JP2004078427A - Data conversion system, conversion controller, program, recording medium, and data conversion method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a data conversion system which performs high speed conversion processing by distributing a load to be imposed on a converter. <P>SOLUTION: This data conversion system is provided so that a plurality of storage devices for recording and reproducing data with an unique format, a plurality of converters for executing the format conversion processing of data to be transferred between the storage devices, and a conversion controller for instructing the format conversion processing of the data to be transferred between the storage devices to the converter in response to a transfer request from the outside are connected through a network to each other. The conversion controller is characterized to divide the format conversion processing of the data to be transferred between the storage devices, and to dynamically assign the data to one or at least two converters in order to optimally distribute the load of the conversion processing. Thus, the plurality of converters share and cooperatively process one data conversion and transfer processing, to execute high speed processing as a whole system. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a data conversion system, a conversion control device, a program, a recording medium, and a data conversion method, and more particularly to a data conversion system that performs format conversion processing on data transferred between storage devices.
[0002]
[Prior art]
For example, in a data recording / reproducing apparatus for recording / reproducing data such as digital video / audio data, a plurality of storages for storing data in different formats in order to enable input / output of data in various formats with the outside. A device is provided. Further, in order to enable data transfer between the storage devices, a converter (generally, a computer or the like) for converting the format of the transferred stream data is connected to the storage device. In such a system (data conversion system) capable of converting the format of transfer data between storage devices, there is a system in which a plurality of converters are provided in order to support transfer processing of a plurality of stream data.
[0003]
In such a data conversion system having a plurality of converters, the format conversion processing function of each converter is fixedly set, and the conversion and transfer of one stream data between certain storage devices is always the same. Was performing the format conversion process. Further, even when the function of each converter is not fixed, one converter selected from a plurality of converters has performed the format conversion processing of one stream data.
[0004]
[Problems to be solved by the invention]
However, in the above-described conventional data conversion system, since the format conversion processing of one stream data is executed by only one converter, there is a problem that the load of the converter increases and the processing speed is slow. Therefore, in order to improve the processing speed in such a system, an expensive high-performance converter had to be introduced.
[0005]
Also, when format conversion processing is performed on a plurality of stream data, the load is concentrated on some converters. Therefore, no matter how many converters are added, the conversion efficiency is poor and the processing speed is not improved. was there.
[0006]
Furthermore, when the processing function of the converter is fixed, if some of the converters fail, the conversion process may not be able to be executed.
[0007]
SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and an object of the present invention is to disperse the load on the converter to improve the processing speed, and to cope with the failure of the converter at low cost. It is to provide a possible new and improved data conversion system and the like.
[0008]
[Means for Solving the Problems]
In order to solve the above problems, according to a first aspect of the present invention, a plurality of storage devices for recording and reproducing data in a unique format; and a plurality of converters for performing format conversion processing of data transferred between the storage devices And a conversion control device that instructs the converter to perform a format conversion process on data transferred between storage devices in response to a transfer request from the outside; and a conversion control device interconnected via a network. : The conversion control device divides the format conversion process of the data transferred between the storage devices and dynamically allocates the data to one or more converters so that the load of the conversion process is optimally distributed. A data conversion system is provided.
[0009]
With this configuration, the storage device can transmit and receive stored data to and from the plurality of converters and another storage device via the network. In addition, the converter can transmit and receive data to and from a plurality of storage devices and another converter via a network, and can perform format conversion processing on the data. Then, it can be transferred to another storage device. Further, when the conversion control device instructs data transfer from one storage device to another storage device in response to a transfer request from a user, the conversion control device does not rely on only one converter to perform the conversion transfer process. Can be divided into one or more, and the divided conversion processes can be dynamically assigned to one or more converters, respectively. At this time, the conversion control device appropriately assigns the divided conversion processes to the respective converters so that the load of the conversion process is appropriately distributed. Each converter to which the divided conversion process is assigned in this way can execute the conversion process assigned to itself, and then transfer the converted data to another converter. As a result, one or two or more converters can share one data conversion and transfer process and cooperate with each other, so that high-speed processing can be performed as a whole system.
[0010]
According to another aspect of the present invention, a plurality of storage devices for recording and reproducing data in a unique format and a plurality of converters for format-converting data transferred between the storage devices are connected via a network. A conversion control device that instructs a converter to perform a format conversion process on data transferred between storage devices in response to an external transfer request: a format of data transferred between storage devices A conversion control device is provided, wherein the conversion process is divided and dynamically assigned to one or more converters so that the load of the conversion process is optimally distributed.
[0011]
With this configuration, when the conversion control device instructs data transfer from one storage device to another storage device in response to a transfer request from a user, the conversion control device does not rely on only one converter to perform the conversion transfer process. The conversion process can be divided into one or more, and the divided conversion processes can be dynamically assigned to one or more converters, respectively. At this time, the conversion control device appropriately assigns the divided conversion processes to the respective converters so that the load of the conversion process is appropriately distributed. Each converter to which the divided conversion process is assigned in this way can execute the conversion process assigned to itself, and then transfer the converted data to another converter. As a result, one or two or more converters can share one data conversion and transfer process and cooperate with each other, so that high-speed processing can be performed as a whole system.
[0012]
In addition, if the conversion control device is configured to allocate the divided format conversion processes to one or more converters so that the entire conversion processing time is the shortest, the load of the conversion process can be appropriately distributed. As a parameter for performing the conversion, the conversion processing time of one or more converters to which the divided conversion processing is assigned is adopted. More specifically, the conversion control device creates, for example, a plurality of combination patterns (hereinafter, referred to as conversion patterns) of the divided conversion process and the converter, and converts the conversion processing time and the processing time according to the processing performance of each converter. The expected time of the conversion process in each conversion pattern may be calculated based on the transfer time between the converters and the like, and the conversion pattern that minimizes the expected time of the conversion process may be selected. As a result, one or two or more converters can be suitably allocated so that the load of the conversion processing can be appropriately distributed and high-speed processing can be performed.
