JP5530901B2 - Data receiving apparatus, data receiving method and program - Google Patents

Description

  The present invention relates to a data receiving apparatus, a data receiving method, and a program.

  As a new content distribution method, a service called IPDC (Internet Protocol Data Cast) that transmits files by broadcast waves has been attracting attention.

  IPDC is a technology for transmitting data using IP (Internet Protocol) packets and using broadcast waves. By applying IPDC, file format contents can be broadcast simultaneously using broadcast waves. Can be delivered to.

  Patent Document 1 discloses a data receiving apparatus that receives a file transmitted simultaneously.

JP-A-2005-222401

  When receiving large data such as moving image content, the data receiving device disclosed in Patent Document 1 is divided at the transmission source and transmitted as a packet. Therefore, the data is extracted from these received packets and reconstructed. It is necessary to perform processing.

  A process for reconstructing data is highly burdened. In particular, when reconstructing a plurality of data at the same time, that is, when viewing a plurality of moving image contents at the same time, a large load is imposed on the data receiving apparatus.

  When processing load is applied to the data reception device by reconstructing a plurality of data at the same time, for example, if the data reception device is a mobile terminal, the consumption time of the rechargeable battery is shortened, and the user can feel free to use multiple video content The problem of not being able to enjoy etc. occurs.

  The present invention has been made in view of the above circumstances, and can reduce the load of data reconstruction processing and can operate without any trouble even when receiving a plurality of large data, An object is to provide a data receiving method and program.

In order to achieve the above object, a data receiving apparatus according to the first aspect of the present invention provides:
A packet receiving means for receiving a packet transmitted from the data transmitting device;
When the packet received by the packet receiving unit is divided, a divided packet storage unit that stores the packet for each identifier for identifying data that is a source of the packet;
Priority acquisition means for obtaining a processing priority for each identifier based on the packet stored by the divided packet storage means ;
If the packet is the divided before Symbol dividing the packet storage means is stored, according to the processing priority includes a packet reconstruction means for determining whether to reconstruct the packets the storage, and
It is characterized by that.

The priority acquisition means includes
Unit time size acquisition means for acquiring a size per unit time indicating the packet transfer rate may be provided.
Further, the unit time size acquisition means includes:
Obtain the size of the packet stored in the divided packet storage means per unit time ,
The priority acquisition means includes
Includes a scheduled time acquisition hand stage the packet reconstruction unit for each of the identifier obtaining the reconstruction is completed scheduled time of the packets stored in the divided packet storage means,
The processing priority may be obtained based on the size obtained by the unit time size obtaining unit and the scheduled time obtained by the scheduled time obtaining unit.

Furthermore, when the divided packet storage means stores the packets of the plurality of identifiers,
The priority acquisition means includes
For each identifier, it is determined whether or not the size obtained by the unit time size acquisition means exceeds a predetermined threshold. If the size does not exceed the predetermined threshold, the processing priority of the identifier is set to a low level. ,
When there are a plurality of identifiers exceeding the predetermined threshold, the identifier with the latest scheduled time obtained by the scheduled time acquisition unit may be obtained, and the processing priority of the identifier may be set to a high level.

In order to achieve the above object, a data receiving method according to the second aspect of the present invention includes:
A data receiving method executed by a data receiving device that receives a packet from a data transmitting device,
A packet receiving step for receiving a packet transmitted from the data transmitting device;
When the packet received by the packet receiving step is divided, a divided packet storing step for storing the packet for each identifier for identifying data that is a source of the packet;
A priority obtaining step for obtaining a processing priority for each identifier based on the packet stored in the divided packet storing step ;
If the packet being Oite the divided before Symbol dividing the packet storage step are stored, according to the processing priority, and the packet reconstruction step of determining whether to reconstruct the packets the storage, the Prepare
It is characterized by that.

In order to achieve the above object, a data receiving program according to the third aspect of the present invention provides:
Computer
A packet receiving means for receiving a packet transmitted from the data transmitting device;
When the packet received by the packet receiving unit is divided, a divided packet storage unit that stores the packet for each identifier for identifying data that is a source of the packet;
Priority acquisition means for obtaining a processing priority for each identifier based on the packet stored by the divided packet storage means ;
If the packet is the divided before Symbol dividing the packet storage means is stored, according to the processing priority, the packet reconstruction unit that determines whether to reconstruct the packets the storage, to function as,
It is characterized by that.

