JP2003273893A - Method for processing ether signal, base station and subscriber's station - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for processing an Ether signal which can reduce the CPU load of a base station, and to provide the base station and a subscriber's station. <P>SOLUTION: The method for processing the Ether signal for a system for transferring data at a terminal connected to the network and the subscriber's station, by radio communicating the base station connected to the network and a plurality of the subscriber's stations in a time division multiple access system comprises the subscriber's station specifying step of specifying the subscriber's station, by using a VLAN tag of the Ether signal with the VLAN tag to be transmitted from the network by the base station, the transfer step of transferring the Ether signal with the VLAN tag to the specified subscriber's state by the base station, and the deleting step of deleting the VLAN tag of the Ether signal with the VLAN tag transferred from the base station by the subscriber's station. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an Ether signal processing method, a base station, and a subscriber station, and more particularly, an Ether signal processing method, a base station, and a subscriber capable of reducing the CPU load of the base station. Regarding the station.

[0002]

2. Description of the Related Art Generally, a communication system which provides a fixed radio access service provides a wide service area as a whole by arranging a large number of cells which are relatively small service areas using one base station.

Therefore, in such a communication system, a plurality of radio lines are formed between a base station and a plurality of subscriber stations, but the plurality of radio lines are connected to each other in order to effectively use the frequency. Use a common frequency channel.

In order to use a common frequency for a plurality of subscriber stations, it is necessary to control so that radio signal interference (collision) does not occur. In order to prevent this interference, a plurality of communications may be separated according to the difference in transmission time.

An example of such a separated communication system is C
SMA (Carrier Sense Multipl)
e Access: Carrier detection multiple access) / CA (Co
collision avoidance) and T
DMA is known.

[0006] CSMA / CA performs carrier sensing based on the reception level, and confirms that the frequency used is not used by another station before transmitting. Therefore, although CSMA / CA has a hidden terminal problem in which each subscriber station transmits without noticing the existence of other stations and causes interference, CSMA / CA will not be described in further detail in this specification. .

In TDMA, all communication is controlled by the base station so that radio signal interference (collision) does not occur, and the time slot used for data communication between the base station and a plurality of subscriber stations is also provided in the base station. Are managed collectively.

FIG. 5 is a diagram showing a configuration example of a radio frame in a communication system adopting TDMA / TDD. In FIG. 5, TS11 (Time Slot 1
1) is an area that can be accessed by all subscriber stations. Frame structure information, information for supervisory control, and arbitration of a time slot request randomly transmitted from each subscriber station in TS14 described later. Control signal for
This is a time zone in which the base station notifies the time slot assigned by the time scheduling in response to the time slot request transmitted from the subscriber station in TS14.

TS12 is a time zone for transmitting downlink user data from the base station to each subscriber station. This time zone is generally divided into fixed-length time zones from the viewpoint of effectively utilizing radio resources and ensuring fairness among a plurality of subscriber stations. In addition, the time zone is determined in consideration of the radio error quality and the efficiency of data to be transmitted.

The TS 13 measures the propagation delay time caused by the distance difference between the base station and a plurality of subscriber stations, adjusts the transmission timing of the radio signal transmitted from each subscriber station, and adjusts the radio signal at the reception of the base station. It is a time zone for controlling so that signals do not collide. Further, the TS13 also transmits an upstream supervisory control signal.

TS14 is a time zone for the subscriber station to request a time slot for transmitting user data in the upstream direction to the base station, and the base station responds to the request made in this time slot. Assign time slots for user data transmission to subscriber stations. And
The base station uses the time slot for user data transmission as TS.
The subscriber station is notified at 11, and the subscriber station transmits user data using the notified time slot. The TS 14 is also divided into fixed-length time zones, like the TS 12.

TS15 is a time zone for transmitting the user data. TS16 is a guard time for preventing interference, which is set at the boundary between the uplink and the downlink. In a conventional communication system that employs TDMA / TDD, the following Ether signal processing is performed using the above radio frame.

FIG. 6 is a diagram showing a conventional Ether signal processing example (base station). In the base station, data for specifying the VLAN and the subscriber station is preset. The base station receives the VLA received from the network.
The transfer destination subscriber station of the N-tagged Ether signal is specified by referring to the preset correspondence data between the VID and the subscriber station.

After that, the base station executes Eth with a VLAN tag.
The VLAN tag is deleted from the er signal and data shift is performed to generate an Ether signal without a VLAN tag. The base station divides the generated VLAN tag-less Ether signal into the size of the downlink wireless MAC frame, and transfers the plurality of divided wireless MAC frames to the specified subscriber station.

FIG. 7 is a diagram showing a conventional Ether signal processing example (subscriber station). The subscriber station synthesizes a plurality of downlink wireless MAC frames transferred from the base station through the above processing to generate a conventional Ether signal without a VLAN tag. Then, the subscriber station transfers the generated conventional Ether signal without VLAN tag to the terminal accommodated (connected) to itself.

[0016]

However, the above-mentioned conventional E
In the thether signal processing method, the base station needs to execute the process of deleting the VLAN tag from this signal each time it receives the VLAN tagged Ether signal from the network. Further, since the VLAN tag is placed at the beginning of the Ether signal, the base station needs to perform the data shift process on the Ether signal after deleting the VLAN tag.

Therefore, in the above-mentioned conventional Ether signal processing method, the CPU load of the base station is excessive,
There has been a problem that the performance and the throughput of the entire communication system are deteriorated.

In view of the above circumstances, the present invention improves the performance of the communication system as a whole and prevents the throughput from decreasing, thereby reducing the CPU load of the base station. The purpose is to provide stations and subscriber stations.

[0019]

According to the present invention, the above problems can be solved by the means described in the claims. That is, the invention according to claim 1 is connected to the network and the subscriber station by performing wireless communication between the base station connected to the network and the plurality of subscriber stations by a time division multiple access method. In an Ether signal processing method in a system in which a terminal transfers data,

A subscriber station identifying step for the base station to identify the subscriber station using a VLAN tag of a VLAN tagged Ether signal transmitted from the network,
A transfer step in which the base station transfers a VLAN-tagged Ether signal transmitted from the network to the specified subscriber station;

The subscriber station has a deleting step of deleting the VLAN tag of the Ether signal with the VLAN tag transferred from the base station.
er signal processing method.

