JP4414065B2 - Data transmission method, data transmission device, and data reception device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a data transmission method, a data transmission device, and a data reception device, and in particular, when transmitting data in units of packets between a plurality of information processing devices, the transmission side compresses data corresponding to a predetermined packet, The receiving side relates to data transmission processing for restoring compressed data corresponding to a predetermined packet.
[0002]
[Prior art]
Currently, TCP / IP (Transmission Control Protocol / Internet Protocol), UDP / IP (User Datagram Protocol / Internet Protocol), and the like are used as typical transmission protocols for transmitting data on the Internet.
However, when data is transmitted on a packet basis using these transmission protocols via a transmission path of low to medium bit rate (9600 bps to 64 Kbps), each transmission protocol such as TCP, UDP, or IP is included in the packet. May be included in the communication overhead, that is, the amount of information in the header portion of the packet may be considerably larger than the amount of information in the data portion.
[0003]
For example, when 10-byte data is transmitted by the UDP / IP protocol, the total size of the UDP / IP packet is 38 bytes even though the data part size of the UDP / IP packet used for transmission by this protocol is 10 bytes. It becomes. In other words, the total size of the UDP / IP packet is about four times the amount of information of the actually transmitted data. If such communication overhead occurs frequently, as a result, the effective transmission rate of data on the transmission path is significantly reduced.
[0004]
Currently, the V. Jacobson header compression method defined in RFC (Request For Comments) 1144 and RFC (Request For Comments) 2508 is used as a technique for reducing communication overhead by using a plurality of transmission protocols.
This header compression method will be described below.
FIG. 28 (a) shows a data transmission system to which the conventional V. Jacobson header compression method is applied.
In the data transmission system Cs1, a gateway server Sga is connected to the Internet In, and a terminal device Teq such as a personal computer is connected to the gateway server Sga by a modem, ISDN (Integrated Service Digital Network), LAN (Local Area Network). ) Etc. are connected via a wired line. Here, the connection between the terminal device Teq and the gateway server Sga is a point-to-point connection that directly connects the transmission source and the transmission destination via a wired line, and is on the transmission path between the terminal device Teq and the gateway server Sga. Then, a packet subjected to data compression processing by the V.Jacobson header compression method is transmitted by a transmission protocol such as a PPP (Point to Point Protocol) protocol.
[0005]
In the data transmission system Cs1, when data is transmitted from the gateway server Sga to the terminal device Teq, the gateway server Sga serves as a transmitting device, and the terminal device Teq serves as a receiving device. On the other hand, when data is transmitted from the terminal device Teq to the gateway server Sga, the gateway server Sga serves as a receiving device, and the terminal device Teq serves as a transmitting device.
[0006]
Hereinafter, data transmission using a packet in the data transmission system Cs1 will be briefly described.
FIG. 28B shows processing necessary for data transmission in the data transmission system divided into a plurality of layers. FIG. 29A to FIG. 29E show the data structure of a packet generated by the processing of each layer.
First, as shown in FIG. 28 (b), in a data transmission system, data is transferred from a server (transmission side device) Sin on the Internet In to a terminal device (reception side device) via a gateway server (relay device) Sga. The case of transmission to Teq (see data flow Df) will be described.
[0007]
Data held by the transmission side device Sin is subjected to the processing of the second layer Ls2 after being subjected to the processing of the first layer (application layer) Ls1. As a result, an RTP packet Prtp corresponding to the RTP (Realtime Transport Protocol) protocol is generated. The RTP packet Prtp is composed of an RTP header portion Hrtp that stores header information and an RTP payload (data portion) Drtp that stores the data. Here, the information in the RTP header portion Hrtp includes a sequence number Isn that is incremented by 1 every time one packet is transmitted, time information (time stamp) Its used for processing on the data receiving side, and other header information. Ith (see FIG. 29A). The size of the RTP header part Hrtp is generally 12 bytes, 2 bytes are assigned to the sequence number Isn, and 4 bytes are assigned to the time stamp Its.
[0008]
Next, the RTP packet Prtp is subjected to the processing of the third layer Ls3, thereby generating a UDP packet Pudp corresponding to the UDP (User Datagram Protocol) protocol. The UDP packet Pudp is composed of a UDP header portion Hudp that stores header information and a data portion Dudp that stores the RTP packet Prtp (see FIG. 29B).
[0009]
Subsequently, the UDP packet Pupd is subjected to the processing of the fourth layer Ls4, whereby an IP packet Pipa corresponding to the IP (Internet Protocol) protocol is generated. The IP packet Pipa includes an IP header part Hipa that stores header information and a data part Dip that stores the UDP packet Pupd (see FIG. 29C).
The IP packet Pipa is sent to the gateway server Sga via the transmission line Cin according to a predetermined transmission standard (for example, Ethernet) by the processing of the fifth layer Ls5.
[0010]
Then, in the gateway server Sga, the IP packet Pipa from the server Sin on the Internet In is received according to a predetermined transmission standard (for example, Ethernet) by the processing of the lower layer Lin2 corresponding to the processing of the fifth layer Ls5 in the transmission side device. The The received IP packet Pipa is separated into its header portion Hipa and data portion Dip by the processing of the upper layer Lin1 corresponding to the processing of the fourth layer Ls4 in the transmission side device. Then, a header part Hipb including information different from the information of the header part Hipa is included in the data part Dip separated by the processing of the upper hierarchy Leq1 corresponding to the predetermined hierarchy (here, the fourth hierarchy Lr4) in the receiving device. As a result, an IP packet Pipb is generated (see FIG. 29 (d)).
[0011]
Thereafter, the IP packet Pipb is subjected to processing of a lower layer Leq2 corresponding to a predetermined layer (here, the fifth layer Lr5) in the receiving side device, and a PPP packet Pppp corresponding to the PPP (point-to-point protocol) protocol. Is transmitted to the terminal device Teq via the wired line Ceq. This PPP packet Pppp is composed of a header part Hppp storing PPP header information Ippp and a CRC code Icrc for checking received data, and a data part Dppp storing the IP packet Pipb (FIG. 29 ( e)).
When the PPP packet Pppp is received by the terminal device Teq as the receiving side device, the PPP packet Pppp is transferred to the header portion Hppp and the data portion Dppp by the processing of the fifth layer Lr5 corresponding to the lower layer Leq2 in the gateway server Sga. To be separated.
[0012]
Next, the IP packet Pipb stored in the PPP data portion Dppp is separated into an IP header portion Hipg and an IP data portion Dip by processing of the fourth layer higher than the fifth layer Lr5. Subsequently, the UDP packet Pudp stored in the IP data part Dip is separated into the UDP header part Hudp and the UDP data part Dudp by the processing of the third layer Lr3 higher than the fourth layer Lr4. Further, the RTP packet Prtp stored in the UDP data part Dudp is separated into the RTP header part Hrtp and the RTP data part Drtp by the processing of the second layer Lr2 higher than the third layer Lr3.
Then, the processing of the first layer (application layer) Lr1 is performed on the data stored in the RTP payload (RTP data portion) Drtp.
[0013]
When data is transmitted from the terminal device Teq to the server Sin on the Internet, the terminal device Teq is a transmission side device and the server Sin is a reception side device. In this case, processing that is completely opposite to the case of transmitting data from the server Sin on the Internet to the terminal device Teq via the gateway server Sga is performed. That is, in each of the layers Lr2 to Lr5 of the terminal device Teq, processing for generating a packet corresponding to each layer is performed, and the gateway server Sga extracts the IP packet Pipb from the PPP packet Pppp from the terminal device Teq. It is converted into an IP packet Pipa and sent to a server Sin on the Internet In based on Ethernet. In the server Sin, the IP packet Pipa is received by the processing of the fifth layer Ls5 and stored in the RTP payload Drtp by the processing of the layers Ls4 to Ls2 in the server Sin corresponding to the layers Lr2 to Lr4 of the terminal device Teq. Data is extracted, and the processing of the application layer Ls1 is performed on the data.
[0014]
In the above description, the processing of the third layer Ls3 and Lr3 shows a case where the UDP packet Pupd corresponding to the UDP protocol is generated. However, in the processing of the third layer, the TCP (Transmission Control Protocol) protocol is used. A TCP packet corresponding to the above may be generated.
[0015]
In the data transmission system Cs1 as described above, when data is transmitted by the PPP protocol using the header compression method of V. Jacobson, the PPP packet Pppp transmitted by the protocol is roughly divided as shown in FIG. Different types of packets are used. One is a compressed packet Py (see FIG. 30B) in which data (transmission information) stored in the data part is compressed, and the other is data (transmission information) stored in the data part. ) Is an uncompressed packet Px (see FIG. 30A). Note that FIG. 30 shows in detail the portion of the PPP packet data structure necessary for the description of the V.Jacobson header compression method.
[0016]
That is, the uncompressed packet Px is composed of a header part Hpx storing header information and a data part Dpx storing transmission information (D) as uncompressed information Ir transmitted by the PPP protocol. The information of the header part Hpx is composed of a compressed / uncompressed identifier Ih1 indicating whether or not the information of the data part Dpx is compressed, and other header information Ih3. In the non-compressed packet Px, the compression / non-compression identifier Ih1 indicates non-compression.
[0017]
The compressed packet Py includes a header part Hpy that stores header information and a data part Dpy that stores difference information (ΔD) as compressed information Id transmitted by the PPP protocol. The information of the header part Hpy is composed of a compressed / uncompressed identifier Ih1 indicating whether or not the information of the data part Dpy is compressed, and other header information Ih3. In the compressed packet Py, the compressed / uncompressed identifier Ih1 indicates compression.
Needless to say, the other header information Ih3 includes the CRC code Icrc shown in FIG. 29 (e).
[0018]
In the PPP packet transmission process using the V. Jacobson header compression method, the uncompressed packet Px is transmitted from the transmission side to the reception side as the first PPP packet, and the compressed packet Py is transmitted as the subsequent PPP packet.
Here, the data portion Dpy of the compressed packet Py to be transmitted stores difference information (ΔD) with the transmission information corresponding to the PPP packet transmitted immediately before as the reference source information. The difference information (ΔD) is specifically a difference between transmission information to be transmitted by the transmission target compressed packet and transmission information as the reference source information.
[0019]
FIG. 31 is a diagram for conceptually explaining a PPP packet transmission process using the conventional V. Jacobson header compression method.
Here, a case where transmission information (D1) to (D4) corresponding to each PPP packet is sequentially transmitted will be described.
First, an uncompressed packet Px (1) is transmitted from the transmission side to the reception side as the first PPP packet. In the data portion Dpx of the uncompressed packet Px (1), transmission information (D1) is stored as uncompressed information Ir.
Thereafter, compressed packets Py (2) to Py (4) are sequentially transmitted as PPP packets from the transmission side to the reception side. In the data portion Dpy of these compressed packets Py (2), Py (3), and Py (4), difference information (D1-D2), (D2-D3), and (D3-D4) are stored as compressed information Id. Stored.
[0020]
Here, the difference information (D1-D2) is difference information between the transmission information (D1) and (D2), and the difference information (D2-D3) is difference information between the transmission information (D2) and (D3). The difference information (D3-D4) is difference information between the transmission information (D3) and (D4). Thus, in each compressed packet, difference information (ΔD) between transmission information corresponding to each compressed packet and transmission information corresponding to the packet transmitted immediately before is stored as compressed information Id.
Transmission of such a compressed packet is continued until a transmission error occurs.
[0021]
On the receiving side, the uncompressed packet Px (1) is received as the first PPP packet, and thereafter, the compressed packets Py (2) to Py (4) are sequentially received as PPP packets.
The uncompressed packet Px (1) is processed by the PPP protocol, and the transmission information (D1) stored in the data part Dpx is extracted. The compressed packets Py (2), Py (3), and Py (4) are processed by the PPP protocol and stored in the data portion Dpy with difference information (D1-D2), (D2-D3), ( D3-D4) is extracted, and the transmission information D2, D3, D4 corresponding to each compressed packet is restored by the header compression method of V. Jacobson. For example, the restoration of the transmission information (D2) is performed by the addition operation of the difference information (D1-D2) and the transmission information D1, and the other transmission information (D3) and (D4) are restored in the same manner.
[0022]
Next, a case where a transmission error occurs in the transmission processing by the PPP protocol using the conventional V. Jacobson compression method will be described.
FIG. 32 shows transmission and reception of signals between the transmission side and the reception side when the transmission error occurs.
On the receiving side, when a transmission error of a predetermined PPP packet is detected, it becomes impossible to restore the PPP packet received after the error occurrence time, so that the sending side is notified that a restoration error has occurred.
For example, as shown in FIG. 32, when the compressed packet Py (2) is not normally transmitted to the receiving side due to a transmission error, the receiving side receives the compressed packet Py (3) following the compressed packet Py (2). However, the transmission information (D3) that is the original information of the difference information stored in the compressed packet Py (3) cannot be restored. This is because the transmission information (D2) that is the original information of the difference information stored in the compressed packet Py (2) is not restored. Therefore, in this case, the receiving side is notified of the occurrence of the restoration error from the receiving side.
[0023]
On the transmission side, when the notification of the occurrence of the restoration error is received, the uncompressed packet Px (5) is transmitted to the reception side as a PPP packet immediately after receiving the notification. On the other hand, on the receiving side, all the compressed packets Py (2) to Py (4) received between the time when the transmission error occurs and the time when the uncompressed packet is received thereafter are discarded.
By the way, the application of the Internet using a mobile phone, for example, e-mail access to the mobile phone and the character information service, etc. are progressing, and the third generation mobile communication (W-CDMA: Wideband-Code Division). An infrastructure for next-generation wireless data communication (up to 384 Kbps) is being prepared for the practical application of (Multiple Access).
[0024]
FIG. 33 (a) is a diagram showing a data transmission system for a wireless terminal device compatible with the W-CDMA.
In this data transmission system Cs2, a gateway server Sga is connected to the Internet In, and a portable wireless terminal device (visual terminal or the like) Tmo is connected to the gateway server Sga via a wireless telephone network Cwr such as W-CDMA. It is connected. Also in such a data transmission system Cs2, on the transmission path between the portable wireless terminal device Tmo and the gateway server Sga, communication of packets subjected to data compression processing by the V.Jacobson header compression method is performed by PPP (Point to This is done by a protocol such as Point Protocol.
[0025]
FIG. 33 (b) shows the processing necessary for data transmission in the data transmission system Cs2 divided into a plurality of layers.
In this data transmission system Cs2, since the transmission path between the portable wireless terminal device Tmo and the gateway server Sga includes the wireless telephone network Cwr, the data transmission processing between them is performed by the terminal device and the gateway server. Is different from the data transmission system Cs1 connected by a wired line only in the following points.
That is, when a PPP packet is transmitted from the gateway server Sga to the portable wireless terminal device Tmo, the PPP packet obtained by the processing of the second layer Lmo2 is processed by the gateway server Sga corresponding to the W-CDMA system of the third layer Lmo3. Is transmitted to the portable wireless terminal device Tmo via the wireless line Cmo.
[0026]
Then, the portable wireless terminal device Tmo receives the PPP packet by processing corresponding to the W-CDMA system of the sixth layer Lr6. Thereafter, similarly to the data transmission system Cs1, the data stored in the RTP payload Drtp is extracted by the processing of the fifth to second layers Lr5 to Lr2, and the processing of the application layer Lr1 is performed on the data. .
The other communication processing in the data transmission system Cs2 shown in FIG. 33 (b) is the same as that in the data transmission system Cs1 shown in FIG. 28 (b). For example, the processing of the first layer Lmo1 and the second layer Lmo2 on the terminal side in the gateway server Sga in the data transmission system Cs2 is the same as the first layer Leq1 and the second layer Leq2 on the terminal side in the gateway server Sga in the data transmission system Cs1. It is the same as the process.
[0027]
[Problems to be solved by the invention]
However, the bit error rate in data transmission in a wired section is 10^-Five-10^-7On the other hand, the bit error rate in data transmission in the wireless section is 10^-3In the data transmission processing based on the PPP protocol using the V. Jacobson header compression method (RFC 1144, RFC 2508), quality degradation of transmission data due to a transmission error in a wireless section becomes a problem.
In other words, in the data transmission system Cs2 including the radio section, when data transmission by the PPP protocol is performed using the header compression method of V. Jacobson, in the case shown in FIG. There is a problem that the received packet is frequently discarded, and as a result, the number of transmission packets discarded is drastically increased.
[0028]
The present invention has been made to solve the above-described problems. When data transmission by a packet is performed by compressing data (transmission information) stored in the packet, a reception side is detected due to an error in a radio section. To obtain a data transmission method, a data transmission device, and a data reception device capable of reducing the number of packets discarded in the transmission, thereby improving the quality of transmission data in a transmission path including a wireless section. Objective.
[0029]
[Means for Solving the Problems]
  BookDepartureClearlyThe data transmission method is a data transmission method in which information is sequentially transmitted from the transmission side to the reception side for each transmission information corresponding to a packet, and an uncompressed packet in which predetermined transmission information is stored as uncompressed information is transmitted. The transmission information following the predetermined transmission information is at least partly compressed and the transmission side processing for continuously transmitting the compressed packets stored as compressed information, and receiving each packet from the transmission side, Receiving side processing that restores transmission information corresponding to each packet based on uncompressed information and compressed information stored in the packet, and the transmitting side processing should be stored in the compressed packet to be transmitted Compressed information is created based on transmission information corresponding to the reference packet that is the uncompressed packet and transmission information corresponding to the target packet as the transmission target. Including the compression processing, and the reception side processing is based on the transmission information corresponding to the compressed packet to be restored based on the transmission information corresponding to the reference packet and the compression information contained in the compressed packet as the restoration target. A restoration process for restoration is included.
[0030]
  BookDepartureTomorrow,the aboveIn the data transmission method, in the transmission side process, as the uncompressed packet, a packet including a packet identifier indicating the packet together with the uncompressed information is transmitted, and as each compressed packet following the uncompressed packet, as the reference packet A packet including a reference packet identifier indicating an uncompressed packet together with the compressed information is transmitted. In the compression process, as the compressed information, transmission information corresponding to the reference packet and transmission information corresponding to the compressed packet are transmitted. It creates difference information.
[0031]
  BookDepartureTomorrow,the aboveIn the data transmission method, in the transmission side process, additional information for calculating the difference information based on transmission information corresponding to the reference packet is stored in the compressed packet. The difference information in the packet is calculated from the transmission information corresponding to the reference packet based on the additional information in the compressed packet.
[0032]
  BookDepartureTomorrow,the aboveIn the data transmission method, the additional information is a sequence number that can identify how many times the compressed packet is transmitted after the non-compressed packet is transmitted as the reference packet.
[0033]
  BookDepartureTomorrow,the aboveIn the data transmission method, the additional information is a variable of a calculation formula for calculating difference information in the compressed packet from transmission information corresponding to the reference packet.
[0034]
  BookDepartureTomorrow,the aboveIn the data transmission method, in the transmission side processing, a plurality of uncompressed packets created to be transmitted before the compressed packet are used as reference packets, and the compressed packets are transmitted corresponding to the respective reference packets. The difference information between the information and the transmission information corresponding to the compressed packet is associated with the reference packet identifier corresponding to each reference packet, and a plurality of sets of the corresponding difference information and reference packet identifier are stored as the compressed information. In the reception-side process, the transmission information corresponding to the compressed packet is restored using any pair of difference information and the packet identifier in the compressed packet.
[0035]
  BookDepartureTomorrow,the aboveIn the data transmission method, in the transmission side processing, the uncompressed packet is transmitted at a constant period.
[0036]
  BookDepartureTomorrow,the aboveIn the data transmission method, in the transmission side process, the uncompressed packet is transmitted when the size of the compressed information included in the compressed packet transmitted to the reception side exceeds a certain value.
[0037]
  BookDepartureTomorrow,the aboveIn the data transmission method, in the reception side processing, when the size of the compressed information included in the compressed packet from the transmission side exceeds a certain value, the transmission side requests transmission of an uncompressed packet. When an uncompressed packet transmission request is received from the receiving side, the uncompressed packet is transmitted to the receiving side.
[0038]
  BookDepartureTomorrow,the aboveIn the data transmission method, in the transmission side process, an uncompressed packet storing the same transmission information is continuously transmitted to the reception side a plurality of times.
[0039]
  BookDepartureTomorrow,the aboveIn the data transmission method, when the receiving side process detects a decompression error in the compressed information stored in the compressed packet, the sending side process notifies the sending side that a decompression error has occurred. In the transmitting side process, the receiving side process The number of times that the uncompressed packets are continuously sent to the receiving side is changed based on the frequency of notification indicating the occurrence of a restoration error from.
[0040]
  BookDepartureTomorrow,the aboveIn the data transmission method, in the transmission side processing, after transmission of the uncompressed packet, an auxiliary transmission packet including a packet identifier and transmission information stored in the uncompressed packet is transmitted a predetermined number of times to the reception side.
[0041]
  BookDepartureTomorrow,the aboveIn the data transmission method, in the transmission side process, the uncompressed packet is given an error correction code and transmitted to the reception side. In the reception side process, the uncompressed packet is given to the uncompressed packet. The error correction processing is performed by the error correction code.
[0042]
  BookDepartureTomorrow,the aboveIn the data transmission method, in the transmission side process, an error correction code is assigned to a packet identifier and transmission information in the uncompressed packet, and in the reception side process, a packet identifier and transmission information included in the uncompressed packet On the other hand, error correction processing is performed using the error correction code assigned thereto.
[0043]
  BookDepartureTomorrow,the aboveIn the data transmission method, when the receiving side process detects a decompression error in the compressed information stored in the compressed packet, the sending side process notifies the sending side that a decompression error has occurred. In the transmitting side process, the receiving side process The process of sending the uncompressed packet with an error correction code attached to the uncompressed packet according to the frequency of notification indicating the occurrence of a restoration error, and sending the uncompressed packet without attaching the error correction code thereto One of the processes to be performed is performed.
[0044]
  BookDepartureTomorrow,the aboveIn the data transmission method, in the transmission side process, only the uncompressed packet is held as retransmission data in a retransmission buffer, and in the reception side process, when a transmission error of the uncompressed packet is detected, the transmission side process On the other hand, when a request for retransmission of an uncompressed packet, which is an error packet, is received, and when the retransmission process of the error packet is received, the uncompressed packet corresponding to the error packet is held in the retransmission buffer. Only in this case, an uncompressed packet corresponding to the error packet is retransmitted to the receiving side.
