JP4000591B2 - Data storage device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a data storage device provided with a hard disk device and a controller that controls reading and writing of data with respect to the hard disk device.
[0002]
[Prior art]
When data is written to the hard disk device, management information that is indispensable for reading the data, for example, information on the data write position, etc. is also written to the hard disk device.
Conventionally, such management information is not particularly protected. As a general data protection technique, so-called mirroring, the entire storage data of the hard disk device including the management information and the actual data is included. There was a technology that could be copied in real time.
[0003]
[Problems to be solved by the invention]
However, the technique such as mirroring has a disadvantage that the storage capacity of the hard disk device requires twice as much storage capacity as originally required, and the cost of the data storage device becomes extremely high.
The present invention has been made in view of such circumstances, and an object of the present invention is to accurately protect management information stored in a hard disk while suppressing an increase in apparatus cost.
[0004]
[Means for Solving the Problems]
In the data storage device provided with the hard disk device and the controller for controlling the reading and writing of data with respect to the hard disk device by providing the configuration according to claim 1, a plurality of the controllers are provided, and the input data is The controller is configured to be distributed to the plurality of controllers as data to be written in parallel, and each of the controllers is configured to control reading and writing to the plurality of hard disk devices, and is controlled by the plurality of controllers. The hard disk device to be processed is divided into groups of the hard disk devices that write the distributed data in parallel, and the group to which the hard disk device belongs and the controller to be controlled are at least two different hard disk devices. The plurality of co It is configured to store management information for managing data stored in the entire hard disk device which is controlled by controller.
[0005]
That is, the input data is configured to be distributed to a plurality of controllers as data to be written in parallel, and in the configuration in which each controller controls reading and writing to a plurality of hard disk devices, the distributed data Thus, a group of hard disk devices that write data in parallel operates as a single hard disk device.
In such an arrangement of hard disk devices, data stored in the entire hard disk device controlled by the plurality of controllers is managed in at least two hard disk devices in which the group to which the group belongs and the controller to be controlled are different. By storing the management information for the management information, even if any abnormality occurs in any of the hard disk devices storing the management information or the controller controlling the hard disk and the management information cannot be read, the same management information is stored. It is possible to access the stored data by reading the management information of the other stored hard disk devices.
In this way, by using the fact that there are a plurality of groups of a plurality of hard disk devices that execute data writing in parallel and write data at high speed, hard disk devices that store management information are appropriately arranged. Thus, management information stored in the hard disk can be accurately protected while suppressing an increase in apparatus cost.
[0006]
The management information is stored when the management information cannot be normally read from the hard disk device storing the management information by providing the configuration according to claim 2. Management information of another hard disk device is copied to a hard disk device other than the hard disk device in which the management information cannot be read and the group belonging to the other hard disk device and the controlled controller are different. Hard disk management means is provided.
That is, even if any abnormality occurs in any of the hard disk devices that store the management information and the management information cannot be read, the management information of the normal hard disk device is transferred to the group to which it belongs and the controller to be controlled. By copying to any other normal hard disk device that is different from each other, it is possible to return to the original highly safe control state, and to continue to access the hard disk device safely.
[0007]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment in which a data storage device of the present invention is provided in a photo printing apparatus will be described with reference to the drawings.
The photographic printing apparatus DP exemplified in this embodiment is known as a so-called digital minilab machine. As shown in the block diagram of FIG. 5, a developed photographic film, memory card, MO or CD- An image input device IR that captures image data for producing a photographic print from R or the like to generate image data for exposure, and an exposure / exposure process that exposes the image data for exposure generated by the image input device IR to the photographic paper 1 And a developing device EP.
[0008]
[Schematic configuration of image input device IR]
As schematically shown in FIG. 5, the image input device IR includes a film scanner 2 for reading a frame image of a photographic film, a data storage device 8 for storing image data of the photographic film output from the film scanner 2, and a film A distribution device 7 for branching a transmission path of image data output from the scanner 2 to the data storage device 8, an external input / output device 4 including a memory reader, an MO drive, a CD-R drive, and the like; In addition to control, there is provided a main control device 6 that executes management of the entire photo print device DP. Further, the main control device 6 displays a simulated image that simulates a finished print image and a monitor that displays and outputs various information. 6a is connected to a console 6b for manual setting of exposure conditions and input of control information.