[0013]
Each of the converters is controlled to execute a format conversion process assigned in parallel while transferring data. With such a configuration, the plurality of converters assigned the divided format conversion processes are controlled. Each of the devices can sequentially convert the data while receiving the data, and then transfer the data to another subsequent converter. As described above, since each converter executes the conversion processing and the transfer processing in a pipeline manner, the entire processing time is further reduced.
[0014]
Further, the conversion control device divides a format conversion process of a plurality of data transferred between the storage devices in response to the plurality of transfer requests, and distributes the load of the conversion process optimally. With such a configuration that one or more converters are dynamically assigned to one or more converters, one or more converters can simultaneously perform not only one data conversion and transfer process but also a plurality of data conversion and transfer processes. it can. Further, even in the case where the conversion and transfer processing of a plurality of data is performed as described above, the processing is assigned to one or more converters, respectively, so that high-speed processing can be performed.
[0015]
In addition, if the data is configured as digital video / audio stream data, one or two or more converters can simultaneously convert, for example, digital video / audio stream data which is continuous data having a relatively large data capacity. Since the conversion and transfer processing can be performed in parallel, such processing can be performed at high speed.
[0016]
According to another aspect of the present invention, a computer includes: a plurality of storage devices that record and reproduce data in a unique format; and a plurality of converters that perform format conversion processing on data transferred between the storage devices. , Which are mutually connected via a network, and instruct a converter to perform a format conversion process of data transferred between storage devices in response to a transfer request from the outside, and transfer the data between the storage devices. And a function of converting the data format conversion processing to be performed and dynamically allocating the conversion processing load to one or more converters so that the load of the conversion processing is optimally distributed. A program is provided.
[0017]
According to another aspect of the present invention, there is provided a computer-readable recording medium comprising: a plurality of storage devices for recording and reproducing data in a specific format by a computer; A converter that is interconnected to a plurality of converters for format conversion of data via a network and instructs the converter to perform format conversion of data transferred between storage devices in response to an external transfer request. A control unit, which divides a format conversion process of data transferred between storage devices and dynamically allocates the conversion process load to one or more converters so that a load of the conversion process is optimally distributed. A computer-readable recording medium that records a program that functions as an apparatus is provided.
[0018]
According to another aspect of the present invention, data transferred between a plurality of storage devices that record and reproduce data in a unique format is formatted using a plurality of converters in response to an external transfer request. A data conversion method for performing a conversion process, wherein a format conversion process of data transferred between storage devices is divided and one or more converters are dynamically allocated so that the load of the conversion process is optimally distributed. A data conversion method is provided, wherein the data conversion method comprises:
[0019]
Further, the divided format conversion processing may be assigned to one or more converters so that the entire conversion processing time is minimized.
[0020]
Each of the converters may be configured to execute a format conversion process assigned in parallel while transferring data.
[0021]
Further, in accordance with the plurality of transfer requests, the format conversion processing of the plurality of data transferred between the storage devices is divided, and one or two or more conversions are performed so that the load of the conversion processing is optimally distributed. It may be configured to dynamically assign to machines.
[0022]
Further, the data may be configured to be digital video / audio stream data.
[0023]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In this specification and the drawings, components having substantially the same function and configuration are denoted by the same reference numerals, and redundant description is omitted.
[0024]
(First Embodiment)
Hereinafter, a data conversion system, a conversion control device, a program, a recording medium, and a data conversion method according to the first embodiment of the present invention will be described.
[0025]
First, an overall configuration of a data conversion system according to the present embodiment will be described with reference to FIG. FIG. 1 is a block diagram showing an overall configuration of a data conversion system 1 according to the present embodiment.
[0026]
As shown in FIG. 1, in the data conversion system 1, a plurality of storage devices S1, S2,..., Sn for recording and reproducing data (hereinafter, may be collectively referred to as a storage device S), and data. A plurality of converters C1, C2,..., Cm (hereinafter, may be collectively referred to as converters C) for format conversion processing and a converter for format conversion of data transferred between the storage devices S. A conversion control device 10 for instructing C is connected via a network 5.
[0027]
In the following, an example in which the data conversion system 1 includes, for example, three storage devices S1, S2, and S3 will be described. However, the present invention is not limited to such an example, and the number of storage devices S installed is, for example, two or four or more. You may.
[0028]
<Network>
The network 5 is, for example, a high-speed communication network configured by, for example, Ethernet (EtherNet: registered trademark). The storage device S, the converter C, and the conversion controller 10 are connected to the network 5 by, for example, a network hub (not shown), and can exchange data with each other. This network 5 is, for example, an asynchronous network. The asynchronous network referred to here is a network that does not need to input and output signals in real time, and the devices connected to the network 5 can transmit and receive data to and from each other without any time limit, for example.
[0029]
The network 5 is not limited to the example of the Ethernet described above. For example, other LANs (Local Area Network), various dedicated line networks, the Internet, WANs (Wide Area Networks), WLLs (Wireless Local Loops), satellite communication networks , A telephone network, a cable TV network, and a cable broadcasting network.
[0030]
<Storage device>
The storage device S is a recording / reproducing device capable of recording and reproducing various data from, for example, a real-time input / output port (not shown). The storage device S includes a recording medium such as a magnetic disk such as a hard disk, a magnetic tape, an optical disk such as an MO, a CDROM or a DVDROM, or a semiconductor memory such as a RAM or a ROM. For example, the data can be stored in a file format, for example, in a unique format.
