JP2004362024A - Usb storage equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide USB storage equipment that can suppress an increase in manufacturing man-hour or development man-hour requirements due to the addition of a direct copying function. <P>SOLUTION: The USB storage equipment 10 comprises an HDD unit 110 that is an IDE device, a USB-IDE bridge 120 capable of USB-connecting the HDD unit 110 as a USB device, a USB host controller 141 USB-connected as a USB host to the HDD unit 110, a USB host controller 142 USB-connectable as a USB host to USB device equipment 70, and a CPU 150 for controlling the USB connections by the USB host controllers 141 and 142 to execute direct copying. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a USB (Universal Serial Bus) storage device.
[0002]
[Prior art]
A USB storage device, which is a USB device device, is equipped with a storage unit such as a hard disk drive (hereinafter, referred to as an HDD), and is a USB host device such as a USB-connected personal computer (Personal Computer, hereinafter, referred to as a PC). From the storage unit. Conventionally, there has been a USB storage device that stores data from another USB device device such as a USB-connected digital camera in a storage unit (so-called direct copy) without using a USB host device. This USB storage device has a USB host function by itself, thereby enabling USB connection with another USB device device and realizing direct copy.
[0003]
The following document describes a USB device having a USB host function for making a USB connection with another USB device.
[Patent Document 1]
Japanese Patent Application Laid-Open No. 2002-55936
Here, a USB storage device 90 will be described as a conventional USB storage device. FIG. 6 is an explanatory diagram showing the internal configuration of a conventional USB storage device 90. The USB storage device 90 is a USB device device that stores data transferred by USB from the USB device device 70 and the USB host device 80. The USB storage device 90 includes an HDD unit 910 that stores data transferred by IDE (Intelligent Drive Electronics), a USB-IDE bridge 920 that performs protocol conversion between USB and IDE, and an IDE connection to the HDD unit 910 as an IDE host. RAM, which is a main memory of an IDE host controller 930, a USB host controller 940 that performs USB connection as a USB host to the USB device device 70, a CPU (Central Processing Unit) 950 that performs various controls in the USB storage device 90, and a CPU (950) ROM (Random Access Memory) 960 and a ROM (Re) for storing data such as programs executed by the CPU 950. d Only Memory) 970, a switch 981 for receiving an input of a direct copy instruction, an LED (Light Emitting Diode) 982, 983 for displaying an operation state, a USB-A port 991, for receiving a USB connection from the USB device 70, a USB A USB-B port 992 for receiving a USB connection from the host device 80 is provided.
[0005]
The ROM 970 stores USB command firmware and IDE command firmware. The USB command firmware is a program for the CPU 950 to issue a USB command to the USB host controller 940, and the IDE command firmware is a program for the CPU 950 to issue an IDE command to the IDE host controller 930. The CPU 950 reads and executes these programs from the ROM 970 to the RAM 960, thereby controlling data exchange with the USB device 70 via the USB host controller 940, and controlling data exchange with the HDD unit 910 via the IDE host controller 930. Control communication.
[0006]
When the USB storage device 90 makes a USB connection with the USB device device 70, by controlling the USB connection to read data stored in the USB device device 70 and controlling the IDE connection to write data to the HDD unit 910, The direct copy with the USB device 70 is performed. On the other hand, when the USB storage device 90 is connected to the USB host device 80 via the USB, the USB host device 80 and the HDD unit 910 are connected via the USB-IDE bridge 920, so that the USB storage device 90 Is stored in the HDD unit 910.
[0007]
[Problems to be solved by the invention]
A conventional USB storage device needs to control a USB connection and an IDE connection at the time of direct copy, and thus requires hardware and software based on two types of interfaces. As a result, at the time of manufacturing a USB storage device, there is a problem that the number of manufacturing steps increases because these hardware and software are incorporated. In addition, storage units that are IDE devices have various specifications having different driving voltages, data transfer, and the like. Therefore, it is necessary to take measures for each of these various specifications. As a result, when developing a USB storage device, there is a problem that the number of development steps increases due to measures for each specification.