[0009]
[Configuration of main controller 6]
As schematically shown in FIG. 5, the main control device 6 performs a simulation for executing a calculation process for predicting a print image when it is produced based on image data input from the film scanner 2 and the data storage device 8. Based on the image data input from the arithmetic unit 10, the film scanner 2, and the data storage device 8, the image processing device 11 generates exposure image data for performing the exposure operation of the exposure / development device EP, and these operations And a controller 12 for managing the above.
The controller 12 is network-connected with the data storage device 8, the film scanner 2, and an exposure control device 21 described later, and exchanges various management information with each other.
[0010]
[Configuration of Data Storage Device 8]
As shown in the block diagram of FIG. 1, the data storage device 8 includes a large number of hard disk devices 31a and 31b, and an HDD controller 32 as a controller CO that controls reading and writing of data with respect to the hard disk devices 31a and 31b (in the drawing). , “HDD-C”), an input buffer memory 33 that temporarily holds image data to be written to the hard disk devices 31a and 31b, and an output that temporarily holds image data output from the hard disk devices 31a and 31b. A buffer memory 34, a communication interface 35, 36 on each of the transmission side and the reception side, and a data storage control unit 37 that manages reading and writing of image data with respect to the hard disk devices 31a, 31b are configured and read by the film scanner 2. Many photographic film images And it is configured so that over data can be stored saved.
Each HDD controller 32 is in charge of controlling a plurality of hard disk devices 31a and 31b, and in this embodiment, the case where two hard disk devices 31a and 31b are controlled is illustrated. Hereinafter, for the sake of convenience, of the two hard disk devices 31a and 31b controlled by each HDD controller 32, the one in which writing is executed in advance will be referred to as the main hard disk device 31a and the other as the secondary hard disk device 31b. is there.
[0011]
The data storage control unit 37 and the HDD controller 32 include a system area 51 for storing various system information and a plurality of image data areas 52, as schematically shown in FIG. 3 as data recording areas of the hard disk devices 31a and 31b. (In FIG. 3, 13 areas are exemplified in one hard disk device) and the management information area 53 for storing the management information of the stored data is managed separately, and each image data area 52 has a photograph. Stores image data for one film. However, although the management information area 53 is secured in both the main hard disk device 31a and the secondary hard disk device 31b, the management information is not actually written in both the management information areas 53. The management information is information essential for reading out the image data stored in the hard disk devices 31a and 31b, and includes, for example, information on the writing position of each frame image in the image data of each photographic film. .
[0012]
As shown in FIG. 3, the main hard disk device 31a and the sub hard disk device 31b controlled by each HDD controller 32 have an image data area 52 specified by a series of serial numbers, and the main hard disk device 31a. After the image data in the thirteenth image data area 52 is written, the image data is written in the first image data area 52 (sequential number is the fourteenth image data area 52) of the secondary hard disk drive 31b.
When the writing position is instructed from the data storage control unit 37 to the HDD controller 32, the image data area 52 of the image data areas 52 is designated.
On the other hand, the HDD controller 32 specifies the start position (“St1”, “St2”, “St3”,...) Of each image data area 52 by the physical sector in each of the main hard disk device 31a and the sub hard disk device 31b. Memorize in the state.
[0013]
The data width of the data bus 38 to which each HDD controller 32 is connected is composed of 64 bits, and the input buffer memory 33 combines image data received as 16-bit data with 64-bit data to connect the data bus. 38.
The data width of the HDD controller 32 connected to the 64-bit data bus 38 is 16 bits, and the four HDD controllers 32 divide the 64-bit data width of the data bus 38 into four parts. Each 16-bit data line is connected.
That is, in the data storage device 8, the hard disk devices 31a and 31b managed by the four HDD controllers 32 are managed as one unit, and the image data input in a continuous state from the film scanner 2 is divided. Thus, since data to be written in parallel is distributed to a plurality (specifically, four) of HDD controllers 32, the data storage control unit 37 collects images for the four HDD controllers 32. The four HDD controllers 32 share the number of the image data area 52 instructed to write or read data and the designated image data area 52.
