JPWO2013111772A1 - Wireless transmission device, wireless transmission system, transmission method, reception method, and program - Google Patents

Abstract

A packet is acquired, its priority is identified and classified into a high-priority packet and a low-priority packet, and a wireless transmission link that transmits the high-priority packet is selected from a plurality of usable wireless transmission links. The low-priority packet is divided into cells that are fixed-length packets, and a wireless transmission link that transmits each cell is selected from the plurality of wireless transmission links. Further, it is determined whether the received packet is a high-priority packet or a cell in which a low-priority packet is divided. Based on the packet determined to be a low-priority packet, the packet before dividing into cells is restored, and the high-priority packet is restored. At least one of the packet and the restored packet is output.

Description

The present invention relates to a wireless transmission device, a wireless transmission system, a transmission method, a reception method, and a program.
This application claims priority based on Japanese Patent Application No. 2012-010903 for which it applied on January 23, 2012, and uses the content here.

The wireless transmission system is a system that can perform communication without the need to attach a fixed cable or the like between transmission devices. Further, in a wireless transmission system, it is possible to perform communication with an improved transmission rate by using a modulation method that multi-values a wireless signal, such as 256 QAM (Quadrature Amplitude Modulation) or 512 QAM.
However, compared to a wired transmission system via a fixed cable, a wireless transmission system performs communication by propagating a wireless signal in a space such as the atmosphere, so communication quality is affected by various factors in the wireless transmission path. Deteriorates. Therefore, enormous overhead such as using an error correction code is required, and the communication speed is lowered.
Therefore, a technique for securing a communication speed by performing communication using a plurality of wireless links has been proposed.

For example, the transmission system described in Patent Document 1 includes a wireless device that demultiplexes a wireless frame transmitted in a wireless section multilinked by a plurality of wireless links for each wireless link in a data link layer.
The aggregation switch reassembles network frames used in external networks into MRL (Multi-Radio-Link) frames, distributes the MRL frames for each radio link, and aggregates the MRL frames for each radio link into a network frame. Reassemble. The radio entrance unit converts the MRL frame distributed by the aggregation switch into a radio frame and transmits the radio frame for each radio link in the radio section, receives the radio frame for each radio link in the radio section, converts the MRL frame into an MRL frame, and performs the aggregation Output to the switch.
As a result, it is said that link control that can immediately respond to fluctuations in the link status and has a high load balancing effect can be performed.

JP 2010-258606 A

  However, in the transmission system described in Patent Document 1, if the link situation deteriorates and the transmission capacity of the wireless link decreases, the communication speed decreases. Further, in the transmission system described in Patent Document 1, it takes time for frame conversion. Due to these effects, the transmission system described in Patent Document 1 may not be able to meet the demand for high-speed communication.

  An object of the present invention is to provide a wireless transmission device, a wireless transmission system, a transmission method, a reception method, and a program that can solve the above-described problems.

  The present invention has been made to solve the above-described problem, and a wireless transmission device according to an aspect of the present invention identifies a packet acquisition unit that acquires a packet and a priority of the packet acquired by the packet acquisition unit. A priority identification unit that classifies the high priority packet and the low priority packet, a high priority packet distribution processing unit that selects a wireless transmission link that transmits the high priority packet among a plurality of usable wireless transmission links, The cell processing unit that divides the low-priority packet into cells that are fixed-length packets and selects a radio transmission link that transmits each cell from among the plurality of usable radio transmission links; and the high-priority packet The high priority packet is wirelessly transmitted by the wireless transmission link determined by the distribution processing unit, and the cell is wirelessly transmitted by the wireless transmission link determined by the cell processing unit Characterized by comprising a radio transmitting section for signal, a.

  The wireless transmission device according to one aspect of the present invention includes a wireless reception unit that receives a packet, and a signal that determines whether the packet received by the wireless reception unit is a high-priority packet or a cell into which a low-priority packet is divided An identification unit, a packet assembly processing unit that restores a packet before division into cells based on a packet that the signal identification unit determines to be a low priority packet, the high priority packet, and the packet assembly processing unit that are restored A packet output unit for outputting the packet.

  According to another aspect of the present invention, a wireless transmission system includes a first wireless transmission device that wirelessly transmits a packet, and a second wireless transmission device that receives a packet transmitted by the first wireless transmission device. 1 radio transmission apparatus, a packet acquisition unit that acquires a packet, a priority identification unit that identifies a priority of a packet acquired by the packet acquisition unit and classifies the packet into a high priority packet and a low priority packet, and can be used A high-priority packet distribution processing unit that selects a radio transmission link that transmits the high-priority packet among a plurality of radio-transmission links, and the low-priority packet is divided into cells that are fixed-length packets, and can be used. A cell processing unit for selecting a radio transmission link for transmitting each cell among a plurality of radio transmission links, and the radio transmission link determined by the high priority packet distribution processing unit Wirelessly transmitting the high-priority packet, and wirelessly transmitting the cell on the wireless transmission link determined by the cell processing unit, wherein the second wireless transmission device receives the packet A wireless reception unit that performs determination, a signal identification unit that determines whether a packet received by the wireless reception unit is a high-priority packet or a cell in which a low-priority packet is divided, and a packet that the signal identification unit determines to be a low-priority packet A packet assembly processing unit for restoring a packet before division into cells, a packet output unit for outputting the high-priority packet, and a packet restored by the packet assembly processing unit. And

  Further, a transmission method according to an aspect of the present invention is a transmission method of a wireless transmission device, wherein a packet acquisition step of acquiring a packet, and a priority of the packet acquired in the packet acquisition step is identified and a high priority packet A priority identification step for classifying the packet into a low-priority packet, a high-priority packet distribution processing step for selecting a wireless transmission link that transmits the high-priority packet among a plurality of usable wireless transmission links, and the low-priority packet. Is divided into cells that are fixed-length packets, and among the plurality of usable wireless transmission links, a cellization processing step that selects a wireless transmission link that transmits each cell, and a high-priority packet distribution processing step The high-priority packet is wirelessly transmitted on the determined wireless transmission link, and the non-determined value determined in the cell processing step is used. Be provided with a, a radio transmitting step of wirelessly transmitting the cell at the transmission link and said.