  According to the present invention, it is possible to reduce the load of data reconstruction processing, and it is possible to operate without any trouble even when a plurality of large data is received.

It is a block diagram which shows the structural example of the data receiver which concerns on embodiment of this invention. It is a figure for demonstrating the outline of the reconstruction process of a packet. It is a flowchart which shows an example of the packet process in the data receiver of FIG. It is a flowchart which shows an example of the priority process in the data receiver of FIG. It is a flowchart which shows an example of the priority acquisition process in the data receiver of FIG. It is a figure for demonstrating the specific example of the priority process in the data receiver of FIG.

  First, a method for receiving file format content by broadcast waves will be described. As shown in FIG. 2, the data transmission server 2 that distributes content divides a file such as a moving image to be transmitted into source blocks, and further divides into FLUTE (File Delivery over Directional Transport) packets defined by RFC3926. Send packets in a carousel manner. In the carousel method, for example, when the original data is divided from packet 0 to packet 10 and transmitted, packet 0, packet 1,... Packet 10, packet 0, packet 1,. This is a method of transmitting in order.

  At this time, the leading packet is an FDT (File Delivery Table). The FDT is a table having information such as the order of the above-described divided FLUTE packets and the position of the original data. The leading packet is determined by the value of TOI (Transport Object Identifier), and when it is 0, it means that it is the leading packet.

A general broadcast wave reception process of the data receiving apparatus 1 that receives a broadcast wave is performed according to the following flow.
(1) A broadcast wave is received, and an MPEG2-TS (Moving Picture Experts Group 2-Transport Stream) packet is acquired.
(2) Reconstruct the MPEG2-TS packet and obtain a UDP / IP (User Datagram Protocol / Internet Protocol) packet.
(3) The FLUTE packet is acquired from the UDP / IP packet.
(4) From the header information of the FLUTE packet, obtain a packet having a TOI of 0 (first packet).
(5) The FLUTE packet is received until the next FDT is received.
(6) If necessary, correct by FEC (Forward Error Correction) and reconstruct the original data.

  In the present embodiment, as shown in FIG. 2, the data to be divided by the data transmission server 2 is “divided source data”, the size of the data is “divided source data size”, and each transmitted packet is “divided packet”. Called. Further, the divided packets received by the data receiving apparatus 1 are referred to as “received packets”, the total size of the received divided packets is referred to as “received data size”, and the total size of the unreceived divided packets is referred to as “unreceived data size”. .

  Subsequently, a data receiving apparatus according to an embodiment of the present invention will be described with reference to the drawings.

  As shown in FIG. 1, the data receiving apparatus 1 includes a transmission / reception unit 10, a main storage unit 11, an external storage unit 12, a control unit 13, a display unit 14, and an operation unit 15. . The transmission / reception unit 10, the main storage unit 11, the external storage unit 12, the display unit 14, and the operation unit 15 are all connected to the control unit 13 via the internal bus 19.

  The transmission / reception unit 10 includes an antenna that receives a broadcast wave, and receives the broadcast wave from the data transmission server 2 via the antenna. When receiving the broadcast wave, the transmission / reception unit 10 converts it into digital data and supplies the converted data to the control unit 13.

  The main storage unit 11 includes a RAM (Random-Access Memory) and the like, reads the program 16 stored in the external storage unit 12, and is also used as a work area for the control unit 13.

  The external storage unit 12 includes a nonvolatile memory such as a flash memory, a hard disk, a DVD-RAM (Digital Versatile Disc Random Access Memory), a DVD-RW (Digital Versatile Disc ReWriteable), and packet processing and priority control described later. A program 16 for causing the control unit 13 to perform processing is stored in advance, and data stored in the external storage unit 12 is supplied to the control unit 13 in accordance with an instruction from the control unit 13, and the data supplied from the control unit 13 Remember. In addition, the external storage unit 12 includes a packet database (hereinafter referred to as packet DB) 130 and a priority database (hereinafter referred to as priority DB) 140, and further, an EPG (Electronic Program Guide) in moving image content, and the like. Is also provided.

  The packet DB 130 is a database that stores a packet when a divided packet is received from the data transmission server 2, and data reconstruction processing is also performed with reference to the packet DB 130.

