The power control unit 114 controls the power control unit 119 to shift to and return from the power saving mode, and manage charging and discharging of the battery 120.
[0020]
The power control unit 119 is connected to the battery 120 and the power connector 121, and supplies power from the battery 120 or the power connector 121 to the entire PC 100. In the power saving mode, the power is transmitted to a specific portion of the PC 100. Supply only. Further, when power is supplied from the outside via the power connector 121, the battery 120 is charged by the power.
[0021]
FIG. 12 shows a state of the PC 100 when the power of the PC 100 is turned off. Blocks of each device in the active state are shown in white, and blocks of each device in the inactive state are shaded.
[0022]
When the power of the PC 100 is turned off, the power control unit 114, the power button 118, the power control unit 119, the battery 120, and the power connector 121 are in an operating state, and the other devices shaded are in an inactive state.
[0023]
The power of the PC 100 is turned off in response to the turning off of the power button 118, or in response to a request from a program for monitoring the elapsed time after the input operation is interrupted or the decrease in the capacity of the battery 120. When the power is turned off, appropriate termination processing of each device is performed according to the sequence control set immediately before. Thereafter, the power supply control unit 114 shuts off the power of each device shaded in FIG.
[0024]
At this time, the power control unit 119 operates by power from the battery 120 or the power connector 121 and supplies this power to the power control unit 114. The power control unit 114 waits for the power button 118 to be turned on and manages the charge of the battery 120.
[0025]
When power-on is instructed by operating the power button 118 in such a power-off state, the operation of the PC 100 is started in the following procedure.
[0026]
First, when the power button 118 is turned on, in response to this, the power control unit 114 controls the power control unit 119 to supply power from the battery 120 or the power connector 121 to the entire PC 100. In response to the power-on, the CPU 101 reads and executes an initial program from a non-volatile area of the system memory 102 (which may be connected to a bus different from the memory bus 106b), and executes various programs mainly from the hard disk device 111. The program is read, each program is stored in the system memory 102, and the system memory 102, the hard disk device 111, the optical disk device 112, the display control unit 103, the LAN control unit 107 are stored in accordance with each program and input data from the keyboard 116 and the mouse 117. , And reads and writes data from and to each device such as the card bus control unit 108, and fulfills the role of the PC 100.
[0027]
FIG. 13 shows the state of the PC 100 in the power saving mode, in which the blocks of the devices in the operating state are outlined and the blocks of the devices in the non-operating state are shaded.
[0028]
As is clear from FIG. 13, the CPU 101, the display control unit 103, the display device 110, the hard disk device 111, and the optical disk device 112 are in a non-operation state. Here, in order to respond to a return request from the outside through the LAN or the expansion card of the card socket 115, the power of the LAN control unit 107 and the card bus control unit 108 is not shut off. If there is no response, the power of each of the control units 107 and 108 may be cut off.
[0029]
In a general PC, a power saving mode is often set. In this power saving mode, the power consumption of the PC 100 is reduced by cutting off the power of some devices. This power saving mode is started in response to an instruction by operating the power button 118, or started in response to a request from a program for monitoring the elapsed time since the input operation was interrupted or a decrease in the capacity of the battery 120. You. When starting the power saving mode, first, the CPU 101, the core logic 105, and the I / O control unit 104, according to a preset sequence control, store the data in the system memory 102 or the hard disk device 111 capable of storing each data even in the power saving mode. And save it. Thereafter, the power control unit 114 controls the power control unit 119 to shut off the power of the CPU 101, the display control unit 103, the display device 110, the hard disk device 111, and the optical disk device 112.
[0030]
To return from the power saving mode, the operation of the power button 118 is detected by the power supply control unit 114, or a return request from the outside via the LAN or the expansion card in the card socket 115 is issued by the keyboard / mouse control unit 113 or the I / O When detected by the power control unit 114 through the O control unit 104, the detection is performed under the control of the power control unit 114.
[0031]
When detecting the operation of the power button 118 or the external return request, the power control unit 114 controls the power control unit 119 to supply the power from the battery 120 or the power connector 121 to the entire PC 100. The CPU 101, the core logic 105, and the I / O control unit 104 read the respective data saved at the start of the power saving mode from the system memory 102 and the hard disk device 111, and perform respective operations immediately before the start of the power saving mode. The state is set, and the operation of the PC 100 is restarted.