[0008]
The present invention has been made to solve the above-described problems, and has as its object to provide a USB storage device capable of suppressing an increase in the number of manufacturing steps or development steps by adding a direct copy function. I do.
[0009]
[Means for Solving the Problems and Their Functions and Effects]
In order to solve the above-described problem, a USB storage device of the present invention is a USB storage device that stores data transferred by USB from a USB device connected via USB as a USB device in a nonvolatile manner, and is different from USB. Storage means for storing data transferred by the interface of the present invention, and the storage means is connected as a USB device by connecting the storage means with the other interface and performing protocol conversion between USB and the other interface. A first USB host unit that makes a USB connection to the storage unit via the bridge unit as a USB host, and a second USB unit that makes a USB connection to the USB device as a USB host. of An SB host unit; and a transfer control unit that controls USB connection by the first and second USB host units to transfer data between the USB device and the storage unit. And
[0010]
According to such a USB storage device, the transfer control unit can exchange data with the USB device device and the storage unit by controlling the USB connection. As a result, there is no need to provide hardware and software based on the interface of the storage means in order to add a data transfer function between the USB device and the storage means. The bridge means absorbs the characteristics of each specification of the storage means and converts the protocol into USB, and the transfer control means controls the USB connection with the bridge means to exchange data with the storage means. Can be. As a result, it is not necessary to take measures for each specification of the storage means in order to add a function of transferring data between the USB device and the storage means. Therefore, it is possible to suppress an increase in the number of manufacturing steps or development steps due to adding a data transfer function between the USB device and the storage means to the USB storage.
[0011]
The USB storage device of the present invention having the above configuration can adopt the following aspects. The transfer control unit may be a unit that controls a USB connection by the first and second USB host units and copies predetermined data stored in the USB device to the storage unit. According to such a USB storage device, an increase in the number of manufacturing steps or development steps due to the addition of the direct copy function to the USB storage apparatus can be suppressed. Note that the predetermined data may be all data stored in the USB device, or may be data of a specific file name or folder name. When copying data to the storage means, the date and time at that time may be added to the file name of the data.
[0012]
Further, the storage means may be means for making a USB connection as a USB device via the bridge means to a USB host device which makes a USB connection as a USB host. Therefore, the bridge means used for transferring data with the USB host device can be used also for transferring data with the USB device device. As a result, an increase in the number of manufacturing steps and an increase in the number of parts can be suppressed by simplifying the hardware configuration.
[0013]
Further, the storage means may be means for storing data transferred by IDE or SCSI. Therefore, even if the storage means has the characteristics according to the specifications based on IDE or SCSI, the number of manufacturing or development man-hours is increased by adding a data transfer function between the USB device and the storage means to the USB storage device. Increase can be suppressed.
[0014]
Further, the storage means may be means for storing data in any of a hard disk, an optical disk, a magneto-optical disk, a flexible disk, and a flash memory. Therefore, it is possible to suppress an increase in manufacturing man-hours or development man-hours due to adding a data transfer function between the USB device device and the storage means to a USB storage device provided with various storage means.
[0015]
BEST MODE FOR CARRYING OUT THE INVENTION
In order to further clarify the configuration and operation of the present invention described above, a USB storage device including an HDD unit will be described below as one of the USB storage devices to which the present invention is applied.
[0016]
First, a hardware configuration of the USB storage device 10 according to one embodiment of the present invention will be described. FIG. 1 is an explanatory diagram showing an external configuration of a USB storage device 10 according to one embodiment of the present invention. FIG. 2 is an explanatory diagram showing the internal configuration of the USB storage device 10 according to one embodiment of the present invention. The USB storage device 10 is a device that stores data transferred by USB from the USB device device 70 and the USB host device 80. The USB device device 70 is a USB mass storage device such as a digital camera or a card reader having a USB device function, and is a device that stores data such as images. The USB host device 80 is a PC having a USB host function.