[0014]
Therefore, as shown in FIG. 4 schematically showing the four HDD controllers 32 and the eight hard disk devices 31a and 31b constituting one unit, the four main hard disk devices 31a and the four sub-disks that are written in parallel are processed. Each of the hard disk devices 31b apparently operates as one hard disk device.
Therefore, the management information for reading image data is not stored in all the hard disk devices 31a and 31b, but is controlled by a plurality (specifically, four) HDD controllers 32. 31a and 31b are divided into groups of hard disk devices 31a and 31b that write data distributed in the above manner in parallel, and the group to which the HDD belongs and the controlled HDD controller 32 are different from each other. The management information for managing data stored in the entire hard disk devices 31a and 31b controlled by a plurality (specifically four) of HDD controllers 32 is stored in each of the two hard disk devices 31a and 31b. Yes.
[0015]
More specifically, referring to FIG. 4, in the present embodiment, a group of four main hard disk devices 31a indicated by “A1”, “A2”, “A3”, and “A4” that perform write processing in parallel is executed in parallel. Management of the hard disk devices 31a and 31b in which the management information is actually stored, divided into four groups of secondary hard disk devices 31b indicated by "B1,""B2,""B3," and "B4". As indicated by the hatching in the information area 53, the “A1” primary hard disk device 31a and the “B2” secondary hard disk device 31b, which are different from each other in the group to which they belong and the controlled HDD controller 32, are actually used. The management information is stored.
[0016]
[Configuration of Distribution Device 7]
As schematically shown in FIG. 2, the distribution device 7 receives the image data sent from the film scanner 2 and the transmission interface 41 for receiving and transmitting image data to and from the data storage device 8. Communication interfaces 42 and 43 on the transmission side and the reception side, a communication interface 44 on the transmission side for transmitting image data to the image processing apparatus 11, a communication line from the film scanner 2, and a signal from the data storage device 8 An output switching circuit 45 for switching which of the lines is connected to the communication interface 44 is provided.
The signal path A of the image data from the communication interface 41 to the output switching circuit 45 branches to the signal path B to the communication interface 42 in the middle, and the image data sent from the film scanner 2 to the image processing apparatus 11 is A branch transmission path is formed so as to reach the hard disk devices 31a and 31b of the data storage device 8 as well.
[0017]
On the other hand, when the image data written in the hard disk devices 31a and 31b of the data storage device 8 is read through the branch transmission path, it is input from the communication interface 43 and reaches the output switching circuit 45 via the signal path C. The output switching circuit 45 selects the signal path A and sends it to the communication interface 44 when the image data is transmitted from the film scanner 2 to the image processing device 11 according to a command from the data storage control unit 37 of the data storage device 8. When connecting to the signal path D and reading image data from the data storage device 8, the signal path C is selected and connected to the signal path D.
The communication interfaces 35, 36, 41, 42, 43, and 44 for transmitting and receiving image data constitute a communication path for transmitting and receiving a clock signal and image data synchronized with the clock signal at high speed.
[0018]
[Description of image data saving and reading operations]
Next, regarding the operation of saving the image data output from the film scanner 2 in the data storage device 8 and the operation of reading out the image data stored in the data storage device 8 and outputting it to the image processing device 11 etc. A description will be given based on the flowcharts of FIGS. 6 and 7 executed by the data storage control unit 37 of the storage device 8.
The data storage control unit 37 repeatedly executes the processing shown in FIGS. 6 and 7 at a high speed, and receives a request for accepting image data from the film scanner 2 (step # 1) or the controller 12 of the main controller 6. Image data transmission request (step # 9 in FIG. 7) is waiting to be received through the network.
[0019]
When the film scanner 2 reads a frame image of a photographic film, it sends a request for accepting the read image data to the controller 12 of the main controller 6 and the data storage device 8 via the network. Then, it waits for a signal indicating that image data can be accepted from both.