[0032]
Now, assuming the PC 100 having such a configuration, if the data transfer between the PCs 100 is performed using the recording medium as described above, the memory card 131 is transferred to the data transfer source as shown in FIG. Of the PC 100, and instructs data writing by operating the keyboard 116 and the mouse 117. When data writing is instructed, the data transfer source PC 100 starts a program for writing data, reads data to be written from the hard disk device 111, and sends the data to the card bus control unit 108. Write to the memory card 131 via the The memory card 131 is carried from the data transfer source PC 100 to the other data transfer destination PC 100, and the memory card 131 is inserted into the card socket 115 of the other data transfer destination PC 100, and the keyboard 116 and the mouse 117 are operated. Instructs data reading. When the other PC 100 at the data transfer destination is instructed to read the data, it starts a program for reading the data, reads the data from the memory card 131 via the card bus control unit 108, and reads the data from the hard disk. Write to device 111.
[0033]
When data is directly transferred from the transfer source PC 100 to the transfer destination other PC 100, for example, each of the PCs 100 is activated, and the respective LAN control units 107 are connected via the cable 132. The shared devices (the hard disk device 111 and the optical disk device 112) are mutually recognized, and data transfer is instructed by operating one of the keyboard 116 and the mouse 117. Thus, the data transfer programs of the respective PCs 100 cooperate to transfer the data to be transferred from the data transfer source hard disk device 111 or the optical disk device 112 to the data transfer destination hard disk device 111 or the optical disk device 112. Will be transferred.
[0034]
Furthermore, if the technology of Patent Document 1 is applied, the hard disk device 111 or the optical disk device 112 of the transfer source PC 100 is controlled by the transfer source PC 100 via the cable 132 to control the I / O of another transfer destination PC 100. It is connected to the control unit 104 and enables direct access to the hard disk device 111 and the optical disk device 112 from the CPU 101 of the transfer destination PC 100.
[0035]
[Patent Document 1]
JP-A-10-105504
[0036]
[Problems to be solved by the invention]
By the way, a method of transferring data between PCs using a recording medium as in the above-described conventional method, a method of transferring data between PCs, and a method of directly accessing a transfer source memory by a transfer destination PC. In either method of transferring data from the memory, it is necessary to turn on the power of both the transfer source PC and the transfer destination PC and start up the system of each PC.
[0037]
For example, neither the method of transferring data between PCs using a recording medium or the method of transferring data between PCs cannot be executed without turning on the power of each PC. . Also, in the method disclosed in Patent Document 1 in which a transfer destination PC directly accesses a transfer source memory and transfers data from the memory, arbitration is performed between the PCs in advance, and storage of the transfer source PC is performed. Since the apparatus is connected to the transfer destination PC, it cannot be executed unless the power of each PC is turned on.
[0038]
However, if the power of each PC is turned on and the system of each PC is started when data is transferred between the PCs as described above, there is a problem that much trouble and time are required, and the usability is poor. Was.
[0039]
For example, when a notebook PC is brought back to the office and data created by the notebook PC is transferred to a desktop PC, the notebook PC is turned on only for data transfer, and the notebook PC is turned on. PC system had to be launched. In particular, when software such as “Windows-OS” which is generally widely used is used, it takes a long time to start and stop the PC system, and such a long time is required only for data migration. Spending was extremely inconvenient.
[0040]
In the case of the technique disclosed in Patent Document 1, the storage device of the transfer source PC is moved from the I / O control device of the transfer source PC to the transfer destination PC when the connection between the transfer source PC and the transfer destination PC is triggered. It is necessary to switch and connect to the I / O control device of the PC, but arbitration processing is required when switching the connection destination of the storage device because the transfer source PC itself uses its own storage device. And complicated control is required.
[0041]
Further, although no particular reference is made to the configuration and mechanism for connecting the storage device of the transfer source PC to the transfer source I / O control device again, it is necessary to consider it in the actual system design. In order to realize this point, it is necessary to adopt a relatively complicated configuration and mechanism.
[0042]
In view of the above, the present invention has been made in view of the above-described conventional problems, and is an information capable of transferring data to a transfer destination without starting up the entire apparatus when the data is transferred. When the processing device is provided and the power supply of the transfer source PC is not turned on, the storage device of the transfer source PC is connected to the transfer destination PC (external interface), and the power supply of the transfer source PC is turned on. An object of the present invention is to enable a simple system configuration in which a storage device of a transfer source PC is connected to an I / O control device of the transfer source PC.