[0017]
The USB storage device 10 serves as a USB host to the HDD unit 110 via the HDD unit 110 that stores data transferred by IDE, the USB-IDE bridge 120 that performs protocol conversion between USB and IDE, and the USB-IDE bridge 120. USB host controller 141 for USB connection, USB host controller 142 for USB connection as a USB host to the USB device 70, CPU 150 for performing various controls in the USB storage device 10, RAM 160 as a main memory of the CPU 150, and programs executed by the CPU 150 , A switch 181 for receiving an input of a direct copy instruction, and an LED 18 for displaying an operation state of the USB storage device 10. Comprises a USB-B port 192 for accepting USB connection from USB-A port 191, USB host device 80 that accepts USB connections from 183, USB device apparatus 70.
[0018]
The HDD unit 110 and the USB-IDE bridge 120 are IDE-connected. The USB-IDE bridge 120, the USB host controller 141, and the USB-B port 192 are connected by USB. The USB host controller 142 and the USB-A port 191 are connected by USB. The CPU 150 is connected to the RAM 160, the ROM 170, the switch 181, the LEDs 182, 183, and the USB host controllers 141, 142 via buses, respectively.
[0019]
The HDD unit 110 is an IDE device that exchanges data with an IDE interface and writes and reads data to and from a disk coated with a magnetic material as a storage medium. The USB-IDE bridge 120 is a chip provided with various controllers and data buffers for performing protocol conversion between USB and IDE, and is compatible with various IDE devices. The transfer mode and the drive voltage can be selected. As a result, the HDD unit 110 can be connected to the USB as a USB device.
[0020]
The USB host controllers 141 and 142 are integrated on a USB controller chip 140 called USB-OTG (On The Go). In the present embodiment, the USB controller chip 140 is “LR38873 made by Sharp” (“Sharp” is a registered trademark), and is a chip provided with two ports of a USB host port and an OTG port. The USB host port side has a USB host function, and the OTG port side can switch between a USB host function and a USB device function. In this embodiment, the USB host port side is the USB host controller 141, and the OTG port side is switched to the USB host function to be the USB host controller 142. Note that, contrary to this embodiment, the USB host controller 142 may be used as the USB host port, and the USB host controller 141 may be used as the OTG port is switched to the USB host. Further, the USB host controllers 141 and 142 may not be constituted by the USB controller chip 140 but may be constituted by another product having an equivalent function or a single chip having a USB host function.
[0021]
The switch 181 is a push-type button, and transmits an instruction signal to the CPU 150 in response to a pressing operation from the user. The LEDs 182 and 183 receive a light emission signal from the CPU 150 and emit light so that the user can confirm.
[0022]
The USB-A port 191 can be connected to the A connector of the USB cable from the USB device device 70, and the USB-B port 192 can be connected to the B connector of the USB cable from the USB host device 80. The USB-A port 191 and the USB-B port 192 have different shapes to prevent insertion of connectors having different relationships.
[0023]
The memory configuration of the ROM 170 will be described. FIG. 3 is an explanatory diagram schematically showing the memory configuration of the ROM 170. The ROM 170 is a non-volatile memory, and stores in advance programs such as an application program for performing direct copy processing, a drive operation firmware for operating the HDD unit 110, and a USB command firmware for exchanging data via USB connection. Have been. These programs are read into the RAM 160 by the CPU 150 and executed as various control processes.