According to the first aspect of the invention, the subscriber station carries out the VLAN tag deletion processing conventionally performed in the base station and the data shift processing associated therewith. Therefore, according to the invention of claim 1, the CP of the base station is
Since the U load can be distributed to multiple subscriber stations, the C
The PU load can be reduced.

The invention according to claim 2 is the Ether signal processing method according to claim 1, wherein the subscriber station is
Ether transmitted from the terminal accommodated in the subscriber station
Transferring a signal to the base station, the base station VL to the Ether signal transmitted from the subscriber station.
An AN tag is added, and the base station sets the VL
Transmitting an Ether signal with an AN tag attached to the network.
This is a ther signal processing method.

According to the second aspect of the present invention, when data is transmitted from the subscriber station to the network through the base station, the VLAN signal is added to the Ether signal by the base station. Therefore, according to the second aspect of the present invention, the CPU load of the base station and the CPU load of the subscriber station can be balanced, so that the performance of the entire communication system can be improved.

According to a third aspect of the present invention, the base station connected to the network and a plurality of subscriber stations are connected to the network and the subscriber station by performing wireless communication by a time division multiple access system. In the Ether signal processing method in the system in which the data transfer with the terminal

A step in which the base station divides the VLAN-tagged Ether signal transmitted from the network into a fixed-length wireless MAC frame and stores the wireless MAC frame in a downlink buffer of the base station; Storing the divided plurality of wireless MAC frames in a downlink subscriber station buffer for a subscriber station indicated by the VLAN tag, referring to a subscriber station correspondence table,

A step in which the base station adds recombining information to the plurality of MAC frames for a subscriber station receiving the plurality of MAC frames to combine the plurality of MAC frames; The station sends a plurality of MAC frames to which the recombining information is added to the VLAN.
Transmitting to the subscriber station indicated by the tag,

The subscriber station receives the MAC frame transmitted from the base station, and the subscriber station receives the plurality of M frames based on the recombined information.
Ether frame with the above-mentioned VLAN tag by combining AC frames
Generating a signal,

The subscriber station deletes the VLAN tag from the generated Ether signal with VLAN tag and shifts the data to generate an Ether signal without a VLAN tag, and the subscriber station generates the Ether signal. And a step of transmitting an Ether signal without a VLAN tag to a terminal accommodated in the subscriber station, the Ether signal processing method.

According to the third aspect of the present invention, the subscriber station carries out the VLAN tag deletion processing conventionally performed in the base station and the data shift processing associated therewith. Therefore, according to the invention of claim 3, the CP of the base station
Since the U load can be distributed to multiple subscriber stations, the C
The PU load can be reduced.

According to a fourth aspect of the present invention, a base station connected to the network and a plurality of subscriber stations perform wireless communication by a time division multiple access system, thereby connecting to the network and the subscriber station. Which is a base station in a system in which a terminal transfers data,

Network interface section, downlink MAC scheduling processing section, uplink MAC scheduling processing section,
It has a TDMA / TDD control unit and a modulation / demodulation unit, and the network interface unit has a downlink buffer, an uplink buffer,
And a VLAN tag-attached Ether signal transferred from a U-CPU, which will be described later, in which the Ether signal with a VLAN tag is divided into wireless MAC frames and transferred to the downlink buffer.
an r-signal is stored in an upstream buffer, and an E-CPU unit for executing upstream processing for transmitting the stored Ether-signal with a VLAN tag to the network is provided.

The downlink MAC scheduling processing section stores a downlink subscriber station buffer prepared for each subscriber station and radio data in the downlink subscriber station buffer,
A D-CPU unit that performs a scheduling process that determines the order of transmitting the stored wireless data to each subscriber station, adds a header area to the wireless MAC frame, and transfers the wireless MAC frame to the TDMA / TDD unit;

The upstream MAC scheduling processing section is provided with an upstream subscriber station buffer prepared for each subscriber station and a plurality of wireless MACs transmitted from TDMA / TDD.
The frame is stored in the upstream subscriber station buffer, the plurality of stored wireless MAC frames are combined to generate an Ether signal, and the subscriber station number and VLAN-of the subscriber station that has transmitted the plurality of wireless MAC frames. A VLAN is added to the generated Ether signal by referring to the subscriber station correspondence table.
A VLAN tag-added Ether signal is generated by adding a tag, and the generated VLAN tag-added Ether signal is added to the E
-Has a U-CPU unit for transmitting to the CPU,

The TDMA / TDD control unit is provided for the wireless MA transferred from the downlink MAC scheduling processing unit.
The C frame is used as a downlink data area, and a header area such as a subscriber station number and recombined information is further added to the downlink data area to make downlink information, which is transferred to the modulation / demodulation unit.

Based on the uplink information transferred from the subscriber station, a wireless MAC frame is generated based on the recombined information in the header area of the uplink information, and based on the subscriber station number in the header area of the uplink information. , The generated wireless MAC
Transfer the frame to the U-CPU,

The modulation / demodulation unit is a base station characterized by modulating downlink information transferred from the TDMA / TDD control unit and demodulating uplink information transferred from the subscriber station. .

According to the fourth aspect of the present invention, the subscriber station carries out the VLAN tag deletion processing conventionally performed in the base station and the data shift processing associated therewith. Therefore, according to the invention of claim 5, the CP of the base station
Since the U load can be distributed to multiple subscriber stations, the C
The PU load can be reduced.

