KR101487525B1 - System and method for transmitting for synchronization signal in multi-channel wireless backhaul - Google Patents

Abstract

The present invention provides a system and a method for transmitting a synchronization signal, in which data is transmitted in accordance with the synchronization signal for implementing a MAC function having multi-channel function in a synchronization scheme wireless backhaul apparatus based on GPS. For a system for transmitting a synchronization signal in a wireless backhaul device to transmit a synchronization signal to one or more terminals, the processor unit of the system for transmitting a synchronization signal generates a wireless backhaul packet to be transmitted to the terminals and selects a first channel to transmit the generated wireless backhaul packet. First register information for receiving the wireless backhaul packet through the first channel among a plurality of registers of a logic unit interworking with the processor unit, and the wireless backhaul packet is transmitted through the first channel or the second channel, which is different from the first channel, while the synchronization signal is generated by using a clock signal, which is synchronized to a signal transmitted from a GPS signal through the first channel, according to whether all of a first buffer unit is occupied.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a synchronous signal transmission system and method in a multi-channel wireless backhaul apparatus,

The present invention relates to a synchronous signal transmission system and method in a multi-channel wireless backhaul apparatus.

Wireless communication systems provide users with various types of data such as voice, data, and so on. Conventional wireless communication systems share available system resources to support communication with a large number of users. In the conventional wireless communication system, since the demand for the communication network capacity is relatively low, it is important to realize the arrangement of the large-scale communication system by using the low-cost technology. Therefore, it is possible to avoid problems such as a high-cost wired network arrangement and wiring difficulty by applying a wireless backhaul.

Recently, as the performance of a wireless communication system has been improved, a bandwidth expansion technique through multiple channels such as a Multi Input Multi Output (MIMO) technique or a beamforming technique has been required for processing and transmitting high-speed data. A high-performance processor or DSP (Digital Signal Processor) is used. However, there is a problem in that it is difficult to synchronize with a high-performance processor or DSP when performing synchronous communication in which data is exchanged at precise time.

Accordingly, the present invention provides a synchronous signal transmission system and method for transmitting data according to a synchronous signal in order to realize a MAC function having a multi-channel function in a GPS-based synchronous wireless backhaul apparatus.

According to another aspect of the present invention, there is provided a system for transmitting a synchronization signal synchronized with a GPS satellite and at least one terminal,

If it is confirmed that the Ethernet packet to be transmitted to one or more terminals is transmitted through the wireless backhaul device, the Ethernet packet is generated as a wireless backhaul packet, a channel to transmit the generated wireless backhaul packet is selected, A processor for transmitting the wireless backhaul packet through the selected channel; And a logic unit for controlling the wireless backhaul packet transmitted from the processor unit to be transmitted to the one or more terminals through the selected channel using a synchronization signal generated based on a signal transmitted from the GPS satellite,

Wherein the processor unit comprises: a packet processor for determining whether to transmit an Ethernet packet to be transmitted to the one or more terminals through an Ethernet device or a wireless backhaul device; A MAC processor for inserting a MAC header for a wireless backhaul into the Ethernet packet to generate a wireless backhaul packet when the packet processor determines that the Ethernet packet is to be transmitted using a wireless backhaul device; And a controller for temporarily storing the wireless backhaul packet generated by the MAC processor and selecting a channel through which to transmit the wireless backhaul packet among the at least one channel, And transmits the stored location information and the wireless backhaul packet to the logic unit so as to transmit the stored location information and the wireless backhaul packet through the selected channel.

Wherein the logic unit is configured to receive a wireless backhaul packet interleaved with the channel selection unit and including a MAC header transmitted through a plurality of channels and to receive a wireless backhaul packet at a buffer position where the received wireless backhaul packet is to be stored, To be stored in the storage unit; A first signal transmission unit for storing a wireless backhaul packet transmitted through a first channel, which is one of the plurality of channels, and transmitting the stored wireless backhaul packet to the plurality of terminals using the synchronization signal; A synchronization generator for generating a synchronization signal for transmitting the wireless backhaul packet using a clock signal synchronized with a signal transmitted from the GPS satellite; And a second signal transmission unit configured to store a wireless backhaul packet transmitted through a second channel, which is one of the plurality of channels, and transmit the stored wireless backhaul packet to the plurality of terminals using a synchronization signal generated in the synchronization generation unit Section.