[0024]
Next, a direct copy control process, which is a control process performed by the CPU 150, will be described. FIG. 4 is a flowchart showing the direct copy control process of the CPU 150. The direct copy control process is a process of storing data stored in the USB device 70 connected via USB in the HDD unit 110. The CPU 150 starts the direct copy control process at a predetermined timing. When the processing is started, it is determined whether or not the USB host device 80 is connected to the USB-B port 192 by USB (step S110). The CPU 150 confirms the USB connection between the HDD unit 110 and the USB host device 80 based on a signal from the USB-IDE bridge 120 via the USB host controller 141, and the USB host device 80 is connected to the USB-B port 192. It is determined whether or not a USB connection is established. If the USB host device 80 is USB-connected to the USB-B port 192 (step S110), a direct copy control process is performed to give priority to the USB connection between the USB host device 80 and the HDD unit 110 over direct copy. finish. Note that the CPU 150 turns on the LED 182 during the USB connection by the USB host device 80.
[0025]
On the other hand, when the USB host device 80 is not USB-connected to the USB-B port 192 (step S110), it is determined whether the USB device device 70 is USB-connected to the USB-A port 191 (step S120). ). The CPU 150 determines whether or not the USB device device 70 is connected to the USB-A port 191 by USB connection by attempting a USB connection to the USB device device via the USB host controller 142. If the USB device 70 is not connected to the USB-A port 191 by USB (step S120), there is no need to perform direct copy, and the direct copy control process ends.
[0026]
On the other hand, when the USB device 70 is connected to the USB-A port 191 by USB (step S120), it is determined whether or not the file data stored in the USB device 70 can be recognized (step S130). . If the file data cannot be recognized by the CPU 150 (eg, if the file data cannot be handled) or if the file data does not exist (step S130), an error display process (step S170) is performed. The copy control processing ends. When recognizing file data, if the file data has a predetermined file format or file name, the file data may be recognized. The CPU 150 turns on the LED 183 during the USB connection by the USB device 70.
[0027]
In the error display process (step S170), the LED 183 is blinked to notify the user that direct copying cannot be performed. Note that the error display process (step S170) only needs to notify the user that direct copying cannot be performed, and may flash and light the LEDs 182 and 183, or may provide a voice notification by providing a speaker or the like. good.
[0028]
On the other hand, if the file data stored in the USB device 70 can be recognized (step S130), it is determined whether the HDD unit 110 can be recognized (step S140). When the HDD unit 110 cannot be recognized, such as when the free storage capacity of the HDD unit 110 is smaller than the data capacity of the recognized file data (step S130), or when the HDD unit 110 is out of order (step S140). After performing the above-described error display processing (step S170), the direct copy control processing ends.
[0029]
On the other hand, if the HDD unit 110 can be recognized (step S140), it is determined whether or not the switch 181 has been pressed by the user (step S150). The CPU 150 waits until an instruction signal based on the pressing operation is transmitted from the switch 181. If the instruction signal is transmitted, the CPU 150 performs a copy process (step S160), and ends the direct copy control process.
[0030]
The copy process (step S160) is a process of copying the recognized file data of the USB device device 70 (step S130) to the HDD unit 110 having the recognized free storage capacity (step S140). The CPU 150 reads file data from the USB device 70 via the USB host controller 142 using the RAM 160 as a buffer, and writes the read file data to the HDD unit 110 via the USB host controller 141. During the copying process (step S160), the CPU 150 blinks the LEDs 182 and 183 alternately to notify the user that copying is in progress.
[0031]
The data management in the copy processing (step S160) will be described. FIG. 5 is an explanatory diagram schematically showing the configuration of data created in the copy processing (step S160). When writing the file data to the HDD unit 110, if there is no direct copy directory in the HDD unit 110, a direct copy directory "$ DIRECT" is created in the HDD unit 110. Thereafter, a folder is created in the directory for direct copy, and all of the recognized file data (step S130) is copied into the folder. The folder created in the direct copy directory is created each time the copy process (step S160) is performed. Each folder name is given a consecutive number such as “$ 00000000” for the first time, “$ 000001” for the second time, “$ 00000002” for the third time, and so on. Note that these folder names need only be able to identify file data for each copy process (step S160), and may be provided with an RTC (Real Time Clock) so that the date and time when the copy was performed may be given.