  A reception method according to an aspect of the present invention is a reception method of a wireless transmission device, wherein a wireless reception step of receiving a packet, and a packet received in the wireless reception step is a high-priority packet or a low-priority packet. A signal identification step for determining whether the cell has been divided, a packet assembly processing step for restoring a packet before division into cells based on the packet determined as a low priority packet in the signal identification step, and the high priority packet, Or a packet output step of outputting at least one of the packets restored in the packet assembly processing step.

  In addition, a program according to an aspect of the present invention enables a computer that controls a wireless transmission apparatus to identify a packet acquisition step of acquiring a packet and a priority of the packet acquired in the packet acquisition step so that a high priority packet and a low priority packet are low. A priority identifying step for classifying the packets into priority packets, a high-priority packet distribution processing step for selecting a wireless transmission link for transmitting the high-priority packets among a plurality of usable wireless transmission links, and the low-priority packets. It is divided into cells that are fixed-length packets, and is determined in a cell processing step for selecting a wireless transmission link for transmitting each cell among the plurality of usable wireless transmission links, and determined in the high-priority packet distribution processing step The high-priority packet is wirelessly transmitted on the wireless transmission link, and is determined in the cell processing step. Is a program for executing and a radio transmission step for wirelessly transmitting said cells in said radio transmission link.

  According to another aspect of the present invention, a program for controlling a wireless transmission device includes a wireless reception step of receiving a packet, and the packet received in the wireless reception step is divided into a high priority packet or a low priority packet. A signal identification step for determining whether the cell is a low-priority packet in the signal identification step, a packet assembly processing step for restoring a packet before division into cells, the high-priority packet, or And a packet output step for outputting at least one of the packets restored in the packet assembly processing step.

  According to the present invention, it is possible to efficiently use the bandwidth and satisfy the request for high-speed communication.

It is a schematic block diagram which shows the function structure of the wireless transmission system in one Embodiment of this invention. 5 is a flowchart illustrating a procedure of processing performed by the wireless transmission device for a packet to be transmitted in the embodiment. 4 is a flowchart illustrating a procedure of processing performed by a wireless transmission device on a received packet in the embodiment. It is a schematic block diagram which shows the minimum structure of this invention in the radio | wireless transmission apparatus of the embodiment. It is a schematic block diagram which shows the minimum structure of this invention in the radio | wireless transmission apparatus of the embodiment.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a schematic block diagram showing a functional configuration of a wireless transmission system according to an embodiment of the present invention. In FIG. 1, a wireless transmission system 1 includes a wireless transmission device (first wireless transmission device) 100 and a wireless transmission device (second wireless transmission device) 200.
The wireless transmission device 100 includes input / output ports (packet acquisition units) 111 to 113, a packet transfer processing unit 120, a link aggregation control unit 130, wireless signal processing units (wireless transmission units) 141 to 143, and antennas 151 to 153.
The link aggregation control unit 130 includes a priority identification unit 131, a high priority packet distribution processing unit 132, a cellization processing unit 133, a bandwidth calculation unit 134, a signal identification unit 135, a packet assembly processing unit 136, a wireless A bandwidth control unit 137.
The wireless transmission device 200 includes input / output ports (packet output units) 211 to 213, a packet transfer processing unit 220, a link aggregation control unit 230, wireless signal processing units (wireless reception units) 241 to 243, and antennas 251 to 251. 253.
The link aggregation control unit 230 includes a priority identification unit 231, a high priority packet distribution processing unit 232, a cellization processing unit 233, a bandwidth calculation unit 234, a signal identification unit 235, a packet assembly processing unit 236, a wireless A bandwidth control unit 237.
In the figure, the data signal path is indicated by a solid line, the control signal path is indicated by a broken line, and the radio line is indicated by a one-dot chain line.

The wireless transmission devices 100 and 200 communicate via wireless transmission links L1 to L3. Here, the wireless transmission link is a wireless communication line. These wireless transmission links L1 to L3 constitute a link aggregation group (LAG) G1.
Here, the link aggregation is a technique that virtually combines a plurality of lines into one virtual line as in the link aggregation defined by IEEE 802.3ad. For example, five physical links of 100 Mbps can be bundled and used as a virtual link of 500 Mbps.
However, unlike the link aggregation defined in IEEE 802.3ad, the wireless transmission system 1 performs link aggregation on the wireless transmission link.
A link aggregation group is a virtual line obtained by link aggregation.

Note that the number of input / output ports included in the wireless transmission devices 100 and 200 is not limited to three as shown in FIG. 1 and may be one or more.
Further, the number of input / output ports included in the wireless transmission device 100 and the number of input / output ports included in the wireless transmission device 200 may be different.

In addition, the configuration of the radio signal processing unit and the antenna included in the radio transmission devices 100 and 200 is not limited to the configuration shown in the figure, and a configuration in which two or more radio channels can be obtained between the radio transmission devices 100 and 200. If it is. Therefore, the number of wireless signal processing units and antennas included in the wireless transmission devices 100 and 200 may be two or more. Further, the number of radio signal processing units and antennas included in the radio transmission apparatuses 100 and 200 may be different from the number of input / output ports.
Also, in the case of MIMO (Multiple Input Multiple Output), the number of wireless signal processing units and antennas included in the wireless transmission device 100 is different from the number of wireless signal processing units and antennas included in the wireless transmission device 200. Also good.
Further, the number of radio transmission links belonging to the link aggregation group G1 is not limited to three as shown in the figure, and may be equal to or less than the number of radio lines between the radio transmission apparatuses 100 and 200.

  The wireless transmission system 1 performs wireless transmission of packets. For example, the wireless transmission device 100 and the wireless transmission device 200 are connected to different communication networks, and the wireless transmission system 1 wirelessly communicates packets between the wireless transmission device 100 and the wireless transmission device 200. Packet transmission between communication networks.

In the present embodiment, the configuration of the wireless transmission device 100 and the configuration of the wireless transmission device 200 are the same. Therefore, the configuration of the wireless transmission device 100 will be described below, and the description of the wireless transmission device 200 will be omitted.
However, the configuration of the wireless transmission device 100 and the configuration of the wireless transmission device 200 may be different. For example, the wireless transmission device 100 may be a transmission-only wireless transmission device, and the wireless transmission device 200 may be a reception-only wireless transmission device. Alternatively, the present invention may be applied to transmission from the wireless transmission device 100 to the wireless transmission device 200, and transmission from the wireless transmission device 200 to the wireless transmission device 100 may be performed by other methods.