[0031]
The format used in the storage device S is, for example, various stream formats such as a DV format and an MPEG-IMX format, or a VTR format, etc., which will be described later in detail. Each storage device S records data in the above-mentioned different format, for example (for example, the storage device S1 records in the MPEG-IMX format, and the storage device S3 records in the DV format). Therefore, by combining such a plurality of storage devices S, data in various formats can be transmitted / received to / from the outside.
[0032]
The data handled by the data conversion system 1 according to the present embodiment is, for example, stream data (hereinafter referred to as video / audio) such as digital video data such as moving images and still images and / or digital audio data such as music information. Data). Therefore, the storage device S can also function as, for example, a streaming server that distributes the video / audio data to the outside from the input / output port, for example.
[0033]
The storage device S can transmit and receive the video and audio data to and from the other storage devices S and the converters C in the data conversion system 1 via the network 5. However, since the format of the stored video / audio data differs between the storage devices S, the video / audio data cannot be directly transmitted / received.
[0034]
<Converter>
The converter C is composed of, for example, a general-purpose computer or workstation having, for example, a processor and a recording device (neither of which is shown), and formats the video / audio data transferred between the storage devices S. It has a function of performing conversion processing.
[0035]
The format conversion process performed by the converter C is not a fixed conversion process (for example, a conversion process such as simply converting the format of the storage device S1 to the format of the storage device S2), but, for example, an arbitrary conversion process. It is flexible. That is, the converter C is variously set by the conversion control device 10 described later, and each time, the process can be started and an arbitrary format conversion process can be executed. Therefore, each converter C can perform a format conversion process on video / audio data transferred between arbitrary storage devices S, for example. Further, the converter C can also convert the data into an intermediate format between the format of one storage device S and the format of another storage device S.
[0036]
The converter C transmits and receives, for example, asynchronously the video and audio data to and from the other converter C and the storage device S via the network 5 using, for example, an FTP (File Transfer Protocol). be able to. For this reason, the converter C receives video / audio data from the storage device S or another converter C as an input, and sends the video / audio data to the storage device S or another converter C as an output. be able to. Furthermore, the converter C can convert the format while outputting the video / audio data and output the data.
[0037]
With such a configuration, each converter C takes out video / audio data stored in a certain storage device S, for example, on a file basis, performs arbitrary format conversion, and sends the data to another subsequent converter C. It can be passed or transmitted to another storage device S for storage. Therefore, when transferring, for example, one video / audio data file (hereinafter, also referred to as one stream) between storage devices S of different formats, each converter C executes the conversion transfer processing of one stream by itself. In addition, a plurality of converters C can cooperate to execute the conversion transfer processing of one stream in a shared manner.
[0038]
To explain a specific example of the sharing process, for example, first, the converter C1 reads a video / audio data file of a certain format from the storage device S1 and converts the format into a predetermined intermediate format {1} while converting the format of the converter C2. To send the data. Next, while receiving the data from the converter C1, the converter C2 sequentially converts the data into an intermediate format (2) and sends it to the converter C3. Further, while receiving the data, the converter C3 sequentially converts the data into a format corresponding to the storage device S2 and stores the data in the storage device S2. As described above, the plurality of converters C perform a series of conversion and transfer processes in parallel, for example, in a pipelined manner, such as sequentially transferring the received stream while executing its own conversion process. be able to.
[0039]
As described above, the data conversion system 1 according to the present embodiment is characterized in that a plurality of converters C can perform conversion and transfer processing of one stream, for example, in a shared manner. , The conversion transfer processing can be executed at high speed. Also, regarding the transfer of a plurality of video / audio data files (hereinafter, also referred to as a plurality of streams) between the storage devices S, the conversion and transfer processing of each stream is shared by the plurality of converters C. High-speed processing becomes possible by distributing the load.
[0040]
<Conversion control device>
The conversion control device 10 is composed of, for example, a general-purpose computer. The conversion control device 10 performs a conversion transfer process of video / audio data between the storage devices S in response to a transfer request from the outside (a user of the system or the like). It functions as, for example, a transfer instruction terminal device instructing C. Further, the conversion control device 10 divides the format conversion process of the data to be transferred and dynamically allocates it to, for example, one or more converters C so that the load of the conversion process is optimally distributed. It has a function, and this function is a major feature of the data conversion system 1 according to the present embodiment.
[0041]
Here, a functional configuration of the conversion control device 10 will be described in detail with reference to FIG. FIG. 2 is a block diagram illustrating a configuration of the conversion control device 10 according to the present embodiment.
[0042]
As shown in FIG. 2, the conversion control device 10 includes a transmission / reception unit 102, an input / output unit 104, a storage unit 106, a conversion processing allocation unit 108, a conversion processing management unit 116, and a control unit 118.
[0043]
The transmission / reception unit 102 has a function of transmitting / receiving various information between the conversion control device 10 and the converter C via the network 5, for example. For example, the transmission / reception unit 102 transmits, for example, a later-described converter setting signal, a processing start event signal, and the like to the converter C. Receives an end event signal and the like.
[0044]
The input / output unit 104 includes various input devices such as a mouse and a keyboard, and output devices such as a monitor, and functions as a user interface between the user of the conversion control device 10 and the control conversion device 10. The user operates the input / output unit 104 to execute a transfer process of a desired digital video / audio data file between the storage devices S from, for example, a GUI (Graphical User Interface) application as shown in FIG. An instruction (that is, a transfer request) can be given to the converter C. When the transfer process is completed, for example, a notification that the transfer process is completed is displayed by the GUI application or the like.
[0045]
The storage unit 106 includes, for example, an external storage device such as a magnetic disk such as a hard disk, a magnetic tape, an optical disk such as an MO, a CDROM or a DVDROM, and a main storage device such as a semiconductor memory. For example, various types of information, programs, and the like relating to the information can be stored and temporarily stored.