[0043]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, the present invention provides an information processing apparatus including a processing unit for processing data, an internal device controlled by the processing unit, and a bus connecting the processing unit and the internal device. An interface for external connection and an internal device connected to the bus when power is supplied to the arithmetic means, the internal device is disconnected from the interface, and the internal device is disconnected from the bus when power is not supplied to the arithmetic means. Connection switching means for connecting the device to the interface.
[0044]
According to the present invention having such a configuration, the internal device is connected to the bus and the internal device is disconnected from the interface when power is supplied to the arithmetic unit. At this time, the arithmetic unit is in an operating state by power supply, can access an internal device via the bus, and can use the internal device. In addition, when power is not supplied to the arithmetic unit, the internal device is disconnected from the bus and the internal device is connected to the interface. At this time, the arithmetic means is in a non-operating state, and the internal device can be accessed and controlled from the outside via the interface. For example, if the internal device is a hard disk device and data is stored in the hard disk device, the hard disk device can be accessed from the outside via an interface, and data can be transferred from the hard disk device to the outside. Also, unlike the start-up time of the entire system, the time required for starting up only the internal device such as a hard disk drive is short, so that no time or effort is required.
[0045]
Further, in order to prevent accidental activation of the system during transportation, the notebook PC is usually provided in a place where the power button can be pressed only when the display panel is open. For example, as shown in FIG. Since the PC 10 is inserted into the relay unit 52 with the display panel closed, the power button cannot be touched when the PC 10 is inserted into the relay unit 52. The state of whether power is supplied to the storage device does not change, and a request to switch the connection destination of the storage device does not occur. That is, complicated arbitration control is unnecessary, and the connection of the storage device is simply performed according to the power-on state of the arithmetic device. It is possible to realize a system in which the previous switching can be performed.
[0046]
Further, in the present invention, when shifting from the power supply to the arithmetic unit to the non-power supply for power saving, the state of the arithmetic unit or the internal device is saved, and the internal device is disconnected from the bus. When connecting the internal device to the interface and returning from non-power supply to power supply for power saving, connect the internal device to the bus and disconnect the internal device from the interface, and then connect the internal device to the arithmetic unit or internal device. The state has been restored.
[0047]
As described above, when the transition to the non-power supply for power saving and the return from the non-power supply to the power supply for power saving, the power supply is interrupted by performing each preset procedure. Also, the operation of the calculating means and the internal device can be continued.
[0048]
Further, in the present invention, the interface connects between the internal device and the external power supply line.
[0049]
When data is transferred via an interface, a power supply for operating the storage device is required. Since the interface connector is provided with the power supply line, the data transfer signal and the power can be supplied by one-touch connection of the interface connector. For example, only the PC 10 is inserted into the power-supplied relay device 52. Thus, it is possible to realize a convenient system in which a power supply and a signal for data transfer can be simultaneously connected.
[0050]
By connecting the internal device and the external power supply line with the interface as described above, power supply to the internal device can be reliably and easily performed.
[0051]
Further, the present invention includes a secondary battery and charging means for charging the secondary battery through an interface from an external power supply line.
[0052]
By providing the function of charging the secondary battery with the power supplied through the interface in this way, for example, only by inserting the PC 10 into the relay unit, the PC 10 is charged while performing data transfer. The system can be realized.
[0053]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
[0054]
FIG. 1 is a block diagram showing an embodiment of the information processing apparatus of the present invention. The information processing apparatus according to the present embodiment is a personal computer (hereinafter, referred to as a PC) 10 and includes a CPU 11. The CPU 11 executes various programs and controls the system memory 12, the display control unit 13, the I / O control unit 14, and the like via the core logic 15. The CPU 11, the system memory 12, the display control unit 13, the I / O control unit 14, the core logic 15, and the like are connected via a bus.
[0055]
Here, a bus related to the CPU 11 is referred to as a processor bus 16a, a bus related to the system memory 12 is referred to as a memory bus 16b, and a bus related to the display control unit 13 and the I / O control unit 14 are referred to as a system bus 16c. In addition, there are a disk bus 16d and an I / O bus 16e.
[0056]
The system bus 16c is also connected to other devices such as a LAN control unit 17 and a card bus control unit 18 via the I / O control unit 14.
[0057]
The system memory 12 stores various programs and subroutines, a work area, and the like. The CPU 11 executes various programs and subroutines, and the CPU 11 uses the work area.