When the data storage control unit 37 of the data storage device 8 receives the image data acceptance request from the film scanner 2 (step # 1), the data storage control unit 37 writes the received image data in any writing position of any of the hard disk devices 31a and 31b. And instructing the HDD controller 32 that controls the corresponding hard disk devices 31a and 31b (step # 2). At this time, writing is instructed by the four HDD controllers 32 as described above.
[0020]
At this time, the HDD controller 32 that controls the hard disk devices 31a and 31b storing the management information among the HDD controllers 32 instructed to write can access the management information and read it normally. After confirmation, a response indicating that the operation is normal is returned to the data storage control unit 37.
Upon receiving this normal response, the data storage control unit 37 transmits a signal indicating that image data can be accepted to the film scanner 2 (step # 4). If the normal response does not come back from (step # 3), the management information of the other hard disk devices 31a, 31b storing the management information, that is, the normal hard disk device 31a from which the normal response has returned. , 31b is copied to another hard disk device 31a, 31b (step # 7), and operates as hard disk management means HC. This copy destination is the hard disk devices 31a and 31b other than the hard disk devices 31a and 31b in which the management information cannot be read and the other hard disk devices 31a and 31b (that is, the hard disk devices 31a and 31b from which the management information has been normally read). The group to which the group belongs and the HDD controller 32 to be controlled are different hard disk devices 31a and 31b.
In the state shown in FIG. 4, if the main hard disk device 31a “A1” cannot read the management information, it is stored in the sub hard disk device 31b “B2” which is the other hard disk device. The management information is copied to the main hard disk device 31a of “A3” in which the group and the HDD controller 32 are different.
When this process returns to normal operation (step # 8), a signal indicating that image data can be accepted is transmitted to the film scanner 2 (step # 4). The process ends abnormally.
[0021]
When the film scanner 2 receives a signal indicating that the image data can be accepted from both the controller 12 of the main control device 6 and the data storage control unit 37 of the data storage device 8, the image of one photographic film is received. Start sending data.
The image data sent out from the film scanner 2 is received by the communication interface 41 of the distribution device 7 and then transmitted through the signal path A and the signal path D from the communication interface 44 to the image processing apparatus 11. The same signal passes through the signal path B and is transmitted from the communication interface 42 to the data storage device 8.
[0022]
When the communication interface 36 receives the image data transmitted from the communication interface 42 of the distribution device 7, the image data is sequentially written in the input buffer memory 33. The input buffer memory 33 adjusts fluctuations in the write processing speed of the hard disk devices 31a and 31b, so that the data storage device 8 can continue to receive high-speed image data.
When data is output from the input buffer memory 33 to the data bus 38, the data is distributed to the four HDD controllers 32 instructed to write by the data storage control unit 37 and sequentially written to the hard disk devices 31a and 31b. It is. That is, the write processing proceeds in parallel in the four hard disk devices 31a and 31b.
At this time, the HDD controller 32 continuously changes the writing position as the image data is received so that the image data is continuously written in the continuous physical sectors in the hard disk devices 31a and 31b.
When the writing of the image data proceeds as described above and the signal indicating that the writing of the image data for one photographic film is completed from the HDD controller 32 (step # 5), the image for the one photographic film is received. The data identification code is transmitted to the controller 12 of the main controller 6 (step # 6).
[0023]
On the other hand, when the image data is read from the data storage device 8, when the image data output request is received from the controller 12 of the main control device 6 with the identification code specified (step # 9 in FIG. 7), the distribution device 7 is transmitted to the output switching circuit 45 of 7 so that the image data input through the signal path C is output to the communication interface 44 (step # 10).
Thereafter, the information on the hard disk devices 31a and 31b and the image data area 52 stored as the location where the image data of the photographic film specified by the identification code received from the controller 12 is written is stored in the corresponding HDD. It transmits to the controller 32 (step # 11). Also when reading out the image data, the information in the image data area 52 and the like are collectively transmitted to the four HDD controllers 32 constituting one unit.