[0046]
The conversion processing allocating unit 108 divides the format conversion processing of the data transferred between the storage devices S based on, for example, a user's transfer request, and distributes the conversion processing load optimally. Alternatively, it is, for example, software having a function of dynamically allocating to two or more converters C. The conversion processing allocating unit 108 has a format conversion table management unit 110, a conversion pattern determination unit 112, and a converter setting unit 114.
[0047]
The format conversion table management unit 110 has a function of managing the format conversion table. The format conversion table is a table in which the format used in each storage device S and the relationship between the intermediate format used when these formats are mutually converted and the division conversion process performed by the converter C are associated with each other. It is. Note that the division conversion process is a format conversion process in which video / audio data is transferred from one storage device S to another storage device S, for example, divided into one or two or more. Say.
[0048]
Here, a specific example of the format conversion table will be described with reference to FIG. FIG. 4 is an explanatory diagram showing a specific example of the format conversion table according to the present embodiment.
[0049]
As shown in FIG. 4, for example, five types of formats (1) to (5) and division conversion processes A to D performed between the formats are associated with each other in the format conversion table. Format (1) is a format of video / audio data stored in the storage device S1, format (3) is a format of video / audio data stored in the storage device S2, and format (4) is This is a format of video / audio data stored in the storage device S3. The formats (2) and (5) are intermediate formats and do not correspond to any storage device S.
[0050]
According to this format conversion table, for example, when transferring video / audio data from the storage device S1 (format {circle around (1)}) to the storage device S3 (format {circle around (4)}), the data is first stored in the storage device S1. The video / audio data being converted is converted to the format (2) by the division conversion processing A, then converted to the format (5) by the division conversion processing C, and further converted to the format (4) by the division conversion processing C. And stored in the storage device S3. That is, the conversion path of the video / audio data from the storage device S1 to the storage device S3 (that is, the combination of the division conversion processes) is “division conversion process A → division conversion process C → division conversion process D”. As described above, in the example of the format conversion table shown in FIG. 4, once the transfer source and transfer destination storage devices S are determined, the format conversion conversion path between the storage devices S can be uniquely determined, for example.
[0051]
The format conversion table management unit 110 can create the format conversion table as described above and store it in, for example, the recording unit 106, and can update and manage this format conversion table as needed. More specifically, the update management will be described. For example, when a new storage device S is added or an intermediate format is newly set, the format conversion table management unit 110 stores the relevant storage in the format conversion table. A format corresponding to the device S or a new intermediate format is added, and the link to the existing format is updated. When the existing storage device S is removed and the existing intermediate format becomes unnecessary, the format corresponding to the storage device S or the intermediate format is deleted from the format conversion table, and the remaining storage device is deleted. Update the link between the format of device S and the intermediate format.
[0052]
The conversion pattern determination unit 112 has, for example, a function of determining an optimum conversion pattern so that the conversion transfer processing of one stream between the storage devices S specified by the user is performed in the shortest time. This conversion pattern refers to a combination of the above-mentioned one or more divided conversion processes constituting the specified conversion transfer process and each converter C. The determination of the conversion pattern is performed by a predetermined algorithm based on, for example, the processing performance of each converter C and the transfer time between the converters C, and the details will be described later. As described above, the conversion pattern determination unit 112 performs one or two or more conversions so that the load of the conversion processing is optimally distributed. Machine C.
[0053]
The converter setting unit 114 has a function of setting each converter C based on the conversion pattern determined by the conversion pattern determining unit 112. That is, the converter setting unit 114 creates a converter setting signal for setting a conversion process content and a data input / output destination for each converter C to which the split conversion process is assigned, and transmits the converter setting signal from the transmission / reception unit 102. To each of the devices C.
[0054]
The conversion processing management unit 116 has a function of managing the operation of the conversion transfer processing of each converter to which the above-described division conversion processing is assigned. Specifically, the conversion processing management unit 116 issues a processing start event signal and transmits the signal to each of the converters C, for example, when the setting of each of the converters is completed. As a result, each converter C starts, for example, alloted divided conversion processing operations simultaneously. In addition, each of the converters C issues a processing end event signal when the division conversion processing ends, for example, and transmits the processing end event signal to the conversion control device 10. The conversion processing management unit 116 determines whether or not all of the conversion transfer processing of the stream specified by the user has been completed, based on whether or not this processing end event signal has been received from all of the converters C. Further, when the conversion processing management unit 116 determines that all the processing is completed, the conversion processing management unit 116 notifies the user that the processing has been completed using, for example, the GUI application.
[0055]
The control unit 118 includes, for example, a CPU (Central Processing Unit) and has a function of controlling the above-described units in the conversion control device 10. The control unit 118 controls based on, for example, a program stored in the storage unit 106 so that the above-described units of the conversion control device 10 can perform the above-described functions. Furthermore, by suitably constructing the computer-readable program according to the process to be executed and storing the program in the storage unit 106, the conversion control device 10 can execute not only the above but also various processes. is there.
[0056]
The conversion control device 10 configured as described above receives a transfer request from the user, and performs one or more conversion processes for converting the format of video / audio data transferred between the storage devices S in response to the transfer request. Machine C can be dynamically assigned. At this time, for example, each division conversion process and each converter C can be suitably combined so that the overall processing time is the shortest. Further, after setting the converter C to which the split conversion process is assigned, the conversion transfer operation of the converter C can be controlled.
[0057]
<Conversion pattern determination processing>
Next, the conversion pattern determination processing by the conversion pattern determination unit 112 of the conversion control device 10 will be described in detail.
[0058]
The conversion pattern determination processing according to the present embodiment calculates an “expected actual processing time” for each conversion pattern by a predetermined algorithm, and selects a conversion pattern that minimizes the “expected actual processing time”. . The “expected actual processing time” is an expected time until the conversion and transfer processing of, for example, 1 frame of video / audio data is completed according to each conversion pattern.