[0045]
  BookDepartureTomorrow,the aboveIn the data transmission method, in the transmission side processing, the packet identifier and transmission information stored in the uncompressed packet are held in the retransmission buffer as retransmission data, and in the reception side processing, the transmission error of the uncompressed packet is stored. Is detected, the transmission side is requested to retransmit the packet identifier and transmission information stored in the uncompressed packet that is an error packet. In the transmission side processing, the packet identifier and transmission information retransmission request is requested. When the packet identifier and transmission information in the uncompressed packet corresponding to the error packet are held in the retransmission buffer, the packet identifier and transmission information are retransmitted to the receiving side.
[0046]
  BookDepartureClearlyThe data transmission method is a data transmission method in which information is sequentially transmitted from the transmission side to the reception side for each transmission information corresponding to a packet, and an uncompressed packet in which predetermined transmission information is stored as uncompressed information is transmitted. The transmission information following the predetermined transmission information, at least a part of which is compressed and transmitted continuously from the compressed packet stored as compressed information, and each packet from the transmission side is received, And receiving side processing for restoring transmission information corresponding to each packet based on uncompressed information and compressed information stored in each packet. In the above transmission side processing, the packet is stored in a compressed packet to be transmitted. The compression information to be generated is generated based on the transmission information corresponding to the reference packet that is the uncompressed packet and the transmission information corresponding to the compressed packet as the transmission target. In the receiving side processing, the transmission information corresponding to the compressed packet to be restored is restored based on the transmission information corresponding to the reference packet and the compression information included in the compressed packet as the restoration target. 1 and the compressed information stored in the compressed packet on the transmitting side are created by a method different from the compressed information creating method in the first data transmitting process, and are stored in the compressed packet on the receiving side. A second data transmission process that restores the compressed information that has been performed by a method different from the restoration method of the compressed information in the first data transmission process, and when the transmission information is transmitted in packets, And the second data transmission process are switched according to the occurrence state of the decompression process error for the compressed packet on the receiving side, the first and second And it performs any data transmission process over data transmission process.
[0047]
  BookDepartureTomorrow,the aboveIn the data transmission method, the second data transmission process includes, as a transmission side process, transmission information corresponding to a previous packet transmitted immediately before the compressed packet, using compressed information stored in the compressed packet to be transmitted. And a compression process created based on the transmission information corresponding to the compressed packet as the transmission target, and the compression information included in the compressed packet to be restored is transmitted as the reception process as a reception side process. It includes a restoration process that restores using information.
[0048]
  BookDepartureTomorrow,the aboveIn the data transmission method, when an error occurs in the restoration process for restoring the compressed information included in the compressed packet on the receiving side, the occurrence of the error is notified from the receiving side to the transmitting side. When the value exceeds a certain value, a process change notification is sent to the reception side so as to change the restoration process at the reception side to the restoration process in the first data transmission process, and then the transmission side performs the process in the first data transmission process. Performs compression processing, and on the one side, when the notification frequency of occurrence of an error falls below a certain value, the processing on the receiving side is changed to change the restoration processing on the receiving side to the restoration processing on the second data transmitting device. Notification is performed, and then the transmission side performs compression processing in the second data transmission processing.
[0049]
  BookDepartureTomorrow,the aboveIn the data transmission method, the reception side performs the compression process on the transmission side when the error occurrence frequency that causes an error in the restoration process for restoring the compression information included in the compressed packet exceeds a predetermined value. A process change request is made to the transmission side so as to change to the compression process in the process. On the other hand, when the error occurrence frequency of the restoration process becomes a predetermined value or less on the reception side, the compression process on the transmission side is changed to the second data transmission. A process change request is made to the transmission side so as to change to the compression process in the process. On the transmission side, of the compression processes in the first and second data transmission processes, the data transmission process according to the process change request from the reception side The compression process is performed.
[0050]
  BookDepartureClearlyThe data transmission method is a data transmission method in which information is sequentially transmitted from the transmission side to the reception side for each transmission information corresponding to a packet, and an uncompressed packet in which predetermined transmission information is stored as uncompressed information is transmitted. The transmission information following the predetermined transmission information, at least a part of which is compressed and transmitted continuously from the compressed packet stored as compressed information, and each packet from the transmission side is received, Receiving side processing for restoring transmission information corresponding to each packet based on uncompressed information and compressed information stored in each packet, and the transmitting side processing is stored in a compressed packet to be transmitted. Based on update information related to a packet transmitted before the compressed packet and transmission information corresponding to the compressed packet as the transmission target. Information relating to the uncompressed packet is set as an initial value of the compression processing to be performed and the update information, and then the update information is information related to the specific compressed packet every time a specific compressed packet is created. The transmission side update processing is performed, and the reception side processing restores the transmission information corresponding to the compressed packet to be restored using the update information related to the packet received earlier than the compressed packet. Each time the restoration process and the information related to the uncompressed packet are set as the initial value of the update information, and the transmission information corresponding to the specific compressed packet is restored, the update information And receiving side update processing for updating information related to the packet.
[0051]
  BookDepartureTomorrow,the aboveIn the data transmission method, the update information includes a reference packet identifier indicating the uncompressed packet or a specific compressed packet as a reference packet, and transmission information corresponding to the reference packet. A reference packet identifier indicating an uncompressed packet or a specific compressed packet as a reference packet, and an information update flag indicating whether or not the update information should be updated, and the information update flag in the specific compressed packet is the update information Is set to a value indicating that the update information should be updated, and an information update flag in a compressed packet other than the specific compressed packet is set to a value indicating that the update information should not be updated.
[0052]
  BookDepartureTomorrow,the aboveIn the data transmission method, in the transmission side processing, the specific compressed packet is transmitted to the reception side every time a predetermined time elapses.
[0053]
  BookDepartureTomorrow,the aboveIn the data transmission method, in the transmission side process, the specific compressed packet is sent to the receiving side every time a certain number of compressed packets are transmitted.
[0054]
  BookDepartureTomorrow,the aboveIn the data transmission method, in the transmission side process, when the reception side requests transmission of the specific compressed packet, the specific compression packet is transmitted to the reception side.
[0055]
  BookDepartureTomorrow,the aboveIn the data transmission method, in the transmission side processing, the specific compressed packet is transmitted when the size of the compression information included in the compressed packet transmitted to the reception side exceeds a certain value.
[0056]
  BookDepartureTomorrow,the aboveIn the data transmission method, in the transmission side processing, the specific compressed packet is transmitted when the average value of the size of the compressed information included in the compressed packet transmitted to the reception side exceeds a certain value.
[0057]
  BookDepartureTomorrow,the aboveIn the data transmission method, the transmission information includes item-specific transmission information corresponding to a plurality of items, and the compression information includes item-specific compression information corresponding to a plurality of items, in the compression information included in the compressed packet. The item-specific compressed information corresponding to each item corresponds to the item-specific compressed information corresponding to each item in the transmission information corresponding to the compressed packet, and the item in the transmission information corresponding to the non-compressed packet or the specific compressed packet. Information obtained by compression using the item-specific transmission information, and each item-specific compression information includes an item type flag that identifies the corresponding item.
[0058]
  BookDepartureTomorrow,the aboveIn the data transmission method, the item-specific compression information includes data length information indicating the data length.
[0059]
  BookDepartureTomorrow,the aboveIn the data transmission method, each item-specific compression information is created using a compression method corresponding to each of a plurality of compression methods, and each item-specific compression information includes the item-specific compression information. The restoration method specifying information indicating the restoration method corresponding to the compression method for restoration is included.
[0060]
  BookDepartureClearlyThe data transmitting apparatus is a data transmitting apparatus that sequentially transmits information to the receiving side for each piece of transmission information corresponding to a packet, and receives the transmission information received as receiving means for receiving the transmission information as an input signal. A non-compressed packet in which predetermined transmission information is stored as uncompressed information, and a packet for generating a compressed packet in which at least a part of the transmission information following the predetermined transmission information is compressed and stored as compressed information Creating means, reference information managing means for storing and managing information related to the uncompressed packet created by the packet creating means as reference information, and each packet created by the packet creating means as a transmission signal A transmission means for transmitting to the receiving side, and the packet creation means is adapted to store the pressure to be stored in the compressed packet to be created by the means. The information is obtained by the transmission information corresponding to the compressed packet, and configured to create, based on the reference information stored in the reference information management unit.
[0061]
  BookDepartureTomorrowA data receiving apparatus that receives information transmitted in units of packets from a transmitting side as a transmission signal and sequentially restores transmission information corresponding to each packet, and receives the transmission signal, and predetermined transmission information is uncompressed. A packet receiving means for outputting a non-compressed packet stored as information and a compressed packet in which at least a part of the transmission information following the predetermined transmission information is compressed and stored as compressed information; and the packet receiving means A packet restoring means for performing restoration processing on each packet based on information stored in each packet and outputting transmission information corresponding to each packet; and the packet restoring means Reference information management means for accumulating and managing information related to the decompressed uncompressed packet as reference information; Output means for outputting transmission information corresponding to each packet from the means, the packet decompression means, transmission information corresponding to the compressed packet, compressed information included in the compressed packet, and reference information management The information is restored based on the reference information stored in the means.
[0062]
  BookDepartureClearlyThe data transmitting apparatus is a data transmitting apparatus that sequentially transmits information to the receiving side for each piece of transmission information corresponding to a packet, and receives the transmission information received as receiving means for receiving the transmission information as an input signal. A non-compressed packet in which predetermined transmission information is stored as non-compressed information, and a packet for generating a compressed packet in which at least part of the transmission information following the predetermined transmission information is compressed and stored as compressed information Creating means, information management means for managing information related to the uncompressed packet and the specific compressed packet created by the packet creating means as update information, and the packet created by the packet creating means as a transmission signal A transmission means for transmitting to the reception side, and the information management means relates to the uncompressed packet as an initial value of the update information. Information is set, and thereafter, each time a specific compressed packet is created, the update information is updated to information related to the specific compressed packet, and the packet creation means is created by the means. The compressed information to be stored in the compressed packet is generated based on the transmission information corresponding to the compressed packet and the update information stored in the reference information management means.
[0063]
  BookDepartureTomorrowA data receiving apparatus that receives information transmitted in units of packets from a transmitting side as a transmission signal and sequentially restores transmission information corresponding to each packet, and receives the transmission signal, and predetermined transmission information is uncompressed A packet receiving means for outputting a non-compressed packet stored as information and a compressed packet in which transmission information following the predetermined transmission information is at least partially compressed and stored as compressed information; and the packet receiving means A packet restoring means for performing restoration processing on each packet based on information stored in each packet and outputting transmission information corresponding to each packet; and the packet restoring means Reference information management for storing and managing information related to uncompressed packets and specific compressed packets that have undergone decompression processing as reference information And output means for outputting transmission information corresponding to each packet restored by the packet restoration means, wherein the information management means sets information related to the uncompressed packet as an initial value of the update information Thereafter, each time a restoration process is performed on the specific compressed packet, the update information is updated to information related to the specific compressed packet, and the packet decompression unit corresponds to the compressed packet. The transmission information is configured to be restored based on the compression information included in the compressed packet and the reference information stored in the reference information management means.
[0064]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the focus and basic principles of the present invention will be described.
As a result of diligent research on a method for improving the quality of transmission data in a network including a wireless transmission path, the present inventor has replaced the existing header compression method such as the V. Jacobson header compression method with a compressed packet to be transmitted. In the wireless transmission path, a header compression method that stores differential information obtained using transmission information corresponding to an uncompressed packet transmitted before the compressed packet as compressed transmission information is used. Has found that the quality of transmission data can be improved.
[0065]
In each of the following embodiments, the data communication is unidirectional from the server Sin on the Internet to the portable wireless terminal device (visual terminal or the like) Tmo as shown by the data flow Df in FIG. Although only transmission will be described, a data communication process for simultaneously communicating data bidirectionally by configuring a communication device such as a server or a terminal device that performs data communication to have both functions of a transmission side and a reception side. Can be realized. In the data communication from the server Sin on the Internet to the portable wireless terminal device Tmo as described above, the gateway server Sga (see FIG. 33B) receives and receives data from the server Sin on the Internet. The transmission processing for transmitting the received data to the terminal device Tmo is performed, and the reception processing for receiving the data from the gateway server Sga is performed by the portable wireless terminal device Tmo.
In each embodiment of the present invention, RTP / UDP / IP packets corresponding to IP packets Pipb (see FIG. 29 (d)) are used as transmission information including various header information, and the header information is compressed to PPP. A case of transmission by a protocol will be described, but transmission information and its transmission protocol are not limited to the RTP / UDP / IP packet and the PPP protocol.
[0066]
(Embodiment 1)
  1 to 11 are diagrams for explaining a data transmission method according to Embodiment 1 of the present invention..
  ThisIn the data transmission method according to the first embodiment, data transmission from the transmission side apparatus to the reception side apparatus is performed in units of packets, while the transmission side apparatus creates and transmits uncompressed packets and compressed packets, and transmission is performed on the reception side. In a data transmission method for receiving a packet from a side device and sequentially restoring the received packet, the compressed packet to be transmitted is transmitted as transmission information corresponding to the compressed packet. The difference information based on the transmission information stored in the uncompressed packet closest to the compressed packet is stored. Here, the difference information stored in the compressed packet to be transmitted should be transmitted from the reference source information by the compressed packet to be transmitted using the transmission information stored in the uncompressed packet as reference source information. This is obtained by subtracting transmission information.
[0067]
In the following description, transmission information stored in an uncompressed packet is also referred to as transmission information corresponding to the uncompressed packet, and transmission information to be transmitted by the compressed packet is referred to as transmission information corresponding to the compressed packet. Say.
FIG. 1 is a diagram for explaining a data transmission method according to Embodiment 1 of the present invention. An uncompressed packet (FIG. (A)) and a compressed packet (FIG. (B)) used in the data transmission method. ) Shows the data structure. Note that, in FIG. 1, as in FIG. 30, portions necessary for describing the header compression method in the data structure of the PPP packet are shown in detail.
[0068]
More specifically, the uncompressed packet Pa is composed of a header portion Hpa that stores header information and a data portion Dpa that stores uncompressed information Ir transmitted by the PPP protocol. The information in the header part Hpa includes a compressed / uncompressed identifier Ih1 indicating whether or not the information in the data part Dpa is compressed, a packet identifier (ID) Ih2a for identifying the uncompressed packet itself, Header information Ih3. Here, the compression / non-compression identifier Ih1 of the uncompressed packet Pa indicates non-compression. The uncompressed information Ir is transmission information (D) transmitted by the uncompressed packet.
[0069]
On the other hand, the compressed packet Pb is composed of a header part Hpb storing header information and a data part Dpb storing compressed information Id transmitted by the PPP protocol. The information in the header part Hpb includes a compressed / uncompressed identifier Ih1 indicating whether or not the information in the data part Dpb is compressed, and an uncompressed packet (reference packet) in which transmission information used as the reference source information is stored. Is made up of a reference packet identifier (ID) Ih2b and other header information Ih3. Here, the compressed / uncompressed identifier Ih1 of the compressed packet Pb indicates compression. The compressed information Id includes transmission information (reference source information) corresponding to an uncompressed packet (reference packet) closest to the compressed packet, transmitted before the compressed packet Pb, and transmission information corresponding to the compressed packet. Difference information.
Needless to say, the other header information Ih3 includes the CRC code Icrc shown in FIG. 29 (e).
[0070]
FIG. 2 is a block diagram for explaining a data transmission apparatus in a data transmission system that performs data transmission by the data transmission method according to the first embodiment.
This data transmitting apparatus 101 corresponds to the gateway server Sga in the data transmission system Cs2 shown in FIG. The data transmitting apparatus 101 receives a first transmission signal S1 including transmission information transmitted from the Internet In side to the receiving side (portable wireless terminal device Tmo), and outputs the transmission information as a reception signal Src. 11, a compressed / uncompressed packet creating unit 12 that packetizes transmission information from the receiving unit 11 based on a transmission standard such as a PPP protocol and outputs an uncompressed packet Pa or a compressed packet Pb, and the packet creating unit 12. Packet transmitting means 16 for transmitting to the receiving side the second transmission signal S2 as a second transmission signal S2 by a method such as W-CDMA.
[0071]
Further, the data transmitting apparatus 101 receives an error occurrence notification receiving unit 14 that receives a restoration error notification signal Ne that is transmitted from the receiving side and indicates that a restoration error has occurred, and outputs an error notification reception signal Sn; The packet creation unit 12 manages the type of packet created, and determines the type of packet to be created next based on the managed packet type information and the error notification reception signal Sn, thereby determining the packet. Compression / non-compression determination means 13 for outputting a signal Jp. Here, in the determination means 13, the management of the packet type is performed by recording the uncompressed / compressed identifier Ih1 of the created packet in association with each packet. In the determination means 13, the type of packet created first after the start of transmission and the type of packet created immediately after receiving the error notification reception signal Sn are uncompressed, and other packet types are compressed. Thus, the packet type is determined.
[0072]
Further, the data transmitting apparatus 101 transmits transmission information (D) stored as uncompressed information Ir in the uncompressed packet Pa in association with a packet identifier (ID) Ih2a for identifying the uncompressed packet. Reference information management means 15 is managed as side reference information Im1. The transmission side reference information Im1 includes an identifier (ID) whose value is equal to the packet identifier (ID) Ih2a, and reference source information (D) equal to the transmission information (D) corresponding to the uncompressed packet Pa. Has been. Each time the packet creating means 12 creates an uncompressed packet, the managing means 15 uses an identifier (ID) recorded as sending side reference information Im1 by the sending side management control signal Cm1 from the creating means 12. ) And reference source information (D) are updated.
[0073]
In the data transmitting apparatus 101, the compressed / uncompressed packet creating means 12 creates either the uncompressed packet Pa or the compressed packet Pb based on the packet determination signal Jp. When the uncompressed packet Pa is created, the transmission information (D) is stored as uncompressed information Ir in the data part Dpa, and the uncompressed packet Pa is specified in the header part Hpa as the packet identifier Ih2a. A value (ID) to be stored is stored. When the compressed packet Pb is created, difference information (ΔD) based on transmission information (D) corresponding to the uncompressed packet as the reference packet is stored as compressed information Id in the data portion Dpb. In the header portion Hpb, a value (ID) for specifying the uncompressed packet Pa as the reference packet is stored as the reference packet identifier Ih2b.
Here, the difference information (ΔD) corresponding to each compressed packet Pb is difference information between transmission information corresponding to the compressed packet and transmission information corresponding to an uncompressed packet as a reference packet. Note that the uncompressed packet as the reference packet is the last uncompressed packet created among the uncompressed packets created before the compressed packet Pb.
[0074]
FIG. 3 is a block diagram for explaining a data receiving apparatus in a data transmission system that performs data transmission by the data transmission method of the first embodiment.
This data receiving device 201 corresponds to the portable wireless terminal device Tmo in the data transmission system Cs2 shown in FIG.
The data receiving apparatus 201 receives a packet receiving unit 21 that receives a packet transmitted as a second transmission signal S2 from the transmitting side by a method such as W-CDMA, and a received packet Rp that is an output of the receiving unit 21. And error packet detecting means 22 for detecting an error packet in which an error has occurred during transmission and outputting the normally transmitted received packet Rp as a normal packet Pno.
The data receiving apparatus 201 receives the normal packet Pno from the detecting means 22, performs a restoration process on the packet Pno and outputs restoration information Irs, and outputs an error occurrence signal Se when a restoration error occurs. Receiving the error occurrence signal Se, an error occurrence notification sending means 24 for sending a restoration error notification signal Ne for notifying the transmission side that a restoration error has occurred, and transmission as the restoration information Irs Output means 26 for outputting information (D) as an output signal S3.
[0075]
Here, the packet restoration means 23 performs a process of extracting transmission information (D) from the data portion Dpa of the uncompressed packet Pa based on the PPP protocol or the like as a decompression process for the uncompressed packet. Further, as a decompression process for the compressed packet, the difference information Id is extracted from the data portion Dpb of the compressed packet Pb based on the PPP protocol, and the transmission information corresponding to the uncompressed packet as the reference packet is referred to. A process for restoring the corresponding transmission information is performed.
[0076]
In addition, when the decompression unit 23 performs the decompression process on the uncompressed packet Pa, the data receiving apparatus 201 transmits the packet identifier (ID) Ih2a and the transmission information in the uncompressed packet Pa that is the target of the decompression process. Reference information management means 25 for managing (D) in association with the reference information Im2 on the receiving side is provided. The receiving side reference information Im2 includes an identifier (ID) whose value is equal to the packet identifier (ID) Ih2a and reference source information (D) equal to the transmission information (D) corresponding to the uncompressed packet Pa. Has been. The management unit 25 uses the identifier recorded as the reception side reference information Im2 by the reception side management control signal Cm2 from the restoration unit 23 every time the packet restoration unit 23 performs a restoration process on the uncompressed packet. (ID) and reference source information (D) are updated.
In the data receiving apparatus 201, when the packet restoration unit 23 performs the restoration process on the compressed packet, the reference packet identifier (ID) in the compressed packet and the transmission information (D) corresponding to the reference packet are respectively The identifier (ID) managed by the reference information management means 25 and the reference source information (D) corresponding to the identifier (ID) are collated. In addition, as a result of the collation, the identifier (ID) and the information (D) are not matched, that is, the management means 25 refers to the reference necessary for the decompression process of the compressed packet that is the subject of the decompression process. When either one of the packet identifier (ID) and the transmission information (D) is not accumulated, an error occurrence signal Se indicating that a restoration error has occurred is output from the packet restoration means 23 to the error occurrence notification transmission means 24. Is done.
[0077]
Next, the function and effect will be described.
4 and 5 are diagrams for explaining the data transmission method of the first embodiment. 4 shows a flow of a plurality of packets from the transmission side to the reception side in a normal transmission state, and FIG. 5 shows a flow of a plurality of packets from the transmission side to the reception side when a transmission error occurs. .