Wherein the first signal transmission unit comprises: a first buffer unit for storing the wireless backhaul packet received from the channel selection unit in a buffer corresponding to the storage location information; When a synchronization signal is generated from the synchronization generation unit, checks a stored register information to confirm a buffer in which a wireless backhaul packet is stored, and transmits the received wireless backhaul packet to the buffer 1 buffer processor; And a controller for controlling to transmit the wireless backhaul packet transmitted from the buffer processor to one of the one or more terminals through the first channel, and when the wireless backhaul packet is transmitted, And a first synchronization transmitting unit for updating the bit value of the information and transmitting the updated bit value to the buffer processing unit.

Wherein the second signal transmission unit comprises: a second buffer unit for storing the wireless backhaul packet received from the channel selection unit in a buffer corresponding to the storage location information; When a synchronization signal is generated from the synchronization generation unit, checks a stored register information to confirm a buffer in which a wireless backhaul packet is stored, and transmits the received wireless backhaul packet to the buffer 2 buffer processor; And a controller for controlling to transmit the wireless backhaul packet transmitted from the buffer processor to one of the one or more terminals via the second channel, and when the wireless backhaul packet is transmitted, And a second synchronization transmitting unit for updating the bit value of the information and transmitting the updated bit value to the buffer processing unit.

According to another aspect of the present invention, there is provided a method for transmitting a synchronization signal to one or more terminals in a synchronous signal transmission system in a wireless backhaul apparatus,

Wherein the processor unit of the synchronous signal transmission system generates a wireless backhaul packet to be transmitted to the one or more terminals and selects a first channel to transmit the generated wireless backhaul packet; Confirming first register information to receive a wireless backhaul packet through the selected first channel among a plurality of registers of a logic unit interlocked with the processor unit to confirm whether the first buffer unit is occupied; Confirming second register information to receive a wireless backhaul packet through a second channel different from the first channel if the entire first buffer is occupied, and checking whether the second buffer is entirely occupied; Transmitting location information for storing the wireless backhaul packet and channel information for the second channel to the logic unit together with the wireless backhaul packet if the empty buffer is present in the second buffer unit; And the logic unit stores the received wireless backhaul packet in a buffer corresponding to the location information, and when a synchronization signal is generated using a clock signal synchronized with a signal transmitted from a GPS satellite, And transmitting the synchronization signal to the terminal while the synchronization signal is generated using the second channel.

Wherein the step of verifying that the entire first buffer is occupied includes the steps of generating position information to be stored in the empty buffer when the buffer is empty in the first buffer unit, And transmitting the wireless backhaul packet to the logic unit together with the wireless backhaul packet.

The step of checking whether the entire second buffer unit is occupied may include temporarily storing the wireless backhaul packet if the second buffer unit is occupied.

The step of transmitting to the terminal may include: checking if the wireless backhaul packet to be transmitted to the terminal is stored by checking the register information stored in the logic unit when the synchronization signal is generated; When a wireless backhaul packet is stored, transmitting a wireless backhaul packet to the terminal through a channel selected by a processor unit of the synchronous signal transmitting system interlocked with the logic unit while the synchronous signal is generated; And updating the register information stored in the logic unit so that the bit value of the register information corresponding to the buffer in which the wireless backhaul packet is stored is updated.

Wherein the logic unit comprises: storing a wireless backhaul packet transmitted from the processor unit in a buffer corresponding to the positional information before confirming that the wireless backhaul packet is stored; And updating the register information stored in the logic unit so that the register information of the buffer in which the wireless backhaul packet is stored is updated according to the location information.

Determining whether to transmit a packet to be transmitted to the terminal through a wireless backhaul device, prior to the step of selecting the first channel; And generating a wireless backhaul packet by inserting a MAC header for a wireless backhaul into the packet if the packet is determined to be transmitted through the wireless backhaul device.

Therefore, according to the present invention, a multi-channel MAC function can be implemented through a general processor, so that it can be easily applied to MIMO (Multi Input Multi Output) applied to high-speed data communication in a wireless environment.

FIG. 1 illustrates an environment in which a GPS-based synchronous wireless backhaul apparatus according to an embodiment of the present invention is applied.
2 is a structural diagram of a synchronization signal transmitting apparatus according to an embodiment of the present invention.
3 is a structural view of a processor unit according to an embodiment of the present invention.
4 is a structural view of a logic unit according to an embodiment of the present invention.
5 is an operational flowchart of a processor unit according to an embodiment of the present invention.
6 is a flowchart illustrating an operation of a logic unit according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

In this specification, a terminal includes a mobile station (MS), a mobile terminal (MT), a subscriber station (SS), a portable subscriber station (PSS) An access terminal (AT), and the like, and may include all or some of functions of a mobile terminal, a subscriber station, a mobile subscriber station, a user equipment, and the like.