[0059]
Hereinafter, an algorithm for determining a conversion pattern will be described in detail with reference to FIG. FIG. 5 is a flowchart illustrating an algorithm of the conversion pattern determination process according to the present embodiment.
[0060]
In the following, along with the description of the algorithm, a specific example of a format conversion table is set based on FIGS. 6 to 9, and an example in which an optimum conversion pattern is calculated based on the algorithm is also described. And FIG. 6 is an explanatory diagram showing a format conversion table in which specific examples of formats are set, and FIG. 7 is a table showing conversion paths and transfer times between source and destination formats. FIG. 8 is a table showing a combination of the converter C and the division conversion process in each conversion pattern, and FIG. 9 is a table showing details of a method of calculating the “expected actual processing time” of each conversion pattern.
[0061]
As shown in FIG. 5, first, in step S10, a conversion path is determined (step S10). Upon receiving the transfer request from the user, the conversion pattern determination unit 112 determines a conversion path with reference to the format conversion table. In the following, a description will be given on the assumption that, for example, a request to transfer one stream, for example, from the storage device S1 to the storage device S2.
[0062]
In the setting example of the format conversion table of FIG. 6, the formats (1), (3), and (4), which are the formats of the storage devices S1 to S3, are "MPEG IMX", "SX", and "DV", respectively. , And the formats (2) and (5), which are intermediate formats, are “Baseband 4: 2: 2” and “Baseband 4: 1: 1”, respectively. These formats are as follows:
"MPEG IMX": A stream format and a VTR format corresponding to an MPEG (Moving Picture Experts Group) -based stream proposed by the applicant of the present invention in SMPTE. The standard name is "Type D-10", and the standard name is "SMPTE356M / 365M". This format is standardized as
“SX”: An MPEG-based stream format developed by the present applicant, which is IBIB. . . . Is a proprietary format having a GOP (Group Of Picture) format.
"DV": DV format, a format defined by IEC61834 of the IEC standard.
"Baseband 4: 2: 2" (YUV422): Baseband is an uncompressed video signal, and the format in which the ratio of the sampling rates of the luminance and chrominance components is Y: U: V = 4: 2: 2. Represents The “MPEG IMX” is a format obtained by compressing the “Baseband 4: 2: 2”. “Baseband 4: 1: 1” (YUV411): This is an uncompressed video signal, and represents a format in which the sampling rate ratio of luminance and chrominance components is Y: U: V = 4: 1: 1. The “DV” is a format obtained by compressing the “Baseband 4: 1: 1”. Therefore, when format conversion is performed between “MPEG IMX” and “DV”, a process of performing interpolation (or thinning) after once converting the video signal to Baseband is performed.
[0063]
FIG. 6 shows the “data amount” (shown in []) in each format. This “data amount” refers to the data capacity per frame in each format. For example, the “data amount” of “MPEG IMX” in the format (1) is, for example, 1.5 Mbit / frame. FIG. 6 also shows “reference conversion time” (shown in parentheses) of each division conversion process. The “reference conversion time” refers to a format conversion processing time per one frame when processing is performed by a reference converter (hereinafter, referred to as a reference converter). For example, the “reference conversion time” of the division conversion processing A from “MPEG IMX” to “Baseband 4: 2: 2” is, for example, 0.3 sec / frame. It is assumed that such “data amount” and “reference conversion time” have been measured in advance and are recorded in the storage unit 106 of the conversion control device 10.
[0064]
According to the format conversion table shown in FIG. 6, when a transfer request is made from the storage device S1 to the storage device S3, format conversion from “MPEG IMX” to “DV” is required. As shown in FIG. 7, the conversion path in this case is “(1) → (2) → (5) → (4)” (the field indicated by a dark color), that is, “division conversion processing A → division conversion processing”. C → division conversion processing D ”, which is uniquely determined, for example.
[0065]
Next, in step S12, a plurality of converters C having a high processing capability are selected from the plurality of converters C by the number of division conversion processes (step S12). When the conversion path is determined, the conversion pattern determination unit 112 selects the converters C by the number of division conversion processes constituting the conversion path. More specifically, since the determined conversion path is, for example, three divisional conversion processes of “division conversion process A → division conversion process C → division conversion process D”, for example, three converters C are selected. .
[0066]
In this selection, for example, three converters C are selected from the plurality of converters C in descending order of the “actual processing performance ratio”. The “actual processing performance ratio” is, for example, a ratio that indicates the magnitude of the performance that can be actually expected of each converter C at the time of the selection when the performance of the reference converter is 1.0. , The operating frequency of the CPU of the converter C, the free space of the memory, and the like, and the CPU load at the time of the selection. Therefore, even if the converter C has a high basic performance, the “actual processing performance ratio” may be low when a large load is applied in another process.
[0067]
In the following specific example, the converter C1 (“actual processing performance ratio” = 2.0), the converter C2 (“actual processing performance ratio” = 1.5), It is assumed that three converters C, which are converters C3 (“actual processing performance ratio” = 1.0), are selected.
[0068]
Further, in step S14, a plurality of conversion patterns are created (step S14). The conversion pattern determination unit 112 creates a plurality of conversion patterns by combining, for example, the plurality of division conversion processes determined in step S10 and the plurality of converters C selected in step S12, for example. At this time, for example, the converter C and the split conversion process are configured such that the converter C having a large “actual processing performance ratio” is in charge of the split conversion process with a large load (that is, the “reference conversion time” is large). Combined.
[0069]
In the specific example, as shown in FIG. 8, for example, four conversion patterns, for example, conversion patterns 1 to 4 are created. For example, in the conversion pattern 1, it indicates that the converter C2 is in charge of the division conversion processing A, the converter C3 is in charge of the division conversion processing C, and the converter C1 is in charge of the division conversion processing D. In the conversion pattern 4, it indicates that the converter C1 is in charge of all the division conversion processes A, C, and D.