  The input / output ports 111 to 113 perform packet acquisition (reception) and packet output (transmission). For example, the input / output ports 111 to 113 are connected to a communication network such as a LAN (Local Area Network) or the Internet and transmit / receive packets to / from devices connected to the communication network.

The input / output ports 111 to 113 output the received packet to the packet transfer processing unit 120 and transmit the packet output from the packet transfer processing unit 120. In particular, the input / output ports 111 to 113 output high priority packets and packets restored by the packet assembly processing unit 136.
Here, the wireless transmission system 1 classifies packets to be transmitted into high priority packets and low priority packets, and preferentially transmits high priority packets. As will be described later, the packet restored by the packet assembly processing unit 136 is a low-priority packet that is divided into cells and wirelessly transmitted.

The packet transfer processing unit 120 outputs the packets output from the input / output ports 111 to 113 to the link aggregation control unit 130 (priority identification unit 131).
Further, the packet transfer processing unit 120 outputs the packet output from the link aggregation control unit 130 (the signal identification unit 135 or the packet assembly processing unit 136) to any of the input / output ports 111 to 113. For example, the packet transfer processing unit 120 selects any of the input / output ports 111 to 113 according to the destination information of the packet, and outputs the packet to the selected port.
Alternatively, when the wireless transmission system 1 performs QoS (Quality Of Service) control, the packet transfer processing unit 120 inputs based on QoS information (for example, CoS (Class Of Service) value) in addition to packet destination information. Any one of the output ports 111 to 113 is selected, and the packet is output to the selected port.

The link aggregation control unit 130 controls the radio signal processing units 141 to 143 to perform packet transmission / reception.
The priority identifying unit 131 identifies the priority of the packets (packets output from the packet transfer processing unit 120) acquired by the input / output ports 111 to 113 and classifies them into high priority packets and low priority packets.

Specifically, the priority identifying unit 131 analyzes the priority of the packet from the packet header information.
For example, the priority identification unit 131 may use a CoS (Class of Service) value of a VLAN tag in a tagged VLAN (tagged Virtual Local Area Network), IPv4 (Internet Protocol Version 4), or IPv6 (Internet Protocol Version 6). Packets are classified based on the DSCP (Differentiated Services Code Point) value.
Further, for example, a value from 0 to 7 is defined as the CoS value of the packet, and the priority identifying unit 131 classifies the packet having the CoS value of 6 or 7 as the high priority packet and the packet having the CoS value of 0 to 5 Is set to a low priority packet.
It should be noted that the classification standard for high priority packets and low priority packets may be set (changed) freely by the administrator of the wireless transmission system 1.

The high priority packet distribution processing unit 132 selects a wireless transmission link that transmits a high priority packet from a plurality of usable wireless transmission links (wireless transmission links).
Here, the high-priority packet distribution processing unit 132 applies a hash function to the value of the header field (MAC address (Media Access Control Address), VLAN tag, IP address, etc.) of the packet, and the wireless transmission link according to some calculation algorithm. Select.

The high-priority packet distribution processing unit 132 selects the wireless transmission link with the best state (for example, the highest received signal level) among the wireless transmission links L1 to L3 as the wireless transmission link for transmitting the high-priority packet. You may make it do.
When the wireless signal processing units 141 to 143 perform communication using adaptive modulation (AMR: Adaptive Modulation Radio), the high-priority packet distribution processing unit 132 selects the wireless transmission link with the best state, so that the transmission rate Fast wireless transmission links can be selected. Therefore, the wireless transmission system 1 can transmit the packet (high priority packet) at a higher speed.

When the wireless signal processing units 141 to 143 perform communication without using adaptive modulation, the high-priority packet distribution processing unit 132 selects the wireless transmission link with the best state, so that the wireless transmission system 1 Communication errors of the packet can be reduced. Therefore, the wireless transmission system 1 can transmit the packet (high priority packet) more accurately.
Further, since retransmission can be suppressed by reducing transmission errors, the wireless transmission system 1 can transmit the packet (high priority packet) at a higher speed.

The radio band control unit 137 controls adaptive modulation of the radio signal processing units 141 to 143 based on the received signal level measured by the radio signal processing units 141 to 143.
Specifically, the wireless band control unit 137 determines a modulation method for each of the wireless signal processing units 141 to 143 based on the received signal level in the wireless signal processing unit, and performs communication using the determined modulation method. The wireless signal processing unit is instructed (a control signal is output). Further, the radio band control unit 137 also outputs a control signal indicating the modulation scheme determined for each of the radio signal processing units 141 to 143 to the band calculation unit 134.

  Based on the control signal from the radio band controller 137, the band calculator 134 communicates the communication speed (communication per unit time) in each of the radio signal processors 141 to 143 (and thus in each of the radio transmission links L1 to L3). The bandwidth in the sense of possible capacity is calculated, and the obtained communication speed information is output to the cell processing unit 133.

The cell processing unit 133 divides the low priority packet into cells. Here, the cell is a fixed-length packet. Note that the cell length (length set as the fixed length of the cell) can be arbitrarily set, for example, by the administrator of the radio transmission link.
When dividing the low-priority packet into cells, the cell processing unit 133 adds a header with a sequence number as information necessary for reproducing the original packet from the cell.
In addition, the cell processing unit 133 includes an identifier indicating the head in the header of the head cell (the cell in which the head portion of the communication data before division is loaded). In addition, the cell processing unit 133 includes an identifier indicating the end in the header of the end cell (the cell in which the end portion of the communication data before the division is loaded).

In addition, the cell processing unit 133 selects a radio transmission link that transmits each cell among the radio transmission links L1 to L3.
For example, the cell processing unit 133 selects a radio transmission link for transmitting a cell according to the communication speed of each radio transmission link calculated by the band calculation unit 134 (distributes the cells). Further, for example, when the communication speeds of the wireless transmission links L1, L2, and L3 are 30 megabits per second (Mbps), 10 megabits per second, and 20 megabits per second, the cell processing unit 133 Distribute the cells in a ratio of 3: 1: 2.

The signal identification unit 135 determines whether the packet received by the wireless signal processing units 141 to 143 is a high priority packet or a cell into which a low priority packet is divided.
For example, when transmitting a high priority packet, the high priority packet distribution processing unit 132 inserts identification information indicating that the packet is a high priority packet into the header of the high priority packet. In cell transmission, the cell processing unit 133 inserts identification information indicating a cell into the header of the packet (cell).
Then, the signal identification unit 135 determines which is the high priority packet or the cell by determining which identification information is inserted.