According to a fifth aspect of the present invention, the base station connected to the network and a plurality of subscriber stations are connected to the network and the subscriber station by wireless communication using a time division multiple access system. The subscriber station in the system for data transfer with a terminal,

It has a modulation / demodulation unit, a TDMA / TDD control unit, and a terminal interface unit. The modulation / demodulation unit demodulates downlink information transmitted from the base station, while
The uplink information transferred from the DMA / TDD control unit is modulated, and the TDMA / TDD control unit wirelessly transmits the downlink information transferred from the modulation / demodulation unit based on the recombined information in the header area of the downlink information. Generate a MAC frame,

The generated wireless MAC frame is transferred to the M-CPU section of the terminal interface section, which will be described later, while the wireless MAC frame transferred from the M-CPU of the terminal interface section, which will be described later, is used as an upstream data area. A header area such as a subscriber station number or recombining information is added to the uplink information to transfer it to the modulation / demodulation unit, and the terminal interface unit uses a downlink buffer,
An uplink buffer and a wireless MAC frame transferred from the TDMA / TDD control are stored in the downlink buffer, and a VLAN-tagged Ether signal is generated based on the recombined information of the header area of the stored wireless MAC frame,

The VLAN tag is deleted from the generated Ether signal with VLAN tag and the downlink processing for transferring the VLAN tag to the terminal and the Eth without VLAN tag transmitted from the terminal are performed.
er signal is divided into wireless MAC frames, re-combination information is added to the divided wireless MAC frames, the combined wireless MAC frames are stored in the upstream buffer, and the stored wireless MAC frames are transferred to the TDMA / TDD control unit. And do M
A subscriber station characterized by having a CPU section.

According to the fifth aspect of the present invention, the subscriber station carries out the VLAN tag deletion processing conventionally performed in the base station and the data shift processing associated therewith. Therefore, according to the invention of claim 5, the CP of the base station
Since the U load can be distributed to multiple subscriber stations, the C
The PU load can be reduced.

According to a sixth aspect of the present invention, the base station connected to the network and a plurality of subscriber stations are connected to the network and the subscriber station by performing wireless communication by a time division multiple access system. In the Ether signal processing method in the system in which the data transfer with the terminal

A VID processing mode indicating a non-transparent mode or a transparent mode is preset in each subscriber station, and the base station uses the VLAN tag of the Ether signal with a VLAN tag transmitted from the network to transmit the subscriber A subscriber station specifying step for specifying a station, and the base station,
A transfer step of transferring the VLAN tagged Ether signal transmitted from the network to the specified subscriber station;

When the VID processing mode set in the subscriber station is the non-transparent mode, the subscriber station deletes the VLAN tag of the Ether signal with VLAN tag transferred from the base station, No VLAN tag Ether
The r signal is transferred to the terminal accommodated in the subscriber station, and when the VID processing mode set in the subscriber station is the transparent mode, the Ether signal with the VLAN tag transferred from the base station is transferred to the terminal. And a step of transferring the data to a terminal accommodated in the subscriber station.

According to the invention described in claim 6, the subscriber station in the transparent mode receives the V signal from the VLAN tagged Ether signal.
Do not delete the LAN tag. Therefore, if the information for identifying the terminal is adopted as the VLAN tag in the invention described in claim 6, one subscriber station can accommodate a plurality of terminals. That is, according to the invention of claim 6, the subscriber station does not delete the VLAN tag,
The Ether signal with the VLAN tag is directly transferred to the terminal.

Therefore, between the subscriber station and the terminal, V
By providing the switching hub capable of identifying the LAN tag, one subscriber station can accommodate a plurality of terminals.

Therefore, in the invention described in claim 6, the terminal accommodated can be flexibly changed by setting and changing the VID processing mode and the VLAN tag by the operation system.

According to the invention described in claim 7, in the Ether signal processing method according to claim 6, a VID processing mode indicating a non-transparent mode or a transparent mode is preset in each subscriber station, and the subscriber station is processed. Transferring an Ether signal transmitted from a terminal accommodated in the subscriber station to the base station, the base station transferring from an subscriber station in which a non-transparent mode is set as the VID processing mode. VLAN tag is added to the generated Ether signal,

Send to the network and send the V
And a step of transmitting the VLAN-tagged Ether signal transferred from the subscriber station in which the transparent mode is set as the ID processing mode, to the network.

According to the seventh aspect of the invention, when data is transmitted from the subscriber station to the network through the base station, the base station adds a VLAN tag to the Ether signal. Therefore, according to the invention described in claim 7, the CPU load of the base station and the CPU load of the subscriber station can be balanced, so that the performance of the entire communication system can be improved.

According to the invention described in claim 7, the subscriber station in the transparent mode does not delete the VLAN tag from the VLAN tagged Ether signal. Therefore, claim 7
If the information for identifying the terminal is adopted as the VLAN tag in the invention described in the above, it is possible to accommodate a plurality of terminals in one subscriber station. That is, according to the invention described in claim 7, the subscriber station transfers the VLAN-tagged Ether signal as it is to the terminal without deleting the VLAN tag.

Therefore, between the subscriber station and the terminal, V
By providing the switching hub capable of identifying the LAN tag, one subscriber station can accommodate a plurality of terminals.

Therefore, in the invention described in claim 7, the terminal accommodated can be flexibly changed by setting and changing the VID processing mode and the VLAN tag by the operation system.

According to an eighth aspect of the present invention, the base station connected to the network and a plurality of subscriber stations are connected to the network and the subscriber station by wireless communication using a time division multiple access system. In an Ether signal processing method in a system in which a terminal performs data transfer with each other, a VID processing mode indicating a non-transparent mode or a transparent mode is preset in each subscriber station,

A step in which the base station divides the VLAN-tagged Ether signal transmitted from the network into fixed-length wireless MAC frames and stores the same in a downlink buffer of the base station; Storing the divided plurality of wireless MAC frames in a downlink subscriber station buffer for a subscriber station indicated by the VLAN tag, referring to a subscriber station correspondence table,

The base station adds, to the plurality of MAC frames, recombining information for a subscriber station receiving the plurality of MAC frames to combine the plurality of MAC frames; The station sends a plurality of MAC frames to which the recombining information is added to the VLAN.
Transmitting to the subscriber station indicated by the tag,

The subscriber station receives the MAC frame transmitted from the base station, and the subscriber station receives the plurality of M frames based on the recombined information.
Ether frame with the above-mentioned VLAN tag by combining AC frames
Generating a signal,

When the subscriber station has the non-transparent mode as the VID processing mode set for the subscriber station, the VLAN is determined from the generated VLAN tagged Ether signal.
By deleting the tag and shifting the data, the VLAN
An untagged Ether signal is generated and the generated VLAN is generated.
While transmitting the untagged Ether signal to the terminal accommodated in the subscriber station,

When the VID processing mode set in the subscriber station is the transparent mode, the generated VLAN is generated.
Transferring the tagged Ether signal to a terminal accommodated in the subscriber station.
This is a ther signal processing method.