Here, the transmission information (D1) to (D4) is information corresponding to each packet collected so as to be transmitted in units of packets. In the first embodiment, the transmission information (D1) is not compressed. The transmission information (D2) to (D4) is compressed by the uncompressed packet Pa (1), and is sequentially transmitted by the compressed packets Pb (2) to Pb (4) following the uncompressed packet Pa (1). .
[0078]
On the transmitting side, first, the uncompressed packet Pa (1) is generated, and the uncompressed packet Pa (1) is transmitted to the receiving side. At this time, the transmission information (D1) is stored as the uncompressed information Ir in the data portion Dpa of the uncompressed packet Pa (1), the identifier Ih1 indicating uncompressed in the header portion Hpa, and the packet identifier for identifying this packet (ID = 0) Ih2a and other header information Ih3 are stored.
[0079]
Next, the compressed packet Pb (2) is generated, and the compressed packet Pb (2) is transmitted to the receiving side. At this time, difference information (D1-D2) is stored as compression information Id in the data portion Dpb of the compressed packet Pb (2), and an identifier Ih1 indicating compression and a reference packet identifier (ID) are stored in the header portion Hpb. = 0) Ih2b and other header information Ih3 are stored. The difference information (D1-D2) is obtained by subtracting the transmission information (D2) corresponding to the compressed packet Pb (2) from the transmission information (D1) corresponding to the uncompressed packet Pa (1) that is the reference packet. Information obtained.
[0080]
Subsequently, the compressed packet Pb (3) is generated, and the compressed packet Pb (3) is transmitted to the receiving side. At this time, the data portion Dpb of the compressed packet Pb (3) stores the difference information (D1-D3) as the compression information Id, and the header portion Hpb contains an identifier Ih1b indicating compression, a reference packet identifier (ID = 0) Ih2b and other header information Ih3 are stored. The difference information (D1-D3) is obtained by subtracting the transmission information (D3) corresponding to the compressed packet Pb (3) from the transmission information (D1) corresponding to the uncompressed packet Pa (1) that is the reference packet. This information is obtained.
[0081]
Further, the compressed packet Pb (4) is generated, and the compressed packet Pb (4) is transmitted to the receiving side. At this time, the difference information (D1-D4) is stored as the compression information Id in the data portion Dpb of the compressed packet Pb (4), and the header portion Hpb includes an identifier Ih1 indicating compression and a reference packet identifier (ID = 0) Ih2b and other header information Ih3 are stored. The difference information (D1-D4) is obtained by subtracting transmission information (D4) corresponding to the compressed packet Pb (4) from transmission information (D1) corresponding to the uncompressed packet Pa (1) which is the reference packet. This information is obtained.
[0082]
Here, the reference packet identifier (ID = 0) Ih2b stored in the header portion Hpb of each compressed packet Pb (2), Pb (3), Pb (4) is used in the decompression process for each compressed packet. This is an identifier indicating that the reference packet required for the above is the uncompressed packet Pa (1).
[0083]
As described above, the uncompressed packet Pa (1) and the subsequent compressed packets Pb (2) to Pb (4) sequentially transmitted from the transmission side are sequentially received on the reception side in the normal data transmission state. The transmission information (D1) to (D4) corresponding to is restored.
That is, on the receiving side, when the uncompressed packet Pa (1) is received, the transmission information (D1) is extracted from the data portion Dpa. Subsequently, when the compressed packet Pb (2) is received, the difference information (D1-D2) is extracted from the data portion Dpb, and the uncompressed packet Pa specified as the reference packet by the reference packet identifier (ID = 0) Ih2b. With reference to the transmission information (D1) corresponding to (1), the transmission information (D2) corresponding to the compressed packet Pb (2) is restored from the difference information (D1-D2).
[0084]
Thereafter, when the compressed packets Pb (3), (4) are received, the difference information (D1-D3), (D1-D4) is extracted from the data portion Dpb, as in the case of the compressed packet Pb (2). By referring to the transmission information (D1) corresponding to the uncompressed packet Pa (1) specified as the reference packet by the reference packet identifier (ID = 0) Ih2b, the difference information (D1-D3), (D1-D4) ), The transmission information (D3) and (D4) corresponding to the compressed packets Pb (3) and (4) are restored.
[0085]
In the first embodiment, even when a transmission error of the compressed packet Pb (2) occurs in the state where the packet is transmitted as described above, the compressed packet Pb ( When the compressed packets Pb (3) and (4) following 2) are received, the transmission information (D3) and (D4) corresponding to the compressed packets Pb (3) and (4) are normally restored. Is called.
That is, in the first embodiment, the difference information (ΔD) stored in the data portion Dpb of each compressed packet Pb is the transmission information corresponding to each compressed packet Pb and the transmission information corresponding to the immediately preceding packet. Is the difference information between the transmission information corresponding to each compressed packet Pb and the transmission information corresponding to the latest uncompressed packet Pa transmitted before the compressed packet Pb. For this reason, in the data transmission system of the first embodiment, even if a transmission error of a compressed packet occurs, this transmission error does not affect the decompression process of the next normally received compressed packet. Accordingly, when a transmission error of a compressed packet occurs, only the error packet is discarded, and the restoration error is not notified from the reception side to the transmission side.
[0086]
If a transmission error of the uncompressed packet Pa (1) occurs during transmission of information by packet, a notification signal Ne indicating the occurrence of a restoration error is transmitted from the receiving side in the same procedure as shown in FIG. To the side. Immediately after the restoration error notification signal Ne is received on the transmission side, an uncompressed packet is transmitted from the transmission side, and the compressed packet is sequentially transmitted following the uncompressed packet. At this time, the receiving side discards the error packet and the subsequent compressed packet, that is, the error received after the occurrence of the transmission error until the uncompressed packet is normally received.
[0087]
Next, the operation of the data transmission apparatus 101 in the data transmission system will be described.
In this data transmitting apparatus 101, as shown in FIG. 4 or FIG. 5, transmission information (D1) to (D4) is sequentially transmitted to the receiving side by corresponding uncompressed packets and compressed packets.
More specifically, for example, transmission information (D1) to (D4) (see FIG. 4) transmitted from a server Sin on the Internet (see FIG. 33 (a)) by a transmission method such as Ethernet is the data transmitting apparatus. When the first transmission signal S1 is input to 101, the transmission means (D1) to (D4) is received by the receiving means 11 by the above transmission method. The received transmission information (D1) to (D4) is sequentially output to the packet creation means 12 as a reception signal Src.
[0088]
In the packet creating means 12, a packet for transmitting each piece of transmission information to the receiving side is created based on a transmission protocol such as the PPP protocol. At this time, the compression / non-compression determination means 13 is inquired about the type of packet to be created. In response to this inquiry, the determination unit 13 provides the packet creation unit 12 with a packet determination signal Jp indicating the packet type.
Specifically, when the transmission information (D1) is input to the packet creation means 12, this is a case where the first packet is created after the start of communication. Information indicating creation of an uncompressed packet is output to the packet creation means 12 as the packet determination signal Jp.
Then, the creation means 12 determines the creation of the uncompressed packet based on the packet determination signal Jp, and creates the uncompressed packet Pa (1) in which the transmission information (D1) is stored as the uncompressed information Ir. .
[0089]
At this time, the value “uncompressed” is set in the compression / non-compression identifier Ih1 of the uncompressed packet Pa (1), and an identifier (ID = ID) indicating the uncompressed packet Pa (1) is set in the packet identifier Ih2a. 0) is set. When the uncompressed packet Pa (1) is created by the creation means 12, the reference information management means 15 uses the transmission side management control signal Cm1 from the creation means 12 as a reference packet as the transmission side reference information Im1. The identifier (ID) and the reference source information (D) are set in the identifier (ID = 0) indicating the uncompressed packet Pa (1) and the transmission information (D1) corresponding to the uncompressed packet Pa (1), respectively. The
The uncompressed packet Pa (1) is output to the packet transmission unit 16 and transmitted to the reception side by the packet transmission unit 16 by a predetermined wireless communication method (for example, W-CDMA).
[0090]
Next, when the transmission information (D2) output from the receiving means 11 is input to the packet creating means 12, even if the first packet is created after the start of communication in this case, the restoration from the receiving side is performed. Since the first packet is not created after the error notification signal is received, the determination unit 13 outputs information indicating the generation of the compressed packet to the packet generation unit 12 as the packet determination signal Jp.
Then, the creation means 12 inquires of the management means 15 about the transmission side reference information Im1. In this case, since the reference packet identifier (ID) is set to the identifier (ID = 0) and the reference source information (D) is set to the transmission information (D1) in the management means 15, the packet creation means 12 The transmission information (D2) is compressed using the transmission information (D1) corresponding to the uncompressed packet Pa (1) indicated by the identifier (ID = 0) as reference source information. Thereby, difference information (D1-D2) between the transmission information (D1) and the transmission information (D2) is generated as the compression information Id stored in the compressed packet.
[0091]
Subsequently, the packet creating means 12 generates a compressed packet Pb (2) in which the difference information (D1-D2) is stored as the compressed information Id of the transmission information (D2). A value “compressed” is set in the compressed / uncompressed identifier Ih1 of the compressed packet Pb (2), and the reference packet identifier Ih2b has the above non-reference packet as a reference packet necessary for the decompression process of the compressed packet Pb (2). An identifier (ID = 0) indicating the compressed packet Pa (1) is set. When the compressed packet Pb (2) is generated by the generating means 12, the reference information managing means 15 updates the reference packet identifier (ID) and the reference source information (D) as the transmission side reference identification Im1. Not done.
Then, the compressed packet Pb (2) is output to the packet transmission unit 16, and is transmitted to the reception side (portable wireless terminal device) by the packet transmission unit 16 by a predetermined wireless communication method (for example, W-CDMA). .
Thereafter, when the transmission information (D3) and (D4) output from the receiving means 11 are input to the packet creation means 12, the difference is made in the same manner as when the transmission information (D2) is input. A compressed packet Pb (3) storing information (D1-D3) and a compressed packet Pb (4) storing difference information (D1-D4) are generated.
[0092]
FIG. 6 shows a flow of processing in the packet creating means 12, which will be briefly described below.
When the transmission information (D) received by the receiving means 11 is input to the packet creating means 12 (step Sa1), the packet creating means 12 inquires of the judging means 13 which one of the uncompressed packet and the compressed packet should be created. (Step Sa2), the type of the packet to be created is determined based on the packet determination signal Jp from the determination means 13 (Step Sa3).
As a result, when an uncompressed packet is to be created, an identifier (ID) is assigned as the packet identifier Ih2a to the uncompressed packet, and an uncompressed packet Pa including the packet identifier Ih2a is created (step Sa7). Thereafter, the transmission side reference information (that is, the identifier (ID) and the reference source information (D)) Im1 managed by the reference information management unit 15 according to an instruction (transmission side management control signal Cm1) from the packet creation unit 12 Is updated (step Sa8).
[0093]
On the other hand, when a compressed packet is to be created, an identifier (ID) and reference source information (D) are transmitted from the packet creation unit 12 to the reference information management unit 15 as transmission side reference information Im1. It is inquired whether it is managed (step Sa4). Next, the data portion Dpb of the compressed packet Pb is created based on the transmission side reference information (identifier (ID) and reference source information (D)) Im1 from the management means 15 (step Sa5). Further, an identifier (ID) is stored in the header part Hpb together with other header information Ih3 as a reference packet identifier Ih2b, and a compressed packet Pb is created (step Sa6).
Then, the created uncompressed packet Pa or compressed packet Pb is sent to the transmission means 16 (step Sa9). Thereafter, the process of the creating unit 12 returns to the process of step Sa2.
Such processing of the creating unit 12 is performed until the transmission of the last transmission information is completed.
[0094]
Next, the operation of the data receiving apparatus 201 in the data transmission system will be described.
In this data receiving apparatus 201, as shown in FIG. 4 or FIG. 5, uncompressed packets and compressed packets transmitted from the transmission side are sequentially received, and a restoration process is performed on each packet.
[0095]
More specifically, for example, the packet receiving means 21 receives the uncompressed packet Pa (1) and the compressed packets Pb (2) to Pb (4) transmitted from the transmitting side in order, and the received packet Rp detects the error packet. It is output to the means 22. Then, the error packet detection means 22 performs error detection processing for each received packet Rp. As a result, when it is confirmed that the received packet Rp is correctly transmitted, the received packet Rp is output to the packet restoration means 23 as a normal packet Pno. On the other hand, when it is not confirmed that the received packet Rp is correctly transmitted, the received packet Rp is discarded. Here, CRC (Cyclic Redundancy Check), which is generally widely used as an error detection method, is used, but the error detection method is not limited to this.
[0096]
When the uncompressed packet Pa (1) is input as the normal packet Pno, the restoration means 23 converts the normal packet Pno into the compressed packet and the uncompressed packet by the compressed / uncompressed identifier Ih1 included in the header portion of the normal packet Pno. Which one is determined. In this case, since the normal packet Pno received by the decompression means 23 is the uncompressed packet Pa (1), the decompression means 23 extracts the transmission information (D1) from the data part Dpa of the uncompressed packet Pa (1). A restoration process is performed.
[0097]
Next, in the management means 25, the receiving side reference information (identifier (ID) and reference source information (D)) Im2 managed by the management means 25 according to the instruction (receiving side management control information) Cm2 from the restoring means 23 Is updated. Thereby, the identifier (ID) and the reference source information (D) recorded in the management unit 25 are changed to the identifier (ID = 0) and the transmission information (D1), respectively. Thereafter, in the restoration means 23, the transmission information (D1) as the restoration information Irs is sent to the output means 26, and the transmission information (D1) is output by the output means 26.
[0098]
Next, when the compressed packet Pb (2) is input as the normal packet Pno, the restoration means 23 converts the normal packet Pno from the compressed packet to the compressed packet by the compressed / uncompressed identifier Ih1 included in the header portion of the normal packet Pno. It is determined which of the packets. In this case, since the normal packet Pno is the compressed packet Pb (2), the identifier (ID = 0) included in the compressed packet as the reference packet identifier Ih2b is sent from the restoring unit 23 to the reference information managing unit 25. In addition, it is inquired whether the reference source information (D1) corresponding to this identifier (ID = 1) is stored in the management means 25.
[0099]
In this case, since the identifier (ID = 0) and the reference source information (D1) corresponding to the identifier (ID = 0) are stored in the management unit 25, the restoration unit 23 stores the reference source stored in the management unit 25. The transmission information (D2) corresponding to the compressed packet Pb (2) is restored using the information (D1) and the difference information (D1-D2) stored in the compressed packet Pb (2). Thereafter, transmission information (D2) is sent from the restoration means 23 to the output means 26 as restoration information Irs of the difference information (D1-D2), and the transmission information (D2) is output by the output means 26.
[0100]
Thereafter, when the compressed packets Pb (3) and Pb (4) are input to the packet decompression unit 23 as the normal packet Pno, the difference is the same as when the compressed packet Pb (2) is input. Transmission information (D3) and (4) are generated as restoration information Irs for information (D1-D3) and difference information (D1-D4). The transmission information (D3) and (4) are sent to the output means 26 and output by the output means 26.
[0101]
Further, either one of the identifier (ID = 0) stored in the normal packet Pno input as a compressed packet to the restoration unit 23 and the corresponding reference source information (D1) is sent to the management unit 25. If not accumulated, the restoration means 23 discards the normal packet Pno input as a compressed packet, and the restoration means 23 sends an error occurrence signal Se indicating that a restoration error has occurred to the error occurrence notification means 24. Is output.
In the notification means 24, when the error occurrence signal Se is input, the notification means 24 notifies the transmission side that a restoration error has occurred by the restoration error notification signal Ne.
[0102]
FIG. 7 shows a processing flow in the packet restoration means 23, which will be briefly described below.
When the normal packet Pno is input from the error packet detection unit 22 (step Sb1), the packet restoration unit 23 determines whether the normal packet Pno is an uncompressed packet or a compressed packet (step Sb2).
[0103]
When the normal packet Pno is the uncompressed packet Pa, the transmission information (D) is extracted from the data part Dpa of the uncompressed packet Pa by the decompression process for the uncompressed packet Pa (step Sb6). Then, the identifier (ID) and the reference source information (D), which are the reception side reference information Im2 in the reference information management means 25, are updated by the instruction of the packet restoration means 23 (reception side management control signal Cm2) (step Sb7). . The transmission information (D) extracted from the data part Dpa of the uncompressed packet Pa is sent to the output means 26 (step Sb10).
On the other hand, when the normal packet Pno is the compressed packet Pb, the packet restoration unit 23 inquires the reference information management unit 25 whether the identifier (ID) and the reference source information (D) are managed as the reception side reference information Im2. Step Sb3).
[0104]
Next, it is determined whether or not an uncompressed packet is received as a reference packet necessary for restoring the difference information of the compressed packet (step Sb4). This determination is made by using the identifier (ID) stored as the reference packet identifier Ih2b in the compressed packet Pb, the transmission information (D) corresponding to the compressed packet Pb, and the identifier (ID) stored in the reference information management means 25. And collation with reference source information (D) corresponding thereto.
[0105]
When an uncompressed packet Pa as a reference packet corresponding to the compressed packet Pb is received, the reference packet information P is stored in the compressed packet Pb using the reference source information (D) stored in the reference information management means 25. Corresponding transmission information (D) is restored (step Sb5). Further, the restored transmission information (D) is sent to the output means 26 (step Sb10). Thereafter, the process of the restoration unit 23 returns to the process of step Sb2.
[0106]
If the result of determination in step Sb4 is that a non-compressed packet as a reference packet corresponding to the received compressed packet has not been received, the packet restoring means 23 compresses the received normal packet Pno. The packet Pb is discarded (step Sb8). Then, the error occurrence signal Se is output to the error occurrence notification means 24 (step Sb9). Thereafter, the process of the restoration unit 23 returns to the process of step Sb2.
Such processing of the restoring means 23 is performed until the last packet is received.
[0107]
As described above, in the data transmission system according to the first embodiment, transmission information is stored in units of packets using uncompressed packets Pa stored without compressing transmission information and compressed packets Pb stored after compressing transmission information. When transmitting, difference information (ΔD) between transmission information corresponding to the compressed packet Pb and transmission information corresponding to the latest uncompressed packet Pa transmitted before the compressed packet is stored in the compressed packet as compressed information Id. Since the non-compressed packet Pa is normally transmitted, even if a transmission error of the compressed packet Pb occurs, difference information (ΔD of the normally transmitted compressed packet Pb after the error packet is stored. ) Can be restored using the transmission information of the uncompressed packet Pa. For this reason, the number of compressed packets discarded due to the occurrence of a compressed packet transmission error is greatly reduced. As a result, it is possible to improve the quality of data transmitted through the wireless section. In other words, the effective speed of data transmission can be improved, and the time and cost required for transmitting a packet that cannot be restored can be greatly reduced.
In the first embodiment, there is one reference packet identifier (ID) Ih2b included in the header portion Hpb of the compressed packet Pb, but the header portion Hpb includes a plurality of reference packet identifiers (ID). It is also possible. However, in this case, it is necessary to continuously transmit a plurality of uncompressed packets.
[0108]
(Modification 1 of Embodiment 1)
FIG. 8A shows a data structure of an uncompressed packet Paa used when the compressed packet includes two reference packet identifiers (ID). In this case, the uncompressed packet Paa is continuously transmitted twice.
The uncompressed packet Paa includes a header part Hpaa that stores header information and a data part Dpaa that stores transmission information (D) as uncompressed information Ir transmitted by the PPP protocol. Here, the information in the header part Hpaa includes the compressed / uncompressed identifier Ih1, the packet identifier (ID) Ih2a, and other header information Ih3. Further, the compression / non-compression identifier Ih1 of the uncompressed packet Paa indicates non-compression.
[0109]
FIG. 8B shows a data structure of a compressed packet Pbb including two reference packet identifiers (identification IDs).
The compressed packet Pbb includes a header part Hpbb that stores header information and a data part Dpbb that stores first and second compressed information Id1 and Id2 transmitted by the PPP protocol. Here, the information in the header part Hpbb includes the compressed / uncompressed identifier Ih1, the first and second reference packet identifiers (ID1, ID2) Ih2b1, Ih2b2, and the like for identifying the uncompressed packet as the reference packet. It consists of other header information Ih3. The compressed / uncompressed identifier Ih1 of the compressed packet Pbb indicates compression. Here, the second compressed information Id2 is difference information (Δ2D) between transmission information corresponding to the latest uncompressed packet Paa transmitted before the compressed packet Pbb and transmission information corresponding to the compressed packet Pbb. It is. The first compressed information Id1 is difference information between transmission information corresponding to the uncompressed packet Paa transmitted immediately before the latest uncompressed packet Paa and transmission information corresponding to the compressed packet Pbb. (Δ1D).
[0110]
In this case, the transmission information (D1) to (D4) shown in FIG. 4 in the first embodiment is transmitted as follows.
FIG. 9 shows the flow of a plurality of packets from the transmission side to the reception side in the normal transmission state.
In the first modification of the first embodiment, the transmission information (D1) and (D2) are sequentially transmitted by the uncompressed packets Paa (1) and Paa (2) without being compressed, and the transmission information (D3) and (D4 ) Are compressed and sequentially transmitted by compressed packets Pb (3) and Pb (4) following the uncompressed packet Paa (2).
[0111]
On the transmitting side, first, the uncompressed packet Paa (1) is generated, and the uncompressed packet Paa (1) is transmitted to the receiving side. At this time, the transmission information (D1) is stored as the uncompressed information Ir in the data portion Dpaa of the uncompressed packet Paa (1), the identifier Ih1 indicating uncompressed in the header portion Hpaa, and a packet for identifying this packet An identifier (ID = 0) Ih2a and other header information Ih3 are stored.
[0112]
Subsequently, the uncompressed packet Paa (2) is generated, and the uncompressed packet Paa (2) is transmitted to the receiving side. At this time, the transmission information (D2) is stored as the uncompressed information Ir in the data portion Dpaa of the uncompressed packet Paa (2). (ID = 1) Ih2a and other header information Ih3 are stored.
[0113]
Thereafter, the compressed packet Pbb (3) is generated, and the compressed packet Pbb (3) is transmitted to the receiving side. At this time, the data portion Dpbb of the compressed packet Pbb (3) stores the first and second compressed information Id1 and Id2 for the transmission information (D3), and the header portion Hpbb contains an identifier Ih1, The first reference packet identifier (ID = 0) Ih2b1, the second reference packet identifier (ID = 1) Ih2b2, and other header information Ih3 are stored.