Alternatively, the signal identification unit 135 determines whether the packet length (data size) received by the wireless signal processing units 141 to 143 is a cell length or longer, and whether the packet is a high priority packet or a cell. The determination may be made using a standard other than the identification information.
When it is determined that the packets received by the wireless signal processing units 141 to 143 are high priority packets, the signal identification unit 135 outputs the packets to the packet transfer processing unit 120. On the other hand, if it is determined that the cell is a cell, the signal identification unit 135 outputs the packet to the packet assembly processing unit 136.

The packet assembly processing unit 136 restores the packet (payload data) before division into cells based on the packet that the signal identification unit 135 determines to be a low priority packet.
Specifically, the packet assembly processing unit 236 temporarily stores the cell from the signal identification unit 235 in a buffer, and restores the packet before division based on header information given to the cell. More specifically, the packet assembly processing unit 236 performs restoration so that the original order of the cells is not changed according to the sequence number included in the header.

Note that the packet assembly processing unit 236 may restore the packet based on the transmission delay of each wireless transmission link.
For example, the radio bandwidth control unit 237 performs the recommendation ITU-T Y. Similarly to the delay measurement function (ETH-DM (Delay Measurement) function) which is one of the functions of Ethernet OAM (here, Ethernet (registered trademark)) defined in 1731, the transmission delay of each wireless transmission link is reduced. taking measurement. Then, the packet assembly processing unit 236 restores the packet after waiting in a buffer for a cell received through another wireless transmission link in accordance with the wireless transmission link with the longest delay.

The wireless signal processing units 141 to 143 wirelessly transmit the high priority packet through the wireless transmission link determined by the high priority packet distribution processing unit 132, and wirelessly transmit the cell through the wireless transmission link determined by the cell processing unit 133. .
Specifically, the radio signal processing units 141 to 143 perform processing such as error correction coding and modulation on a packet (high priority packet or cell) from the high priority packet distribution processing unit 132 or the cell processing unit 133. To convert it to an analog signal.
Then, the wireless signal processing units 141 to 143 wirelessly transmit the packets converted into the analog signals from the antennas 151 to 153. Here, the wireless signal processing units 141 to 143 perform wireless transmission of packets by adaptive modulation according to the control of the wireless band control unit 137.

In addition, the wireless signal processing units 141 to 143 receive a packet.
Specifically, the radio signal processing units 141 to 143 receive the packets transmitted as radio signals by the antennas 151 to 153. Then, the wireless signal processing units 141 to 143 perform processing such as demodulation and error correction on the received wireless signal, and converts the received wireless signal into a packet as digital data. Then, the radio signal processing units 141 to 143 output the packet as the digital data to the signal identification unit 135.
Further, the wireless signal processing units 141 to 143 measure the reception signal levels at the antennas 151 to 153 and output the measurement results to the wireless band control unit 137.

The antennas 151 to 153 transmit the packets converted into radio signals by the radio signal processing units 141 to 143 to the radio transmission apparatus 200 (antennas 251 to 253) via the radio transmission link.
The antennas 151 to 153 receive signals from the wireless transmission device 200 (antennas 251 to 253) via the wireless transmission link and output the signals to the wireless signal processing units 141 to 143.

Note that whether or not to apply link aggregation in the wireless transmission system 1 may be switchable. Alternatively, the wireless transmission system 1 may use a wireless transmission link that is link-aggregated and a wireless transmission link that is not link-aggregated.
For example, the administrator of the wireless transmission system 1 sets whether to apply link aggregation, and the packet transfer processing unit 120 and the wireless signal processing units 141 to 143 switch operations according to the setting.
When the link aggregation is not applied, the packet transfer processing unit 120 directly sends the packets from the input / output ports 111 to 113 to the radio signal processing units 141 to 143 without going through the link aggregation control unit 130. Output (transfer). When the link aggregation is not applied, the wireless signal processing units 141 to 143 output the received packets directly to the packet transfer processing unit 120 without going through the link aggregation control unit 130.

Note that when the application of link aggregation can be switched, the packet transfer processing unit 120 analyzes the output destination of the packet from the input / output ports 111 to 113. When the packet transfer processing unit 120 determines that the output destination is a wireless transmission link that forms a link aggregation group, the packet transfer processing unit 120 outputs the packet to the priority identification unit 131. Then, hereinafter, the wireless transmission device 100 performs processing according to the procedure shown in FIG.
On the other hand, if it is determined that the output destination is not a wireless transmission link that forms a link aggregation group, the packet transfer processing unit 120 determines a wireless transmission link that transmits the packet, and performs wireless signal processing according to the determined wireless transmission link Directly output to the unit (any of 141 to 143). Then, the wireless signal processing unit that has received the output transmits the packet as a wireless signal.
The same applies when the wireless transmission system 1 uses a link-aggregated wireless transmission link and a wireless transmission link that is not link-aggregated.

Further, when the application / non-application of link aggregation can be switched, the wireless signal processing units 241 to 243 that have received the packet determine whether or not the wireless transmission links of the wireless signal processing units 241 to 243 form a link aggregation group. judge.
If the wireless signal processing units 241 to 243 determine that the wireless transmission link constitutes a link aggregation group, the wireless signal processing units 241 to 243 output the packet to the signal identification unit 235. Then, hereinafter, the wireless transmission device 200 performs processing according to the procedure shown in FIG. On the other hand, when it is determined that the wireless transmission link does not form a link aggregation group, the wireless signal processing units 241 to 243 directly output the packet to the packet transfer processing unit 220.
The same applies when the wireless transmission system 1 uses a link-aggregated wireless transmission link and a wireless transmission link that is not link-aggregated.

  Next, the operation of the wireless transmission system 1 will be described with reference to FIG. 2 and FIG. Hereinafter, a case where a packet is transmitted from the wireless transmission device 100 to the wireless transmission device 200 will be described. The same applies to the reverse transmission.

FIG. 2 is a flowchart illustrating a procedure of processing performed by the wireless transmission device 100 for a packet to be transmitted. When any of the input / output ports 111 to 113 receives a packet, the wireless transmission device 100 starts the process of FIG.
In the process shown in FIG. 5, first, the input / output ports 111 to 113 that have received a packet output the packet to the priority identifying unit 131 via the packet transfer processing unit 120, and the priority identifying unit 131 receives the packet. Are classified into either a high priority packet or a low priority packet (step S101).
Specifically, as described above, the priority identifying unit 131 analyzes the priority of the packet from the header information of the packet.