  The priority DB 140 is a database that stores packet priority information, and stores priority values (high, medium, low, etc.) and operations according to the priorities (processing, discard, stay, etc.). Yes.

  The control unit 13 includes a CPU (Central Processing Unit) and the like, and executes packet processing and priority processing described later according to a program 16 stored in the external storage unit 12. The control unit 13 includes a packet processing unit 110 and a priority processing unit 120 as main functions provided by the program 16. The packet processing unit 110 includes a header processing unit 111 and a packet reconstruction unit 112, and the priority processing unit 120 includes an accumulation rate measurement unit 121 and a priority acquisition unit 122.

  The header processing unit 111 performs processing such as the above-described broadcast wave reception processing, decoding of received packets, analysis of header information, header removal, and the like, and further includes a timer function. The header processing unit 111 also determines whether or not the received packet is a fragmented packet, and if it is a fragmented packet, stores the packet in the packet DB 130 for each packet identifier. The identifier is an identifier assigned to each division source data, can specify the division source data, and is, for example, a file name of the division source.

  The packet restructuring unit 112 reconstructs the division source data based on the divided packet. At this time, the packet restructuring unit 112 refers to the priority of the packet stored in the priority DB 140, and if there is a corresponding priority, processes the divided packet according to the priority.

  The accumulation rate measurement unit 121 refers to the received packet stored in the packet DB 130 and obtains the ratio of the received data size to the division source data size. Further, the accumulated amount of received packets per unit time (size / sec, etc.) is also obtained. The accumulated amount per unit time represents the transfer rate (bit per second etc.) for each identifier.

  The priority obtaining unit 122 obtains the priority of the packet for each identifier based on the value obtained by the accumulation rate measuring unit 121, and stores the obtained priority in the priority DB 140. The priority is obtained from the value obtained by the accumulation rate measuring unit 121, but is not limited thereto. For example, an identifier having a high priority may be set in advance by the user, or the priority of a packet used by the user (for example, a packet of moving image content being viewed) may be increased. This priority is stored in the priority DB 140.

  The display unit 14 includes an LCD (Liquid Crystal Display) or an organic EL (Electro Luminescence). The display unit 14 displays each data and information.

  The operation unit 15 includes an input device such as a keyboard, a mouse, an operation key, and a touch panel, and an interface device that connects the input device and the like to the internal bus 19. The operation unit 15 has a function of inputting a user instruction.

  The above is the configuration of the data receiving apparatus 1.

  Next, the operation of the data receiving apparatus 1 will be described using the flowcharts shown in FIGS. In the data receiving apparatus 1, the packet processing unit 110 and the priority processing unit 120 provided by the program 16 operate. Note that the packet processing unit 110 and the priority processing unit 120 operate in parallel.

  When the transmission / reception unit 10 supplies packet data to the control unit 13, the packet processing unit 110 starts the processing of the packet processing unit 110 illustrated in FIG.

  The header processing unit 111 performs packet reception processing (S100). Packet reception processing includes, for example, the above-described broadcast wave reception processing (1) to (3), CRC (Cyclic Redundancy Check) of received packets, decryption processing of encrypted packets, and determination of packet integrity Processing.

  Next, the header processing unit 111 executes a header analysis process (S101). In the header analysis process, each piece of header information attached to the packet is extracted. For example, analysis of FLUTE, UDP, TCP (Transmission Control Protocol), ULE (Unidirectional Lightweight Encapsulation) header, etc. is executed. When a FLUTE packet is received here, the header processing unit 111 determines a packet whose TOI is 0 based on the header information of the FLUTE packet, and acquires the FDT.

  Further, the header processing unit 111 determines whether or not the received packet is a fragmented packet (S102). If the packet is a fragmented packet, the header processing unit 111 classifies the divided packet for each identifier and stores the fragmented packet in the packet DB 130 (S104). ). At this time, the header processing unit 111 also stores the packet reception time in the packet DB 130 at the same time.

  The method for determining whether or not the packet is a divided packet is arbitrary. For example, the determination may be made based on the field of the IP header of the received packet, or may be made based on FDT.

  If the received packet is not a fragmented packet, the header processing unit 111 executes non-segmented packet processing (S103). Non-divided packet processing executes processing for sending a packet to an application running on the data receiving apparatus 1, processing for relaying the received packet, and the like.