[0070]
In this example, in any of the conversion patterns, the converter C1 having the largest "actual processing performance ratio" is assigned to the divided conversion processing D having the largest "reference conversion time". On the other hand, the converter C3 having the smallest “real processing performance ratio” is only assigned to the divided conversion process C having the smallest “standard conversion time” in the conversion pattern 1.
[0071]
Thereafter, in step S16, "expected actual processing time" of each conversion pattern is calculated (step S16). The conversion pattern determination unit 112 calculates “expected actual processing time” for each conversion pattern created in step S14. What influences the “expected actual processing time” is, for example, the “expected actual conversion time” and the “expected actual transfer time”.
[0072]
The “expected actual conversion time” is the time required for each converter C to execute one or more divided conversion processes in charge of 1 frame of data, and is calculated by the following equation.
“Actual conversion expected time” = (sum of “reference conversion time” of divided conversion processing in charge) / (“actual processing performance ratio”)
[0073]
The “expected actual transfer time” is the expected time required for transfer of 1 frame in the transfer format in the transfer between the converters C, and is calculated by the following equation. "Expected actual transfer time" = ("data amount" of transfer format) / ("actual transfer capacity")
The “actual transfer capacity” is an expected value [bit / sec] of the capacity of the network 5 at the time of processing, and is obtained, for example, from the congestion degree of the network 5.
[0074]
By calculating such “expected actual conversion time” and “expected actual transfer time” for the conversion processing and transfer processing of all converters C, “expected actual processing time” is calculated by the following equation. .
“Expected actual processing time” = max (max (each “expected actual conversion time”), max (each “expected actual transfer time”)
That is, the “expected actual processing time” is, for example, the largest time among the times required for the plurality of conversion processes and the transfer processes as described above. The reason for this is that the split conversion process assigned to each converter C and the transfer process between the converters C are performed in parallel, for example, in a pipeline (that is, processed in parallel). This is because, for example, the processing time of a bottleneck location in the pipeline is the completion waiting time for 1 frame of data.
[0075]
When the "actual processing conversion time" of each conversion pattern shown in FIG. 8 is calculated by such a calculation method, the result is as shown in FIG. Hereinafter, for example, the “expected actual processing time” in the case of the conversion pattern 2 will be described.
[0076]
First, the converter C2 performs a conversion process from the format (1) to the format (2) (that is, the split conversion process A, which is indicated by (1) → (2) in FIG. 9) and a format. It is responsible for the conversion process from (2) to format (5) (that is, the division conversion process C, which is indicated by (2) → (5) in FIG. 9). Therefore, the “expected actual conversion time” of the converter C2 is obtained by subtracting “0.3 + 0.1 = 0.4 sec / frame” which is the sum of the “reference conversion times” of the divided conversion processes from the “actual conversion time” of the converter C2. Dividing by "1.5" which is the "performance ratio", it is calculated as "0.266 ... sec / frame".
[0077]
Further, since the data transfer from the converter C2 to the converter C1 is performed in the format (5) (that is, “Baseband 4: 1: 1”), the “expected actual transfer time” of the transfer is determined by the format to be transferred. The “data amount” of “4.0 MBit / frame” is divided by the “actual transfer capacity” of “10 MBit / frame” to calculate “0.4 sec / frame”.
[0078]
Further, the converter C1 is in charge of only the conversion process from the format (5) to the format (4) (that is, the division conversion process D, which is indicated by (5) → (4) in FIG. 9). are doing. Therefore, the “expected actual conversion time” of the converter C1 is obtained by dividing “0.5 sec / frame” that is the “standard conversion time” by “2.0” that is the “real processing performance ratio” of the converter C1. Is calculated as “0.25 sec / frame”.
[0079]
Of the two "expected actual conversion times" and one "expected actual transfer time" calculated in this way, the largest one is the "expected actual transfer time" required for data transfer from converter C2 to converter C1. ". Therefore, the “expected actual processing time” of the conversion pattern 2 is “0.4 sec / frame”.
[0080]
In the above, the calculation of the “expected actual processing time” of the conversion pattern 2 has been described. However, the “expected actual processing time” of the other conversion patterns can be calculated in the same manner, and a description thereof will be omitted.
[0081]
Next, in step S18, a conversion pattern is determined (step S18). The conversion pattern determination unit 112 adopts the conversion pattern in which the “expected actual processing time” calculated in step S16 is the minimum. In the above specific example, as shown in FIG. 9, the “expected actual processing time” of the conversion pattern 2 among the four conversion patterns 1 to 4 is the smallest, so the conversion pattern 2 is selected.
[0082]
As described above, in the conversion pattern determination processing according to the present embodiment, for example, a plurality of conversion patterns obtained by combining each division conversion processing and each converter C are created, and the “expected actual processing time” of each conversion pattern is calculated. calculate. Next, the “expected actual processing time” is compared, and the conversion pattern having the minimum “expected actual processing time” is adopted. As a result, the converters C can be appropriately assigned so that a series of conversion transfer processing times between the storage devices S is minimized.
[0083]
<Data conversion method>
Next, a data conversion method using the data conversion system 1 as described above will be described with reference to FIG. FIG. 10 is a flowchart illustrating an operation flow of the data conversion method according to the present embodiment.
[0084]
As shown in FIG. 10, first, in step S100, a transfer request from a user is accepted (step S100). For example, the user of the conversion control device 10 operates the input / output unit 104 to instruct to transfer, for example, one video / audio data file (one stream) from one storage device S to another storage device S. . Upon receiving such a transfer request, the control unit 118 of the conversion control device 10 instructs the conversion processing allocating unit 108 to perform a process according to the content of the transfer request.
[0085]
Next, in step S102, an optimal conversion pattern is determined (step S102). The conversion pattern determination unit 112 of the conversion control device 10 assigns one or more converters C to each of the converters C so that the conversion transfer processing of, for example, one stream between the requested storage devices S is performed in the shortest time, for example. The optimum conversion pattern is determined by allocating to each of the division conversion processes.