[0024]
At this time, as in the case of writing image data, the HDD controller 32 that controls the hard disk devices 31a and 31b storing the management information among the HDD controllers 32 instructed to read is managed by the HDD controller 32. After confirming that the information can be accessed and read normally, a response indicating that the information is operating normally is returned to the data storage control unit 37. If this normal response does not come back, the same processing as in Step # 7 and Step # 8 at the time of writing is executed in Step # 18 and Step # 19.
[0025]
If the image data can be read normally, the controller 12 is inquired whether the image data can be accepted (step # 13), and a signal indicating that the image data can be accepted is received (step # 14). Then, transmission of image data is started (step # 15).
As a result, 16-bit width image data read from the designated positions of the hard disk devices 31a and 31b are sequentially output to the data bus 38 from each of the four HDD controllers 32, and the output buffer memory 34 and the communication interface. Then, the data is output to the distribution device 7 via 35.
The image data input to the distribution device 7 is output to the image processing device 11 via the communication interface 43, the output switching circuit 45, and the communication interface 44.
When the transmission of the image data for one photographic film is completed in this way (step # 16), the output switching circuit 45 of the distribution device 7 outputs the image data from the film scanner 2 on the signal path A to the communication interface 44. An instruction is issued to switch to the state (step # 17).
[0026]
[Schematic configuration of exposure / development apparatus EP]
As shown in FIG. 5, the exposure / development apparatus EP includes an exposure unit 20 that exposes and forms an image of image data for exposure received from the image input device IR on the photographic paper 1 inside the housing, and the exposure unit 20. A large number of photographic papers 1 drawn out from a photographic paper magazine 23 arranged on the upper surface of the housing, an exposure control device 21 for controlling the image, a development processing device 22 for developing the photographic paper 1 exposed by the exposure unit 20 And a photographic paper transport system PT that is transported to the development processing apparatus 22 by the transport rollers 25 and the like. The exposure unit 20 includes an exposure head 20a in which PLZT micro light shutters are arranged in a line, and adopts a PLZT light shutter system.
Outside the housing of the exposure / development apparatus EP, a sorter for classifying the photographic paper 1 developed and dried by the development processing apparatus 22 by order and discharged from the discharge port of the development processing apparatus 22. A conveyor 27 is provided for conveying the photographic paper 1 to a sorter (not shown).
Further, a cutter 28 for cutting the long photographic paper 1 drawn from the photographic paper magazine 23 into a set print size is provided in the middle of the conveyance path of the photographic paper conveyance system PT.
[0027]
[Photo print production operation]
Next, a photographic print production operation by the photographic printing apparatus DP having the above configuration will be schematically described.
When the operator inputs an instruction to make a photographic print for a photographic film frame image, the main controller 6 instructs the film scanner 2 to read the photographic film, and the image data of the photographic film is sent from the film scanner 2. Are sequentially received and recorded in a memory built in the image processing apparatus 11. At this time, the image data is written to the data storage device 8 in parallel.
On the other hand, when the operator inputs an instruction to produce a photographic print for image data recorded on a recording medium such as a memory card, MO, or CD-R, the main controller 6 drives the corresponding drive of the external input / output device 4. The image data is instructed to be read, and the image data is sequentially received from the drive and recorded in the memory.
Furthermore, when a reprint production request is received from a customer who has previously produced a print, the operator inputs the identification code corresponding to the requested photographic film from the console 6b. As described above, the corresponding image data is sequentially read from the data storage device 8 and stored in the memory built in the image processing device 11.
[0028]
The main control device 6 displays the simulated image obtained by the simulation calculation unit 10 on the monitor 6a based on the input image data.
The operator observes the simulated image on the monitor 6a and appropriately inputs image correction instruction information from the console 6b.
The main control device 6 generates image data for exposure in the image processing device 11 in a state where the input image correction instruction information is reflected, and sends it to the exposure control device 21.
When the exposure control device 21 detects that the front end of the photographic paper 1 has been conveyed to a predetermined exposure start position based on the conveyance information of the photographic paper 1 obtained from the photographic paper conveyance system PT, the exposure unit 20 The image data for exposure is sequentially transmitted to the exposure unit 20 at a speed corresponding to the exposure processing speed.