  When the header processing unit 111 stores the fragmented packet in the packet DB 130, the packet restructuring unit 112 refers to the priority DB 140 and determines whether there is a priority corresponding to the received fragmented packet (S105). . If there is a corresponding priority, the priority is specified (S106), and it is determined whether or not the packet is to be processed based on the priority (S107). When there is no corresponding priority, or when it is determined that the packet is to be processed based on the priority, the received packet is referred to and the division source data size is acquired (S108).

  If it is determined that the packet is not processed according to the priority, the packet restructuring unit 112 discards the received packet as it is (S111) and ends the processing.

  The determination of the received packet according to the priority follows the definition stored in the priority DB 140. This definition is composed of priority by identifier and operation by priority. Examples of operations according to priority include “receive all packets with high priority”, “receive 50% packets during priority”, and “discard all packets when low priority”. However, the present invention is not limited to this, and the packet may be retained, and the operation may be defined according to an accumulation amount or a unit time accumulation amount described later. In the present embodiment, for the sake of easy understanding, the priority to be defined is three levels: high, medium, and low.

  Even when the received packet is discarded according to the priority, when the content in the file format is received by the broadcast wave, the packet is transmitted by the carousel method as described above. It is possible to receive. That is, discarding a predetermined percentage of received packets means delaying the completion time of reconstruction.

  Further, the method of obtaining the division source data size is arbitrary, and can be obtained from, for example, the content-length of the FDT.

  Next, the packet restructuring unit 112 reconstructs the divided packet data (S109), and determines whether or not the data reconstruction is completed (S110). This determination is made by comparing the division source data size with the received data size, but is not limited to this, and may be made based on the number of received divided packets or whether the last divided packet has been received. . Further, the data reconstruction method is arbitrary. For example, the data may be reconstructed based on the IP header, or may be reconstructed while complementing with FEC based on the FDT.

  The packet reconstruction unit 112 ends the packet processing when the data reconstruction is not completed, and processes the data for which the reconstruction is completed when the data reconstruction is completed (S103), and terminates the packet processing. .

  Next, when the packet processing unit 110 stores the divided packet in the packet DB 130, the priority processing unit 120 starts the processing of the priority processing unit 120 illustrated in FIG.

  The accumulation rate measuring unit 121 refers to the packet DB 130 and acquires the division source data size (S200). Since packet data of all identifiers currently being reconstructed is stored in the packet DB 130, the division source data size of all identifiers is acquired.

  Next, the accumulation rate measuring unit 121 acquires the received data size with reference to the packet DB 130 (S201).

  Next, the accumulation rate measuring unit 121 calculates an accumulation rate (S202). Here, the accumulation rate is the ratio of the received data size to the division source data size. That is, the calculation result of “division source data size ÷ received data size” is obtained.

  Next, the accumulation rate measuring unit 121 obtains an accumulation amount (size / time) per unit time (S203). This is calculated by “received data size ÷ elapsed time”. The elapsed time can be obtained based on the reception time stored in the packet DB 130, and the unit time can be arbitrarily determined. For example, milliseconds or microseconds may be used.

  When the accumulation rate measurement unit 121 obtains these two values, the priority acquisition unit 122 executes a priority acquisition process (S204) and ends the priority process.

  The priority acquisition process in the priority acquisition unit 122 determines whether or not data of a plurality of identifiers is being reconstructed as shown in FIG. 5 (S300). Since the divided packets are classified for each identifier and stored in the packet DB 130, this determination can be made by referring to the packet DB 130.

  When the data of one identifier is reconstructed (not plural), the priority acquisition unit 122 ends the priority acquisition process. When the data of a plurality of identifiers are reconstructed, the priority acquisition unit 122 obtains the time necessary for accumulation for each identifier, that is, the time necessary for reception of all the divided packets necessary for reconstruction (S301). ). This time is obtained by “unreceived data size ÷ unit time accumulated amount”.

  Next, the priority acquisition part 122 calculates | requires the reconstruction completion estimated time for every identifier (S302). This can be obtained by adding the time required for accumulation obtained in step S301 to the current time.

  Next, the priority acquisition unit 122 determines whether the unit time accumulation amount exceeds the threshold for each identifier (S303). Here, the threshold value of the unit time accumulation amount can be arbitrarily defined, and may be stored in advance in the storage unit or may be hard-coded.