[0114]
Here, the first compressed information Id1 corresponds to the compressed packet Pbb (3) from the transmission information (D1) corresponding to the packet Paa (1) using the uncompressed packet Pa (1) as a reference packet. It is difference information (D1-D3) obtained by subtracting transmission information (D3). The compressed information Id2 is transmitted from the transmission information (D2) corresponding to the packet Paa (2) to the transmission information (D3 corresponding to the compressed packet Pbb (3) using the uncompressed packet Paa (2) as a reference packet. ) Is obtained by subtracting the difference information (D2-D3).
[0115]
Further, the compressed packet Pbb (4) is generated, and the compressed packet Pbb (4) is transmitted to the receiving side. At this time, the data portion Dpbb of the compressed packet Pbb (4) stores the first and second compressed information Id1 and Id2 for the transmission information (D4), and the header portion Hpbb contains an identifier Ih1, The first reference packet identifier (ID = 0) Ih2b1, the second reference packet identifier (ID = 1) Ih2b2, and other header information Ih3 are stored.
[0116]
Here, the first compressed information Id1 corresponds to the compressed packet Pb (4) from the transmission information (D1) corresponding to the packet Paa (1) using the uncompressed packet Paa (1) as a reference source packet. Difference information (D1-D4) obtained by subtracting transmission information (D4) to be transmitted. The second compressed information Id2 corresponds to the compressed packet Pb (4) from the transmission information (D2) corresponding to the packet Paa (2) using the uncompressed packet Paa (2) as a reference source packet. It is difference information (D2-D4) obtained by subtracting transmission information (D4).
[0117]
Note that the first packet identifier (ID = 0) Ih2b1 stored in the header portion Hpbb of each compressed packet Pbb (3), Pbb (4) has the reference packet as the uncompressed packet Paa (1). It shows that there is. The second packet identifier (ID = 1) Ih2b2 stored in the header part Hpbb of each compressed packet Pbb (3), Pbb (4) has the reference packet as the uncompressed packet Paa (2). It shows that there is.
[0118]
As described above, the uncompressed packets Paa (1) and Paa (2) sequentially transmitted from the transmitting side and the subsequent compressed packets Pbb (3) and Pbb (4) are sequentially received on the receiving side in a normal data transmission state. The received transmission information (D1) to (D4) corresponding to each packet is restored.
That is, on the receiving side, when uncompressed packets Paa (1) and Paa (2) are received, transmission information (D1) and (D2) are extracted from the data portion Dpaa. Subsequently, when the compressed packet Pbb (3) is received, the second difference information (D2-D3) is extracted from the data portion Dpbb, and the second reference packet identifier (ID = 1) Ih2b2 specifies. With reference to the transmission information (D2) corresponding to the second uncompressed packet Pa (2), the transmission information (D3) corresponding to the compressed packet Pbb (3) is restored from the difference information (D2-D3).
[0119]
Thereafter, when the compressed packet Pbb (4) is received, the difference information (D2-D4) is extracted from the data portion Dpbb as in the case of the compressed packet Pbb (3), and the second reference packet identifier (ID) = 1) With reference to transmission information (D2) corresponding to uncompressed packet Paa (2) specified by Ih2b2, transmission information (D4) corresponding to compressed packet Pbb (4) is obtained from difference information (D2-D4). ) Is restored.
[0120]
Here, since both the uncompressed packets Paa (1) and Paa (2), which are reference packets for the compressed packets Pbb (3) and Pbb (4), are normally received, the uncompressed packets that are close to the compressed packets. Although Paa (2) is a reference packet, when a transmission error of an uncompressed packet Paa (2) close to each compressed packet occurs, the previous uncompressed packet Paa (1) is used as a reference packet and A restoration process is performed.
[0121]
In this way, two uncompressed packets Paa are transmitted in succession, and as the subsequent compressed packet Pbb, difference information (Δ1D), (Δ2D) based on the transmission information of the two uncompressed packets, and the two uncompressed packets Of the plurality of identifiers (ID1) and (ID2) in the compressed packet by transmitting a packet storing the first and second reference packet identifiers (ID1, ID2) Ih2b1 and Ih2b2 indicating that is a reference packet If the reference information management means 25 stores at least one identifier and the reference source information corresponding to this identifier, the compressed packet can be restored. In other words, the number of compressed packets discarded due to transmission errors of uncompressed packets can be reduced.
[0122]
In the first embodiment, the compression / non-compression determination unit 13 in the data transmitting apparatus 101 creates an uncompressed packet immediately after the start of communication and immediately after receiving the decoding error notification signal Ne from the error occurrence notification receiving unit 14. After that, until the decoding error notification signal Ne is received, the packet creation unit 12 is controlled to create a compressed packet. The compression / non-compression determination unit 13 The configuration is not limited to the configuration, and the packet creation unit 12 may be controlled so that uncompressed packets are periodically transmitted.
In other words, in this case, in a state where there is no notification of the occurrence of a restoration error from the reception side, the transmission side compresses / non-compresses so that one uncompressed packet is transmitted each time a predetermined number of compressed packets are transmitted. The compression determination unit 13 instructs the packet creation unit 12. For example, when the number of compressed packets predetermined as the transmission interval of uncompressed packets is 3, transmission of one uncompressed packet and subsequent transmission of three compressed packets are repeated.
[0123]
The effect by such a structure is demonstrated easily.
Header information such as TCP / IP packets and UDP / IP packets necessary for transmitting image information and audio information, as well as header information such as TCP / IP packets is transmitted in a PPP packet (that is, in FIGS. 1A and 1B). Stored in the data portion Dpa and Dpb of the packet).
However, the difference information between the two connected packets of the image information, the audio information, and the header information is usually very small or zero, but the difference information between the distant packets tends to be large. There is. Therefore, by periodically transmitting uncompressed packets, the average value of the difference information is reduced while improving the quality of data transmitted by radio, that is, the information compression efficiency in the data portion is also improved. be able to.
[0124]
Further, the compression / non-compression determination unit 13 in the data transmission apparatus 101 of the first embodiment obtains the average size m of the difference information stored in the data part of the compressed packet, and this size exceeds a certain value x. In this case, the packet creation unit 12 may be controlled to transmit an uncompressed packet.
Here, the average size m of the difference information is obtained as an average value of the difference information of a plurality of compressed packets transmitted from the last transmission of the uncompressed packet to the present time. Specifically, four compressed packets are transmitted from the last uncompressed packet to the present time, and the sizes of the difference information of these four compressed packets are “2”, “4”, “4”, respectively. , “6”, the average size m of the difference information at the present time is 4 = (2 + 4 + 4 + 6) / 4.
Also in this case, the average value of the difference information can be reduced, that is, the information compression efficiency in the data portion can be improved while improving the quality of data transmitted by radio.
[0125]
The average size m of the difference information may be measured by the data receiving device 201.
Specifically, on the receiving side, the packet restoration unit 23 measures the average size m of the difference information, and outputs an oversize signal to the error occurrence notification unit 24 when the average size m exceeds a certain value x. The configuration. Further, the error occurrence notification transmission means 24 not only transmits the restoration error notification signal Ne to the transmission side when receiving the error occurrence signal Se, but also transmits an uncompressed packet to the transmission side when receiving the oversize signal. A packet request signal for requesting transmission is transmitted.
On the other hand, on the transmission side, the error notification unit 14 in the data transmission terminal 101 compresses / compresses the error notification reception signal Sn not only when receiving the restoration error notification signal Ne but also when receiving the packet request signal. The output is made to the non-compression determination means 13.
[0126]
In addition, the transmission of the uncompressed packet is not when the average size x of the difference information exceeds a certain value x as described above, but when a compressed packet whose difference information size exceeds the certain value m is transmitted or received. Sometimes it can be done.
For example, the data transmitting apparatus 101 may transmit an uncompressed packet subsequent to the compressed packet as the transmission target when the size of the compression information included in the compressed packet to be transmitted exceeds a certain value. Good.
[0127]
Further, the data receiving apparatus 201 requests the transmitting side to transmit an uncompressed packet when the size of the compressed information included in the compressed packet to be subjected to the decompression process received from the transmitting side exceeds a certain value, The transmitting apparatus 101 may transmit the uncompressed packet to the receiving side immediately after receiving the transmission request for the uncompressed packet from the receiving side.
[0128]
(Modification 2 of Embodiment 1)
Further, in the first embodiment, as shown in FIG. 1, the data portion Dpb of the compressed packet Pb includes difference information (the difference information between the entire transmission information corresponding to the compressed packet and the entire transmission information corresponding to the uncompressed packet ( ΔD) is stored, but in the data portion Dpb of the compressed packet Pb, information obtained by compressing only a part of the transmission information corresponding to the compressed packet may be stored.
That is, the transmission information is divided into compression target information to be compressed and non-compression target information to be compressed, and the compression target information in the transmission information corresponding to the uncompressed packet is stored in the data portion of the compressed packet. And difference information with respect to the compression target information in the transmission information corresponding to the compressed packet, and non-compression target information in the transmission information corresponding to the compressed packet.
[0129]
FIG. 10A shows the data structure of an uncompressed packet Pc used when transmission information is composed of compression target information and non-compression target information.
The uncompressed packet Pc is composed of a header portion Hpc storing header information and a data portion Dpc storing uncompressed information Ir transmitted by the PPP protocol. The information in the header part Hpc is used to identify the compressed / uncompressed identifier Ih1 indicating whether or not the information in the data part is compressed, as in the uncompressed packet Pa shown in FIG. Packet identifier (ID) Ih2a and other header information Ih3. Here, uncompressed compression target information and non-compression target information Inc are stored in the data portion Dpc, and the uncompressed compression target information includes first, second, and third information. It consists of item-specific uncompressed information Ira, Irb, and Irc corresponding to the items to be compressed. Specifically, the item-specific uncompressed information Ira, Irb, and Irc are information (Da) and (Da) corresponding to the first, second, and third items to be compressed in the transmission information corresponding to the uncompressed packet, respectively. Db) and (Dc).
[0130]
FIG. 10B shows a data structure of a compressed packet Pd used when transmission information is composed of compression target information and non-compression target information.
The compressed packet Pd includes a header portion Hpd that stores header information and a data portion Dpb that stores partially compressed information transmitted by the PPP protocol. As in the compressed packet Pb shown in FIG. 1B, the information in the header part Hpb includes a compressed / uncompressed identifier Ih1 indicating whether or not the information in the data part is compressed, and a reference packet for identifying the reference packet. It consists of an identifier (ID) Ih2b and other header information Ih3.
[0131]
Here, the data portion Dpb stores compressed compression target information and non-compression target information Inc, and the compressed compression target information includes the first, second, and third compressions. It consists of item-specific compression information Ida, Idb, Idc corresponding to the target item. Specifically, the item-specific compression information Ida includes the information (Da) corresponding to the first compression target item in the transmission information corresponding to the uncompressed packet, and the first information in the transmission information corresponding to the compressed packet. This is difference information (ΔDa) from information (Da) corresponding to the compression target item. The item-specific compression information Idb corresponds to the information (Db) corresponding to the second compression target item in the transmission information corresponding to the uncompressed packet and the second compression target item in the transmission information corresponding to the compressed packet. Difference information (ΔDb) with the information (Db). The item-specific compression information Idc corresponds to the information (Dc) corresponding to the third compression target item in the transmission information corresponding to the uncompressed packet and the third compression target item in the transmission information corresponding to the compressed packet. Difference information (ΔDc) with the information (Dc) to be performed.
[0132]
In this case, the reference information management unit 15 in the data transmission apparatus 101 includes a reference packet identifier (ID), each compression target item, and information corresponding to each compression target item in the reference source information (transmission information in the reference packet) ( The item-specific reference source information) is stored in a table.
Similarly to the reference information management unit 15, the reference information management unit 25 in the data receiving apparatus 201 also tabulates the reference packet identifier (ID), the items to be compressed, and the item-specific reference source information. The configuration is to memorize
In such a configuration, since the transmission information is compressed for each individual compression target item, the management unit 15 and the management unit are maintained while maintaining the effect that a certain amount of information can be reduced by the information compression. The storage capacity of a memory such as a RAM mounted on the memory 25 can be reduced.
[0133]
(Modification 3 of Embodiment 1)
Furthermore, in the first embodiment and the first modification thereof or the second modification thereof, the data portion of the compressed packet includes information obtained by compressing all or part of the transmission information corresponding to the compressed packet as shown in FIG. ) Or as shown in FIG. 10 (b), the difference information between the whole or part of the transmission information corresponding to the uncompressed packet and the whole or part of the transmission information corresponding to the compressed packet is stored. Instead of the difference information or together with the difference information, difference specifying additional information (K) for calculating the difference information may be stored in the header portion or the data portion of the compressed packet.
For example, in the compressed packet Pb shown in FIG. 1B, instead of the difference information, difference specifying additional information (K) for calculating the difference information can be stored.
Further, in the compressed packet Pd shown in FIG. 10 (b), instead of the difference information that is at least a part of the item-by-item compression information, a difference specifying addition for calculating the difference information is added. Information (K) can be stored.
[0134]
FIG. 11 is a diagram for explaining the data structure of the packet used when the difference specifying additional information (K) is stored in the compressed packet as described above.
FIGS. 11A and 11B show the data structures of the uncompressed packet Pe and the compressed packet Pf used in this case, respectively.
The uncompressed packet Pe is composed of a header part Hpe storing header information and a data part Dpe storing transmission information transmitted by the PPP protocol. The uncompressed packet Pc shown in FIG. It has the same configuration.
[0135]
The compressed packet Pf includes a header part Hpf that stores header information and a data part Dpf that stores partially compressed information transmitted by the PPP protocol. In addition to the compressed / uncompressed identifier Ih1, reference packet identifier (ID) Ih2b, and other header information Ih3 in the compressed packet Pd shown in FIG. ) Ih4 is stored. Further, the data portion Dpf includes three item-specific compression information Ida, Idb, Idc and non-compression target information Inc, as in the compressed packet Pd shown in FIG.
Here, the difference specifying additional information (K) is a sequence number indicating the number of the compressed packet positioned from the uncompressed packet referred to in the decompression process. Further, the difference information (ΔDa) and (ΔDb) as the item-specific compression information Ida and Idb is equal to the difference specifying additional information (K). Therefore, the data size of the difference information (ΔDa) and (ΔDb) is 0 byte.
[0136]
Hereinafter, the case where the difference specifying additional information (K) is stored in the compressed packet will be described by taking data transmission using the RTP (Real Time Protocol) protocol as an example.
Specifically, image information or audio information is converted into RTP format data according to the RTP protocol defined in RFC 1889/1890, and the RTP format data is further converted into UDP / IP format data according to the UDP protocol and the IP protocol. A case where data in the RTP / UDP / IP format is transmitted from the data transmission terminal 101 to the data reception terminal 201 will be described. The RTP / UDP / IP format data corresponds to the IP packet Pipb shown in FIG.
[0137]
Normally, the sequence number Isn (see FIG. 29A) included in the header Hrtp of the RTP packet Prtp is incremented by 1 each time one RTP packet is created. Also, the packet identification ID (IPv4 (Internet Protocol version 4) ID) (not shown) included in the header Hipb of the IP packet Pipb increases by 1 each time one IP packet is created. Is. When these values are stored as differential information in the compressed packet, if the number of the compressed packet that is located from the uncompressed packet as the reference packet corresponding to the compressed packet is known, 0 is obtained. Can be.
[0138]
In other words, when the sequence number Isn in the header part Hrtp of the RTP packet Prtp is stored in the compressed packet as simple difference information, the amount of information of the sequence number Isn is always required to be 1 byte or more. By using this, the size of the difference information corresponding to the sequence number Isn is normally 0 bytes, and the compression efficiency can be improved.
For example, when the size of the difference specifying additional information (K) is 1 byte, the size of the difference information of the sequence number Isn in the header part Hrtp of the RTP packet is normally 0 bytes, and the sum of the difference specifying additional information and the difference information is usually 1 byte. In this case, the information amount of the RTP packet does not change even if the difference specifying additional information (K) is used.
However, when the transmission information includes a plurality of pieces of compression target information that can be restored using the same calculation method as the above calculation method (that is, the sum of the difference specifying additional information and the difference information), for example, as described above, the RTP packet When there are two types of information such as a sequence number in the header part and IPv4ID in the header part of the IP packet, a substantial effect can be obtained by using the difference specifying additional information, and compression efficiency can be improved. Can do.
[0139]
Further, using the difference specifying additional information as a variable, the difference information corresponding to the target compressed packet is obtained from the transmission information corresponding to the reference packet (uncompressed packet) used for the restoration process of the target compressed packet to be processed. A calculation formula may be used.
Here, as the above-described calculation formula, for example, a formula that defines four arithmetic operations (addition, subtraction, integration, division) and function operations such as sin and cos can be considered.
The calculation formula using the difference specifying additional information as a variable may be determined in advance on the transmission side and the reception side in advance, or may be dynamically changed during data transmission according to a certain rule. As a result, it is possible to further improve the compression efficiency of transmission information stored in the data portion of the PPP packet, and to further improve the quality and effective transmission rate of the wirelessly transmitted data.
[0140]
(Embodiment 2)
  FIG. 12 is a block diagram for explaining a data transmission method according to the second embodiment of the present invention, and shows a data transmission apparatus in a data transmission system using this data transmission method..
  ThisIn addition to the configuration of the data transmission apparatus 101 of the first embodiment, the data transmission apparatus 102 monitors the number of transmissions of the uncompressed packet output from the compressed / uncompressed packet creation means 12 to the reception side. A packet transmission frequency monitoring means 31 is provided. The transmission number monitoring means 31 receives the packet from the compressed / uncompressed packet creation means 12 and outputs the same uncompressed packet Pa to the packet transmitting means 16 continuously for a certain number of times (here, twice), and then The compressed packet Pb following the compressed packet Pa is output to the packet transmitting means 16. Other configurations of the data transmitting apparatus 102 are the same as those of the data transmitting apparatus 101 of the first embodiment.
  The data receiving apparatus in the data transmission system of the second embodiment has the same configuration as the data receiving apparatus 201 in the data transmission system of the first embodiment.
[0141]
Next, the function and effect will be described.
In the data transmission apparatus 102 according to the second embodiment configured as described above, the transmission count monitoring unit 31 monitors the number of transmissions of uncompressed packets, and the packet generation unit 12 outputs the uncompressed packets to the transmission count monitoring unit 31. Then, the same number of uncompressed packets Pa (1) are output from the transmission count monitoring means 31 to the packet transmission means 16 for a predetermined number of times (here, twice) as shown in FIG. Thereafter, the compressed packets Pb (2), Pb (3), and Pb (4) following the uncompressed packets are sequentially output to the packet transmitting means 16. In the packet transmission unit 16, the packets supplied from the transmission number monitoring unit 31 are sequentially transmitted by a predetermined wireless transmission method such as W-CDMA.
Other operations in the data transmission apparatus 102 are performed in the same manner as the data transmission apparatus 101 of the first embodiment.
[0142]
Further, in the data receiving apparatus, when two consecutive uncompressed packets Pa (1) are normally received as shown in FIG. 13, the reference information management means 25 sequentially identifies the identifier (ID) and the reference source information ( D) is updated. As a result, when the compressed packet Pb (2), Pb (3), Pb (4) is received following the uncompressed packet, the identifier (ID = 0) and the reference source information held in the reference information management means 25 (D1) will be referred to.
Even when one of the two consecutive uncompressed packets Pa (1) is not transmitted to the receiving side due to a transmission error, the normally transmitted uncompressed packet is transmitted via the error packet detecting means 22 to the packet restoring means. 23 is input. For this reason, in the reference information management means 25, the identifier (ID) and the reference source information (D) which are the receiving side reference information Im2 are updated to those for the uncompressed packet Pa (1).
[0143]
As described above, in the second embodiment, in addition to the configuration of the first embodiment, the uncompressed packet Pa is continuously transmitted twice, and then the compressed packet Pb following the uncompressed packet Pa is transmitted. Even if a transmission error occurs in one of a plurality of uncompressed packets transmitted, the receiving side can correctly restore the differential information of the subsequent compressed packets. As a result, the number of received packets discarded due to a restoration error on the receiving side is reduced, and the quality of data transmitted by radio can be improved.
In the second embodiment, the uncompressed packet is transmitted twice continuously, but the number of continuous transmissions of the uncompressed packet may be three or more.
[0144]
In the second embodiment, the transmission count monitoring unit 31 is configured to manage the transmission count of the uncompressed packet so that the uncompressed packet itself is transmitted a plurality of times. After an uncompressed packet is transmitted, an auxiliary packet that stores a packet identifier (ID) and transmission information (D) corresponding to the uncompressed packet and that is different from the uncompressed packet is transmitted continuously one or more times. The configuration may be such that the number of packet transmissions is managed.
In this case, the packet creation means 12 creates an auxiliary packet storing a packet identifier (ID) and transmission information (D) corresponding to the uncompressed packet after creating the uncompressed packet. Thereafter, a plurality of compressed packets corresponding to the uncompressed packets (that is, compressed packets storing difference information created using transmission information of the uncompressed packets) are created. When the uncompressed packet, the auxiliary packet, and each compressed packet are supplied to the transmission count monitoring means 31 in the order of creation, the transmission count monitoring means 31 transmits the uncompressed packet, and then the auxiliary packet It is transmitted continuously a predetermined number of times. Thereafter, each compressed packet is transmitted sequentially.
[0145]
In such a configuration, a reference packet identifier and reference source information are transmitted at least twice before a compressed packet corresponding to the uncompressed packet is transmitted by one uncompressed packet and a predetermined number of auxiliary packets. Therefore, even if a transmission error occurs in one of these uncompressed packets and auxiliary packets, the receiving side can correctly restore the differential information of the subsequent compressed packets.
As a result, the number of received packets discarded due to a restoration error on the receiving side is reduced, and the quality of data transmitted by radio can be improved.
[0146]
Further, in the second embodiment, the uncompressed packet or the auxiliary packet is continuously transmitted a predetermined number of times. However, the continuous transmission frequency of the uncompressed packet or the auxiliary packet is changed from the receiving side to the transmitting side. You may make it change according to the notification frequency of the restoration | recovery error performed.