[0086]
Further, in step S104, each converter C is set (step S104). The converter setting unit 114 of the conversion control device 10 sets one or two or more converters C, which are to share the processing, based on the conversion pattern determined by the conversion pattern determining unit 112. That is, the converter setting unit 114 transmits, to each converter C, a converter setting signal for setting the content of the division conversion process to be executed by the converter C and the data input / output destination. .
[0087]
Thereafter, in step S106, the conversion and transfer processing process of each converter C is started (step S106). The converter C that receives the converter setting signal (that is, the converter C to which the split conversion process is assigned in the determined conversion pattern) starts its own conversion transfer process.
[0088]
Next, in step S108, an input / output format and a conversion path are set in the conversion and transfer processing process of each converter C. (Step S108). Based on the converter setting signal, each converter C performs its own conversion and transfer process, for example, an input / output format and a conversion path (that is, assigned division conversion process contents) in accordance with the format conversion table. Set.
[0089]
Further, in step S110, a processing start event is issued to each converter C (step S110). The conversion processing management unit 116 of the conversion control device 10 issues a processing start event signal and transmits it to each of the converters C, for example, when the setting of all the converters C in step S108 is completed.
[0090]
Thereafter, in step S112, each converter C executes each conversion transfer process (step S112). Upon receiving the processing start event signal from the conversion control device 10, each of the converters C starts the respective conversion and transfer processes simultaneously, for example. As described above, the plurality of converters C can execute the assigned division conversion processes, for example, simultaneously and in parallel while delivering video / audio data according to the specified conversion path. For this reason, the processing speed is dramatically improved as compared with the case where all the conversion and transfer processes of one stream are executed by one converter C. By this step, one stream of a certain storage device S is transferred to another storage device S after format conversion, and stored.
[0091]
Next, in step S114, a processing end event is issued (step S114). When each converter C completes its own conversion and transfer processing, it issues a processing end event signal and transmits it to the conversion control device 10 and ends its own conversion and transfer processing process.
[0092]
Further, in step S116, completion of the transfer process is notified (step S116). Upon receiving the processing end event signals from all the converters C, the conversion controller 10 recognizes that the conversion and transfer processes in the converters C have all been completed. Next, the user is notified that the transfer process has been completed, for example, by displaying it on the monitor of the input / output unit 104 or the like. In this step, all operation flows end.
[0093]
In the above-described operation flow, conversion and transfer of one stream has been described. However, in the case of conversion and transfer of a plurality of streams, the processing content of each stream is, for example, substantially the same as that of the above-described one stream.
[0094]
As described above, in the data conversion system 1 according to the present embodiment, a plurality of converters C are processed in parallel in a transfer process between storage devices S having mutually different formats, thereby converting one stream. Processing can be sped up. Furthermore, in the conversion processing of one stream, for example, a plurality of converters C can be operated, so that, for example, the number of converters C in a non-operating state is reduced, and the utilization efficiency of the converter C is improved. In addition, regarding the conversion processing of multiple streams,
By dynamically distributing the load of each format conversion process, high-speed processing can be performed, and the utilization efficiency of the converter C is also increased.
[0095]
Further, as the number of converters C increases, the load can be dispersed, and therefore, an improvement in the conversion processing speed of a plurality of streams can be expected. Further, for example, if a high-performance converter C is introduced, further improvement in the conversion processing speed can be expected for the conversion processing of one stream.
[0096]
Further, since the conversion control device 10 can set the conversion processing function of each converter C in various ways, the flexibility of the converter C is enhanced and various format conversion processes can be executed.
[0097]
Further, by operating a plurality of converters C composed of general-purpose computers dynamically, the conversion processing can be executed even if some of the converters C fail.
[0098]
Further, by connecting the converters C composed of, for example, inexpensive general-purpose computers to each other without introducing, for example, an expensive high-speed computer, the performance of the converter C as a whole can be improved.
[0099]
The preferred embodiment of the present invention has been described with reference to the accompanying drawings, but the present invention is not limited to this example. It is obvious that a person skilled in the art can conceive various changes or modifications within the scope of the technical idea described in the claims, and those changes naturally fall within the technical scope of the present invention. It is understood to belong.
[0100]
For example, in the data conversion system 1 according to the above-described embodiment, the conversion control device 10 itself receives the user's transfer request and sets and starts the converter C. However, the present invention is not limited to this example. For example, separately from the conversion control device 10, for example, one or more transfer instruction terminals may be connected to the network 5 as client terminals for receiving, for example, one or more user transfer requests. That is, the conversion control device 10 may be configured to function as a server of the transfer instruction terminal and respond to the transfer request requested from the transfer instruction terminal.
[0101]
Further, in the data conversion system 1 according to the embodiment, all of the formats used in each storage device S are different from each other, but the present invention is not limited to this example. For example, for example, some (one or more) storage devices S may use the same format.
[0102]
Further, in the format conversion table according to the above-described embodiment, if the transfer source and the destination storage device S are determined, the conversion path can be uniquely determined, but the present invention is not limited to such an example. For example, when data is transferred from one storage device S to another storage device S, for example, a plurality of types of conversion paths may exist. In this case, the conversion processing allocating unit 108 may be configured to select a conversion path that can minimize the processing time, for example, from a plurality of conversion paths before determining the conversion pattern. Such a configuration change is relatively easy, for example, by modifying a program that defines the function of the conversion processing allocating unit 108, which is software.
[0103]
Further, in the data conversion system according to the above-described embodiment, each converter C can operate in parallel with respect to transfer of one stream, and performs processing in a pipeline manner. However, the present invention is not limited to such an example. For example, the conversion and transfer processing of each converter C is performed sequentially (that is, after the conversion processing of one converter C is completed, another converter starts the next conversion processing). It may be a configuration. In this case, the “actual processing conversion time” may be calculated by the following equation.