Since the unit time accumulation amount represents the packet transfer rate, the processing here is
When the packet transfer rate is below a certain rate, the possibility of some kind of communication trouble is taken into consideration.

  If the unit time accumulation amount does not exceed the threshold, the priority acquisition unit 122 stores the priority of the corresponding identifier in the priority DB 140 with the lowest priority (S304). Further, by notifying the display unit 14 that the reception of the corresponding identifier is interrupted, the user is notified (S305), and the priority acquisition process is terminated. When the unit time accumulation amount exceeds the threshold, the priority acquisition unit 122 determines whether there are a plurality of corresponding identifiers (S306).

  When there is only one corresponding identifier, the priority acquisition unit 122 sets the priority of the identifier to the highest and stores it in the priority DB 140 (S307), and ends the priority acquisition processing. When there are a plurality of corresponding identifiers, the priority acquisition unit 122 determines whether there is an identifier with a preset high priority (S308).

  When there is no identifier with a high priority set in advance, the priority acquisition unit 122 determines the expected completion time for reconstruction of each corresponding identifier, and sets the highest priority for the identifier with the earliest expected reconstruction completion time. Is stored in the priority DB 140 (S309), and the priority acquisition process is terminated. If there is an identifier with a high priority set in advance, the priority acquisition unit 122 determines whether there are a plurality of corresponding identifiers (S310).

  When there is only one corresponding identifier, the priority acquisition unit 122 sets the priority of the identifier highest and stores it in the priority DB 140 (S311), and ends the priority acquisition processing. When there are a plurality of corresponding identifiers, the priority acquisition unit 122 sets the priority of the identifier having the latest estimated reconstruction completion time to the highest priority and stores it in the priority DB 140 (S312), and ends the priority acquisition processing.

  Note that the data receiving apparatus 1 can store priorities in the priority DB 140 in advance other than the priorities obtained by the priority acquisition unit 122.

  The priority processing may be started due to the expiration of a preset timer.

  As described above, when the priority processing according to the present embodiment is executed, the priority processing unit 120 assigns a priority for each identifier according to the data reconstruction state. As a result, the packet processing unit 110 can concentrate on the processing of high priority packets, and can reduce the processing load related to data reconstruction.

  Subsequently, in order to facilitate understanding, a specific operation of the data receiving apparatus 1 will be described. In the following specific example, the operation when the data receiving device 1 is mounted on a mobile phone and the user is watching the moving image content will be described.

  As shown in FIG. 6, the external storage unit 12 stores an EPG (program guide data) and a divided packet. The EPG is a program table related to video content on a racetrack, and is stored in the external storage unit 12 in advance. The data receiving apparatus 1 receives broadcast waves for three sessions, extracts packets, and reconstructs data. The dotted line indicates the current time. In this case, the current time is 10:37.

  The hatched portion in the EPG is the content currently received by the data receiving apparatus 1, the hatched portion in the packet DB 130 is a received packet, and the blank portion is an unreceived packet.

  Note that the identifier of the packet transmitted for each session can be obtained from the above FDT.

  The accumulation rate measurement unit 121 refers to the packet DB 130 and acquires the division source data size. Referring to FIG. 6, the division source data sizes of all sessions 1, 2, and 3 are 15 Mbytes.

  Next, the accumulation rate measurement unit 121 acquires the received data size. Referring to FIG. 6, the received data size of session 1 is 10 Mbytes, the received data size of session 2 is 5 Mbytes, and the received data size of session 3 is 10 Mbytes.

  Next, the accumulation rate measuring unit 121 obtains the accumulation rate. This calculation is performed according to “Received data size ÷ Division source data size”. For example, in the case of session 1, since the received data size is 10 Mbytes and the division source data size is 15 Mbytes, the accumulation rate is 2/3, that is, about 67%.

  Next, the accumulation rate measurement unit 121 obtains an accumulation amount per unit time. This calculation is performed based on the time during which the content of each session is received, that is, the time during which reconstruction processing is performed. For example, in the case of session 1, since the received data size is 10 Mbytes and the elapsed time is 17 minutes (10: 37-10: 20), the unit time accumulation amount is about 0.59 Mbyte / min. Become.