In this specification, a base station (BS) is an access point (AP), a radio access station (RAS), a node B, a base transceiver station (BTS) Mobile Multihop Relay) -BS, and may include all or some of the functions of an access point, a radio access station, a Node B, a base transceiver station, and an MMR-BS.

Hereinafter, a system and method for transmitting a synchronization signal in a wireless backhaul apparatus having a multi-channel transmission scheme according to an embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 1 illustrates an environment in which a GPS-based synchronous wireless backhaul apparatus according to an embodiment of the present invention is applied.

As shown in FIG. 1, the GPS satellite 100 transmits a GPS signal to a land station 200 or a terminal 300 'while circulating a specific orbit of the universe. In the embodiment of the present invention, for convenience of explanation, the GPS satellite 100 transmits a GPS signal to the central station 200, but the present invention is not limited thereto.

The central station 200 has a built-in synchronization signal transmission device 400 (not shown) and generates a GPS-based synchronization signal to transmit and receive data to and from the terminals 300 and 300 '. Herein, the synchronous signal transmitting apparatus 400 transmits a signal using a MIMO (Multi Input Multi Out) transmission method. For this purpose, in the embodiment of the present invention, a signal is transmitted through two channels, But it is not necessarily limited thereto.

When the central station 200 transmits data to the terminals 300 and 300 ', data is transmitted through the MAC function in the wireless backhaul apparatus. The wireless backhaul device and the MAC function are already known and will not be described in detail in the embodiments of the present invention.

A structure of a synchronous signal transmitting apparatus 400 for generating a synchronous signal in such an environment and transmitting data to the terminals 300 and 300 'based on the generated synchronous signal will be described with reference to FIG.

2 is a structural diagram of a synchronization signal transmitting apparatus according to an embodiment of the present invention.

As shown in FIG. 2, when the synchronization signal transmitting apparatus 400 confirms that the Ethernet packet to be transmitted to one or more terminals is transmitted through the wireless backhaul apparatus, the synchronization signal transmitting apparatus 400 generates an Ethernet packet as a wireless backhaul packet, A processor unit 410 for selecting a channel to be transmitted and transmitting the wireless backhaul packet through a selected channel based on register information of a buffer and a wireless backhaul packet transmitted from the processor unit 410 based on a signal transmitted from a GPS satellite And a logic unit 420 for controlling the processor unit 410 to transmit the generated synchronization signal to one or more terminals through the selected channel.

That is, if the processor unit 410 confirms that the Ethernet packet to be transmitted to the terminals 300 and 300 'is transmitted through the wireless backhaul apparatus, the processor unit 410 inserts the MAC header for the wireless backhaul into the Ethernet packet and transmits the MAC header to the logic unit 420 do. Here, the processor unit 410 transmits the Ethernet packet to the logic unit 420 through two channels. The detailed structure of the processor unit 410 will be described first with reference to FIG.

3 is a structural view of a processor unit according to an embodiment of the present invention.

3, the processor unit 410 includes a packet processing unit 411, a MAC processing unit 412, and a channel selection unit 413. [

The packet processing unit 411 processes an Ethernet packet to be transmitted to the terminals 300 and 300 '. Then, it decides whether to transmit an Ethernet packet to be transmitted to the terminal 300 or 300 'using an Ethernet device or a wireless backhaul device. Here, it is known that the Ethernet processing unit 411 determines a method of processing an Ethernet packet or a transmission means, and a detailed description thereof will be omitted in the embodiment of the present invention.

The MAC processing unit 412 inserts the MAC header for the wireless backhaul into the Ethernet packet processed by the packet processing unit 411. The MAC header for the wireless backhaul includes packet type information indicating whether it is an Ethernet packet or a packet for a wireless backhaul, a serial number for the packet, and identification information of the terminal to which the packet is to be transmitted.

The channel selection unit 413 interlocks with the logic unit 420 and delivers the wireless backhaul packet having the MAC header inserted therein to the logic unit 420 in the MAC processing unit 412. At this time, the channel selection unit 413 selects a channel to transmit a wireless backhaul packet among a plurality of channels, and transmits a wireless backhaul packet to the logic unit 420 through the selected channel.