[0058]
The display control unit 13 receives the display data written by the CPU 11, controls the display device 20 via the display interface in response to the data, and displays an image indicated by the display data on the screen of the display device 20. The display device 20 is a CRT, an LCD, or the like.
[0059]
The I / O control unit 14 accesses the hard disk device 21 or the optical disk device 22 via the disk bus 16d in accordance with a data read request or a data write request from the CPU 11, and instructs reading or writing of data to or from the hard disk of the hard disk device 21. Or instructs the optical disk device 22 to read or write data on the optical disk.
[0060]
The I / O control unit 14 accesses the LAN control unit 17 and the card bus control unit 18 via the system bus 16c, and instructs these control units 17 and 18 to read and write data. Further, the I / O control unit 14 is connected to the keyboard / mouse control unit 23 and the power supply control unit 24 via the I / O bus 16e.
[0061]
The LAN control unit 17 controls connection with the LAN, and transmits and receives data to and from other terminal devices via the LAN.
[0062]
The card bus control section 18 handles a computer system expansion card (a PC card such as a memory card, a modem card, or a LAN card) which is removably inserted into the card socket 25. Perform connection control.
[0063]
The keyboard / mouse control unit 23 is connected to a keyboard 26 and a mouse (pointing device) 27 and outputs input data from the keyboard 26 and the mouse 27 to the CPU 11. The keyboard / mouse control unit 23 plays a role of instructing the power control unit 24 to return from the power saving mode in response to the operation of the keyboard 26 and the mouse 27 in the power saving mode.
[0064]
The power control unit 24 is connected to the I / O bus 16e, the power button 28, and the power control unit 29, controls the power control unit 29 in response to the operation of the power button 28, and turns on and off the power of the PC 10. In addition, the power control unit 24 controls the power control unit 29 to shift to and return from the power saving mode and manage charging and discharging of the battery 30.
[0065]
The power saving mode is started in response to an instruction from the operation of the power button 28, or is started in response to a request from a program for monitoring the elapsed time since the input operation was interrupted or a decrease in the capacity of the battery 30. . Further, the return from the power saving mode is performed in response to an instruction by operating the power button 28, or in response to a return request from the outside via a LAN or an expansion card in the card socket 25.
[0066]
The power control unit 29 is connected to the battery 30 and the power connector 31, receives power from the battery 30 or power from the outside via the power connector 31, and distributes and supplies the power to the entire PC 10. In the power saving mode, the power control unit 29 supplies power only to a specific portion of the PC 10 to reduce power consumption. Further, when power is supplied from outside via the power connector 31 or the relay connector 45, the power control unit 29 charges the battery 30 with the power.
[0067]
The configuration of the PC 10 described so far is a general one. The PC 10 according to the present embodiment includes a bus selector 41, an interface bridge controller 42, an interface bus connector 43, an HDD button 44, and a relay connector 45 in addition to the above configuration. Further, the power control unit 29 has a function corresponding to the HDD button 44 and the relay connector 45.
[0068]
The bus selection unit 41 is controlled by the power supply control unit 24, and connects and disconnects the disk bus 16d of the hard disk device 21 and the optical disk device 22. When the power of the PC 10 is on, the disk bus 16d of the hard disk device 21 and the optical disk device 22 is connected to the I / O control unit 14 via the bus selector 41, and the disk bus 16d of each of the devices 21 and 22 is connected to the interface bridge. It is separated from the control unit 42. When the power of the PC 10 is off, the disk bus 16 d of the hard disk device 21 and the optical disk device 22 is disconnected from the I / O control unit 14, and the disk bus 16 d of each of the devices 21 and 22 is connected via the bus selection unit 41. It is connected to the interface bridge control unit 42.
[0069]
Similarly, when the power of the PC 10 is turned on by returning from the power saving mode and the power of the PC 10 is turned off by the power saving mode, the power control unit 24 controls the bus selection unit 41.
[0070]
Hereinafter, a state in which the power of the PC 10 is turned off and the disk bus 16d of the hard disk device 21 and the optical disk device 22 is connected to the interface bridge control unit 42 is referred to as an external drive function mode.
[0071]
The interface bridge controller 42 is connected to the bus selector 41, the interface bus connector 43, and the relay connector 45. When the interface bridge control unit 42 is connected to the disk bus 16d via the bus selection unit 41, the interface bridge control unit 42 determines the difference in specifications between the external bus connected via the interface bus connector 43 and the relay connector 45 and the disk bus 16d. Absorb.