[0032]
According to the USB storage device 10 of the embodiment described above, the CPU 150 can exchange data with the USB device device 70 and the HDD unit 110 by controlling the USB connection by the USB host controllers 141 and 142. . As a result, in order to add the direct copy function to the USB storage device 10, there is no need to provide hardware and software based on IDE which is an interface of the HDD unit 110. Further, the USB-IDE bridge 120 absorbs the characteristics of each specification of the HDD unit 110 and converts the protocol into a USB, and the CPU 150 controls the USB connection with the USB-IDE bridge 120 to connect with the HDD unit 110. Data can be exchanged. As a result, it is not necessary to take measures for each specification of the HDD unit 110 in order to add the direct copy function to the USB storage device 10. Therefore, an increase in the number of manufacturing steps or development steps due to the addition of the direct copy function to the USB storage device 10 can be suppressed.
[0033]
Although the embodiments of the present invention have been described above, the present invention is not limited to these embodiments at all, and it is needless to say that the present invention can be implemented in various forms without departing from the spirit of the present invention. is there. For example, the interface of the HDD unit 110 is not limited to the IDE, and may be another interface such as a SCSI (Small Computer System Interface). What is necessary is just to provide the bridge which converts. The storage unit included in the USB storage device 10 is not limited to the HDD unit 110, but may be a device that stores data in an optical disk, a magneto-optical disk, a flexible disk, a flash memory, or the like.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing an external configuration of a USB storage device 10 according to one embodiment of the present invention.
FIG. 2 is an explanatory diagram showing an internal configuration of a USB storage device 10 according to one embodiment of the present invention.
FIG. 3 is an explanatory diagram schematically showing a memory configuration of a ROM 170.
FIG. 4 is a flowchart showing a direct copy control process of a CPU 150.
FIG. 5 is an explanatory diagram schematically showing a configuration of data created in a copy process (step S160).
FIG. 6 is an explanatory diagram showing the internal configuration of a conventional USB storage device 90.
[Explanation of symbols]
10 USB storage device 70 USB device device 80 USB host device 90 USB storage device 110 HDD unit 120 USB-IDE bridge 140 USB controller chips 141 and 142 USB host controller 150 CPU
160 ... RAM
170 ... ROM
181 ... Switch 182,183 ... LED
191, USB-A port 192, USB-B port 910, HDD unit 920, USB-IDE bridge 930, IDE host controller 940, USB host controller 950, CPU
960 ... RAM
970 ... ROM
981 ... switch 982, 983 ... LED
191: USB-A port 192: USB-B port

Claims (5)

A USB storage device for nonvolatilely storing data transferred by USB from a USB device device to be USB-connected as a USB device,
Storage means for storing data transferred by another interface different from USB;
A bridge unit that connects to the storage unit using the other interface, performs protocol conversion between USB and the other interface, and enables the storage unit to be connected to a USB device as a USB device;
First USB host means for making a USB connection as a USB host to the storage means via the bridge means;
Second USB host means for making a USB connection as a USB host to the USB device,
A USB storage device comprising: transfer control means for controlling a USB connection by the first and second USB host means to transfer data between the USB device device and the storage means. The USB storage device according to claim 1, wherein
The USB storage device, wherein the transfer control unit controls USB connection by the first and second USB host units and copies predetermined data stored in the USB device unit to the storage unit. The USB storage device according to claim 1, wherein:
A USB storage device, wherein the storage means is a means for making a USB connection as a USB device via the bridge means to a USB host device which makes a USB connection as a USB host. 4. The USB storage device according to claim 1, wherein said storage means is means for storing data transferred by IDE or SCSI. The USB storage device according to any one of claims 1 to 4, wherein
A USB storage device, wherein the storage means is means for storing data in any of a hard disk, an optical disk, a magneto-optical disk, a flexible disk, and a flash memory.

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