Next, the priority identifying unit 131 determines whether or not the packets from the input / output ports 111 to 113 are classified as high priority packets in step S101 (step S102).
When it is determined that the packet is classified as a high priority packet (step S102: YES), the priority identification unit 131 outputs the packet to the high priority packet distribution processing unit 132, and the high priority packet distribution processing unit 132 outputs the packet. Distribution to any of the wireless transmission links L1 to L3 (step S111).

Specifically, the high priority packet distribution processing unit 132 determines a wireless transmission link for transmitting the packet (selected from the wireless transmission links L1 to L3), and a wireless signal processing unit (in accordance with the determined wireless transmission link ( 141 to 143).
For example, as described above, the high priority packet distribution processing unit 132 selects a wireless transmission link by applying a hash function to the value of the header field of the packet. Alternatively, as described above, the high-priority packet distribution processing unit 132 may select the wireless transmission link having the best state (for example, the highest received signal level) among the wireless transmission links L1 to L3. .

Then, the high priority packet distribution processing unit 132 outputs the packet to the radio signal processing unit corresponding to the radio transmission link selected in Step S111 among the radio signal processing units 141 to 143, and receives the output of the packet. The signal processing unit (any of 141 to 143) wirelessly transmits the packet (step S112).
Thereafter, the process of FIG.

  On the other hand, if it is determined in step S102 that the packet has been classified as a low priority packet (step S102: NO), the priority identifying unit 131 outputs the packet to the cellization processing unit 133, and the cellization processing unit 133 Packet communication data (payload data) is divided into a plurality of pieces of data having a predetermined data length (the length of data that can be stored in a cell) (step S121).

Then, the cell processing unit 133 assigns (combines or inserts) a header (Header), a trailer (attached to the rear part of the data) as necessary, to each data divided in Step S121, A cell is generated (step S122).
At that time, as described above, the cell processing unit 133 adds a header with a sequence number as information necessary for reproducing the original packet from the cell. In addition, the cell processing unit 133 includes an identifier indicating the head in the header of the head cell (the cell in which the head portion of the communication data before division is loaded). In addition, the cell processing unit 133 includes an identifier indicating the end in the header of the end cell (the cell in which the end portion of the communication data before the division is loaded).

Next, the cell processing unit 133 distributes each cell generated in step S122 to one of the wireless transmission links L1 to L3 (step S123).
Specifically, the cell processing unit 133 determines a radio transmission link for transmitting each cell (selected from the radio transmission links L1 to L3), and performs radio signal processing units (141 to 141) corresponding to the determined radio transmission link. 143), the cell is output.
For example, as described above, the cell processing unit 133 distributes cells according to the available bandwidth (transmission rate) of each wireless transmission link measured by the wireless bandwidth control unit 137.

Then, the cell processing unit 133 outputs each cell to the radio signal processing unit corresponding to the radio transmission link selected in step S123 among the radio signal processing units 141 to 143, and receives the cell output. The unit (any of 141 to 143) wirelessly transmits the cell (step S124).
Thereafter, the process of FIG.

FIG. 3 is a flowchart illustrating a procedure of processing performed by the wireless transmission device 200 on a received packet. When any one of the wireless signal processing units 241 to 243 receives a packet (high priority packet or cell), the wireless transmission device 200 starts the processing in FIG.
In the process of FIG. 6, first, the wireless signal processing units 241 to 243 that have received a packet output the packet to the signal identification unit 235, and the signal identification unit 235 analyzes the priority of the packet (step S201). .

Then, the signal identification unit 235 determines whether the packet is a high priority packet or a cell into which a low priority packet is divided based on the analysis result in step S201 (step S202).
When it is determined that the packet is a high priority packet (step S202: YES), the signal identification unit 235 outputs the packet to the packet transfer processing unit 220, and the packet transfer processing unit 220 sets the output destination of the packet as an input / output port. One of 211 to 213 is determined (selected) (step S211).
For example, as described above, the packet transfer processing unit 220 selects one of the input / output ports 211 to 213 based on the destination information and QoS information of the packet.

Then, the packet transfer processing unit 220 outputs the packet (high priority packet) from the signal identification unit 235 to the input / output port (any of 211 to 213) selected in step S211 and receives the output of the packet. The input / output port (any of 211 to 213) outputs (transmits) the packet (step S212).
Thereafter, the process of FIG.

On the other hand, when it is determined in step S202 that the cell is a divided low priority packet (step S202: NO), the signal identification unit 235 outputs the cell to the packet assembly processing unit 236 and the packet assembly processing unit 236. Restores (assembles) the packet before division using the cell (step S221).
Specifically, as described above, the packet assembly processing unit 236 temporarily stores the cell from the signal identification unit 235 in the buffer, and restores the packet before division based on the header information given to the cell. .

Then, the packet assembly processing unit 236 determines whether or not the packet is completed, that is, whether or not all the cells divided from the packet are acquired and the process of step S221 is performed (step S222).
When it is determined that the packet is completed (step S222: YES), the packet assembly processing unit 236 outputs the packet to the packet transfer processing unit 220, and the packet transfer processing unit 220 sets the output destination of the packet as an input / output port. Any one of 211 to 213 is determined (selected) (step S231).
For example, as in step S211, the packet transfer processing unit 220 selects one of the input / output ports 211 to 213 based on the destination information and QoS information of the packet.

Then, the packet transfer processing unit 220 outputs the packet (low priority packet) from the packet assembly processing unit 236 to the input / output port (any one of 211 to 213) selected in step S223, and outputs the packet. The received input / output port (any of 211 to 213) outputs (transmits) the packet (step S232).
Thereafter, the process of FIG.
On the other hand, if it is determined in step S222 that the packet is not completed (step S222: NO), the processing in FIG. In this case, the packet assembly processing unit 236 waits for further cell acquisition and then continues the packet restoration process (step S221).

  As described above, when the input / output ports 111 to 113 acquire a packet in the wireless transmission device 100, the priority identifying unit 131 identifies the priority of the packet and classifies the packet into a high priority packet and a low priority packet. . Then, the high-priority packets are transmitted as they are (without cell division) by the wireless signal processing units 141 to 143. On the other hand, for the low priority packet, the cell processing unit 133 divides the cell, and the radio signal processing units 141 to 143 transmit the cell.