[0072]
For example, if the external bus is a USB (Universal Serial Bus) and the disk bus 16d is an ATAPI bus, the interface bridge control unit 42 converts the specifications of the ATAPI bus into USB specifications. As a result, the hard disk device 21 and the optical disk device 22 are externally recognized as USB devices via the interface bus connector 43 or the relay connector 45. Note that a USB 2.0 or IEEE 1394 bus or the like may be used instead of the USB.
[0073]
The HDD button 44 is operated when the external PC 61 is connected to the interface bus connector 43 via the external bus 51 as shown in FIG. 2, and the hard disk device 21, the optical disk device 22, and related devices (for example, the interface bridge controller 42) Etc.) for turning on and off the power.
[0074]
When the power of the PC 10 is turned off, the hard disk device 21 and the optical disk device 22 are connected to the interface bridge controller 42 and are in the external drive function mode. However, even in the external drive function mode, data transfer from the hard disk device 21 or the optical disk device 22 to the external PC 61 as described later is not necessarily performed. It is uneconomical to turn on the power of the device 21 and the optical disk device 22. Therefore, the hard disk device 21 and the optical disk device 22 are turned on only when the power is turned on by the operation of the HDD button 44 in the external drive function mode, and the respective devices 21 and 22 are turned on. Enables data transfer.
[0075]
When the power supply control unit 24 sets the external drive function mode by controlling the bus selection unit 41 when the power of the PC 10 is turned off, the power control unit 24 notifies the power control unit 29 of this mode. The power control unit 29 turns on the power of the hard disk device 21 and the optical disk device 22 when a signal indicating an ON operation of the HDD button 44 is input in a state where the external drive function mode is set. When the power control unit 29 receives a signal indicating an operation of turning off the HDD button 44, the power supply of the hard disk device 21 and the optical disk device 22 is shut off.
[0076]
The relay connector 45 is connected to the connector 53 of the relay unit 52. The relay unit 52 relays the PC 10 and the external PC 61 instead of connecting the external PC 61 to the interface bus connector 43 via the external bus 51. The relay unit 52 includes a connector 53 connected to a relay connector 45 of the PC 10 via an external bus (USB bus) 62, an interface bus connector 54 connected to an external PC 61 via an external bus (USB bus) 63, and A power connector 55 and the like connected to the external power supply line 64 are provided.
[0077]
Also, the relay unit 52 relays an external power supply line 64 to the relay connector 45 of the PC 10 via the power connector 55 and the connector 53, and controls power from the outside via the relay unit 52 and the relay connector 45. To the unit 29. Therefore, the power control unit 29 can receive not only the power supply from the battery 30 and the power connector 31 but also the power supply from the relay unit 52.
[0078]
As described above, the power control unit 24 of the PC 10 sets the external drive function mode when the power of the PC 10 is turned off, and notifies the power control unit 29 of this mode. When the power control unit 29 detects that the connector 53 of the relay unit 52 has been connected through the relay connector 45, the power control unit 29 turns on the power of the hard disk device 21 and the optical disk device 22. When the power control unit 29 cannot detect that the connector 53 of the relay unit 52 has been connected, the power control unit 29 shuts off the power of the hard disk device 21 and the optical disk device 22.
[0079]
Therefore, when the power of the PC 10 is turned off and the PC 10 is connected to the relay unit 52, the power of the hard disk device 21 and the optical disk device 22 is turned on without operating the HDD button 44.
[0080]
3A and 3B are a plan view and a side view of the relay unit 52. FIG. As is clear from FIG. 3, the relay unit 52 includes a support plate 56 and a frame 57 provided on the support plate 56, and the connector 53 is disposed on a portion of the support plate 56 surrounded by the frame 57. The interface bus connector 54 and the power connector 55 are arranged on the back side of the frame 57. An external bus 63 is connected to the interface bus connector 54, and an external power supply line 64 is connected to the power connector 55.
[0081]
FIG. 4 is a side view showing the appearance of the PC 10. As is clear from FIG. 4, an interface bus connector 43, a relay connector 45, and an HDD button 44 are arranged on the side surface of the main body of the PC 10.
[0082]
As shown in FIGS. 5A and 5B, the main body of the PC 10 is inserted into the frame 57 of the relay unit 52 with the main body side on which the interface bus connector 43 and the like are arranged facing downward. At this time, the position of the main body of the PC 10 is regulated by the frame 57, the interface bus connector 43 on the side surface of the main body of the PC 10 faces the connector 53 of the relay unit 52, and the interface bus connector 43 and the connector 53 are fitted and connected. Is done.