According to the invention described in claim 8, the subscriber station in the transparent mode receives the V signal from the VLAN tagged Ether signal.
Do not delete the LAN tag. Therefore, if the information for identifying the terminal is adopted as the VLAN tag in the invention described in claim 8, one subscriber station can accommodate a plurality of terminals. That is, according to the invention of claim 8, the subscriber station does not delete the VLAN tag,
The Ether signal with the VLAN tag is directly transferred to the terminal.

Therefore, between the subscriber station and the terminal, V
By providing the switching hub capable of identifying the LAN tag, one subscriber station can accommodate a plurality of terminals.

Therefore, in the invention described in claim 8, the terminal to be accommodated can be flexibly changed by setting and changing the VID processing mode and the VLAN tag by the operation system.

According to a ninth aspect of the present invention, a base station connected to a network and a plurality of subscriber stations in which a VID processing mode indicating a non-transparent mode or a transparent mode is preset are time division multiple access system. By performing wireless communication with, the network and the terminal connected to the subscriber station is the base station in a system for performing data transfer,

Network interface section, downlink MAC scheduling processing section, uplink MAC scheduling processing section,
It has a TDMA / TDD control unit and a modulation / demodulation unit, and the network interface unit has a downlink buffer, an uplink buffer,
And a VLAN tag-attached Ether signal transferred from a U-CPU, which will be described later, in which the Ether signal with a VLAN tag is divided into wireless MAC frames and transferred to the downlink buffer.
an r-signal is stored in an upstream buffer, and an E-CPU unit for executing upstream processing for transmitting the stored Ether-signal with a VLAN tag to the network is provided.

The downlink MAC scheduling processing section stores a downlink subscriber station buffer prepared for each subscriber station and radio data in the downlink subscriber station buffer,
A D-CPU unit that performs a scheduling process that determines the order of transmitting the stored wireless data to each subscriber station, adds a header area to the wireless MAC frame, and transfers the wireless MAC frame to the TDMA / TDD unit;

The uplink MAC scheduling processing section comprises an uplink subscriber station buffer prepared for each subscriber station and a plurality of radio MACs transmitted from TDMA / TDD.
The frame is stored in the upstream subscriber station buffer, the plurality of stored wireless MAC frames are combined to generate an Ether signal, and the subscriber station number and VLAN-of the subscriber station that has transmitted the plurality of wireless MAC frames. A VLAN is added to the generated Ether signal by referring to the subscriber station correspondence table.
A VLAN tag-added Ether signal is generated by adding a tag, and the generated VLAN tag-added Ether signal is added to the E
-Has a U-CPU unit for transmitting to the CPU,

The TDMA / TDD control unit is configured to transmit the wireless MA transferred from the downlink MAC scheduling processing unit.
The C frame is used as a downlink data area, and a header area such as a subscriber station number and recombined information is further added to the downlink data area to make downlink information, which is transferred to the modulation / demodulation unit.

Based on the uplink information transferred from the subscriber station, a wireless MAC frame is generated based on the recombined information in the header area of the uplink information, and based on the subscriber station number in the header area of the uplink information. , The generated wireless MAC
The frame is transferred to the U-CPU, and the modulator / demodulator modulates the downlink information transferred from the TDMA / TDD controller, while demodulating the uplink information transferred from the subscriber station. And the base station.

According to the ninth aspect of the invention, the transparent mode subscriber station receives the V signal from the VLAN tagged Ether signal.
Do not delete the LAN tag. Therefore, if the information for identifying the terminal is adopted as the VLAN tag in the invention described in claim 9, one subscriber station can accommodate a plurality of terminals. That is, according to the invention of claim 9, the subscriber station does not delete the VLAN tag,
The Ether signal with the VLAN tag is directly transferred to the terminal.

Therefore, between the subscriber station and the terminal, V
By providing the switching hub capable of identifying the LAN tag, one subscriber station can accommodate a plurality of terminals.

Therefore, in the invention described in claim 9, the terminal to be accommodated can be flexibly changed by setting and changing the VID processing mode and the VLAN tag by the operation system.

According to a tenth aspect of the invention, a base station connected to the network and a plurality of subscriber stations in which a VID processing mode indicating a non-transparent mode or a transparent mode is preset are time division multiple access system. By performing wireless communication with the network, the terminal connected to the subscriber station is the subscriber station in a system for performing data transfer,

It has a modulation / demodulation unit, a TDMA / TDD control unit, and a terminal interface unit. The modulation / demodulation unit demodulates downlink information transmitted from the base station, while
The uplink information transferred from the DMA / TDD control unit is modulated, and the TDMA / TDD control unit wirelessly transmits the downlink information transferred from the modulation / demodulation unit based on the recombined information in the header area of the downlink information. While generating a MAC frame and transferring the generated wireless MAC frame to the M-CPU unit of the terminal interface unit described later,

The radio MAC frame transferred from the M-CPU of the terminal interface section to be described later is used as an upstream data area, and a header area such as a subscriber station number or recombined information is added to the upstream data area to provide upstream line information. , Transfer this to the modulator / demodulator,

The terminal interface unit stores in the downlink buffer, the uplink buffer, and the radio MAC frame transferred from the TDMA / TDD control in the downlink buffer, and uses the recombined information in the header area of the stored radio MAC frame as the recombined information. On the basis of this, an Ether signal with a VLAN tag is generated, and if the VID processing mode set in the subscriber station is a non-transparent mode, the VLAN tag of the Ether signal with a VLAN tag transferred from the base station is deleted. And transfers the Ether signal without VLAN tag to the terminal accommodated in the subscriber station,

When the VID processing mode set for the subscriber station is the transparent mode, the downlink processing for transferring the VLAN tagged Ether signal transferred from the base station to the terminal accommodated in the subscriber station. And a VLAN-tagged Ether signal transmitted from the terminal is divided into wireless MAC frames, recombined information is added to the divided wireless MAC frames, and the wireless MAC frames are stored in the upstream buffer. The subscriber station is characterized in that it has an M-CPU unit that performs an upstream process for transferring to a TDMA / TDD control unit.