For example, when changing the number of continuous transmissions of uncompressed packets, the compression / non-compression transmission determination unit 13 counts the number of times the error notification reception signal Sn from the error occurrence notification reception unit 14 is input per unit time, The count value is compared with a certain reference value Y, and a transmission frequency control signal is output to the transmission frequency monitoring means 31 according to the comparison result. The transmission count monitoring means 31 increases or decreases the transmission count of the uncompressed packet or the auxiliary packet based on the transmission count control signal. Specifically, when the count value exceeds a certain reference value Y, the number of transmissions of the uncompressed packet or auxiliary packet increases, and when the count value becomes equal to or less than the reference value Y, the uncompressed packet Alternatively, the number of auxiliary packet transmissions is reduced.
[0147]
In such a configuration, when the quality of transmission data is relatively stable, the transmission efficiency can be increased by reducing the number of transmissions of uncompressed packets or auxiliary packets, and the quality of transmission data is unstable Can reduce the number of packets discarded on the receiving side due to a restoration error by increasing the number of transmissions of uncompressed packets or auxiliary packets.
[0148]
(Embodiment 3)
  14 and 15 are diagrams for explaining a data transmission method according to the third embodiment of the present invention..
  Figure14 is a block diagram showing a data transmission apparatus in a data transmission system that performs data transmission by this data transmission method.
  In addition to the configuration of the data transmitting apparatus 101 of the first embodiment, the data transmitting apparatus 103 receives the uncompressed packet Pa and the compressed packet Pb output from the compressed / uncompressed packet creation unit 12, and receives the uncompressed packet Pa. Error correction code adding means 32 for assigning an error correction code to the ECC-added uncompressed packet Pac to which an error correction code (Error Correction Code) has been assigned by the means 32 and a compressed packet that has passed through the means 32 Pb is supplied to the packet transmission means 16. The other configuration of the data transmitting apparatus 103 according to the third embodiment is the same as that of the data transmitting apparatus 101 according to the first embodiment.
[0149]
FIG. 15 is a block diagram illustrating a data receiving apparatus in a data transmission system that performs data transmission by the data transmission method of the third embodiment.
In addition to the configuration of the data receiving apparatus 201 of the first embodiment, the data receiving apparatus 203 of the third embodiment is given an error correction code in the received packet Rp output from the packet receiving means 21. Error correction means 41 for performing error correction processing on the uncompressed packet Pac being output and outputting the compressed packet Pb to which the error correction code is not given as it is. The packet output from the error correction means 41 is The error packet detection means 22 is supplied. Other configurations of the data receiving apparatus 203 are the same as those of the data receiving apparatus 201 of the first embodiment.
[0150]
Next, the function and effect will be described.
In the data transmitting apparatus 103 according to the third embodiment having such a configuration, an uncompressed packet created by the packet creating unit 12, that is, a packet in which reference source information used for decompression processing of a compressed packet is stored is an error. When input to the correction code adding means 32, the error correction code adding means 32 adds an error correction code to the uncompressed packet Pa, and the ECC added uncompressed packet Pac with the error correction code added to the packet transmitting means 16. Is output. The compressed packet Pb created by the packet creating means 12 is output to the packet transmitting means 16 as it is without being processed by the error correction code adding means 32. Other operations in the data transmitting apparatus 103 are the same as those of the data transmitting apparatus 101 of the first embodiment.
On the other hand, in the data receiving device 203, when the received packet Rp output from the packet receiving unit 21 is input to the error correcting unit 41, an ECC-added uncompressed packet to which an error correction code is assigned among the received packets Rp. Pac is subjected to error correction processing and output to the error packet detection unit 22, and the compressed packet Pb to which no error correction code is assigned is output to the error packet detection unit 22 as it is. Other operations in the data receiving apparatus 203 are the same as those of the data transmitting apparatus 201 of the first embodiment.
[0151]
As described above, in the third embodiment, the error correction code is added to the uncompressed packet Pa on the transmitting side to transmit the ECC-added uncompressed packet Pac, and the error correction is performed on the ECC-added uncompressed packet Pac on the receiving side. Since error correction processing is performed using a code, even if a transmission error occurs, many uncompressed packets are relieved on the receiving side by error correction processing. Occurrence can be suppressed.
As a result, the number of received packets discarded due to the decompression error of the compressed packet that follows the uncompressed packet is reduced, and the quality of data transmitted by radio can be improved.
[0152]
In the third embodiment, an error correction code is added to the uncompressed packet itself. However, reference information (identifier (identifier)) necessary for decompression processing of a part of the uncompressed packet, that is, the subsequent compressed packet. An error correction code may be added only to a part including ID) and reference source information (D)).
In this case, error correction processing is performed on at least the identifier (ID) and reference source information (D) necessary for decompression of the compressed packet on the receiving side.
[0153]
As a result, the number of received packets discarded due to the decompression error of the compressed packet that follows the uncompressed packet is reduced, and the quality of data transmitted by radio can be improved.
[0154]
Furthermore, in the third embodiment, an error correction code is always added to the uncompressed packet. However, the uncompressed packet is changed according to the frequency of notification of restoration error performed from the reception side to the transmission side. It may be determined whether or not an error correction code is to be added.
In this case, the compression / non-compression transmission determination unit 13 counts the number of times the error notification reception signal Sn from the error occurrence notification reception unit 14 is input per unit time, and the count value and a constant reference value Y are obtained. The comparison is made, and an error correction control signal is output to the creating means 12 in accordance with the comparison result. Based on this error correction control signal, the creation means 12 notifies the error correction code adding means 32 whether or not to add an error correction code to the uncompressed packet. Specifically, when the count value exceeds a certain reference value Y, the error correction code adding means 32 adds an error correction code to the uncompressed packet and outputs it from the means 32, and the count value is the reference value. When the value becomes Y or less, the error correction code adding means 32 outputs the uncompressed packet from the means 32 without being given an error correction code.
In such a configuration, when the quality of transmission data is relatively stable, by transmitting the uncompressed packet as it is, it is possible to suppress the size of the entire uncompressed packet and increase the effective data transmission rate. When the quality of transmission data is unstable, the number of packets discarded on the receiving side due to a restoration error can be reduced by adding an error correction code to an uncompressed packet.
[0155]
(Embodiment 4)
  FIGS. 16 and 17 are block diagrams for explaining a data transmission method according to the fourth embodiment of the present invention. FIG. 16 shows a data transmission apparatus 104 in a data transmission system using this transmission method..
[0156]
This data transmission apparatus 104 receives the retransmission request notification signal Nr of the uncompressed packet from the reception side instead of the error occurrence notification reception means 14 in the data transmission apparatus 101 of the first embodiment, and receives the retransmission request reception signal Sr. Retransmission request notification receiving means 14d for outputting the packet, and the packet creating means 12 and the compressed / uncompressed transmission judging means 13 in the data transmitting apparatus 101 so that the uncompressed packet is created according to the retransmission request received signal Sr. The configuration of is changed.
[0157]
That is, the compression / non-compression transmission determination unit 13d in the data transmission apparatus 104 outputs a packet determination signal Jp indicating the type of packet generated by the packet generation unit 12d to the packet generation unit 12d and receives a retransmission request. When the signal Sr is received, instead of the packet determination signal Jp, a re-creation command signal Sc is output to the packet creation means 12d so that an uncompressed packet requested for retransmission is created again.
[0158]
Further, the packet creation means 12d in the data transmission apparatus 104 creates one of the uncompressed packet and the compressed packet based on the packet determination signal Jp, and stores it in the reference management means 15 when receiving the re-creation command signal Sc. Based on the identifier (ID) and the reference source information (D), the last created uncompressed packet is created again. The retransmission request notification signal Nr, the retransmission request reception signal Sr, and the re-creation command signal Sc include an identifier (ID) that identifies an uncompressed packet to be retransmitted.
The other configuration of the data transmitting apparatus 104 according to the fourth embodiment is the same as that of the data transmitting apparatus 101 according to the first embodiment.
[0159]
FIG. 17 shows the data receiving device 204 in the data transmission system of the fourth embodiment.
In addition to the configuration of the data receiving apparatus 201 of the first embodiment, the data receiving apparatus 204 of the fourth embodiment temporarily receives a compressed packet determined to be a restoration error packet Pre from among the received compressed packets. The data receiving device 201 generates an error so as to perform a restoration process on the compressed packet determined to be the restoration error packet Pre based on the reference information of the retransmitted uncompressed packet. The notification transmission unit 24 and the packet restoration unit 23 are modified.
That is, in this data receiving apparatus 204, in place of the error occurrence notification transmitting unit 24 in the data receiving apparatus 201 of the first embodiment, when a restoration error occurs, restoration processing of the restoration error packet is performed based on the error occurrence signal Sre. Retransmission request transmission means 24d for outputting a signal (retransmission request notification signal) Nr requesting retransmission of an uncompressed packet as a required reference packet to the transmission side is provided.
[0160]
Further, the packet restoring means 23d in the data receiving apparatus 204 receives the identifier (ID) and the reference source information (D) as the receiving side reference information Im2 necessary for the restoration processing of the received compressed packet in the reference information managing means 25. When it is not stored, it is determined that the received compressed packet is a decompression error packet, and the error occurrence signal Sre is output to the retransmission request notification transmission means 24d. The error occurrence signal Sre includes an identifier (ID) that identifies an uncompressed packet to be retransmitted.
In the data receiving apparatus 204, the decompression process for the compressed packet determined to be the decompression error packet Pre is performed based on the retransmitted identifier (ID) and transmission information (D) of the uncompressed packet. Yes.
Other configurations in the data receiving apparatus 204 of this embodiment are the same as those of the data receiving apparatus 201 in the first embodiment.
[0161]
Next, the function and effect will be described.
In the data transmission system of the fourth embodiment having such a configuration, when a decompression error of the compressed packet Pb occurs, the non-compressed packet is retransmitted from the transmission side by the retransmission request notification signal Nr from the reception side.
That is, on the reception side, the packet restoration unit 23d holds the compressed packet Pb in the reference information management unit 25 with the identifier (ID) and the reference source information (D) that are the reception side reference information Im2 necessary for the restoration process. If it is determined that the packet is a restoration error packet Pre, the compressed packet Pre is output from the packet restoration unit 23d to the restoration waiting information storage unit 42 and temporarily stored. At this time, an error occurrence signal Sre including the reference packet identifier (ID) of the restoration error packet Pre is output to the retransmission request notification unit 24d. Then, the retransmission request notification transmission unit 24d transmits a retransmission request notification signal Nr including the reference packet identifier (ID) to the transmission side.
[0162]
In the data transmission device 104, when the retransmission request notification signal Nr including the reference packet identifier (ID) is received by the reception unit 14d, the retransmission request reception signal Sr is output from the reception unit 14d to the determination unit 13d. A signal (re-creation command signal) Sc instructing creation of an uncompressed packet specified by the reference packet identifier is output from the determination unit 13 to the packet creation unit 12d. Then, the packet creation unit 12d uses the identifier (ID) and the reference source information (D) that are the transmission-side reference information Im1 stored in the reference information management unit 15, and the non-requirement necessary for the restoration process of the restoration error packet. The compressed packet is created again, and the created uncompressed packet is retransmitted by the packet transmission means 16 to the receiving side.
[0163]
On the receiving side, when the retransmitted uncompressed packet is received by the packet receiving means 21, it is supplied to the packet restoring means 23d via the error packet detecting means 22. Then, the packet restoration unit 23d extracts the identifier (ID) and the transmission information (D) from the retransmission uncompressed packet, and based on the extracted identifier (ID) and transmission information (D), the restoration waiting information storage unit The difference information (ΔD) of the compressed packet stored in 42 is restored. On the other hand, the extracted identifier (ID) and transmission information (D) are supplied to the reference information management means 25, and the identifier (ID) and the reference source information (D) as the receiving side reference information Im2 are updated by these information. Is done.
[0164]
As described above, in the fourth embodiment, when a decompression error of a compressed packet occurs, on the transmission side, in response to the retransmission request notification signal Nr from the reception side, Since the retransmission is performed, the reception compressed packet does not have a restoration error because the receiving side does not have the receiving side reference information (identifier (ID) and reference source information (D)) necessary for the restoration processing of the received compressed packet. Even if the packet is determined to be a packet, the restoration error packet can be correctly restored after the retransmission processing of the uncompressed packet is completed. As a result, the number of received packets discarded due to a decompression error of the compressed packet can be reduced, and the quality of the wirelessly transmitted data can be improved.
[0165]
In the fourth embodiment, the reference information management unit 15 stores the identifier (ID) and transmission information (D) included in the uncompressed packet. The compressed packet itself may be stored.
In this case, when the uncompressed packet is retransmitted, the creation process of the uncompressed packet in the packet creating unit 12d can be omitted.
[0166]
In the fourth embodiment, the uncompressed packet itself is retransmitted in response to a retransmission request from the receiving side. However, when there is a retransmission request from the receiving side, an identifier (ID) in the uncompressed packet In addition, only the portion including the transmission information (D) may be stored in a predetermined retransmission packet and retransmitted.
In this case as well, the restoration process for the received compressed packet determined to be a restoration error packet becomes possible after the retransmission packet is transmitted, and the number of received packets discarded due to the restoration error of the compressed packet is reduced and transmitted wirelessly. Data quality can be improved.
[0167]
Further, in Embodiments 1 to 4, the compressed packet stores, as compressed information, difference information (first difference information) between transmission information corresponding to the uncompressed packet and transmission information corresponding to the compressed packet. However, the compression information stored in the compressed packet is switched between the first difference information and other difference information (second difference information) according to the packet transmission status. May be.
Here, as the second difference information, the difference information defined in the V. Jacobson document described in the prior art, that is, the transmission information corresponding to the compressed packet and the packet created immediately before it are included. The difference information (refer FIG. 31) with corresponding transmission information is mentioned.
[0168]
Hereinafter, as described above, the data transmission method for switching the compression information stored in the compressed packet between the first difference information and the second difference information according to the packet transmission status is described in the first embodiment. A case where the present invention is applied to a data transmission system will be briefly described with reference to FIGS.
In this case, the error occurrence notification receiving unit 14 in the data receiving apparatus 101 is configured to calculate the reception frequency (z) of the restoration error notification signal Ne transmitted from the receiving side per unit time. The compressed / uncompressed packet creating means 12 receives a signal indicating the reception frequency (z) calculated by the error occurrence notification receiving means 14, and the reception frequency (z) exceeds a certain reference value Y. In this case, the first difference information is created as the compressed information stored in the compressed packet. On the other hand, when the reception frequency (z) is smaller than the reference value Y, the second information is used as the compressed information. The difference information is created.
[0169]
The operation in this case will be briefly described.
First, when an error occurs in the restoration process for restoring the compression information included in the compressed packet on the reception side, the reception side notifies the transmission side of the occurrence of the error. Then, on the transmission side, when the notification frequency of occurrence of an error exceeds a certain value, a process change notification is made to the reception side so as to change the restoration process on the reception side to the restoration process using the first difference information. . Thereafter, compression processing using the first difference information is performed on the transmission side. On the other hand, when the notification frequency of occurrence of an error becomes a certain value or less on the transmission side, a process change notification is sent to the reception side so that the restoration process on the reception side is changed to the restoration process using the second difference information. Thereafter, compression processing using the second difference information is performed on the transmission side. Then, on the reception side, a decompression process corresponding to the compression process on the transmission side is performed.
In this case, an identifier indicating whether the compressed information is the first or second difference information may be included in the compressed packet Pb.
[0170]
As described above, the method of switching the compressed information Id stored in the compressed packet Pb between the first difference information and the second difference information has the following effects.
That is, normally, the difference between two consecutive packets of information such as the transmission information (image information and audio information) and header information is often very small or zero, but the difference between packets that are far away is There is a tendency to grow. Therefore, by switching between the first difference information and the second difference information as the compression information, the average value of the difference information is reduced, that is, the data portion, while improving the quality of data transmitted by radio. It is also possible to improve the compression efficiency of information stored in.
[0171]
Further, in the method of using the above-described compressed information by switching between the first difference information and the second difference information, the transmission side determines which of the first and second difference information is used. However, it may be determined by a command from the reception side which of the first and second difference information is used as the compression information.
In this case, switching between the first difference information and the second difference information may be performed based on, for example, the number of transmission errors generated per unit time.
In this case, the number of occurrences of transmission errors per unit time (transmission error occurrence rate) is obtained by the error packet detection means 22 of the data receiver, and the obtained transmission error occurrence rate is transmitted by the error occurrence notification means 24. To be notified.
[0172]
Furthermore, the switching between the first difference information and the second difference information may be performed according to the frequency of occurrence of restoration errors on the receiving side.
In this case, the reception side packet restoration means 23 obtains the restoration error occurrence frequency (z) per unit time, compares the restoration error occurrence frequency (z) with a certain reference value Y, and the comparison result is The error occurrence notification means 24 notifies the transmission side, and the transmission side uses one of the first and second difference information as the compression information in accordance with the notified comparison result.
[0173]
The operation in this case will be briefly described.
On the reception side, when the error occurrence frequency at which an error in the restoration process for restoring the compression information included in the compressed packet occurs exceeds a predetermined value, the compression process on the transmission side is performed using the first difference information. A process change request is made to the transmission side to change to On the other hand, on the receiving side, when the error occurrence frequency of the restoration processing becomes a predetermined value or less, a processing change request is made to the sending side to change the compression processing on the transmitting side to the compression processing using the second difference information. Is called.
On the transmission side, compression processing is performed using difference information in response to a processing change request from the reception side, and on the reception side, restoration processing corresponding to compression processing using the difference information requested to the transmission side is performed. Is done.
[0174]
(Embodiment 5)
  18 to 27 are diagrams for explaining a data transmission method and a data transmission system using the data transmission method according to the fifth embodiment of the present invention..
  ThisThe data transmission system of Embodiment 5 is a system that transmits information from the transmission side to the reception side in packet units, and the transmission side stores uncompressed packets storing transmission information and compressed transmission information. When creating a compressed packet, the transmission information is compressed using transmission information (reference source information) corresponding to an uncompressed packet and a specific compressed packet, and the reception side compresses the transmission information that has been compressed with the reference source information. Used to restore.
[0175]
FIG. 18 is a diagram showing a data structure (format) of an uncompressed packet (FIG. (A)) and a compressed packet (FIG. (B)) used in the data transmission system of the fifth embodiment.
The uncompressed packet Pg is composed of a header part Hpg storing header information and a data part Dpg storing uncompressed information Ir transmitted by the PPP protocol. As in the header part Hpa in the uncompressed packet Pa of the first embodiment, the header part Hpg information identifies the compressed / uncompressed identifier Ih1 indicating whether or not the data part information is compressed, and the uncompressed packet. Packet identifier (ID) Ih2a and other header information Ih3. Here, the uncompressed information Ir is transmission information (D) transmitted by the uncompressed packet.
The compressed packet Ph is composed of a header portion Hph storing header information and a data portion Dph storing compressed information Id transmitted by the PPP protocol. The information of the header part Hph includes a compressed / uncompressed identifier Ih1 indicating whether or not the information of the data part is compressed, and a reference packet identifier (referred to as a reference packet necessary for the decompression process of the compressed information Id). ID) Ih2b, a reference information update flag Ih5 indicating whether or not to update the reference source information used in the restoration process, and other header information Ih3.
[0176]
Here, in the normal compressed packet Ph, the reference information update flag Ih5 is set to a value “Off” indicating that the reference source information is not updated. In the specific compressed packet Ph, the reference information update flag Ih5 is set. Is set to a value “On” indicating that the reference source information is updated. The compressed information Id includes transmission information (D) corresponding to an uncompressed packet or a specific compressed packet closest to the compressed packet transmitted before the compressed packet Pb to be transmitted, and the transmission target. The difference information (ΔD) from the transmission information (D) corresponding to the compressed packet.
Needless to say, the other header information Ih3 includes the CRC code Icrc shown in FIG. 27 (e).
[0177]
FIG. 19 is a block diagram showing a data transmission apparatus in the data transmission system of the fifth embodiment.
Similar to the data transmission apparatus 101 of the first embodiment, the data transmission apparatus 105 receives the first transmission signal S1 including the transmission information (D) and outputs the reception signal Src, and the reception signal 11 In response to Src, the transmission information (D) is packetized based on the control signal, and the compressed / uncompressed packet creating means 12e for creating the uncompressed packet Pg or the compressed packet Ph, and the packet creating means 12e Packet transmitting means 16 for transmitting the packet to the receiving side as the second transmission signal S2.
[0178]
Further, like the data transmission apparatus 101, the data transmission apparatus 105 receives an error notification reception signal 14 that receives the restoration error notification signal Ne from the reception side and outputs an error notification reception signal Sn, and the packet generation means. 12e manages the type of the packet created in 12e, determines the type of the packet to be created next based on the managed packet type information and the error notification reception signal Sn, and determines the packet judgment signal Jp And a compression / non-compression transmission judging means 13 for outputting the above as a control signal to the packet creating means 12e. Here, in the packet creation means 12e, either the uncompressed packet Pg or the compressed packet Ph is created in accordance with the packet determination signal Jp.
[0179]
The data transmitting apparatus 105 manages the transmission history of the compressed packet transmitted to the receiving side based on the compressed / uncompressed identifier Ih1 and the reference information update flag Ih5 from the packet generating unit 12e, and generates a compressed packet. There are sometimes reference information update determination means 17 for determining whether or not to update the reference source information. Here, the reference information update determination means 17 outputs a reference information update signal Jr for instructing update of reference source information to the packet creation means 12e as the control signal every time a packet is created n times (for example, 3 times). It is the composition to do. When the reference information update signal Jr is input as the control signal, the packet creating means 12e has a value “On” indicating that the reference source information is updated as the reference information update flag Ih5 in the header portion Hph of the compressed packet Ph. "Is stored, and a specific compressed packet is created. On the other hand, when the reference information update signal Jr is not input, a value “Off” indicating that the reference source information is not updated is stored in the header portion Hph of the compressed packet Ph as the reference information update flag Ih5. A compressed packet is created.