The exposure unit 20 operates each optical shutter of the exposure head 20a based on the received exposure image data to form a latent image of the print image on the photographic paper 1.
The photographic paper 1 subjected to the exposure processing in the exposure unit 20 is transported to the development processing device 22 by the photographic paper transport system PT, and is developed by sequentially passing through the respective development processing tanks. Is further dried and discharged from the discharge port onto the conveyor 27, and is collected for each order by the sorter.
[0029]
[Another embodiment]
Hereinafter, other embodiments of the present invention will be listed.
(1) In the above embodiment, the case where data to be written in parallel is distributed to four HDD controllers 32 is illustrated, but may be distributed to five or more HDD controllers 32. You may distribute to three or less HDD controllers 32.
(2) In the above embodiment, a case where one HDD controller 32 controls two hard disk devices 31a and 31b is exemplified. However, one HDD controller 32 allows three or more hard disk devices 31a and 31b to be controlled. You may comprise so that it may control.
(3) Although the case where the data storage device 8 is provided in the photo print device DP is illustrated in the above embodiment, it can be applied to various uses that require high-speed writing of various data.
[0030]
(4) In the above embodiment, prior to reading / writing image data from / to the hard disk devices 31a, 31b, it is confirmed whether or not the management information can be read. The case of copying to 31a, 31b is illustrated, but when the management information becomes inaccessible during writing or reading of image data, an interrupt request is generated from the HDD controller 32 to the data storage control unit 37 In response to the interrupt request, the management information may be copied to another normal hard disk device 31a, 31b.
(5) In the above embodiment, as the configuration for dividing the image data received from the film scanner 2 and distributing it to the plurality of HDD controllers 32, the connection itself between the HDD controller 32 and the data line of the data bus 38 is distributed. However, it is also possible to connect all the 64-bit width data lines of the data bus 38 to each HDD controller 32 and select any 16 bits within the HDD controller 32.
[0031]
【The invention's effect】
According to the configuration of the first aspect, the management information is stored by using a plurality of groups of a plurality of hard disk devices that execute the writing process in parallel and execute the data writing at high speed. By appropriately arranging the hard disk device, management information stored in the hard disk can be accurately protected while suppressing an increase in device cost.
According to the configuration of claim 2, even if any abnormality occurs in any of the hard disk devices storing the management information and the management information cannot be read, the normal hard disk device can be managed. By copying the information to another normal hard disk drive that is different in the group to which it belongs and the controller to be controlled, it is possible to return to the original highly secure control state, and to access the hard disk drive safely. Can continue.
[Brief description of the drawings]
FIG. 1 is a block diagram of a data storage device according to an embodiment of the present invention.
FIG. 2 is a block diagram of the distribution device according to the embodiment of the present invention.
FIG. 3 is an explanatory diagram of a storage area of the hard disk device according to the embodiment of the invention.
FIG. 4 is a schematic configuration diagram of a main part of the data storage device according to the embodiment of the present invention.
FIG. 5 is a block diagram of a photo printing apparatus according to an embodiment of the present invention.
FIG. 6 is a flowchart according to the embodiment of the present invention.
FIG. 7 is a flowchart according to the embodiment of the present invention.
[Explanation of symbols]
31a, 31b hard disk drive
CO controller
HC hard disk management means

Claims (2)

A data storage device provided with a hard disk device and a controller that controls reading and writing of data to the hard disk device,
A plurality of the controllers are provided, and input data is configured to be distributed to the plurality of controllers as data to be written in parallel.
Each of the controllers is configured to control reading and writing to a plurality of hard disk devices,
The hard disk device controlled by the plurality of controllers is divided into groups of the hard disk devices that write the distributed data in parallel, and the group to which the controller belongs and the controller to be controlled A data storage device configured to store management information for managing data stored in the entire hard disk device controlled by the plurality of controllers in at least two different hard disk devices. When the management information cannot be normally read from the hard disk device storing the management information, the management information is read from the other hard disk devices storing the management information. 2. The hard disk management means for copying to a hard disk device other than the hard disk device in a state where it cannot be taken out and in which the group belonging to the other hard disk device and the controlled controller are different. Data storage device.

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