[0083]
Therefore, the PC 10 is connected to the relay unit 52 by an operation of inserting the main body of the PC 10 into the frame 57 of the relay unit 52. Therefore, when the main body of the PC 10 is inserted into the frame 57 of the relay unit 52 after the power of the PC 10 is turned off, the power supply of the hard disk device 21 and the optical disk device 22 can be performed even if the HDD button 44 is not operated. Will be performed. At the same time, the relay connector 45 of the PC 10 is connected to the external PC 61 via the external bus 62, the connectors 53 and 54 of the relay unit 52, and the external bus 63. That is, by simply inserting the main body of the PC 10 into the frame 57 of the relay unit 52, the power of the hard disk device 21 and the optical disk device 22 is turned on, and the connection between the PC 10 and the external PC 61 is made.
[0084]
FIG. 6 shows a state of the PC 10 when the power of the PC 10 is turned on. Blocks of each device in the operating state are shown in white, and blocks of each device in the non-operating state are shaded.
[0085]
When the power of the PC 10 is turned on, the interface bridge control unit 42, the interface bus connector 43, the HDD button 44, and the relay connector 45 are in an inactive state, and the other outlined devices are in an active state.
[0086]
At this time, the hard disk device 21 and the optical disk device 22 are connected to the I / O control unit 14 via the bus selection unit 41, and the devices 21 and 22 are disconnected from the interface bridge control unit 42. Of course, the same connection and disconnection are performed when the power of the PC 10 is turned on by returning from the power saving mode.
[0087]
In this state, the hard disk device 21 and the optical disk device 22 can be accessed inside the PC 10, and the normal operation of the PC 10 is possible.
[0088]
FIG. 7 shows the state of the PC 10 when the power of the PC 10 is turned off. The blocks of each device in the operating state are outlined, and the blocks of each device in the non-operating state are shaded.
[0089]
When the power of the PC 10 is turned off, the power control unit 24, the power button 28, the power control unit 29, the battery 30, the power connector 31, the bus selection unit 41, the interface bridge control unit 42, the interface bus connector 43, the HDD button 44, and The relay connector 45 and the like are in the operating state, and the other devices shaded are in the inactive state.
[0090]
At this time, the external drive function mode is set, the hard disk device 21 and the optical disk device 22 are connected to the interface bridge control unit 42 via the bus selection unit 41, and the devices 21 and 22 are disconnected from the I / O control unit 14. It is.
[0091]
In the external drive function mode, when power-on is instructed by operating the HDD button 44, the power of the hard disk device 21 and the optical disk device 22 is turned on, and data transfer from the interface bus connector 43 to the external PC 61 is enabled. . Alternatively, even when the main body of the PC 10 is inserted into the frame 57 of the relay unit 52, the power supply of the hard disk device 21 and the optical disk device 22 is turned on, and the data transfer from the relay connector 45 to the external PC 61 is enabled.
[0092]
FIG. 8 shows the state of the PC 10 in the power saving mode, in which blocks of each device in the operating state are shown in white and blocks of each device in the non-operating state are shaded.
[0093]
In the power saving mode, the CPU 11, the display control unit 13, and the display device 20 are in a non-operation state, and the other devices in outline are in operation states.
[0094]
When starting the power saving mode, the power saving mode is set after the data of the CPU 11, the core logic 15, and the I / O control unit 14 are saved, and the hard disk device 21 and the optical disk device 22 are set to the I / O mode. The devices 21 and 22 are disconnected from the control unit 14 and connected to the interface bridge control unit 42, and the external drive function mode is set.
[0095]
Conversely, when returning from the power saving mode, after the hard disk device 21 and the optical disk device 22 are connected to the I / O control unit 14 and the respective devices 21 and 22 are disconnected from the interface bridge control unit 42, And the respective data of the CPU 11, the core logic 15, and the I / O control unit 14 are restored.
[0096]
Next, the connection switching control of the hard disk device 21 and the optical disk device 22 by the power control unit 24 will be described with reference to the flowchart of FIG.
[0097]
First, when the power of the PC 10 is off, the power control unit 24 connects the hard disk device 21 and the optical disk device 22 to the interface bridge control unit 42 via the bus selection unit 41 (step S70), and operates the power button 28. Waiting for an instruction to turn on the PC 10 ("No" in step S71).