[0180]
Further, the data transmitting apparatus 105 transmits transmission information (D) referred to when creating compressed information corresponding to each compressed packet, and a reference packet identifier (ID) indicating a reference packet corresponding to the transmission information (D). ), And reference information management means 15e for managing as transmission side reference information (reference source information (D) and identifier (ID)) Im1. In the reference information management unit 15e, when a non-compressed packet is created or when a specific compressed packet including the update determination flag “On” Ih5 is created, the reference information management unit 15e uses the transmission side management control signal Cm1 from the packet creation unit 12e. The reference source information (D) and the identifier (ID) as the transmission side reference information Im1 are updated.
[0181]
FIG. 20 is a block diagram for explaining a data receiving apparatus in the data transmission system of the fifth embodiment.
Similar to the data receiving apparatus 201 of the first embodiment, the data receiving apparatus 205 receives the packet transmitted as the second transmission signal S2 from the transmitting side and outputs the received packet Rp, The received packet Rp is received, the error packet detecting means 22 for outputting the normally transmitted normal packet Pno by the error packet detecting process, and the normal packet Pno from the detecting means 22 is received and stored in each packet. Packet decompression means 23e for decompressing uncompressed information or compressed information, and output means 26 for outputting decompression information (transmission information (D)) Irs obtained by the decompression processing as an output signal S3.
[0182]
The data receiving apparatus 205 also transmits transmission information (D) that is referred to when decompressing compressed information corresponding to each compressed packet, and a reference packet identifier that identifies a reference packet corresponding to the transmission information (D). ID) is associated with the reference information management means 25e that manages the received reference information (reference source information (D) and identifier (ID)) Im2. In the reference information management unit 25e, when the decompression process for the uncompressed packet is performed, or when the decompression process for the specific compressed packet including the update determination flag “On” Ih5 is performed, reception from the packet decompression unit 23e is performed. By the side management control signal Cm2, the reference source information (D) and the identifier (ID) which are the reception side reference information Im2 are updated.
[0183]
Further, when performing the restoration process on the compressed packet Ph in the packet restoration unit 23e, the reference packet identifier (ID) stored in the compressed packet Ph and the reference source information (D) corresponding to the identifier (ID) Is stored in the reference information management unit 25e, and an error occurrence signal Se indicating that a restoration error has occurred for the compressed packet is output according to the determination result.
Further, the data receiving apparatus 205 receives an error occurrence signal Se indicating the occurrence of a restoration error from the packet restoration means 23e, and an error occurs that notifies the transmission side of the occurrence of the restoration error on the receiving side by means of the restoration error notification signal Ne. A notification transmission unit 24 is provided.
[0184]
Next, the function and effect will be described.
21 and 22 are diagrams for explaining the data transmission method according to the fifth embodiment. FIG. 21 shows the flow of a plurality of packets from the transmission side to the reception side in a normal transmission state, and FIG. 22 shows the flow of a plurality of packets from the transmission side to the reception side when a transmission error occurs. .
Here, the transmission information (D1) to (D11) is information corresponding to each packet collected so as to be transmitted in units of packets. In the fifth embodiment, the transmission information (D1) is not compressed. The transmission information (D2) to (D11) is compressed by the uncompressed packet Pg (1), and is sequentially transmitted by the compressed packets Ph (2) to Ph (11) following the uncompressed packet Pg (1). .
[0185]
On the transmitting side, first, the uncompressed packet Pg (1) is generated, and the uncompressed packet Pg (1) is transmitted to the receiving side. At this time, the transmission information (D1) is stored as uncompressed information Ir in the data portion Dpg of the uncompressed packet Pg (1), the header portion Hpg has an identifier Ih1 indicating uncompressed, and a packet identifier for identifying this packet. (ID = 0) Ih2a and other header information Ih3 are stored.
Thereafter, compressed packets Ph (2) to Ph (11) are sequentially generated and transmitted to the receiving side.
[0186]
When creating such a compressed packet, for example, the header portion Hph of the compressed packets Ph (2) to Ph (5) includes an identifier Ih1 indicating compression, a reference packet identifier (ID = 0) Ih2b, reference An information update flag Ih5 and other header information Ih3 are stored. The data portions Dph of the compressed packets Ph (2) to Ph (5) have difference information (D1-D2), difference information (D1-D3), difference information (D1-D4), and difference information (D1- D5) is stored.
However, in the fifth embodiment, the reference source information is updated every time three packets are transmitted. Therefore, in the compressed packets Ph (2) to Ph (4), the reference information update flag of the header portion Hph. The value of Ih5 is a value “Off” indicating that the reference source information is not updated. On the other hand, in the compressed packet Ph (5), the value of the reference information update flag Ih5 of the header portion Hph is the reference source information. The value is “On” indicating update. That is, after transmission of the compressed packet Ph (5), the reference packet identifier is a value (ID = 1) indicating the compressed packet Ph (5), and the reference information is transmission information (D5) corresponding to the reference packet Ph (5). ) Is updated.
[0187]
Accordingly, the header portion Hph of the four compressed packets Ph (6) to Ph (9) following the compressed packet Ph (5) includes an identifier Ih1, a reference packet identifier (ID = 1) Ih2b, and an update determination flag Ih5 indicating compression. , And other header information Ih3. The data portions Dph of the compressed packets Ph (6) to Ph (9) have difference information (D5-D6), difference information (D5-D7), difference information (D5-D8), and difference information (D5- D9) is stored.
In these compressed packets Ph (6) to Ph (8), the value of the reference information update flag Ih5 of the header portion Hph is a value “Off” indicating that the reference source information is not updated, whereas the compressed packet In Ph (9), the value of the reference information update flag Ih5 in the header portion Hph is a value “On” indicating that the reference source information is updated. That is, after transmission of the compressed packet Ph (9), the reference packet identifier is a value (ID = 2) indicating the compressed packet Ph (9), and the reference source information is transmission information (D9) corresponding to the reference packet Ph (9). ) Has been updated.
[0188]
Therefore, the header portion Hph of the compressed packets Ph (10) and Ph (11) following the compressed packet Ph (9) includes an identifier Ih1, a reference packet identifier (ID = 2) Ih2b, an update determination flag Ih5, and Other header information Ih3 is stored. Also, difference information (D9-D10) and difference information (D9-D11) are stored in the data portions Dph of the compressed packets Ph (10) and Ph (11), respectively.
In these compressed packets Ph (10) and Ph (11), the value of the reference information update flag Ih5 of the header portion Hph is a value “Off” indicating that the reference source information is not updated.
[0189]
As described above, the uncompressed packet Pg (1) sequentially transmitted from the transmission side and the subsequent compressed packets Ph (2) to Ph (11) are sequentially received at the reception side in the normal data transmission state. The transmission information (D1) to (D11) corresponding to is restored.
That is, on the receiving side, when the uncompressed packet Pg (1) is received, the transmission information (D1) that is the uncompressed information Ir is extracted from the data portion Dpg. Thereafter, when the compressed packets Ph (2) to Ph (11) are received, the difference information of the data part Dph is restored to the transmission information based on the reference source information.
Specifically, the difference information (D1-D2), (D1-D3), (D1-D4), (D1-) of the packets Ph (2), Ph (3), Ph (4), and Ph (5). D5) is restored with reference to the transmission information (D1) corresponding to the uncompressed packet Pg (1) specified by the identifier (ID = 0).
[0190]
Further, the difference information (D5-D6), (D5-D7), (D5-D8) and (D5-D9) of the packets Ph (6), Ph (7), Ph (8), and Ph (9) are The data is restored with reference to the transmission information (D5) corresponding to the compressed packet Ph (5) specified by the identifier (ID = 1).
Further, the difference information (D9-D10) and (D9-D11) between the packets Ph (10) and Ph (11) is the transmission information (D9-D11) corresponding to the compressed packet Ph (9) specified by the identifier (ID = 2). D9) is restored.
When a packet transmission is performed as described above and a transmission error occurs in the compressed packet Ph (10) as shown in FIG. 22, when the compressed packet Pb (11) is received, The differential information (D9-D11) stored in the compressed packet Pb (11) is restored in the same manner as when no transmission error has occurred in the compressed packet Pb (10).
[0191]
That is, also in the fifth embodiment, as in the first embodiment, in the restoration process of the difference information (ΔD) stored in each compressed packet Ph, the compression that is always the processing target is used as the reference source information. Rather than using the transmission information corresponding to the packet immediately before the packet, the transmission information corresponding to the uncompressed packet transmitted first or immediately after the occurrence of the restoration error, and the specific information transmitted each time a predetermined number of packets are transmitted Transmission information corresponding to the compressed packet is used.
Therefore, in the fifth embodiment, even when a transmission error of a compressed packet other than a specific compressed packet occurs, this transmission error does not affect the decompression process of the next normally received compressed packet. In this case, only the error packet is discarded on the reception side, and the restoration error is not notified from the reception side to the transmission side.
[0192]
When a transmission error of the uncompressed packet Pg (1) or a transmission error of a specific compressed packet occurs during transmission of information by packet, a notification of the occurrence of a restoration error is performed in the same procedure as shown in FIG. Is transmitted to the transmitting side. Immediately after the notification of the occurrence of the restoration error is received on the transmission side, an uncompressed packet is transmitted from the transmission side, and thereafter, a normal compressed packet and a specific compressed packet are repeatedly transmitted. At this time, the receiving side discards the error packet and the subsequent compressed packet.
[0193]
Next, the operation of the data transmission apparatus 105 when data transmission is performed as described above will be described.
For example, continuous transmission information (D1) to (D11) (see FIGS. 21 and 22) transmitted from the information providing side by a transmission method such as Ethernet is input to the data transmission device 105 as the first transmission signal S1. Then, the receiving means 11 receives these transmission information (D1) to (D11) by the above transmission method. The received transmission information is sequentially output to the compressed / uncompressed packet creation unit 12e as received information Src.
[0194]
The packet creation means 12e creates a packet for transmitting each piece of transmission information to the receiving side based on a transmission protocol such as the PPP protocol. At this time, according to the packet determination signal Jp from the compression / non-compression transmission determination unit 13 and the reference information update signal Jr from the reference information update determination unit 17, the uncompressed packet, the normal compressed packet, and the specific compressed packet One is created. The uncompressed packet Pg and the compressed packet Ph generated in this way are sequentially output to the packet transmission unit 16, and transmitted to the reception side as the second transmission signal S2 by the packet transmission unit 16.
Specifically, when communication is started, and when the error notification reception signal Sn is input from the error occurrence notification reception unit 14 to the determination unit 13, the packet determination signal Jp instructs the creation of an uncompressed packet, In other cases, creation of a compressed packet is instructed by the packet determination signal Jp.
[0195]
In addition, when the creation of a compressed packet is instructed, when the reference information update signal Jr instructs to update the transmission side reference information Im1, a specific compressed packet is created as the compressed packet, and the reference information update signal Jr is transmitted to the transmission side. When the update of the reference information Im1 is not instructed, a normal compressed packet is created as a compressed packet.
Here, the compression / non-compression determination unit 13 determines which of the uncompressed packet and the compressed packet should be created based on the compression / non-compression identifier Ih1 of each created packet and the error notification reception signal Sn. A packet determination signal Jp indicating the type of packet to be created is output. Specifically, immediately after the start of communication, a packet determination signal Jp indicating that an uncompressed packet should be generated is output. When the notification reception signal Sn is input, a packet indicating that a compressed packet should be generated A determination signal Jp is output.
[0196]
Further, the packet creation means 12e creates the uncompressed packet Pg as in the first embodiment. The compressed packet Ph is created based on the transmission side reference information Im1 (specifically, the identifier (ID) and the reference source information (D)) managed by the reference information management unit 15e. At this time, the reference information update flag Ih5 whose value is set to “Off” is stored in the header portion Hph of the normal compressed packet together with the compressed / uncompressed identifier Ih1, the reference packet identifier Ih2b, and other header information Ih3. Is done. Also, in the header portion Hph of a specific compressed packet, a reference information update flag Ih5 whose value is set to “On” is stored together with a compressed / uncompressed identifier Ih1, a reference packet identifier Ih2b, and other header information Ih3. The In the data portion Dph of these compressed packets, difference information (ΔD) based on the reference source information managed by the reference information management means 15e is stored.
[0197]
When the uncompressed packet Pg or the specific compressed packet Ph is created, the reference information management unit 15e uses the identifier that is the transmission side reference information Im1 based on the transmission side update control signal Cm1 from the packet creation unit 12e. (ID) and corresponding reference source information (D) are updated to a reference packet identifier (D) and corresponding transmission information (D) for identifying the packet Pg or Ph.
[0198]
In addition, the reference information update determination unit 17 transmits the non-compressed packet or a specific compressed packet after transmission based on the compression / non-compression identifier Ih1 of each created packet and the reference information update flag Ih5 of the compressed packet. The number of normal compressed packets is counted. When the count value reaches a predetermined value (here, 3), the reference information update signal Jr is output and the count value is reset. When the count value is less than a predetermined value (here, 3), the reference information update signal Jr is not output.
[0199]
Hereinafter, the processing in the packet creating means 12e will be described according to the flow shown in FIG.
In the packet creation means 12e, when the transmission information received by the reception means 11 is input (step Sc1), the determination means 13 is inquired as to which of the uncompressed packet and the compressed packet should be created (step Sc1). Sc2), the type of the packet to be created is determined based on the packet determination signal Jp from the determination means 13 (step Sc3).
As a result, when an uncompressed packet is to be created, an identifier (ID) for identifying the uncompressed packet is assigned as a packet identifier Ih2a, and an uncompressed packet Pg including the packet identifier (ID) is created. (Step Sc11). Thereafter, the identifier (ID) and the corresponding reference source information (D) managed as the transmission-side reference information Im1 by the reference information management unit 15e according to the instruction (transmission-side management control signal Cm1) from the packet creation unit 12e. It is updated (step Sc12).
[0200]
On the other hand, when a compressed packet is to be created, an identifier (ID) and reference source information (as reference information Im1 managed by the management unit 15 as transmission side reference information Im1) are sent from the packet creation unit 12e to the reference information management unit 15. D) is queried (step Sc4). Then, the data portion Dph of the compressed packet is created based on the identifier (ID) and the reference source information (D) obtained by the inquiry (step Sc5).
Thereafter, in the packet creation means 12e, the determination means 17 is inquired whether or not the transmission side reference information Im1 is to be updated (step Sc6), and the transmission side reference information is based on the reference information update signal Jr from the determination means 17. It is determined whether or not Im1 is updated (step Sc7).
As a result, when the transmission side reference information Im1 is to be updated, the identifier (ID) and the reference source information (D) managed by the reference information management unit 15e are updated by an instruction from the packet creation unit 12e. (Step Sc8), a specific compressed packet Ph is created (Step Sc9).
[0201]
On the other hand, when the transmission side reference information Im1 should not be updated, a normal compressed packet is created (step Sc10).
Then, each of the packets is sent to the transmission means 16 (step Sc13).
Thereafter, the processing of the packet creation means 12e returns to step Sc2. Such processing is performed until the last packet is transmitted.
[0202]
Next, the operation of the data receiving apparatus 205 when packets are sequentially transmitted as shown in FIGS. 21 and 22 will be described.
In the packet receiving means 21, the packets Pg (1), Ph (2) to Ph (11) transmitted from the transmitting side are received in order and output to the error packet detecting means 22. When the error packet detection means 22 confirms that the received packet has been transmitted correctly, the received packet is output to the packet restoration means 23e as a normal packet Pno. If it is not confirmed that the received packet has been transmitted correctly, the received packet is discarded as an error packet. Here, CRC (Cyclic Redundancy Check), which is generally widely used as an error detection method, is used, but the error detection method is not limited to this.
[0203]
In the packet restoration means 23e, the normal received packet Pno is either a compressed packet or an uncompressed packet by the compressed / uncompressed identifier Ih1 included in the header part of the received normal packet (hereinafter also referred to as a normal received packet) Pno. It is determined whether there is any.
For example, when the normal received packet Pno input to the decompression means 23e is an uncompressed packet Pg (1), the decompression means 23e obtains transmission information (D1) from the data portion Dpg of the uncompressed packet Pg (1). The restoration process to be taken out is performed.
[0204]
Next, in the management unit 25e, the identifier (ID) and the reference source information (D) accumulated as the reception side reference information Im2 are updated by the reception side management control signal Cm2 from the restoration unit 23e. Thereby, the identifier (ID) and the reference source information (D) recorded in the management means 25e as the receiving side reference information Im2 are changed to the identifier (ID = 0) and the transmission information (D1), respectively. Thereafter, the restoration means 23e outputs the transmission information (D1), which is the restored information, to the output means 26, and the transmission means (D1) is output from the output means 26.
[0205]
On the other hand, when the packet input to the decompression unit 23e is, for example, a specific compressed packet Ph (5), the reference packet identifier (ID = 0) included in the compressed packet and the reference information management unit 25e An inquiry is made as to whether reference source information (D1) corresponding to this is stored. When the reference packet identifier (ID = 0) and the corresponding reference source information (D1) are stored in the management unit 25e, the reference unit information (D1) and the difference information (D1-D5) are stored in the recovery unit 23e. Is used to restore the transmission information (D5) corresponding to this packet.
At this time, if either one of the reference packet identifier (ID = 0) and the corresponding reference source information (D1) is not stored in the management unit 25e, the received compressed packet is discarded as an error packet, An error occurrence signal Se indicating that a restoration error has occurred is output to the error occurrence notification means 24. Then, the notification means 24 transmits a restoration error notification signal Ne to the transmission side.
[0206]
Further, in the restoration means 23e, when the reference information update flag Ih5 of the header portion Hph is checked, and this indicates that the reception side reference information Im2 is to be updated, the reception side update control signal Cm2 is sent to the reference information management means 25e. Is output. In the management means 25e, the stored identifier (ID) and the corresponding reference source information (D) are updated with new information, for example, the reference packet identifier (ID = 1) and the reference source information by the receiving side update control signal Cm2. Updated to (D5). Thereafter, the transmission information (D5) restored by the restoration means 23e is outputted to the output means 26, and the transmission information (D5) is outputted by the output means 26 as the reception signal S3.
When the packet input to the restoration unit 23e is a normal compressed packet, the restoration unit 23e and the reference information management unit 25e are the same as those in the first embodiment except for the check processing of the reference information update flag Ih5. Processing is performed.
[0207]
Hereinafter, the processing in the packet restoration means 23e will be described according to the flow shown in FIG.
In the packet restoration unit 23e, when the normal reception packet Pno is input from the error packet detection unit 22 (step Sd1), it is determined whether the normal reception packet is an uncompressed packet or a compressed packet (step Sd2). .
If the normal received packet is an uncompressed packet, the transmission information (D) is extracted from the data portion Dpg of the uncompressed packet Pg by the restoration process for the uncompressed packet (step Sd12). Then, in response to an instruction from the packet restoration unit 23e, the identifier (ID) and the reference source information (D) which are the reception side reference information Im2 in the reference information management unit 25e are updated to the packet identifier and transmission information of the uncompressed packet ( Step Sd13). The transmission information extracted from the data portion of the uncompressed packet is sent to the output means 26 (step Sd9).
[0208]
When the normal received packet is a compressed packet, the packet restoration means 23e sends the reference information management means 25e the reference packet identifier (ID) Ih2b stored in the compressed packet and the reference source information (D) corresponding to the identifier Ih2b. ) Is recorded (step Sd3), and it is determined whether these are stored in the reference information management means 25e (step Sd4).
[0209]
If the reference packet identifier (ID) Ih2b and the corresponding reference source information (D) are not stored in the reference information management means 25e, the normal reception packet is discarded as an error packet (step Sd10), and an error occurrence signal Se is output to the error occurrence notification transmitting means 24 (step Sd11). Thereafter, the process by the packet restoration means 23e returns to the process of step Sd2.
On the other hand, when the reference packet identifier (ID) Ih2b and the corresponding reference source information (D) are stored in the reference information management means 25e, the difference information of the compressed packet is transmitted to the transmission information based on the reference source information. Restored (step Sd5).
[0210]
Next, it is determined whether or not the reference information update flag Ih5 stored in the compressed packet indicates that the reference information is updated (step Sd6), and if the reference information is updated, The identifier (ID) and the reference source information (D) stored as the receiving side reference information Im2 in the reference information management unit 25e are updated to new information (step Sd8). Thereafter, the transmission information is output to the output means 26 (step Sd9). If the result of determination in step Sd6 does not indicate that the reference information is to be updated, the transmission information is output to the output means 26 without updating the receiving side reference information Im2 (step Sd9 )
Thereafter, the processing of the packet restoring means 23e returns to step Sd2. Such processing is performed until the last packet is received.
[0211]
As described above, in the data transmission method according to the fifth embodiment, when transmission information is transmitted in packet units using uncompressed packets stored without compressing transmission information and compressed packets stored with compressed transmission information. Since the transmission information corresponding to the compressed packet is compressed using the previously transmitted uncompressed packet or the transmission information corresponding to the specific compressed packet as reference source information, the uncompressed packet and the specific compressed packet are compressed. Even if a compressed packet transmission error occurs, the difference information of the normally transmitted compressed packet after the error packet is the transmission information corresponding to the uncompressed packet or a specific compressed packet. Can be restored. For this reason, the number of compressed packets discarded due to the occurrence of a compressed packet transmission error is greatly reduced. As a result, it is possible to improve the quality of data transmitted through the wireless section. In other words, the effective speed of data transmission can be improved, and the time and cost of packet transmission that cannot be restored can be greatly reduced.
[0212]
In the fifth embodiment, the transmission side is configured to transmit one specific compressed packet every time a predetermined number (three) of compressed packets are transmitted, in other words, at the timing of updating the transmission side and reception side reference information. The specific compressed packet may be transmitted every time a predetermined time (n seconds) elapses, or the difference information stored in the compressed packet has a constant threshold value. You may make it perform when exceeding.
[0213]
The specific compressed packet is transmitted when a request for updating reference source information is received from the receiving side, or when the size of the difference information or the average value of the difference information exceeds a certain threshold. It may be.
For example, on the transmission side, when the reception side requests transmission of the specific compressed packet, the specific compression packet is transmitted to the reception side.
On the transmitting side, the specific compressed packet is transmitted when the size of the compressed information included in the compressed packet transmitted to the receiving side exceeds a certain value.
Further, in the transmission side processing, when the average value of the size of the compression information included in the compressed packet transmitted to the receiving side exceeds a certain value, the specific compressed packet is transmitted.