By dividing the low-priority packet into cells and transmitting, the wireless transmission device 100 can transmit without creating a vacant state (a state in which the wireless transmission link is not used for communication) in the wireless transmission link, or wireless transmission It is possible to reduce the space generated in the link. In this respect, the wireless transmission device 100 can efficiently use the bandwidth.
Also, by transmitting the high priority packet as it is (without cell division), the wireless transmission device 100 can transmit the high priority packet at a higher speed. In this respect, the wireless transmission device 100 can satisfy the request for high-speed communication more.

  In addition, the wireless signal processing units 141 to 143 perform wireless transmission of packets by adaptive modulation. Therefore, when the state of the wireless transmission link is good, the wireless transmission device 100 can perform communication at higher speed. On the other hand, even when the state of the wireless transmission link deteriorates, the wireless transmission device 100 can continue communication.

  Further, the cell processing unit 133 selects a radio transmission link for transmitting a cell according to the communication speed of each radio transmission link. Therefore, the wireless transmission device 100 can transmit without creating a space in the wireless transmission link, or can reduce the space generated in the wireless transmission link. In this respect, the wireless transmission device 100 can efficiently use the bandwidth.

Here, in IEEE802.3ad, a rule for selecting a physical link is not defined. Therefore, in communication according to IEEE 802.3ad, depending on the physical link selection rule and the input traffic, there is a possibility that even if a plurality of physical links can be used, the transfer is biased to a specific link. is there. Furthermore, if the bandwidth of the physical link (capacity that can be communicated per unit time) is exceeded, communication data may not be transmitted and discarded even if the bandwidth of another physical link can be used. . Thus, even if a plurality of physical links are bundled, there is a possibility that the band cannot be effectively used.
On the other hand, the wireless transmission device 100 selects a wireless transmission link for transmitting a cell according to the communication speed of each wireless transmission link, thereby preventing the bias of the wireless transmission link to be used and efficiently using the band. Can be used.

Further, the high priority packet distribution processing unit 132 selects a wireless transmission link having the best state among the wireless transmission links L1 to L3 as a wireless transmission link for transmitting the high priority packet.
Therefore, when the wireless signal processing units 141 to 143 perform communication using adaptive modulation, the high-priority packet distribution processing unit 132 selects the wireless transmission link with the best state, so that the wireless transmission link with a high transmission rate is obtained. The wireless transmission system 1 can transmit the packet (high priority packet) at a higher speed.

When the wireless signal processing units 141 to 143 perform communication without using adaptive modulation, the high-priority packet distribution processing unit 132 selects the wireless transmission link with the best state, so that the wireless transmission system 1 Communication errors of the packet can be reduced. Therefore, the wireless transmission system 1 can transmit the packet (high priority packet) more accurately.
Further, since retransmission can be suppressed by reducing transmission errors, the wireless transmission system 1 can transmit the packet (high priority packet) at a higher speed.

  In the wireless transmission device 200, when the wireless signal processing units 241 to 243 receive a packet, the signal identification unit 235 determines whether the packet is a high priority packet or a low priority packet. Then, the high priority packet is transmitted as it is (without performing restoration processing for cell division) from the input / output ports 211 to 213. On the other hand, for cells, the packet assembly processing unit 236 performs restoration processing for cell division, and transmits the restored packets from the input / output ports 211 to 213.

By transmitting the high priority packet as it is (without performing restoration processing for cell division), the wireless transmission device 200 can transmit the high priority packet at higher speed. In this respect, the wireless transmission device 200 can more satisfy the request for high-speed communication.
Further, by restoring the low priority packet from the cell, the wireless transmission device 200 can receive the low priority packet transmitted by efficiently using the bandwidth in the cell division. Therefore, the wireless transmission system 1 can use the band efficiently.

Next, the minimum configuration of the present invention in the wireless transmission devices 100 and 200 will be described with reference to FIG. 4 and FIG.
FIG. 4 is a schematic block diagram showing the minimum configuration of the present invention in the wireless transmission device 100 among the units shown in FIG. In the figure, among the units of the wireless transmission device 100 shown in FIG. 1, the input / output ports 111 to 113, the priority identifying unit 131, the high priority packet distribution processing unit 132, the cellization processing unit 133, and the wireless Signal processing units 141 to 143 are shown.

In this configuration, as described above based on the configuration shown in FIG. 1, when the input / output ports 111 to 113 receive a packet, the packet transfer processing unit 120 divides the packet into a high priority packet and a low priority packet. Classify either.
And about a high priority packet, the high priority packet distribution process part 132 determines the radio transmission link to transmit, and the radio signal process parts 141-143 transmit a packet on the said radio transmission link. On the other hand, for the low priority packet, the cell processing unit 133 divides the cell into cells and determines a link for transmitting each cell, and the radio signal processing units 141 to 143 transmit the cell through the radio transmission link.

By dividing the low-priority packet into cells and transmitting, the wireless transmission device 100 can transmit without creating a vacant state (a state in which the wireless transmission link is not used for communication) in the wireless transmission link, or wireless transmission It is possible to reduce the space generated in the link. In this respect, the wireless transmission device 100 can efficiently use the bandwidth.
Also, by transmitting the high priority packet as it is (without cell division), the wireless transmission device 100 can transmit the high priority packet at a higher speed. In this respect, the wireless transmission device 100 can satisfy the request for high-speed communication more.

  FIG. 5 is a schematic block diagram showing the minimum configuration of the present invention in the wireless transmission device 200 among the units shown in FIG. In the drawing, input / output ports 211 to 213, a signal identification unit 235, a packet assembly processing unit 236, and wireless signal processing units 241 to 243 among the units of the wireless transmission device 200 shown in FIG. 1 are shown. ing.

In this configuration, as described above based on the configuration shown in FIG. 1, when the wireless signal processing units 241 to 243 receive a packet, the signal identification unit 235 determines whether the packet is a high priority packet or a low priority packet. It is determined whether it is a divided cell.
And about the high priority packet, the signal identification part 235 outputs the said packet to either of the input / output ports 211-213, and the input / output ports 211-213 which received the output transmit the said packet. On the other hand, for the cell, the cell processing unit 233 restores the packet before division based on the cell, and outputs the packet to one of the input / output ports 211 to 213. The input / output ports 211 to 213 that have received the output transmit the packet.