  When each value is obtained as described above, the accumulation rate measurement unit 121 obtains the value shown in FIG. The unit of the unit time accumulation amount is “Mbyte / minute”. This unit is not limited to a minute unit, and may be a second unit, or may be a millisecond or a microsecond unit. Also, the size unit is not limited to the Mbyte unit, but may be a Kbyte unit, a byte unit, or a bit unit.

  Next, the priority acquisition unit 122 determines whether or not a packet with a plurality of identifiers is being reconstructed. As shown in FIG. 6, since the data reception device 1 receives and reconstructs the contents of a plurality of sessions, the priority acquisition unit 122 determines that a packet with a plurality of identifiers is reconstructed.

  Next, the priority acquisition part 122 calculates | requires the time required for accumulation | storage, ie, the estimated remaining time for which reconstruction is completed for every identifier. This calculation is performed by “unreceived data size ÷ unit time accumulation amount”. For example, in the case of session 1, since the unreceived data size is 5 Mbytes and the unit time accumulation amount is 0.59 Mbytes / min, the remaining time is calculated to be about 8.5 minutes.

  Next, the priority acquisition part 122 calculates | requires the reconstruction completion estimated time for every identifier. This calculation is performed by “current time + expected remaining time”. For example, in the case of session 1, since the current time is 10:37 and the expected remaining time is approximately 8.5 minutes, the estimated rebuild completion time is approximately 10:46 minutes.

  When each value is obtained as described above, the priority acquisition unit 122 obtains the value shown in FIG.

  Next, the priority acquisition unit 122 determines whether the unit time accumulation amount for each identifier exceeds a threshold value. When the threshold is defined as 0.6 Mbyte / min in advance, the content of session 1 is calculated to be equal to or lower than the threshold, and the content of sessions 2 and 3 is determined to be equal to or higher than the threshold.

  Since the session 1 is below the threshold, the priority acquisition unit 122 stores the lowest priority in the priority DB 140 so that the content packet of the session 1 is not received thereafter. Further, a reception interruption notification is transmitted to the display unit 14 to notify the user that reception of the content of the session 1 has been stopped.

  Next, the priority acquisition unit 122 determines whether there are a plurality of identifiers exceeding the threshold. Since the contents exceeding the threshold are the contents of the sessions 2 and 3, the priority acquisition unit 122 next determines whether there is an identifier having a high priority.

  Here, a case where the priority is not set in the priority DB 140 in advance and a plurality of patterns when the priority is set in advance will be described.

  First, as illustrated in FIG. 6C, when the priority is not set in the priority DB 140 in advance, the priority acquisition unit 122 sets the highest priority for the content with the earliest expected reconstruction completion time. And stored in the priority DB 140.

  That is, since the estimated reconstruction completion time of the content of session 3 is the earliest, the priority acquisition unit 122 sets the priority of the content of session 3 to the highest and sets the priority of the content of session 2 to the normal priority. These priorities are stored in the priority DB 140. As described above, when the priority acquisition unit 122 determines the priority, the priority stored in the priority DB 140 is as illustrated in FIG.

  In this way, the priority acquisition unit 122 stores the priority of the content of the session 3 in the priority DB 140 at a high level, so that the packet reconstruction unit 112 preferentially reconstructs the packet of the content of the session 3. Can do.

  Note that the priority of the content of the session 2 in this case does not need to be a normal priority. For example, the priority may be set to the lowest priority and dedicated to data reconstruction of the content of the session 3.

  Next, as illustrated in FIG. 6D, when the priority of the content “Motobaba entrance” is set in advance, the priority acquisition unit 122 determines whether there are a plurality of corresponding contents. If there is only one corresponding content, the priority of the content is made highest and stored in the priority DB 140.

  That is, since only the content of session 2 corresponds to “main Baba entrance”, the priority acquisition unit 122 sets the priority of the content of session 2 to the highest priority and stores it in the priority DB 140, and prioritizes the content of session 3. The degree is stored in the priority DB 140 with a normal priority. As described above, when the priority acquisition unit 122 obtains the priority, the priority stored in the priority DB 140 is as illustrated in FIG.

  In this way, the priority acquisition unit 122 stores the priority of the content of the session 2 at a high level in the priority DB 140, so that the packet reconstruction unit 112 preferentially reconstructs the packet of the content of the session 2 Can do.