Still further, the timing determination method for updating the transmission side and reception side reference information may be a combination of the above methods.
[0214]
By determining the timing for updating the transmission side and reception side reference information as described above, the following effects can be obtained.
Usually, the difference between the two connected packets of the image information, the audio information, and the header information is very small or often zero, but the difference between the distant packets tends to be large. For this reason, by periodically transmitting uncompressed packets, it is expected to improve the quality of data transmitted wirelessly, while reducing the average value of difference information, that is, improving the compression efficiency of the data part. it can.
[0215]
(Modification of Embodiment 5)
Furthermore, in the fifth embodiment, the compression information stored in the data portion Dph of the compressed packet Ph includes the entire transmission information corresponding to the compressed packet and the uncompressed packet as shown in FIGS. Although the difference information (ΔD) with respect to the entire corresponding transmission information is used, the compression information stored in the data portion Dph of the compressed packet Ph may be obtained by compressing only a part of the transmission information corresponding to the compressed packet. .
That is, the transmission information is divided into compression target information corresponding to a plurality of items to be compressed and non-compression target information not to be compressed, and the data portion Dph of the compressed packet Ph contains uncompressed packets. The difference information between the compression target information in the corresponding transmission information and the compression target information in the transmission information corresponding to the compressed packet is stored as item-specific compression information, and the non-compression target information in the transmission information corresponding to the compressed packet is stored. .
[0216]
FIG. 25A shows the data structure of an uncompressed packet used when transmission information is composed of compression target information and compression non-target information.
The uncompressed packet Pi is composed of a header part Hpi that stores header information and a data part Dpi that stores transmission information (D) transmitted by the PPP protocol as uncompressed information Ir. As with the uncompressed packet Pg shown in FIG. 18A, the header part Hpi includes a compressed / uncompressed identifier Ih1 indicating whether or not the information in the data part is compressed, and a packet identifier for identifying the uncompressed packet. (ID) Ih2a and other header information Ih3. Here, the uncompressed information Ir is composed of item-by-item compression target information Ira, Irb, Irc, Ird corresponding to four items to be compressed, and non-compression target information Inc that is not to be compressed. Yes. Here, item-specific transmission information (Da), (Db), (Dc), (Dd) is stored as the item-specific compression target information (item-specific uncompressed information) Ira, Irb, Irc, Ird.
[0217]
FIG. 25B shows the data structure of the compressed packet Pj used when the transmission information is composed of compression target information and non-compression target information.
The compressed packet Pj is composed of a header part Hpj storing header information and a data part Dpj storing partly compressed information (ΔD) transmitted by the PPP protocol. The header portion Hpj stores a compressed / uncompressed identifier Ih1, a reference packet identifier (ID) Ih2b, a reference information update flag Ih5, a difference information presence / absence flag Ih6, and other header information Ih3. Here, the difference information presence / absence flag Ih6 is a flag indicating whether or not compressed item-by-item compression target information includes a non-zero value.
[0218]
Here, the data portion Dpj includes item-specific compression information Ida, Idb, Idc, Idd corresponding to the four compression target items, and uncompressed non-compression target information Inc. The compressed information Ida is a difference between item-specific transmission information (Da) in transmission information corresponding to an uncompressed packet and item-specific transmission information (Da) in transmission information corresponding to a compressed packet (item-specific difference information (ΔDa)). ). The compressed information Idb is a difference between item-specific transmission information (Db) in transmission information corresponding to an uncompressed packet and item-specific transmission information (Db) in transmission information corresponding to a compressed packet (item-specific difference information (ΔDb)). ). The compressed information Idc is a difference between item-specific transmission information (Dc) in transmission information corresponding to an uncompressed packet and item-specific transmission information (Dc) in transmission information corresponding to a compressed packet (item-specific difference information (ΔDc)). ). The compressed information Idd is a difference between item-specific transmission information (Dd) in transmission information corresponding to an uncompressed packet and item-specific transmission information (Dd) in transmission information corresponding to a compressed packet (item-specific difference information (ΔDd)). ).
[0219]
In this case, the reference information management unit 15e in the data transmission device 105 includes a reference packet identifier (ID), information indicating each compression target item to be compressed, and reference source compression (item) corresponding to each compression target item. The other reference source information) is tabulated and stored as transmission side reference information Im1.
Similarly to the reference information management unit 15e, the reference information management unit 25e in the data receiving apparatus 205 also includes a reference packet identifier (ID), information indicating each compression target item to be compressed, and each compression target item. The reference source compression (item-specific reference source information) corresponding to the table is stored as the receiving side reference information Im2.
[0220]
FIG. 25 (c) specifically shows processing for compressing the transmission information D (Y) to create a compressed packet Pj (Y).
In this case, the reference information management means 15e sends the reference packet identifier (ID = X) and item-specific reference source information (Da (X)), (Db (X)), (Dc () as the transmission side reference information Im1. X)) and (Dd (X)) are stored.
[0221]
Further, each item-specific difference information (ΔDa), (ΔDb), (ΔDc), (ΔDd) is referred to for each item as transmission side reference information Im1, as shown in the following (Expression 1) to (Expression 4). The corresponding item-specific transmission information (Da (X)) in the original information (Da (X)), (Db (X)), (Dc (X)), (Dd (X)) and transmission information (D (Y)). Y)), (Db (Y)), (Dc (Y)), and (Dd (Y)).
ΔDa = Da (X) −Da (Y) = 0 (Formula 1)
ΔDb = Db (X) −Db (Y) ≠ 0 (Expression 2)
ΔDc = Dc (X) −Dc (Y) ≠ 0 (Expression 3)
ΔDd = Dd (X) −Dd (Y) = 0 (Expression 4)
[0222]
Thus, the value of item-specific difference information (ΔDa) and (ΔDd) is 0, but the value of item-specific difference information (ΔDb) and (ΔDc) is not 0, so the header portion of the compressed packet Pj (Y) The Hj difference information presence / absence flag Ih6 is set with a value “On” indicating that there is a plurality of item-specific difference information whose value is not 0, and the data of the compressed packet Pj (Y) The part Dj stores only item-specific difference information (ΔDb) and (ΔDc).
[0223]
FIG. 26 is an enlarged view showing a part of the compressed packet Pj (Y).
Each item-specific difference information includes a subsequent difference information presence flag and a reference source information type flag as information (format) common to these items. Here, the value of the subsequent difference information presence / absence flag Ico1 in the compressed information (item-specific difference information (ΔDb)) Idb is stored in the data portion Dpj after the item-specific difference information (ΔDb). The reference source information type flag Ico2 in the compression information Idb should refer to the item-specific transmission information (Db) when restoring the item-specific difference information Idb. Is shown. Further, the value of the subsequent difference information presence / absence flag Ico1 in the compression information (item-specific difference information (ΔDd)) Idc is a value “Off” indicating that there is no compression information following the item-specific difference information (ΔDd) in the data portion Dpj. The reference source information type flag Ico2 in the compression information Idc indicates that the item-specific transmission information (Dc) should be referred to when the compression information is restored.
[0224]
In this way, by including the subsequent difference information presence / absence flag Ico1 and the reference source information type flag Ico2 in each item-specific difference information, only the item-specific difference information whose information amount is not 0 is included in the data portion of the compressed packet. Can be included as an element.
As a result, the transmission information can be compressed for each component (information corresponding to each compression target item) in the transmission information, and the reference information management means 15e on the transmission side is maintained while maintaining a certain compression effect. In addition, it is possible to reduce a storage area including a RAM or the like in the reference information management unit 25e on the receiving side.
[0225]
Further, the item-specific difference information Idc includes the difference information length data Iun1 and the compression method type flag Inu2 as unique information (format) separately from the common information (subsequent difference information presence flag and reference source information type flag). I have it.
Here, the difference information length data Iun1 indicates the data size of the item-specific difference information Idc, and the compression method type flag Inu2 includes a plurality of restoration methods for restoring the item-specific difference information Idc. It is specified from among.
By including the difference information length data Iun1 in the item-specific difference information (ΔDc) as described above, when the item-specific difference information (ΔDc) is small, the size can be reduced, and the compression efficiency is further increased. Can do.
[0226]
The compression method type flag Iun2 is made up of, for example, 2-bit information, and the compression efficiency can be further improved by predefining a compression method corresponding to the value.
For example, when the value of the compression method type flag Iun2 is “00”, the item-specific difference information is the difference (ΔDn) with respect to the reference source information, and when the value is “01”, the item-specific difference information is ( ΔDn / 2), if the value is “10”, the item-specific difference information is (ΔDn / 8), and if the value is “11”, the item-specific difference information is (ΔDn / 64). To do.
[0227]
FIG. 27 is a diagram for explaining specific information stored in the uncompressed packet Pi and the compressed packet Pj. FIG. 27A shows data (transmission information) to be transmitted by the packet. FIG. 27 (b) shows transmission information in an uncompressed packet and difference information in a compressed packet. Here, a case where RTP data (only a part is described) is transmitted is taken as an example.
[0228]
The transmission information is the IP packet (RTP / UDP / IP data) Pipb shown in FIG. 29 (d), and the transmission information includes information corresponding to the first to fourth compression target items K1 to K4. It is. Information corresponding to the first and second compression target items K1 and K2 (compression target information Ira and Irb shown in FIG. 25A) is a sequence number (SN) and a time stamp (ST) of the RTP packet, respectively. The information corresponding to the third compression target item K3 (compression target information Irc shown in FIG. 25A) is the identifier (ID) of the IP packet, and the information corresponding to the fourth compression target item K4 (FIG. 25A ) Is a UDP port number (Port No.). The specific information corresponding to each compression target item in each of the transmission information (D1) to (D5) is No. in the table of FIG. 1-No. As shown in column 5.
[0229]
When actually transmitting RTP / UDP / IP data as transmission information (D1) to (D5), the transmission information is stored in a PPP packet (uncompressed packet and compressed packet) by the PPP protocol, and the data transmitting apparatus 105 to the data receiving device 205.
At this time, the compression target information Ira, Irb, Irc, Ird in the transmission information (D1) is stored as it is without being compressed in the data portion Dpi of the uncompressed packet Pi (1). The header portion Hpi stores 1-bit compressed / uncompressed identifiers Ih1, 5-bit packet identifiers (ID) Ih2a, Ih2b and other header information Ih3 (not shown in FIG. 27 (b)). .
[0230]
Further, in the data portion Dpj of the compressed packets Pj (2) and Pj (3), item-by-item compression target information (item-by-item uncompressed information) corresponding to each compression target item in the transmission information (D2) and (D3). Ira, Irb, Irc, and Ird are compressed, and item-specific compression information Ida, Idb, Idc, and Idd are stored. Here, the item-specific compressed information Ida corresponding to the sequence numbers (SN) in the compressed packets Pj (2) and Pj (3) are 8-bit difference information “1” and “2”, respectively. The item-specific compression information Idb corresponding to the time stamp (ST) in the compressed packets Pj (2) and Pj (3) is 16-bit difference information “50” and “100”, respectively. The item-specific compressed information Idc corresponding to the identifier (ID) of the IP packet in the compressed packets Pj (2) and Pj (3) is 8-bit difference information “1” and “2”, respectively. The item-specific compression information Idd corresponding to the UDP port number (Port No.) in the compressed packets Pj (2) and Pj (3) is 0 bit.
[0231]
The header portions Hpj of the compressed packets Pj (2) and Pj (3) include a 1-bit compressed / uncompressed identifier Ih1, a 5-bit reference packet identifier (identification ID) Ih2b, and a 1-bit reference information update flag Ih5. A 1-bit difference information presence / absence flag Ih6 and other header information Ih3 (not shown in FIG. 27B) are stored.
[0232]
In FIG. 26 and FIG. 27, as the data structure of the packet, the reference information type flag Ico2, the difference information length data Iun1, and the compression method type flag Iun2 are shown as being included in the difference information (ΔDn). However, these are generated when the reference source information is updated, that is, when an uncompressed packet Pi is created or a specific compressed packet (a compressed packet whose reference information update flag Ih5 has a value of “On”) Pj. When it is done, it may be added to the header part Hpi, Hpj or the data part Dpi, Dpj.
[0233]
In this case, by configuring the reference information management unit 15e on the transmission side and the reference information management unit 25e on the reception side to manage the difference information length data Iun1 and the compression method type flag Iun2 for each item reference source information, On the reception side, it is possible to perform a decompression process on the compressed packet based on the data Iun1 and the flag Iun2.
[0234]
Thereby, it is not necessary to include the difference information length data Iun1 and the compression method type flag Iun2 every time the compressed packet is transmitted in the item-specific difference information (ΔDn) in the compressed packet, and the compression efficiency can be further improved.
[0235]
When the item-specific reference source information as described above is updated, the reference information type flag Ico2, the difference information length data Iun1, and the compression method type flag Iun2 are added to the header part or data part of the uncompressed packet or specific compressed packet. Although there are a plurality of compression methods for transmission information and there are a plurality of compression methods, this method is particularly effective when the compression method changes at regular intervals, and the effect of increasing the compression efficiency is further increased. I can expect that.
[0236]
In the fifth embodiment, the method of using an uncompressed packet, a specific compressed packet, and a normal compressed packet is shown as a data transmission process for transmitting information for each transmission information corresponding to a packet unit. In the transmission process, the data transmission method described in the fifth embodiment and other data transmission methods may be switched according to the packet transmission status.
Here, as the other data transmission method, the data transmission method of the first to fourth embodiments or the data transmission method using the conventional V. Jacobson header compression method (see FIG. 31) can be used.
[0237]
【The invention's effect】
  As aboveBookDepartureClearlyAccording to such a data transmission method, when transmitting information in units of packets, the transmitting side continuously transmits a compressed packet including compressed transmission information following an uncompressed packet including uncompressed transmission information. The compression information to be stored in the compressed packet to be transmitted is created based on the transmission information corresponding to the reference packet that is the uncompressed packet and the transmission information corresponding to the target packet as the transmission target, On the receiving side, the transmission information corresponding to the compressed packet is restored based on the compression information included in the compressed packet and the transmission information corresponding to the reference packet, so that a transmission error of the compressed packet occurs in the wireless section. Even on the receiving side, the subsequent compressed packet can be restored based on the transmission information corresponding to the uncompressed packet as the reference packet.As a result, the number of packets discarded on the receiving side due to the occurrence of an error in the radio section can be reduced, thereby improving the quality of transmission data in the transmission path including the radio section.
[0238]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, the transmitting side transmits a packet including a reference packet identifier indicating the uncompressed packet as the reference packet together with the compressed information as each compressed packet following the uncompressed packet. It is possible to specify a reference packet necessary for the restoration process for the packet by the reference packet identifier.
  Further, since the difference information between the transmission information corresponding to the reference packet and the transmission information corresponding to the compressed packet is created as the compressed information, the compressed information included in the compressed packet is created by a simple arithmetic process. Can do.
[0239]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, additional information for calculating the difference information based on transmission information corresponding to the reference packet is stored in the compressed packet on the transmitting side, and a difference in the compressed packet is stored on the receiving side. Since the information is calculated from the transmission information corresponding to the reference packet based on the additional information, the information amount of the difference information can be reduced, the data compression efficiency can be improved, and the data transmission efficiency is also improved. Can be made.
[0240]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, as the additional information, a sequence number that can identify the number of packets sent after sending the uncompressed packet as the reference packet is used as the additional information. For transmission information that increases by a certain amount, the difference information can be 0 bits.
[0241]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, as the additional information, since a variable of a calculation formula for calculating the difference information in the compressed packet from the transmission information corresponding to the reference packet is used, transmission information that varies according to a certain function each time a packet is transmitted For, difference information can be greatly reduced.
[0242]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, on the transmission side, a plurality of uncompressed packets created to be transmitted before the compressed packet are used as reference packets, and the compressed packet includes transmission information corresponding to each reference packet. Associating difference information with transmission information corresponding to the compressed packet and reference packet identifiers corresponding to the reference packets, storing a plurality of sets of corresponding difference information and reference packet identifiers as the compressed information, In the reception-side processing, the transmission information corresponding to the compressed packet is restored using the difference information and the packet identifier of any pair in the compressed packet, so that the uncompressed packet including the information necessary for restoring the compressed packet is processed. The reliability of the transmission process can be improved, which can greatly improve the quality of data transmitted wirelessly. Can.
[0243]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, since the non-compressed packet is transmitted at a constant period in the transmission side processing, the data size of the compressed packet is prevented from becoming extremely large, and the compression efficiency of transmission information is within a substantially constant fluctuation range. Can fit in. As a result, not only the quality of the wirelessly transmitted data but also the data transmission efficiency can be improved.
[0244]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, the transmitting side transmits the uncompressed packet when the size of the compressed information included in the compressed packet to be transmitted to the receiving side exceeds a certain value, so that the data size of the compressed packet is kept small. Therefore, it is possible to increase the compression efficiency of transmission information, and it is possible to improve not only the quality of wireless transmission data but also the data transmission efficiency.
[0245]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, when the size of the compressed information included in the compressed packet from the transmission side exceeds a certain value, the reception side requests the transmission side to transmit an uncompressed packet. Since the uncompressed packet is transmitted to the receiving side in response to the transmission request of the uncompressed packet, it is possible to suppress the data size of the compressed packet and increase the compression efficiency of the transmission information, and not only the quality of the wireless transmission data Data transmission efficiency can also be improved.
[0246]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, the transmission side transmits uncompressed packets storing the same transmission information to the reception side several times in succession, so that the reliability of transmission processing for the uncompressed packets necessary for decompression of the compressed packets is increased. Thus, the quality of data transmitted by radio can be greatly improved.
[0247]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, when the receiving side detects a restoration error of the compressed information stored in the compressed packet, the receiving side notifies the sending side that a restoration error has occurred, and the sending side sends a restoration error from the receiving side. Since the number of times the non-compressed packet is continuously sent to the receiving side is changed based on the frequency of notification indicating the occurrence of the occurrence of the non-compressed packet, the continuous transmission of the uncompressed packet can be performed efficiently.
[0248]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, the transmitting side transmits the auxiliary transmission packet including the packet identifier and transmission information stored in the uncompressed packet to the receiving side a predetermined number of times after transmitting the uncompressed packet. The reliability of transmission processing for necessary information can be improved, and thereby the quality of data transmitted by radio can be greatly improved.
[0249]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, the transmitting side adds the error correction code to the uncompressed packet and transmits it to the receiving side, and the receiving side processing adds the error to the uncompressed packet. Since error correction processing is performed using correction codes, the reliability of transmission processing for uncompressed packets containing information necessary for decompression of compressed packets can be greatly improved, thereby greatly improving the quality of wirelessly transmitted data. be able to.
[0250]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, on the transmitting side, an error correction code is assigned to the packet identifier and transmission information in the uncompressed packet, and on the receiving side, the packet identifier and transmission information included in the uncompressed packet are Since error correction processing is performed using the error correction code assigned to them, the reliability of transmission processing for information necessary for decompression of compressed packets can be greatly improved, thereby increasing the quality of data transmitted wirelessly. Can be improved.
[0251]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, when the receiving side detects a restoration error of the compressed information stored in the compressed packet, the receiving side notifies the sending side that a restoration error has occurred, and the sending side sends a restoration error from the receiving side. One of a process for transmitting the uncompressed packet without adding an error correction code thereto, and a process for transmitting the uncompressed packet without adding an error correction code to the uncompressed packet according to the frequency of notification indicating the occurrence of Therefore, it is possible to effectively perform the process of giving an error correction code to the uncompressed packet and the error correction process for the uncompressed packet.
[0252]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, only the uncompressed packet is held in the retransmission buffer as retransmission data on the transmission side, and the uncompressed packet corresponding to the error packet is retransmitted in response to a retransmission request for the error packet from the reception side. Only when it is held in the buffer, the uncompressed packet corresponding to the error packet is retransmitted to the receiving side, so that the reliability of transmission processing for information necessary for decompression of the compressed packet is greatly improved, and the uncompressed packet Thus, the quality of data transmitted wirelessly and the data transmission efficiency can be greatly improved.
[0253]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, on the transmitting side, the packet identifier and transmission information stored in the uncompressed packet are held in the retransmission buffer as retransmission data, and the packet identifier stored in the error packet from the receiving side and In response to a retransmission request for transmission information, only when the packet identifier and transmission information in the uncompressed packet corresponding to the error packet are held in the retransmission buffer, the packet identifier and transmission information are retransmitted to the receiving side. The reliability of transmission processing for information necessary for decompression of compressed packets can be greatly improved, non-compressed packets can be retransmitted efficiently, and the data recording capacity in the retransmission buffer can be reduced.
[0254]
  BookDepartureClearlyAccording to the data transmission method, the transmitting side continuously transmits the compressed packet including the compressed transmission information following the non-compressed packet including the uncompressed transmission information. The compressed information to be stored is created based on the transmission information corresponding to the reference packet that is the uncompressed packet and the transmission information corresponding to the target packet as the transmission target, and the reception side supports the compressed packet. First data transmission processing for restoring the transmission information to be performed based on the compression information included in the compressed packet and the transmission information corresponding to the reference packet, and the compressed information stored in the compressed packet on the transmission side, The compression information is created by a method different from the compression information creation method in the first data transmission process, and the compressed information stored in the compressed packet is received on the receiving side. A second data transmission process that restores by a method different from the decompression method of the compressed information in the first data transmission process, and the first and second data transmission processes are restored to the compressed packet on the receiving side. Since switching is performed according to the processing error occurrence status, the quality of wireless transmission data can be improved when the error occurrence frequency is high, and the compression efficiency of transmission information can be improved when the error occurrence frequency is low. it can.
[0255]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, as the second data transmission process, on the transmission side, the compressed information stored in the compressed packet to be transmitted is changed to transmission information corresponding to the previous packet transmitted immediately before the compressed packet. And based on the transmission information corresponding to the compressed packet as the transmission target, and on the receiving side, the compressed information included in the compressed packet to be restored is restored using the transmission information corresponding to the previous packet. Since data transmission processing is performed, when the frequency of error occurrence is low, the compression efficiency of transmission information can be greatly improved.