“Actual process conversion time” = max (each (“Actual conversion expected time” + “Actual transfer expected time”))
[0104]
The algorithm for determining the conversion pattern is not limited to the above example. For example, it is possible to suitably combine the split conversion process and the converter C so that the load of the conversion process can be optimally distributed. Any algorithm may be used.
[0105]
【The invention's effect】
As described above, according to the present invention, the format conversion processing of one data transferred between storage devices is dynamically allocated to one or more converters to distribute the load of the conversion processing. Therefore, the conversion process can be sped up. In addition, even when a plurality of data are transferred, the load of the conversion processing is dispersed for each data, so that the conversion processing of the plurality of data can be speeded up.
[0106]
In addition, by connecting inexpensive converters in parallel without using expensive high-performance converters, it is possible to improve the performance of the entire system and reduce the installation cost of the system.
[0107]
Further, even if some of the converters fail, the processing of the failed converter can be substituted for the other converters, so that the system cannot be disabled.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating an entire configuration of a data conversion system according to a first embodiment;
FIG. 2 is a block diagram illustrating a configuration of a conversion control device according to the first embodiment;
FIG. 3 is an example of a screen displayed on a monitor during transfer conversion processing.
FIG. 4 is an explanatory diagram illustrating a specific example of a format conversion table according to the first embodiment;
FIG. 5 is a flowchart illustrating an algorithm of a conversion pattern determination process according to the first embodiment;
FIG. 6 is an explanatory diagram showing a format conversion table in which specific examples of formats are set.
FIG. 7 is a table showing conversion paths and transfer times between formats that are a transfer source and a transfer destination.
FIG. 8 is a table showing combinations of converters and division conversion processing in each conversion pattern.
FIG. 9 is a table illustrating details of a method of calculating an “expected actual processing time” of each conversion pattern;
FIG. 10 is a flowchart illustrating an operation flow of the data conversion method according to the first embodiment;
[Explanation of symbols]
1: Data conversion system
5: Network
10: Conversion control device
108: Conversion processing allocating unit
110: Format conversion table management unit
112: Conversion pattern determination unit
114: Converter setting section
116: Conversion processing management unit
S (S1, S2, ...): storage device
C (C1, C2, ...): Converter

Claims (13)

A plurality of storage devices for recording and reproducing data in a unique format;
A plurality of converters for performing format conversion processing of the data transferred between the storage devices;
A conversion control device that instructs the converter to perform a format conversion process of the data transferred between the storage devices in response to a transfer request from outside;
Is a data conversion system interconnected via a network,
The conversion control device comprises:
A format conversion process of the data transferred between the storage devices is divided and dynamically assigned to one or more of the converters so that a load of the conversion process is optimally distributed. , Data conversion system. A plurality of storage devices for recording and reproducing data in a unique format, and a plurality of converters for format-converting the data transferred between the storage devices, which are mutually connected via a network;
A conversion control device for instructing the converter to perform a format conversion process of the data transferred between the storage devices in response to an external transfer request, comprising:
A format conversion process of the data transferred between the storage devices is divided and dynamically assigned to one or more of the converters so that a load of the conversion process is optimally distributed. , Conversion control device. 3. The conversion control device according to claim 2, wherein the divided format conversion processes are assigned to the one or more converters such that the entire conversion processing time is minimized. 3. The conversion control device according to claim 2, wherein each of the converters is controlled so as to execute the assigned format conversion process concurrently while transferring the data. In accordance with the plurality of transfer requests, one or two or more of the plurality of data are converted so that the format conversion processing of the plurality of data transferred between the storage devices is optimally distributed. 3. The conversion control device according to claim 2, wherein the conversion control device is dynamically assigned to the converter. 3. The conversion control device according to claim 2, wherein the data is digital video / audio stream data. Playing computer:
A plurality of storage devices for recording and reproducing data in a unique format, and a plurality of converters for format-converting the data transferred between the storage devices, which are mutually connected via a network;
A conversion control device that instructs the converter to perform a format conversion process of the data transferred between the storage devices in response to a transfer request from the outside,
A conversion control device that divides the format conversion process of the data transferred between the storage devices and dynamically allocates the data to one or more of the converters so that the load of the conversion process is optimally distributed;
A program characterized by functioning as a program. A computer-readable recording medium, comprising:
Play computer
A plurality of storage devices for recording and reproducing data in a unique format, and a plurality of converters for format-converting the data transferred between the storage devices, which are mutually connected via a network;
A conversion control device that instructs the converter to perform a format conversion process of the data transferred between the storage devices in response to a transfer request from the outside,
A conversion control device that divides the format conversion process of the data transferred between the storage devices and dynamically allocates the data to one or more of the converters so that the load of the conversion process is optimally distributed;
A computer-readable recording medium that stores a program that functions as a computer. A data conversion method for performing format conversion processing of the data transferred between a plurality of storage devices that record and reproduce data in a unique format using a plurality of converters in response to an external transfer request:
A format conversion process for data transferred between the storage devices is divided and dynamically assigned to one or more of the converters so that a load of the conversion process is optimally distributed. Data conversion method. 10. The data conversion method according to claim 9, wherein the divided format conversion processing is assigned to the one or more converters such that the entire conversion processing time is minimized. 10. The data conversion method according to claim 9, wherein each of the converters executes the assigned format conversion processing in parallel while transferring the data. In accordance with the plurality of transfer requests, one or two or more of the plurality of data are converted so that the format conversion processing of the plurality of data transferred between the storage devices is optimally distributed. The data conversion method according to claim 9, wherein the data is dynamically assigned to a converter. The data conversion method according to claim 9, wherein the data is digital video / audio stream data.

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