  Note that the priority of the content of the session 3 in this case does not need to be a normal priority. For example, the priority may be set to the lowest priority and dedicated to the data reconstruction of the content of the session 3.

  Next, as shown in FIG. 6 (e), a case will be described in which the priorities of the contents “viewing the user” and “near the betting ticket release deadline” are set in advance.

  First, when the user is viewing the content of the session 2, the priority acquisition unit 122 stores the highest priority of the content in the priority DB 140, and when viewing the content of the session 3. The highest priority of the content is stored in the priority DB 140.

  However, when the user is not viewing the content of session 1 or the content of sessions 2 and 3, the priority acquisition unit 122 determines content that is close to the betting ticket release deadline.

  In this case, since the contents of both the sessions 2 and 3 are applicable, the priority acquisition unit 122 sets the priority of the content with the latest reconstruction completion estimated time as the highest priority and stores it in the priority DB 140.

  That is, since the predicted reconstruction completion time of the content of session 2 is later, the priority acquisition unit 122 sets the priority of the content of session 2 to the highest and stores it in the priority DB 140. As described above, when the priority acquisition unit 122 obtains the priority, the priority stored in the priority DB 140 is as illustrated in FIG.

  In this way, the priority acquisition unit 122 stores the priority of the content of the session 2 at a high level in the priority DB 140, so that the packet reconstruction unit 112 preferentially reconstructs the packet of the content of the session 2 Can do.

  Note that the priority of the content of the session 3 in this case does not need to be a normal priority. For example, the priority may be set to the lowest priority and dedicated to the data reconstruction of the content of the session 3.

  As described above, even when the data receiving apparatus 1 according to the present embodiment is mounted on a mobile phone and receives a plurality of moving image contents at the same time, priority can be given to each content. By reconstructing data according to the above, it is possible to reduce the load and further reduce the battery consumption.

  In addition, since the data receiving apparatus 1 according to the present embodiment can set the content whose priority is to be increased in advance, the content that the user wants to view can be preferentially received. Therefore, the content intended by the user can be preferentially received, and the user's stress can be reduced.

[Modification]
The present invention is not limited to the above embodiment, and various modifications and applications are possible. In the above-described embodiment, an example in which a mobile phone is mounted has been described. However, the present invention is not limited to this. The present invention can also be applied to various network devices.

  Further, in the present embodiment, the specific operation when transmitting and receiving file format contents by broadcast waves has been described. However, the present invention is not limited to this, and the present invention can be applied to a data receiving apparatus that transmits and receives packets on a network. Can be applied. Naturally, the present invention can be applied to a device having a data reconstruction function.

  Moreover, although this embodiment demonstrated the data receiver 1 comprised from the transmission / reception part 10 provided with the antenna which receives a broadcast wave, it is not restricted to this. For example, when the data reception device 1 and the data transmission server are connected via a network, the transmission / reception unit 10 includes a network termination device or a wireless communication device connected to the network, and a serial interface or a LAN (Local Area) connected to them. (Network) interface may be used. The transmission / reception unit 10 may receive a packet from the data transmission server 2 via the network and supply the received packet to the control unit 13.

  In this embodiment, the priority is obtained based on the received data size, the division source data size, and the time related to the reconstruction. However, the priority is not limited to this. For example, the source, the destination IP (Internet Protocol) address, The priority may be obtained from the source, destination port number, and the like.

  In this embodiment, the processing according to the priority is determined in advance. However, the processing is not limited to this. For example, “if the accumulation rate is 75% or more, 75% of packets are received” or the like. The operation may be defined according to the rate and other obtained values.

  In the present embodiment, content whose priority is to be increased can be set in advance. However, the present invention is not limited to this. For example, content whose priority is to be decreased in advance or content whose priority is not changed under any circumstances is set. can do.

  In the present embodiment, the priority is obtained when the packet with a plurality of identifiers is reconstructed to reduce the load. However, the present invention is not limited to this, and priority is given even when a single identifier is reconstructed. The load may be reduced by finding the degree.

  In the present embodiment, the content whose unit time accumulation amount is less than the threshold is set as the lowest priority, the content with the short delivery end time, the content with the estimated reconstruction completion time is late, and the preset content with the highest priority. However, the present invention is not limited to this, and may not be extremely high and may not be the lowest. For example, the priority may be divided into 10 levels and selected from a low level priority (1 to 5) and a high level priority (6 to 10).