[0256]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, when the notification frequency of error occurrence from the reception side exceeds a certain value on the transmission side, the first data transmission process is performed, and the notification frequency of the error occurrence becomes a certain value or less. In this case, since the compression process in the second data transmission process is performed, the transmission method with high quality of wireless transmission data when the error occurrence frequency is high and the compression efficiency of transmission information when the error occurrence frequency is low are high. The transmission method can be switched adaptively.
[0257]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, when the occurrence frequency of the restoration process error for the compressed packet exceeds a predetermined value on the receiving side, the first data transmission process is performed, and the error occurrence frequency of the restoration process is less than or equal to a predetermined value. Since the second data transmission process is performed, the transmission method with high quality of wireless transmission data when the error occurrence frequency is high, and the transmission method with high compression efficiency of transmission information when the error occurrence frequency is low, Can be switched adaptively.
[0258]
  BookDepartureClearlyAccording to such a data transmission method, when transmitting information in units of packets, on the transmission side, the compressed information to be stored in the compressed packet to be transmitted is updated related to the packet transmitted before the compressed packet. Created based on the information and transmission information corresponding to the compressed packet as the transmission target. At this time, information related to the uncompressed packet is set as an initial value of the update information, and then a specific compressed packet is set. The update information is updated to information related to the specific compressed packet, and on the receiving side, the transmission information corresponding to the compressed packet to be restored is received before the compressed packet. In this case, the information related to the uncompressed packet is set as the initial value of the update information, and then the specific compression is performed. Each time the transmission information corresponding to the packet is restored, the update information is updated to information related to the specific compressed packet, so that the quality of transmission data in the radio section is improved and the effective speed of data transmission is improved. At the same time, the data compression efficiency can be increased, and as a result, the time and cost of packet transmission that cannot be restored can be greatly reduced. Furthermore, since the reference information necessary for the decompression process is updated in the compressed packet by transmitting a specific compressed packet, it is possible to increase the compression efficiency of the transmission information while keeping the data transmission efficiency high.
[0259]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, the compressed packet stores a reference packet identifier indicating the uncompressed packet or a specific compressed packet as a reference packet, and an information update flag indicating whether or not the update information should be updated. The receiving side can easily determine whether or not the update information should be updated by the information update flag.
[0260]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, since the specific compressed packet is sent to the receiving side every time a certain period of time elapses in the data transmission method, an increase in the amount of difference information in the compressed packet is suppressed, and transmission data in the wireless section is suppressed. The quality of data can be improved to increase the effective speed of data transmission, and the data compression efficiency can be further increased.
[0261]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, since the specific compressed packet is sent to the receiving side each time a certain number of compressed packets are transmitted, the increase in the amount of difference information in the compressed packet is suppressed in the data transmission method. The quality of transmission data in the section can be improved to improve the effective speed of data transmission, and the data compression efficiency can be further increased.
[0262]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, in the transmission side process, when the transmission of the specific compressed packet is requested from the reception side, the specific compression packet is transmitted to the reception side. It is possible to improve the effective speed of data transmission and further increase the data compression efficiency.
[0263]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, since the specific processing packet is transmitted when the size of the compression information included in the compressed packet to be transmitted to the reception side exceeds a certain value in the transmission side processing, the amount of difference information in the compressed packet is transmitted. Can be suppressed.
[0264]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, in the transmission side processing, when the average value of the size of the compression information included in the compressed packet transmitted to the reception side exceeds a certain value, the specific compressed packet is transmitted. While suppressing the increase in the amount of difference information, it is possible to stably control the difference information. In this case as well, it goes without saying that the time and cost of packet transmission that cannot be restored can be further greatly reduced.
[0265]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, the transmission information includes item-specific transmission information corresponding to a plurality of items, and the compression information includes item-specific compression information corresponding to a plurality of items, in the compression information included in the compressed packet. The item-specific compressed information corresponding to each item corresponds to the item-specific compressed information corresponding to each item in the transmission information corresponding to the compressed packet, and the item in the transmission information corresponding to the non-compressed packet or the specific compressed packet. Information that is obtained by compressing using the item-specific transmission information, and since each item-specific compression information includes an item type flag that identifies the corresponding item, the compression processing for the transmission information is performed for each item. It is possible to achieve the optimal compression effect for each item and reduce the storage area consisting of RAM etc. that stores update information etc. Rukoto can. As a result, not only can the time and cost for packet transmission that cannot be restored be reduced, but also the cost for manufacturing the transmission terminal device and the reception terminal device can be reduced.
[0266]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, since the item-specific compression information includes data length information indicating the data length, the restoration process for the item-specific compression information can be efficiently performed.
[0267]
  BookDepartureClearlyAccording tothe aboveIn the data transmission method, since each item-specific compression information includes restoration method specifying information indicating a restoration method corresponding to the compression method for restoring the item-specific compression information, various compression processes are performed. It is possible to efficiently perform the decompression process for a plurality of item-specific compressed information.
[0268]
  BookDepartureClearlyAccording to the data transmitting apparatus, the received transmission information is received, and at least a part of the uncompressed packet in which the predetermined transmission information is stored as uncompressed information and the transmission information following the predetermined transmission information are compressed. A packet creating means for creating a compressed packet stored as compressed information, and a reference information managing means for accumulating and managing information related to the uncompressed packet created by the packet creating means as reference information Provided with the packet creation means, compression information to be stored in the compressed packet to be created by the means, transmission information corresponding to the compressed packet, and reference information stored in the reference information management means, Therefore, even if a transmission error occurs in the compressed packet in the wireless section, the receiving side can convert the subsequent compressed packet It can be restored on the basis of the transmission information corresponding to the uncompressed packet as the irradiation packet. Thereby, the number of packets discarded on the receiving side due to the occurrence of an error in the radio section can be reduced, and as a result, the quality of transmission data in the transmission path including the radio section can be improved.
[0269]
  BookDepartureClearlyAccording to such a data receiving apparatus, the data receiving apparatus that receives information transmitted in units of packets from the transmitting side as a transmission signal and sequentially restores transmission information corresponding to each packet receives the transmission signal, A packet receiving means for outputting an uncompressed packet in which transmission information is stored as uncompressed information, and a compressed packet in which at least part of the transmission information following the predetermined transmission information is compressed and stored as compressed information Packet restoration means for performing restoration processing on each packet based on information stored in each packet, and information related to the uncompressed packet subjected to restoration processing by the packet restoration means as reference information Reference information management means for accumulating and managing, wherein the packet restoration means is configured to transmit transmission information corresponding to the compressed packet. Since the restoration is made based on the compression information included in the compressed packet and the reference information stored in the reference information management means, even if a transmission error of the compressed packet occurs in the wireless section, it continues The compressed packet can be restored based on the transmission information corresponding to the uncompressed packet as the reference packet, thereby improving the quality of transmission data in the transmission path including the wireless section.
[0270]
  BookDepartureClearlyAccording to the data transmitting apparatus, the received transmission information is received, and at least a part of the uncompressed packet in which the predetermined transmission information is stored as uncompressed information and the transmission information following the predetermined transmission information are compressed. A packet creating means for creating a compressed packet stored as compressed information, and an information managing means for managing information related to the uncompressed packet and the specific compressed packet created by the packet creating means as update information; The information management means sets information related to the uncompressed packet as an initial value of the update information, and thereafter, the update information is set to the specific compressed packet every time a specific compressed packet is created. The packet creation means is compressed to be stored in a compressed packet to be created by the means. Since the information is generated based on the transmission information corresponding to the compressed packet and the update information stored in the reference information management means, the quality of the transmission data in the radio section is improved and the data transmission The effective speed can be improved and the data compression efficiency can be improved. As a result, the time and cost for packet transmission that cannot be restored can be greatly reduced. In addition, since the reference information necessary for the decompression process is updated to the compressed packet by sending a specific compressed packet, the transmission information is compressed while keeping the data transmission efficiency high while reducing the number of non-compressed packet transmissions. Efficiency can be increased.
[0271]
  BookDepartureClearlyAccording to such a data receiving apparatus, the data receiving apparatus that receives information transmitted in units of packets from the transmitting side as a transmission signal and sequentially restores transmission information corresponding to each packet receives the transmission signal, A packet receiving means for outputting an uncompressed packet in which transmission information is stored as uncompressed information, and a compressed packet in which at least part of the transmission information following the predetermined transmission information is compressed and stored as compressed information A packet restoration unit that performs a restoration process on each packet based on the information stored in each packet, and an uncompressed packet and a specific compressed packet that have been restored by the packet restoration unit Reference information management means for accumulating and managing information as reference information, wherein the information management means To set information related to the uncompressed packet, and then update the updated information to information related to the specific compressed packet each time a restoration process is performed on the specific compressed packet. Since the packet restoring means is configured to restore the transmission information corresponding to the compressed packet based on the compressed information included in the compressed packet and the reference information stored in the reference information managing means, the wireless section In addition to improving the quality of transmission data and improving the effective speed of data transmission, the data compression efficiency can also be improved. As a result, the time and cost of packet transmission that cannot be restored can be greatly reduced. . In addition, every time a specific compressed packet is restored, the reference information necessary for the restoration process is updated to the compressed packet. Therefore, the transmission efficiency of data and the compression efficiency of transmission information can be reduced with the number of transmission times of uncompressed packets being reduced. High transmission processing can be realized.
[Brief description of the drawings]
BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a diagram for explaining a data transmission method according to Embodiment 1 of the present invention, in which an uncompressed packet (FIG. (A)) and a compressed packet (FIG. (B)) used in the data transmission method; ) Shows the data structure.
FIG. 2 is a block diagram for explaining a data transmission system using the data transmission method of the first embodiment, and shows a data transmission apparatus in the data transmission system.
FIG. 3 is a block diagram for explaining a data transmission system using the data transmission method of the first embodiment, and shows a data receiving apparatus in the data transmission system.
FIG. 4 is a diagram for explaining the data transmission method of the first embodiment, and shows a flow of a plurality of packets from a transmission side to a reception side in a normal transmission state.
FIG. 5 is a diagram for explaining the data transmission method according to the first embodiment, and shows a flow of a plurality of packets from the transmission side to the reception side when a transmission error occurs.
6 is a diagram showing a flow of packet creation processing in the data transmitting apparatus of the first embodiment. FIG.
FIG. 7 is a diagram showing a flow of packet restoration processing in the data receiving apparatus of the first embodiment.
FIG. 8 is a diagram for explaining a data transmission method according to a first modification of the first embodiment of the present invention, in which an uncompressed packet (FIG. (A)) and a compressed packet ( The data structure of FIG. (B)) is shown.
FIG. 9 is a diagram for explaining a data transmission method according to the first modification of the first embodiment, and shows a flow of a plurality of packets from the transmission side to the reception side in a normal transmission state.
FIG. 10 is a diagram for explaining a data transmission method according to a second modification of the first embodiment of the present invention, in which an uncompressed packet (FIG. (A)) and a compressed packet ( The data structure of FIG. (B)) is shown.
FIG. 11 is a diagram for explaining a data transmission method according to a third modification of the first embodiment of the present invention, in which an uncompressed packet (FIG. (A)) and a compressed packet ( The data structure of FIG. (B)) is shown.
FIG. 12 is a block diagram for explaining a data transmission system using a data transmission method according to a second embodiment of the present invention, and shows a data transmission apparatus in the data transmission system.
FIG. 13 is a diagram for explaining a data transmission method according to the second embodiment, and shows a flow of a plurality of packets from a transmission side to a reception side in a normal transmission state.
FIG. 14 is a block diagram for explaining a data transmission system using a data transmission method according to a third embodiment of the present invention, and shows a data transmission apparatus in the data transmission system.
FIG. 15 is a block diagram for explaining a data transmission system using the data transmission method according to the third embodiment, and shows a data receiving apparatus in the data transmission system;
FIG. 16 is a block diagram for explaining a data transmission system using a data transmission method according to a fourth embodiment of the present invention, and shows a data transmission device in the data transmission system;
FIG. 17 is a block diagram for explaining a data transmission system using the data transmission method according to the fourth embodiment, and shows a data receiving apparatus in the data transmission system;
FIG. 18 is a diagram for explaining a data transmission method according to a fifth embodiment of the present invention, and shows an uncompressed packet (FIG. (A)) and a compressed packet (FIG. (B)) used in the data transmission method. ) Shows the data structure.
FIG. 19 is a block diagram for explaining a data transmission system using the data transmission method of the fifth embodiment, and shows a data transmission apparatus in the data transmission system.
FIG. 20 is a block diagram for explaining a data transmission system using the data transmission method of the fifth embodiment, and shows a data receiving device in the data transmission system.
FIG. 21 is a diagram for explaining the data transmission method of the fifth embodiment, and shows a flow of a plurality of packets from the transmission side to the reception side in a normal transmission state.
FIG. 22 is a diagram for explaining the data transmission method of the fifth embodiment, and shows a flow of a plurality of packets from the transmission side to the reception side when a transmission error occurs.
FIG. 23 is a diagram showing a flow of packet creation processing in the data transmitting apparatus of the fifth embodiment.
FIG. 24 is a diagram showing a flow of packet restoration processing in the data receiving apparatus of the fifth embodiment.
FIG. 25 is a diagram for explaining a data transmission method according to a modification of the fifth embodiment of the present invention, in which an uncompressed packet (FIG. (A)) and a compressed packet (FIG. The data structure of (b)) and the process of creating the compressed packet Pj (Y) by compressing the transmission information D (Y) (FIG. (c)) are shown.
FIG. 26 is an enlarged view showing a part of a compressed packet Pj (Y) in a modification of the fifth embodiment.
FIG. 27 shows transmission information (FIG. (A)) to be transmitted in the modification of the fifth embodiment, and specific information stored in uncompressed packet Pi and compressed packet Pj (FIG. (B)). It is a figure for demonstrating.
FIG. 28 is a diagram for explaining a conventional data transmission system to which V. Jacobson header compression is applied, the entire configuration of the data transmission system (FIG. (A)), and data transmission in the data transmission system; Shows the necessary processing (Figure (b)).
FIG. 29 is a diagram showing a data structure of a packet used in the conventional data transmission system, and shows an RTP packet (FIG. (A)), a UDP packet (FIG. (B)), an IP packet (FIG. (C), FIG. (d)) and a PPP packet (FIG. (e)) are shown.
30 is a diagram showing a data structure of a PPP packet used in a data transmission system to which conventional V. Jacobson header compression is applied, and shows an uncompressed packet (FIG. (A)) and a compressed packet (FIG. (B) )).
FIG. 31 is a diagram for conceptually explaining PPP packet transmission processing using a conventional V. Jacobson header compression scheme;
FIG. 32 is a diagram for explaining a case where a transmission error has occurred in a PPP packet transmission process using the conventional V. Jacobson header compression method;
FIG. 33 is a diagram for explaining a data transmission system having a radio transmission section to which conventional V. Jacobson header compression is applied, and an overall configuration of the data transmission system (FIG. (A)); The figure shows the processing (Figure (b)) required for data transmission in the data transmission system.
[Explanation of symbols]
11 Receiving means
12 Compressed / uncompressed packet creation means
13 Compressed / uncompressed transmission judging means
14 Error occurrence notification receiving means
15 Reference information management means
16 Packet transmission means
17 Reference information update determination means
21 Packet receiving means
22 Error packet detection means
23 Packet recovery means
24 Error occurrence notification transmission means
25 Reference information management means
26 Output means
31 Uncompressed packet transmission frequency monitoring means
32 Error correction code adding means
41 Error correction means
42 Restoration waiting information storage means
101, 102, 103, 104, 105 Data transmission device
201, 203, 204, 205 Data receiving device
Cm1 Sending side management control signal
Cm2 Receiver management control signal
Dcp compressed data
Dpa, Dpaa, Dpb, Dpbb, Dpc, Dpd, Dpe, Dpf, Dpg, Dph, Dpi data part
Hpa, Hpaa, Hpb, Hpbb, Hpc, Hpd, Hpe, Hpf, Hpg, Hph, Hpj header part
Ico1 Subsequent difference information presence / absence flag
Ico2 reference information type flag
Id compression information (difference information (ΔD))
Ida, Idb, Idc, Idd Item-specific compression information
Id1 first compression information (difference information (Δ1D))
Id2 second compression information (difference information (Δ2D))
Ih1 compressed / uncompressed identifier
Ih2a packet identifier (ID)
Ih2b first reference packet identifier (ID1)
Ih2b1 Second reference packet identifier (ID2)
Ih2b2 reference packet identifier (ID)
Ih3 Other header information
Ih4 difference specific additional information
Ih5 reference information update flag
Ih6 Difference information presence / absence flag
Im1 sender reference information
Im2 reception term reference information
Inc Information not subject to compression
Ir uncompressed information (transmission information (D))
Ira, Irb, Irc, Ird Item-by-item compression target information
Irs restoration information (transmission information (D))
Iun1 differential information length data
Iun2 compression type flag
Jp Packet discrimination signal
Jr reference information update signal
K1 to K4 First to fourth compression target items
Ne restoration error notification signal
Nr retransmission request notification signal
Pa, Pa (1), Paa (1), Pc, Pe, Pg, Pg (1), Pi, Pi (1) Uncompressed packet
Pac ECC added uncompressed packet
Pb, Pb (2) to Pb (4), Pbb (2) to Pbb (4), Pd, Pf, Ph, Ph (2) to Ph (11), Pj, Pj (Y), Pj (2), Pj (3) Compressed packet
Pno normal packet
Pre restoration error packet
Rp received packet
S1, S2 first and second transmission signals
S3 output signal
Sc rebuild command signal
Se error signal
Sn error notification reception signal
Sr Retransmission request received signal
Src received signal

Claims (8)

The information in packets with a data transmission method for sending heat,
The uncompressed packet transfer transmission information is stored as uncompressed information to send more than one sender process heat transmission information to send compressed packets least a portion of which is stored as compressed information is compressed When,
Receiving the uncompressed packet and the compressed packet, and receiving side processing for restoring transmission information corresponding to the compressed packet,
The above sender process is
First transmission information that is a difference between transmission information corresponding to the first uncompressed packet transmitted before the compressed packet to be transmitted and transmission information corresponding to the compressed packet is created, and the compressed packet is A compression process for creating second compressed information that is a difference between transmission information corresponding to the second uncompressed packet transmitted previously and transmission information corresponding to the compressed packet;
A transmission process for transmitting a compressed packet including both the first compressed information and the second compressed information ;
The above receiving process is
A receiving process for receiving a compressed packet including both the first compressed information and the second compressed information;
A restoration process for restoring transmission information corresponding to the compressed packet by using either the first compressed information or the second compressed information included in the compressed packet ;
A data transmission method characterized by the above. The data transmission method according to claim 1, wherein
If the first uncompressed packet and the second uncompressed packet are normally received before decompressing the compressed packet, the receiving-side processing may receive the first uncompressed packet and the second uncompressed packet. Selecting an uncompressed packet close to the compressed packet from among the uncompressed packets, and using the transmission information corresponding to the selected uncompressed packet to restore the transmission information corresponding to the compressed packet;
A data transmission method characterized by the above. The data transmission method according to claim 1, wherein
The receiving side process detects a transmission error in one of the first uncompressed packet and the second uncompressed packet before restoring the compressed packet, and when the other is normally received, A normally received uncompressed packet is selected from the first uncompressed packet and the second uncompressed packet, and transmission information corresponding to the selected uncompressed packet is used to correspond to the compressed packet. Restore transmission information,
A data transmission method characterized by the above. The data transmission method according to claim 1, wherein
If the receiving side process detects a transmission error in both the first uncompressed packet and the second uncompressed packet before restoring the compressed packet, the receiving side process restores the transmission information corresponding to the compressed packet. And notify the sender that a restoration error has occurred.
A data transmission method characterized by the above. The data transmission method according to claim 1, wherein
In the transmission side processing, the uncompressed packet is transmitted to the reception side with an error correction code added thereto,
In the receiving side processing, the uncorrected packet is subjected to error correction processing using an error correction code attached thereto ,
A data transmission method characterized by the above. The data transmission method according to claim 4 , wherein
On SL sender process, depending on the frequency of the notification indicating the occurrence of a restoration error from the receiving end, the process of transmitting the uncompressed packet thereto by applying an error correction code, the uncompressed packet thereto Perform one of the processes to send without adding an error correction code ,
A data transmission method characterized by the above. A data transmission device that sends information in packets,
Receiving means for receiving heat transmission information as an input signal,
Receiving the transmission information the received and uncompressed packet transfer transmission information is stored as uncompressed data, and transmission information subsequent to the predetermined transmission information is stored as compressed information at least a partially is compressed A packet creation means for creating a compressed packet;
Reference information management means for accumulating and managing information related to uncompressed packets created by the packet creation means as reference information;
Two or more uncompressed packets created by the packet creation means, and a transmission means for sending the compressed packets to the receiving side,
Said packet creating unit creates the transmission information corresponding to the first non-compressed packet transmitted before the compressed packet to be transmitted, the first compressed information which is the difference between the transmission information corresponding to the compressed packet A second compressed information that is a difference between transmission information corresponding to the second uncompressed packet transmitted before the compressed packet and transmission information corresponding to the compressed packet;
The transmission means transmits a compressed packet including both the first compressed information and the second compressed information to the receiving side.
A data transmitting apparatus characterized by that. A data receiving device that receives uncompressed packets and compressed packets and sequentially restores transmission information corresponding to each of the compressed packets,
And two or more non-compressed packet, receives the compressed packet, transfer transmission information uncompressed packet is stored as uncompressed data,及Beauty Transmission information is stored as at least compressed information part is compressed Packet receiving means for outputting compressed packets,
Receiving the output of said packet receiving means is subjected to a restoration process on the respective packet, a packet restoration unit for outputting transmission information corresponding to the compressed packet,
Reference information management means for accumulating and managing information related to uncompressed packets subjected to the restoration processing by the packet restoration means as reference information;
Output means for outputting transmission information corresponding to the compressed packet from the packet restoration means,
The packet receiving means includes: first compressed information that is a difference between transmission information corresponding to the first uncompressed packet transmitted before the compressed packet and transmission information corresponding to the compressed packet; first compressed information And a compressed packet including both transmission information corresponding to the second uncompressed packet transmitted before the compressed packet and second compressed information which is a difference between the transmission information corresponding to the compressed packet And
The packet restoring means, using either of the first compressed information or the second compression information included in the compressed packet, to restore the transmission information corresponding to the compressed packet,
A data receiving apparatus.

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