According to the tenth aspect of the present invention, the subscriber station in the transparent mode does not delete the VLAN tag from the VLAN tagged Ether signal. Therefore, if the information for identifying a terminal is adopted as the VLAN tag in the invention described in claim 10, one subscriber station can accommodate a plurality of terminals. That is, according to the invention described in claim 10, the subscriber station transfers the VLAN-tagged Ether signal as it is to the terminal without deleting the VLAN tag.

Therefore, between the subscriber station and the terminal, V
By providing the switching hub capable of identifying the LAN tag, one subscriber station can accommodate a plurality of terminals.

Therefore, in the invention described in claim 10, by setting and changing information on the VID processing mode and the VLAN tag by the operation system,
The terminal to be accommodated can be flexibly changed.

[0082]

BEST MODE FOR CARRYING OUT THE INVENTION Preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings. FIG. 4 is a diagram showing an example of a communication system to which the embodiment of the present invention is applied. A base station 11 is connected to the network (IP network). The base station 11 uses the antenna 12 to
It wirelessly communicates with the subscriber stations 21 to 23. A time division multiple access system is adopted for this communication.

FIG. 1 is a diagram showing a base station according to the first embodiment of the present invention. In FIG. 1, the base station is a VLAN-tagged Ether transmitted from the network.
The signal is divided into fixed-length wireless MAC frames and stored in the downlink buffer of the base station.

The base station refers to the VLAN-subscriber station correspondence table and stores the plurality of divided radio MAC frames in the subscriber subscriber buffer for the subscriber station indicated by the VLAN tag.

The VLAN-subscriber station correspondence table is VL
It is conceivable that the AN corresponds to the subscriber station number of the subscriber station, but the subscriber station is from the VLAN and the subscriber station is from the subscriber station to the V.
Anything can be used as long as it can identify the LAN.

The base station adds, to a plurality of MAC frames, recombining information for a subscriber station receiving the plurality of MAC frames to combine the plurality of MAC frames. Since the VLAN tagged Ether signal is divided into a plurality of parts and transmitted to each subscriber station, the subscriber station can combine the plurality of wireless MAC frames to generate the VLAN tagged Ether signal. is there.

As the recombining information, information obtained by dividing the Ether signal into wireless MAC frames can be used, but is not limited to this. Therefore, the recomposition information may be any information as long as it can regenerate the divided Ether signal.

The base station uses a plurality of Ms to which the recombining information is added.
The AC frame is transmitted to the subscriber station indicated by the VLAN tag. The base station according to the first embodiment of the present invention has been described above, and the base station will be described in more detail below.

The base station comprises a network interface section and a downlink MA.
It has a C scheduling processing unit, an uplink MAC scheduling processing unit, a TDMA / TDD control unit, and a modulation / demodulation unit.

The network interface section has a downstream buffer for storing data transferred to the subscriber station and an upstream buffer for storing data transferred from the subscriber station.
Furthermore, the network interface unit includes an E-CPU unit that performs downlink processing and uplink processing. Here, the downlink processing refers to processing of dividing the VLAN tagged Ether signal into wireless MAC frames and transferring them to the downlink buffer.
In addition, the upstream processing is the V transferred from the U-CPU described later.
Store the Ethernet signal with LAN tag in the upstream buffer,
This is a process of transmitting the stored Ether signal with VLAN tag to the network.

The downlink MAC scheduling processing section has a downlink subscriber station buffer prepared for each subscriber station. Further, the downlink MAC scheduling processing unit
-Has a CPU section. Here, the D-CPU unit stores the wireless data in the downlink subscriber station buffer, performs a scheduling process that determines the order of transmitting the stored wireless data to each subscriber station, and adds a header area to the wireless MAC frame. Transfer to the TDMA / TDD section.

In order to secure fairness in the order of data transfer from the base station to each subscriber station, the scheduling processing section may be operated by, for example, round robin control.

The uplink MAC scheduling processing section has an uplink subscriber station buffer prepared for each subscriber station. Further, the uplink MAC scheduling processing unit
-It has a CPU section. U-CPU part is TDMA /
A plurality of wireless MAC frames transmitted from TDD are stored in the upstream subscriber station buffer, and the plurality of stored wireless MAC frames are stored.
A VLAN tag is added to the generated Ether signal by referring to the subscriber station number of the subscriber station that has transmitted a plurality of wireless MAC frames and the VLAN-subscriber station correspondence table by combining the frames to generate the Ether signal. Then, the Ethernet tag-attached Ether signal is generated, and the generated VLAN tag-attached Ether signal is transmitted to the E-CPU.

The TDMA / TDD control section uses the wireless MAC frame transferred from the downlink MAC scheduling processing section as a downlink data area, and further adds a header area such as a subscriber station number and recombining information to the downlink data area. This is downlink information, which is transferred to the modem unit.

The TDMA / TDD control unit also generates a wireless MAC frame of the uplink information transferred from the subscriber station based on the recombined information of the header area of the uplink information, and stores the radio MAC frame in the header area of the uplink information. The generated wireless MAC frame is transferred to the U-CPU of the uplink MAC scheduling processing unit based on the subscriber station number. The modulator / demodulator modulates the downlink information transferred from the TDMA / TDD controller. The modem unit demodulates the uplink information transferred from the subscriber station.

FIG. 2 is a diagram showing a subscriber station according to the first embodiment of the present invention. The subscriber station receives the MAC frame transmitted from the base station. The subscriber station synthesizes the plurality of received MAC frames based on the re-synthesis information to generate a VLAN tagged Ether signal.

The subscriber station deletes the VLAN tag from the generated Ether signal with a VLAN tag and shifts the data to generate an Ether signal without a VLAN tag.
The subscriber station transmits the generated Ether signal without VLAN tag to the terminal accommodated in the subscriber station.

Although the subscriber station according to the first embodiment of the present invention has been described above, the subscriber station will be described in more detail below. The subscriber station has a modem and a TD.
It has an MA / TDD control unit and a terminal interface unit.

The modulator / demodulator demodulates the downlink information transmitted from the base station. In addition, the modulation / demodulation unit uses TDMA /
Modulates the uplink information transferred from the TDD control unit.
The TDMA / TDD control unit generates a wireless MAC frame from the downlink information transferred from the modulation / demodulation unit based on the recombined information in the header area of the downlink information, and uses the generated wireless MAC frame as the M of the terminal interface unit described later. -C
Transfer to the PU unit.