By transmitting the high priority packet as it is (without performing restoration processing for cell division), the wireless transmission device 200 can transmit the high priority packet at higher speed. In this respect, the wireless transmission device 200 can more satisfy the request for high-speed communication.
Further, by restoring the low priority packet from the cell, the wireless transmission device 200 can receive the low priority packet transmitted by efficiently using the bandwidth in the cell division. Therefore, the wireless transmission system 1 can use the band efficiently.

Note that a program for realizing all or part of the functions of wireless transmission apparatuses 100 and 200 is recorded on a computer-readable recording medium, and the program recorded on the recording medium is read into a computer system and executed. The processing of each unit may be performed as necessary. Here, the “computer system” includes an OS and hardware such as peripheral devices.
Further, the “computer system” includes a homepage providing environment (or display environment) if a WWW system is used.
The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system.
Furthermore, the “computer-readable recording medium” dynamically holds a program for a short time like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. In this case, a volatile memory in a computer system serving as a server or a client in that case, and a program that holds a program for a certain period of time are also included.
The program may be a program for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes design changes and the like without departing from the gist of the present invention.

  A part or all of the above-described embodiment can be described as in the following supplementary notes, but is not limited thereto.

  (Additional remark 1) The packet acquisition part which acquires a packet, the priority identification part which identifies the priority of the packet which the said packet acquisition part acquired, and classify | categorizes it into a high priority packet and a low priority packet, and several usable A high-priority packet distribution processing unit that selects a radio transmission link that transmits the high-priority packet from among the wireless transmission links, and the low-priority packet is divided into cells that are fixed-length packets, The cell transmission processing unit that selects a wireless transmission link that transmits each cell from among the wireless transmission links, and the high-priority packet wirelessly transmitted by the wireless transmission link determined by the high-priority packet distribution processing unit, A wireless transmission device comprising: a wireless transmission unit that wirelessly transmits the cell through the wireless transmission link determined by the conversion processing unit.

  (Supplementary note 2) The wireless transmission device according to supplementary note 1, wherein the wireless transmission unit wirelessly transmits a packet by adaptive modulation.

  (Supplementary note 3) The wireless transmission device according to supplementary note 2, wherein the cell processing unit selects a wireless transmission link for transmitting the cell according to a communication speed of each wireless transmission link.

  (Additional remark 4) The said high priority packet distribution process part selects the radio transmission link with the best state among the said several useable radio transmission links as a radio transmission link which transmits the said high priority packet. The wireless transmission device according to any one of supplementary notes 1 to 3, wherein the wireless transmission device is characterized.

  (Supplementary Note 5) A wireless reception unit that receives a packet, a signal identification unit that determines whether a packet received by the wireless reception unit is a high-priority packet or a cell into which a low-priority packet is divided, and the signal identification unit includes A packet assembly processing unit that restores a packet before division into cells based on a packet determined to be a low-priority packet; a packet output unit that outputs the high-priority packet; and a packet restored by the packet assembly processing unit; A wireless transmission device comprising:

  (Supplementary Note 6) A first wireless transmission device that wirelessly transmits a packet and a second wireless transmission device that receives a packet transmitted by the first wireless transmission device, the first wireless transmission device acquiring the packet A packet acquisition unit, a priority identification unit that identifies the priority of the packet acquired by the packet acquisition unit and classifies the packet into a high-priority packet and a low-priority packet, and a plurality of usable wireless transmission links, A high-priority packet distribution processing unit that selects a radio transmission link that transmits a high-priority packet; and the low-priority packet is divided into cells that are fixed-length packets, and each of the usable radio transmission links A cell processing unit for selecting a radio transmission link for transmitting a cell; and the high-priority packet wirelessly transmitted by the radio transmission link determined by the high-priority packet distribution processing unit, A wireless transmission unit that wirelessly transmits the cell on the wireless transmission link determined by the cell processing unit, wherein the second wireless transmission device includes a wireless reception unit that receives a packet, and the wireless reception unit Is a signal identification unit that determines whether the received packet is a high-priority packet or a cell in which a low-priority packet is divided, and based on the packet that the signal identification unit has determined to be a low-priority packet, A wireless transmission system comprising: a packet assembly processing unit that restores a packet; a packet output unit that outputs the high-priority packet and the packet restored by the packet assembly processing unit.

  (Additional remark 7) It is the transmission method of a radio | wireless transmission apparatus, Comprising: The packet acquisition step which acquires a packet, The priority of the packet acquired in the said packet acquisition step is identified, and it classify | categorizes into a high priority packet and a low priority packet The priority identification step, the high priority packet distribution processing step for selecting a radio transmission link for transmitting the high priority packet among a plurality of usable radio transmission links, and the low priority packet are fixed-length packets. In the cell transmission processing step of selecting a wireless transmission link for transmitting each cell among the plurality of usable wireless transmission links, and the wireless transmission link determined in the high priority packet distribution processing step. The high-priority packet is wirelessly transmitted, and the cell is not transmitted through the wireless transmission link determined in the cell processing step. Transmission method characterized by comprising a, a radio transmission step of transmitting.

  (Additional remark 8) It is the reception method of a radio | wireless transmission apparatus, Comprising: The radio | wireless reception step which receives a packet, and determines whether the packet received by the said radio | wireless reception step is a high priority packet or the cell into which the low priority packet was divided | segmented A signal identification step; a packet assembly processing step for restoring a packet before division into cells based on the packet determined as a low priority packet in the signal identification step; and the high priority packet or the packet assembly processing step. A packet output step of outputting at least one of the restored packets.

  (Supplementary Note 9) A packet acquisition step for acquiring a packet to a computer that controls the wireless transmission device, and a priority for identifying the priority of the packet acquired in the packet acquisition step and classifying the packet into a high priority packet and a low priority packet A high-priority packet distribution processing step for selecting a wireless transmission link that transmits the high-priority packet among a plurality of usable wireless transmission links, and the low-priority packet as a cell having a fixed length. The cell transmission processing step of selecting a wireless transmission link for transmitting each cell from among the plurality of usable wireless transmission links, and the wireless transmission link determined in the high priority packet distribution processing step A high-priority packet is wirelessly transmitted, and the wireless transmission link determined in the cell processing step is used to transmit the packet. The program for executing a wireless transmission step, the wirelessly transmitting.