[0098]
When there is an instruction to turn on the power of the PC 10 by operating the power button 28 (“Yes” in step S71), in response to this, the power control unit 24 controls the power control unit 29 to turn on the power of the PC 10. Turn on and set the state of FIG. Then, the power supply control unit 24 controls the bus selection unit 41 to connect the hard disk device 21 and the optical disk device 22 to the I / O control unit 14 and disconnects the devices 21 and 22 from the interface bridge control unit 42 ( Step S72). Thus, the normal operation state of the PC 10 is set.
[0099]
In this normal operation state, the operation waits for an instruction to turn off the power of the PC 10 by operating the power button 28 or the start of the power saving mode (“No” in step S73).
[0100]
For example, if there is an instruction to turn off the power of the PC 10 by operating the power button 28 (“Yes” in step S73), the power control unit 24 controls the power control unit 29 in response to the instruction to turn off the power of the PC 10. Turn off and set the state of FIG. 7 (step S74). Further, the power supply control unit 24 controls the bus selection unit 41 to connect the hard disk device 21 and the optical disk device 22 to the interface bridge control unit 42, and disconnects the devices 21 and 22 from the I / O control unit 14, The external drive function mode is set (step S75), and the process returns to step S71.
[0101]
In the state in which the external drive function mode is set, when the power on is instructed by operating the HDD button 44 or when the main body of the PC 10 is inserted into the frame 57 of the relay unit 52, the hard disk device 21 and the optical disk device 22 Is turned on. When the external PC 61 is connected to the interface bus connector 43 or the external PC 61 is connected to the relay connector 45 via the relay unit 52, the external PC 61 is connected to the hard disk device 21 and the optical disk device 22 via the interface bridge controller 42. Is done. At this time, the external PC 61 can directly access and control the hard disk device 21 and the optical disk device 22, and can read and write data from the respective devices 21 and 22.
[0102]
On the other hand, when the start of the power saving mode is instructed (step S76), the CPU 11, the core logic 15, and the I / O control unit 14 can store each data in the power saving mode according to a preset sequence control. Is stored in the system memory 12 or the hard disk device 21 and saved. Thereafter, the power control unit 24 controls the power control unit 29 to shut off the power of the CPU 11, the display control unit 13, and the display device 20, and sets the state of the power saving mode of FIG. 8 (step S77). ). Then, the power supply control unit 24 controls the power control unit 29 to connect the hard disk device 21 and the optical disk device 22 to the interface bridge control unit 42, and disconnects the devices 21 and 22 from the I / O control unit 14, The external drive function mode is set (step S78).
[0103]
In the state where the external drive function mode is set, as described above, when the power-on is instructed by operating the HDD button 44 or when the main body of the PC 10 is inserted into the frame 57 of the relay unit 52, the hard disk The power of the device 21 and the optical disk device 22 is turned on, so that the external PC 61 can directly access the hard disk device 21 and the optical disk device 22 and perform read / write control.
[0104]
In the state of the power saving mode, it is on standby to return from the power saving mode ("No" in step S79). When the return from the power saving mode is instructed (“Yes” in step S79), the power supply control unit 24 controls the bus selection unit 41 to send the hard disk device 21 and the optical disk device 22 to the I / O control unit 14. Then, the respective devices 21 and 22 are disconnected from the interface bridge controller 42 (step S80), and the power controller 29 is controlled to turn on the power of the PC 10. Thereafter, the CPU 11, the core logic 15, and the I / O control unit 14 read the respective data saved at the start of the power saving mode from the system memory 12 and the hard disk device 21 according to a preset sequence control. Then, the respective operation states immediately before the start of the power saving mode are set, and the operation of the PC 10 is restarted (step S81). Thereafter, the process returns to step S73.
[0105]
As described above, in the present embodiment, when the power of the PC 10 is turned off and when the power saving mode is set, the hard disk device 21 and the optical disk device 22 are connected to the interface bridge control unit 42 and the external drive function is connected. When the power is turned on by operating the HDD button 44 or the main body of the PC 10 is inserted into the frame 57 of the relay unit 52, the hard disk device 21 and the optical disk device 22 are set. Is turned on to enable direct access and control of the hard disk device 21 and the optical disk device 22 from the external PC 61. FIG. 10 conceptually shows the PC 10 of the present embodiment. As shown in FIG. 10, the external PC 61 can directly control the hard disk device 21 and the optical disk device 22 by treating the hard disk device 21 and the optical disk device 22 of the PC 10 as a virtual own peripheral device 65.