Further, the TDMA / TDD control unit is a wireless M unit transferred from the M-CPU of the terminal interface unit described later.
The AC frame is used as an upstream data area, and a header area such as a subscriber station number and recombining information is further added to the upstream data area to provide uplink information, which is transferred to the modulation / demodulation unit.

The terminal interface section has a downlink buffer for accumulating data transmitted from the base station and an up buffer for accumulating data transmitted from the terminal. Furthermore, the terminal interface unit includes an M-CPU unit that performs downlink processing and uplink processing. Here, the downlink processing means that the wireless MAC frame transferred from the TDMA / TDD control is stored in the downlink buffer, and the VLAN is based on the recomposition information of the header area of the stored wireless MAC frame.
This is a process of generating an Ether signal with a tag, deleting the VLAN tag from the generated Ether signal with a VLAN tag, and transferring the VLAN tag to the terminal.

Uplink processing means VLA transmitted from the terminal.
The N-tagged Ether signal is divided into wireless MAC frames, re-combined information is added to the divided wireless MAC frames, and the wireless MAC frames are stored in the upstream buffer.
This is a process of transferring a C frame to the TDMA / TDD control unit.

FIG. 3 is a diagram showing a second embodiment of the present invention. In FIG. 3, the base station divides the VLAN-tagged Ether signal transmitted from the network into fixed-length wireless MAC frames and stores them in the downlink buffer of the base station.

The base station refers to the VLAN-subscriber station correspondence table and stores the plurality of divided radio MAC frames in the downlink subscriber station buffer for the subscriber station indicated by the VLAN tag.

The base station adds, to the plurality of MAC frames, recombining information for a subscriber station receiving the plurality of MAC frames to combine the plurality of MAC frames.

The base station uses a plurality of MAs to which composite information is added.
The C frame is transmitted to the subscriber station indicated by the VLAN tag. The subscriber station receives the MAC frame transmitted from the base station. The subscriber station synthesizes the plurality of received MAC frames based on the re-synthesis information, and E
Generate a ther signal.

In the present embodiment, each subscriber station is preset with the VID processing mode indicating the non-transparent mode or the transparent mode. When the VID processing mode set in the subscriber station is the non-transparent mode, the subscriber station uses the generated VLAN tagged Ether signal to obtain the VLA.
By deleting the N tag and shifting the data, VLA
Generated VLAN without N tag and generated VLAN
The untagged Ether signal is transmitted to the terminal accommodated in the subscriber station.

On the other hand, when the VID processing mode set in the subscriber station is the transparent mode, the subscriber station transfers the generated VLAN-tagged Ether signal to the terminal accommodated in the subscriber station. As shown in FIG. 3, a subscriber station in which the transparent mode is set as the VID processing mode can accommodate a plurality of subscribers. In this case, the subscriber station
Based on the AN tag, the terminal housed by itself is identified, and the VLAN tagged Ether signal is transferred to the terminal identified by this VLAN tag.

[0109]

As described above, according to the present invention,
The CPU load of the base station can be reduced. Therefore, according to the present invention, it is possible to improve the performance of the entire communication system and prevent a decrease in throughput.

Further, in the present invention, a plurality of terminals can be accommodated in the subscriber station to which the transparent mode is set. Therefore, according to the present invention, by switching between the transparent mode and the non-transparent mode, the subscriber station can be a subscriber station accommodating a single user or a subscriber station accommodating a plurality of users. be able to.

[Brief description of drawings]

FIG. 1 is a diagram showing a base station according to a first embodiment of the present invention.

FIG. 2 is a diagram showing a subscriber station according to the first embodiment of the present invention.

FIG. 3 is a diagram showing a second embodiment of the present invention.

FIG. 4 is a diagram showing an example of a communication system to which an embodiment of the present invention is applied.

FIG. 5 is a diagram illustrating a configuration example of a radio frame in a communication system that employs TDMA / TDD.

FIG. 6 is a diagram illustrating a conventional Ether signal processing example (base station).

FIG. 7 is a diagram showing a conventional Ether signal processing example (subscriber station).

[Explanation of symbols]

11 base stations 12 antennas 21 (1) Subscriber station 21 (2) Subscriber station 21 (3) Subscriber station 22 (1) Antenna 22 (2) Antenna 22 (3) Antenna TS11 Downstream header area TS12 downlink data area TS13 DMF area TS14 slot demand area TS15 upstream data area TS16 guard time

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Yukihide Mizumoto             2-3-1, Otemachi, Chiyoda-ku, Tokyo             Inside Telegraph and Telephone Corporation (72) Inventor Fumio Murakami             5-1-1 Shimorenjaku, Mitaka City, Tokyo Japan             Wireless Co., Ltd. F term (reference) 5K033 AA01 CA11 CB11 CC01 DA19                       DB09 DB16 EC04                 5K067 AA22 BB21 CC04 DD04 EE12                       HH22

Claims (10)