  In addition, the data receiving apparatus 1 according to the present embodiment can be realized using a normal computer system, not a dedicated system. For example, the program 16 for executing the above operation is stored and distributed in a computer-readable recording medium (flexible disk, CD-ROM, DVD-ROM, etc.), and the program 16 is installed in the computer. Thus, the data receiving device 1 that executes the above-described processing may be configured. Alternatively, the program 16 may be stored in a storage device included in a server device on a communication network such as the Internet, and the data receiving device 1 may be configured by being downloaded by a normal computer system.

  When the functions of the data receiving device 1 are realized by sharing of an OS (operating system) and an application program, or by cooperation between the OS and the application program, only the application program portion is stored in a recording medium or a storage device. May be.

  It is also possible to superimpose the program 16 on a carrier wave and distribute it via a communication network. For example, the program 16 may be posted on a bulletin board (BBS: Bulletin Board System) on a communication network, and the program 16 may be distributed via the network. The program 16 may be started and executed in the same manner as other application programs under the control of the OS, so that the above-described processing may be executed.

DESCRIPTION OF SYMBOLS 1 Data receiver 2 Data transmission server 10 Transmission / reception part 11 Main memory part 12 External storage part 13 Control part 14 Display part 15 Operation part 16 Program 19 Internal bus 110 Packet processing part 111 Header processing part 112 Packet reconstruction part 120 Priority processing Unit 121 storage rate measurement unit 122 priority acquisition unit 130 packet database 140 priority database

Claims (6)

A packet receiving means for receiving a packet transmitted from the data transmitting device;
When the packet received by the packet receiving unit is divided, a divided packet storage unit that stores the packet for each identifier for identifying data that is a source of the packet;
Priority acquisition means for obtaining a processing priority for each identifier based on the packet stored by the divided packet storage means ;
If the packet is the divided before Symbol dividing the packet storage means is stored, according to the processing priority includes a packet reconstruction means for determining whether to reconstruct the packets the storage, and
A data receiving apparatus. The priority acquisition means includes
Unit time size obtaining means for obtaining a size per unit time indicating the transfer rate of the packet;
The data receiving device according to claim 1. The unit time size acquisition means includes:
Obtain the size of the packet stored in the divided packet storage means per unit time ,
The priority acquisition means includes
Includes a scheduled time acquisition hand stage the packet reconstruction unit for each of the identifier obtaining the reconstruction is completed scheduled time of the packets stored in the divided packet storage means,
Obtaining the processing priority based on the size obtained by the unit time size obtaining unit and the scheduled time obtained by the scheduled time obtaining unit;
The data receiving apparatus according to claim 2 . When the divided packet storage means stores the packets of a plurality of identifiers,
The priority acquisition means includes
For each identifier, it is determined whether or not the size obtained by the unit time size acquisition means exceeds a predetermined threshold. If the size does not exceed the predetermined threshold, the processing priority of the identifier is set to a low level. ,
When there are a plurality of the identifiers exceeding the predetermined threshold, the identifier with the latest scheduled time obtained by the scheduled time acquisition means is obtained, and the processing priority of the identifier is set to a high level.
The data receiving apparatus according to claim 3 . A data receiving method executed by a data receiving device that receives a packet from a data transmitting device,
A packet receiving step for receiving a packet transmitted from the data transmitting device;
When the packet received by the packet receiving step is divided, a divided packet storing step for storing the packet for each identifier for identifying data that is a source of the packet;
A priority obtaining step for obtaining a processing priority for each identifier based on the packet stored in the divided packet storing step ;
If the packet being Oite the divided before Symbol dividing the packet storage step are stored, according to the processing priority, and the packet reconstruction step of determining whether to reconstruct the packets the storage, the Prepare
A data receiving method. Computer
A packet receiving means for receiving a packet transmitted from the data transmitting device;
When the packet received by the packet receiving unit is divided, a divided packet storage unit that stores the packet for each identifier for identifying data that is a source of the packet;
Priority acquisition means for obtaining a processing priority for each identifier based on the packet stored by the divided packet storage means ;
If the packet is the divided before Symbol dividing the packet storage means is stored, according to the processing priority, the packet reconstruction unit that determines whether to reconstruct the packets the storage, to function as,
A data receiving program characterized by the above.

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