  (Additional remark 10) The signal which determines whether the packet which received the packet to the computer which controls a wireless transmission apparatus receives the packet at the said radio | wireless reception step is a high priority packet or the cell into which the low priority packet was divided | segmented An identification step; a packet assembly processing step for restoring a packet before division into cells based on the packet determined as a low-priority packet in the signal identification step; and a restoration in the high-priority packet or the packet assembly processing step A packet output step for outputting at least one of the received packets.

  According to the present invention, it is possible to efficiently use the bandwidth and satisfy the request for high-speed communication.

DESCRIPTION OF SYMBOLS 1 Wireless transmission system 100, 200 Wireless transmission apparatus 111-113, 211-213 Input / output port 120, 220 Packet transfer process part 130, 230 Link aggregation control part 131,231 Priority identification part 132,232 High priority packet distribution process part 133, 233 Cell processing unit 134, 234 Band calculation unit 135, 235 Signal identification unit 136, 236 Packet assembly processing unit 137, 237 Radio band control unit 141-143, 241-243 Radio signal processing unit 151-153, 251 253 antenna

Claims (10)

A packet acquisition unit for acquiring packets;
A priority identifying unit that identifies the priority of the packet acquired by the packet acquisition unit and classifies the packet into a high-priority packet and a low-priority packet;
A high-priority packet distribution processing unit that selects a wireless transmission link that transmits the high-priority packet among a plurality of usable wireless transmission links;
A cellization processing unit that divides the low-priority packet into cells that are fixed-length packets, and selects a wireless transmission link that transmits each cell among the plurality of usable wireless transmission links;
A wireless transmission unit that wirelessly transmits the high-priority packet on the wireless transmission link determined by the high-priority packet distribution processing unit, and wirelessly transmits the cell on the wireless transmission link determined by the cellization processing unit;
A wireless transmission device comprising:   The wireless transmission device according to claim 1, wherein the wireless transmission unit wirelessly transmits a packet by adaptive modulation.   The radio transmission apparatus according to claim 2, wherein the cell processing unit selects a radio transmission link for transmitting the cell according to a communication speed of each radio transmission link.   The high-priority packet distribution processing unit selects a wireless transmission link with the best state among the plurality of usable wireless transmission links as a wireless transmission link for transmitting the high-priority packet. Item 4. The wireless transmission device according to any one of Items 1 to 3. A wireless receiver for receiving packets;
A signal identification unit for determining whether a packet received by the wireless reception unit is a high-priority packet or a cell into which a low-priority packet is divided;
Based on the packet determined by the signal identification unit as a low-priority packet, a packet assembly processing unit that restores the packet before division into cells;
A packet output unit for outputting the high priority packet and the packet restored by the packet assembly processing unit;
A wireless transmission device comprising: A first wireless transmission device for wirelessly transmitting a packet;
A second wireless transmission device that receives a packet transmitted by the first wireless transmission device;
The first wireless transmission device is
A packet acquisition unit for acquiring packets;
A priority identifying unit that identifies the priority of the packet acquired by the packet acquisition unit and classifies the packet into a high-priority packet and a low-priority packet;
A high-priority packet distribution processing unit that selects a wireless transmission link that transmits the high-priority packet among a plurality of usable wireless transmission links;
A cellization processing unit that divides the low-priority packet into cells that are fixed-length packets, and selects a wireless transmission link that transmits each cell among the plurality of usable wireless transmission links;
A wireless transmission unit that wirelessly transmits the high-priority packet on the wireless transmission link determined by the high-priority packet distribution processing unit, and wirelessly transmits the cell on the wireless transmission link determined by the cellization processing unit;
Comprising
The second wireless transmission device is:
A wireless receiver for receiving packets;
A signal identification unit for determining whether a packet received by the wireless reception unit is a high-priority packet or a cell into which a low-priority packet is divided;
Based on the packet determined by the signal identification unit as a low-priority packet, a packet assembly processing unit that restores the packet before division into cells;
A packet output unit for outputting the high priority packet and the packet restored by the packet assembly processing unit;
A wireless transmission system comprising: A transmission method for a wireless transmission device, comprising:
A packet acquisition step of acquiring a packet;
A priority identification step of identifying the priority of the packet acquired in the packet acquisition step and classifying it into a high priority packet and a low priority packet;
A high-priority packet distribution processing step of selecting a wireless transmission link for transmitting the high-priority packet among a plurality of usable wireless transmission links;
A cellization processing step of dividing the low-priority packet into cells that are fixed-length packets, and selecting a wireless transmission link that transmits each cell among the plurality of usable wireless transmission links;
A wireless transmission step of wirelessly transmitting the high-priority packet on the wireless transmission link determined in the high-priority packet distribution processing step, and wirelessly transmitting the cell on the wireless transmission link determined in the cellization processing step When,
The transmission method characterized by comprising. A method for receiving a wireless transmission device, comprising:
A radio reception step of receiving a packet;
A signal identification step for determining whether the packet received in the wireless reception step is a high-priority packet or a cell into which a low-priority packet is divided;
Based on the packet determined as the low priority packet in the signal identification step, a packet assembly processing step for restoring the packet before division into cells,
A packet output step of outputting at least one of the high-priority packet or the packet restored in the packet assembly processing step;
A receiving method comprising: To the computer that controls the wireless transmission device,
A packet acquisition step of acquiring a packet;
A priority identification step of identifying the priority of the packet acquired in the packet acquisition step and classifying it into a high priority packet and a low priority packet;
A high-priority packet distribution processing step of selecting a wireless transmission link for transmitting the high-priority packet among a plurality of usable wireless transmission links;
A cellization processing step of dividing the low-priority packet into cells that are fixed-length packets, and selecting a wireless transmission link that transmits each cell among the plurality of usable wireless transmission links;
A wireless transmission step of wirelessly transmitting the high-priority packet on the wireless transmission link determined in the high-priority packet distribution processing step, and wirelessly transmitting the cell on the wireless transmission link determined in the cellization processing step When,
A program for running To the computer that controls the wireless transmission device,
A radio reception step of receiving a packet;
A signal identification step for determining whether the packet received in the wireless reception step is a high-priority packet or a cell into which a low-priority packet is divided;
Based on the packet determined as the low priority packet in the signal identification step, a packet assembly processing step for restoring the packet before division into cells,
A packet output step of outputting at least one of the high-priority packet or the packet restored in the packet assembly processing step;
A program for running

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