[Claims] 1. A base station connected to a network and a plurality of subscriber stations perform wireless communication by a time division multiple access system, whereby the network and a terminal connected to the subscriber station perform data transfer. E in the system to do
In the method for processing a ther signal, the base station specifies a subscriber station using the VLAN tag of an Ether signal with a VLAN tag transmitted from a network, the subscriber station specifying step, and the base station is specified. A transfer step of transferring the VLAN tagged Ether signal transmitted from the network to the subscriber station, and a deleting step of deleting the VLAN tag of the VLAN tagged Ether signal transferred from the base station by the subscriber station. And an Ether signal processing method comprising: 2. The Ether signal processing method according to claim 1, wherein the subscriber station transfers an Ether signal transmitted from a terminal accommodated in the subscriber station to the base station, The station sends an Ether from the subscriber station
Assigning a VLAN tag to the signal, the base station setting the Ether to which the VLAN tag is attached
Transmitting the signal to the network, and an Ether signal processing method. 3. A base station connected to a network and a plurality of subscriber stations perform wireless communication by a time division multiple access system, whereby the network and a terminal connected to the subscriber station perform data transfer. E in the system to do
In the ther signal processing method, the base station transmits the VLA transmitted from the network.
Dividing the N-tagged Ether signal into a fixed-length wireless MAC frame and storing it in a downlink buffer of the base station; the base station is divided by referring to a VLAN-subscriber station correspondence table. Storing a plurality of wireless MAC frames in a downlink subscriber station buffer for a subscriber station indicated by the VLAN tag, the base station receiving the plurality of MAC frames with respect to the plurality of MAC frames. A subscriber station adding recombining information for combining these plurality of MAC frames; and the base station adding a plurality of MACs to which the recombining information is added.
Transmitting a frame to a subscriber station indicated by the VLAN tag; the subscriber station receiving a MAC frame transmitted from the base station; and the subscriber station based on the recombined information. And combining the received plurality of MAC frames to generate the VLAN tagged Ether signal, the subscriber station generating the VLAN tagged Ether signal.
a step of generating an Ether signal without a VLAN tag by deleting the VLAN tag from the r signal and performing data shift;
and a step of transmitting an er signal to a terminal accommodated in the subscriber station, the Ether signal processing method. 4. A plurality of base stations connected to a network
Wireless communication with time-division multiple access system
By connecting to the network and the subscriber station,
Before in the system to transfer data with the terminal to be continued
The base station, the network interface unit, downlink MAC scheduling processing
Unit, uplink MAC scheduling processing unit, TDMA / T
The network interface unit includes a DD buffer, an uplink buffer, and a VLAN tag E.
The ther signal is divided into wireless MAC frames, and the
Downstream processing to transfer to buffer and transfer from U-CPU described later
VLAN tagged Ether signal to upstream buffer
Storing and storing the stored Ether signal with VLAN tag
E-CPU unit that executes upstream processing to send to network
Wherein the downlink MAC scheduling processing unit is provided for each subscriber station.
Subscriber station buffer and radio data prepared in
Is stored in the downlink subscriber station buffer, and the stored radio
A schedule that determines the order in which data is sent to each subscriber station
Ring processing is performed and the header area is added to the wireless MAC frame.
D-CPU unit that gives and transfers to TDMA / TDD unit
And the uplink MAC scheduling processing unit
Subscriber station buffer and TDMA /
A plurality of wireless MAC frames transmitted from TDD are
Stored in the uplink subscriber station buffer and storing the plurality of radios
The MAC frame is combined to generate an Ether signal,
Subscriber of subscriber station that has transmitted multiple wireless MAC frames
Refer to station number and VLAN-subscriber station correspondence table
And attach a VLAN tag to the generated Ether signal.
Generates an Ether signal with a VLAN tag, and
Send Ether signal with VLAN tag to the E-CPU
A U-CPU unit for performing the downlink MAC scan.
The wireless MAC frame transferred from the routing processing unit.
Further joins the downlink data area as a downlink data area
The header area such as the station number and recomposition information is added to the downlink.
The line information is transferred to the modulation / demodulation unit, and the uplink information transferred from the subscriber station is transferred to the uplink circuit.
Based on the recomposition information in the header area of the line information, the wireless MAC frame is
Subscriber in the header area of the uplink information that generates a frame
The generated wireless MAC frame is U based on the station number.
-Transfer to the CPU, the modem unit transfers from the TDMA / TDD control unit
From the subscriber station while modulating the downlink information that is
A base station characterized by demodulating uplink information transferred. 5. A base station connected to a network and a plurality of subscriber stations perform wireless communication by a time division multiple access method, whereby the network and a terminal connected to the subscriber station perform data transfer. The subscriber station in the system for performing, including a modulation / demodulation unit, a TDMA / TDD control unit, and a terminal interface unit, the modulation / demodulation unit demodulates downlink information transmitted from the base station, while the TDMA / Modulates the uplink information transferred from the TDD controller, and the TDMA / TDD controller uses the downlink MAC information transferred from the modulator / demodulator based on the recombined information in the header area of the downlink information to establish the wireless MAC. A frame is generated and the generated wireless MAC frame is transferred to the M-CPU unit of the terminal interface unit described later, while the terminal interface The wireless MAC frame transferred from the M-CPU of the communication unit is used as an upstream data area, and a header area such as a subscriber station number and recombined information is further added to the upstream data area to serve as upstream line information. And the terminal interface unit includes a downlink buffer, an uplink buffer, and the TDMA / T.
The wireless MAC frame transferred from the DD control is stored in the downlink buffer, and based on the recombined information in the header area of the stored wireless MAC frame, Et with VLAN tag is added.
a her signal is generated, and the generated VLAN tag-added Eth
er signal, a VLAN tag is deleted from the er signal and transferred to the terminal, and a VLAN tag-less Ether signal transmitted from the terminal is divided into wireless MAC frames, and recombined information is added to the divided wireless MAC frames. Then, the subscriber station is characterized in that it has an M-CPU unit for performing an upstream process of storing the wireless MAC frame in the upstream buffer and transferring the stored wireless MAC frame to the TDMA / TDD control unit. 6. A base station connected to a network and a plurality of subscriber stations perform wireless communication by a time division multiple access method, whereby the network and a terminal connected to the subscriber station perform data transfer. E in the system to do
In the ther signal processing method, V indicating the non-transparent mode or the transparent mode is given to each subscriber station.
An ID processing mode is set in advance, the base station specifies a subscriber station using a VLAN tag of a VLAN-tagged Ether signal transmitted from a network, and a subscriber station specifying step, A transfer step of transferring a VLAN-tagged Ether signal transmitted from the network to the identified subscriber station; and the VI setting the subscriber station as the subscriber station.