[0106]
Therefore, without turning on the power of the PC 10 and taking a long time to start up the system of the PC 10, only the hard disk drive 21 and the optical disc drive 22 are started up in a short time, and the internal The data can be transferred to the external PC 61. Further, the power consumption of the PC 10 at this time is only the power consumption of the devices 21 and 22.
[0107]
Note that the present invention is not limited to the above-described embodiment, and can be variously modified. For example, another type of bus may be applied as a bus in the PC 10. In addition, the CPU 11 and the core logic 15 may be integrated, the core logic 15 and the I / O control unit 14 may be integrated, or the core logic 15 and the display control unit 13 may be integrated. Furthermore, the hard disk device 21 and the optical disk device 22 are illustrated as internal devices of the PC 10 directly controlled by the external PC 61, but other types of internal devices such as an audio device for inputting and outputting audio may be used. Absent.
[0108]
【The invention's effect】
As described above, according to the present invention, the internal device is disconnected from the bus and the internal device is connected to the interface at the time of non-power supply to the arithmetic means. At this time, the internal device is externally connected via the interface. Can be accessed and controlled. For this reason, it is possible to start up the internal device in a short time and control only the internal device without having to start up the entire information processing apparatus over a long time.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating an embodiment of an information processing apparatus according to the present invention.
FIG. 2 is a perspective view showing a state where the information processing apparatus of FIG. 1 is connected to an external personal computer via an external bus.
FIGS. 3A and 3B are a plan view and a side view showing the appearance of a relay unit for relay-connecting the information processing apparatus of FIG. 1 to an external personal computer.
FIG. 4 is a side view showing the appearance of the information processing apparatus of FIG. 1;
FIGS. 5A and 5B are perspective views showing a state where the information processing apparatus of FIG. 1 is inserted into a relay unit.
FIG. 6 is a block diagram illustrating a power-on state of the information processing apparatus of FIG. 1;
FIG. 7 is a block diagram illustrating a power-off state of the information processing apparatus of FIG. 1;
FIG. 8 is a block diagram showing a state of the information processing apparatus of FIG. 1 in a power saving mode.
FIG. 9 is a flowchart illustrating a control process by a power supply control unit of the information processing apparatus of FIG. 1;
FIG. 10 is a perspective view conceptually showing a relationship between the information processing apparatus of FIG. 1 and an external personal computer.
FIG. 11 is a block diagram showing a conventional personal computer.
FIG. 12 is a block diagram showing a state in which the power supply of the PC in FIG. 11 is off.
FIG. 13 is a block diagram illustrating a state of a power saving mode of the PC in FIG. 11;
FIG. 14 is a perspective view conceptually showing data transfer by the PC in FIG. 11;
[Explanation of symbols]
10 Personal computer (PC)
11 CPU
12 System memory
13 Display control unit
14 I / O control unit
15 core logic
16a-16e bus
17 LAN control unit
18 Card bus controller
20 Display device
21 Hard Disk Drive
22 Optical disk drive
23 Keyboard and mouse controller
24 Power control unit
25 Card Socket
26 Keyboard
27 mouse
28 Power Button
29 Power control unit
30 Battery
31 Power Connector
41 Bus selection section
42 Interface Bridge Controller
43 Interface bus connector
44 HDD button
45 Relay connector
52 Relay unit
53 Connector
54 Interface Bus Connector
55 power connector

Claims (4)

In an information processing apparatus including a computing unit that processes data, an internal device controlled by the computing unit, and a bus that connects the computing unit and the internal device,
An interface for externally connecting internal devices,
Connection switching for connecting the internal device to the bus and disconnecting the internal device from the interface when supplying power to the arithmetic means, and disconnecting the internal device from the bus and connecting the internal device to the interface when non-power is supplied to the arithmetic means And an information processing apparatus. When shifting from power supply to the arithmetic means to non-power supply for power saving, the state of the arithmetic means or the internal device is evacuated, then the internal device is disconnected from the bus, and the internal device is connected to the interface. ,
When returning from non-power supply to power supply for power saving, connect the internal device to the bus, disconnect the internal device from the interface, and then restore the state of the arithmetic means or the internal device. The information processing apparatus according to claim 1, wherein The information processing apparatus according to claim 1, wherein the interface connects between the internal device and an external power supply line. The information processing apparatus according to claim 3, further comprising: a secondary battery; and charging means for charging the secondary battery through an interface from an external power supply line.

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