When the D processing mode is the non-transparent mode, the VLAN tag of the Ether signal with the VLAN tag transferred from the base station is deleted, and the Ether signal without the VLAN tag is transferred to the terminal accommodated in the subscriber station, Transferring the VLAN-tagged Ether signal transferred from the base station to the terminal accommodated in the subscriber station when the VID processing mode set in the subscriber station is the transparent mode. An Ether signal processing method characterized by the above. 7. The Ether signal processing method according to claim 6, wherein each subscriber station has a V indicating a non-transparent mode or a transparent mode.
An ID processing mode is preset, the subscriber station transfers an Ether signal transmitted from a terminal accommodated in the subscriber station to the base station; Ether transferred from a subscriber station that is set to transparent mode
Adding a VLAN tag to the signal and transmitting to the network, and transmitting to the network an Ethernet signal with a VLAN tag transferred from a subscriber station in which a transparent mode is set as the VID processing mode, An Ether signal processing method comprising: 8. A base station connected to a network and a plurality of subscriber stations perform wireless communication by a time-division multiple access method, whereby the network and a terminal connected to the subscriber station perform data transfer. E in the system to do
In the ther signal processing method, V indicating the non-transparent mode or the transparent mode is given to each subscriber station.
The ID processing mode is preset and the base station transmits the VLA transmitted from the network.
Dividing the N-tagged Ether signal into a fixed-length wireless MAC frame and storing it in a downlink buffer of the base station; the base station is divided by referring to a VLAN-subscriber station correspondence table. Storing a plurality of wireless MAC frames in a downlink subscriber station buffer for a subscriber station indicated by the VLAN tag, the base station receiving the plurality of MAC frames with respect to the plurality of MAC frames. A subscriber station adding recombining information for combining these plurality of MAC frames; and the base station adding a plurality of MACs to which the recombining information is added.
Transmitting a frame to a subscriber station indicated by the VLAN tag; the subscriber station receiving a MAC frame transmitted from the base station; and the subscriber station based on the recombined information. And combining the received plurality of MAC frames to generate the VLAN tagged Ether signal, the subscriber station setting the VI signal set to the subscriber station.
If the D processing mode is the non-transparent mode, the generated V
By removing the VLAN tag from the Ethernet signal with LAN tag and performing data shift, Et without VLAN tag
A her signal is generated, and the generated VLAN tag Et is not generated.
While transmitting the her signal to the terminal accommodated in the subscriber station, when the VID processing mode set in the subscriber station is the transparent mode, the generated Eth with VLAN tag is generated.
er signal to a terminal accommodated in the subscriber station, and an Ether signal processing method. 9. A base station connected to a network and a plurality of subscriber stations in which a non-transparent mode or a VID processing mode indicating a transparent mode is preset to perform wireless communication by a time division multiple access method. A base station in a system in which the network and a terminal connected to the subscriber station transfer data, the network interface unit, the downlink MAC scheduling processing unit, the uplink MAC scheduling processing unit, and the TDMA / T
The network interface unit includes a DD buffer, an uplink buffer, and a VLAN tag E.
The ether signal is divided into wireless MAC frames, the downlink processing for transferring to the downlink buffer and the VLAN tagged Ether signal transferred from the U-CPU described later are stored in the uplink buffer, and the stored VLAN tagged Ether signal is sent to the network. The downlink MAC scheduling processing unit has an E-CPU unit that executes an uplink process for transmitting, and the downlink MAC scheduling processing unit stores a downlink subscriber station buffer prepared for each subscriber station and radio data in the downlink subscriber station buffer. A D-CPU that performs a scheduling process that determines the order in which the stored wireless data is transmitted to each subscriber station, adds a header area to the wireless MAC frame, and transfers the wireless MAC frame to the TDMA / TDD unit.
The uplink MAC scheduling processor includes an uplink subscriber station buffer prepared for each subscriber station and a TDMA /
A subscriber who stores a plurality of wireless MAC frames transmitted from TDD in the upstream subscriber station buffer, synthesizes the plurality of stored wireless MAC frames to generate an Ether signal, and transmits the plurality of wireless MAC frames By referring to the subscriber station number of the station and the VLAN-subscriber station correspondence table, a VLAN tag is added to the generated Ether signal to generate a VLAN tag Ether signal, and the generated VLAN tag Ether signal is generated. The TDMA / TDD control unit has a U-CPU unit for transmitting to the E-CPU, and the TDMA / TDD control unit uses the wireless MAC frame transferred from the downlink MAC scheduling processing unit as a downlink data region, and a subscriber to the downlink data region. A header area such as a station number or recombined information is added to form downlink information, which is transferred to the modulator / demodulator. On the other hand, based on the uplink information transferred from the subscriber station, a wireless MAC frame is generated based on the recombined information of the header area of the uplink information, and based on the subscriber station number of the header area of the uplink information, The generated wireless MAC frame is U
-Transfer to the CPU, the modulation / demodulation unit modulates the downlink information transferred from the TDMA / TDD control unit, while demodulating the uplink information transferred from the subscriber station. Station. 10. A base station connected to the network,
A VID processing mode indicating a non-transparent mode or a transparent mode is preset, and wireless communication is performed with a plurality of subscriber stations by a time division multiple access method, whereby the network and a terminal connected to the subscriber station. Is a subscriber station in a system for performing data transfer, and has a modulation / demodulation unit, a TDMA / TDD control unit, and a terminal interface unit, and the modulation / demodulation unit demodulates downlink information transmitted from the base station. On the other hand, the TDMA / TDD controller modulates the uplink information transferred from the TDMA / TDD controller, and the TDMA / TDD controller uses the downlink information transferred from the modulator / demodulator to re-synthesize the header area of the downlink information. Wireless MAC frame is generated based on the above, and the generated wireless MAC frame is transferred to the M-CPU unit of the terminal interface unit described later. On the other hand, the wireless MAC frame transferred from the M-CPU of the terminal interface section, which will be described later, is used as an upstream data area, and a header area such as a subscriber station number or recombined information is further added to the upstream data area to provide uplink information. , And transfers it to the modulator / demodulator, and the terminal interface unit includes a downlink buffer, an uplink buffer, and the TDMA / T.
The wireless MAC frame transferred from the DD control is stored in the downlink buffer, and based on the recombined information in the header area of the stored wireless MAC frame, Et with VLAN tag is added.
VLA of the Ether signal with VLAN tag transferred from the base station when a her signal is generated and the VID processing mode set in the subscriber station is the non-transparent mode.
The N tag is deleted, the Ether signal without the VLAN tag is transferred to the terminal accommodated in the subscriber station, and when the VID processing mode set in the subscriber station is the transparent mode, the base station transmits the signal. Transferred VLAN tagged Ether
Downstream processing for transferring the r signal to the terminal accommodated in the subscriber station, and VLAN tag Ether transmitted from the terminal
The signal is divided into wireless MAC frames, and the divided wireless M
Recombining information is added to the AC frame and stored in the upstream buffer, and the stored wireless MAC frame is stored in the TD.
MC for performing upstream processing for transfer to MA / TDD control unit
A subscriber station having a PU unit.