In the exemplary embodiment of the present invention, the transmission of the wireless backhaul packet using the first channel and the second channel, which are two channels, is described as an example. The channel selection unit 413 selects the transmission path of the temporarily stored wireless backhaul packet It is divided into two. In the embodiment of the present invention, the first channel is selected first and then the wireless backhaul packet is alternately transmitted to the second channel. However, the present invention is not limited thereto.

The channel selection unit 413 includes a data storage area for temporarily storing a wireless backhaul packet into which a MAC header for a wireless backhaul is inserted and a buffer storage unit 422-2 and 423-3 of a logic unit 420, And a register checking area for periodically reading the register values stored in the buffer units 422-1 and 423-1 according to a preset period to check the empty space of the buffer units 422-1 and 423-1.

Therefore, the channel selector 413 selects the position (i) of the buffer unit of the first buffer unit 422-1 or the second buffer unit 423-1 in which the wireless backhaul packet is to be stored based on the read register value, And transmits the channel number and the position information, which are channel information to be transmitted, to the logic unit 420 together with the wireless backhaul packet. When the buffer units 422-1 and 423-1 are filled with packets, the channel is changed so that the wireless backhaul packets are transmitted to the other buffer units 422-1 and 423-1.

The logic unit 420 of FIG. 2 receives a radio backhaul packet including a MAC header transmitted from the processor unit 410 through two channels, and generates a scheduler, a CRC, And performs a data transmission function. The detailed structure of the logic unit 420 will be described with reference to FIG.

4 is a structural view of a logic unit according to an embodiment of the present invention.

4, the logic unit 420 includes an interface unit 421, a first signal transmission unit 422, a second signal transmission unit 423, and a synchronization generation unit 424. The first signal transmission unit 422 and the second signal transmission unit 423 are connected to the buffer units 422-1 and 423-1, the buffer processing units 422-2 and 423-2, and the synchronous transfer unit 422- 3, 423-3).

The interface unit 421 receives a radio backhaul packet in which a MAC header transmitted through two channels is inserted through the channel selection unit 413 of the processor unit 410, So that the wireless backhaul packet is temporarily stored in the location (i).

Since the wireless backhaul packet is transmitted through two channels in the embodiment of the present invention, the wireless backhaul packet transmitted through the first channel is stored in the first buffer unit 422-1 of the first signal transmission unit 422 And the wireless backhaul packet transmitted through the second channel is stored in the second buffer unit 423-1 of the second signal transmission unit 423. [ In the embodiment of the present invention, the buffer units 422-1 and 423-1 will be described by taking as an example the case of using multiple buffers each having 64 buffers each having a capacity of 2KB, but the present invention is not limited thereto.

Upon receiving the GPS signal transmitted from the GPS satellite 100, the synchronization generating unit 424 generates a synchronization signal for transmitting the wireless backhaul packet to the terminals 300 and 300 'using the clock signal synchronized with the GPS signal To the first buffer processing unit 422-2 and the second buffer processing unit 423-2, respectively. At this time, the synchronization signal is generated as a signal for distinguishing the downlink interval and the uplink interval. The GPS signal is assumed to be 1 PPS (Pulse Per Second) signal, and the clock signal synchronized with the GPS signal is assumed to be a clock signal having a signal amplitude of 40 MHz.

The first buffer processor 422-2 receives the storage location information for storing the wireless backhaul packet from the channel selector 413 and updates the register information. At this time, the wireless backhaul packet is a packet transmitted through the first channel. In addition, based on the synchronization signal generated by the synchronization generating unit 424, the wireless backhaul packet temporarily stored in the first buffer unit 422-1 is transmitted to the first synchronization transmitting unit 422-3.

The first buffer processor 422-2 notifies the synchronization generator 424 of which buffer in the first buffer 422-1 is empty by setting register information indicating the presence or absence of data in each buffer as a bit value And stores it. When the wireless backhaul packet is processed by the first synchronization transmitting unit 422-3 and the changed register information is received, the stored register information is updated. This will be described in detail later.

The second buffer processor 423-2 receives the storage location information to store the wireless backhaul packet from the channel selector 413 and updates the register information. At this time, the wireless backhaul packet is a packet transmitted through the second channel. In addition, based on the synchronization signal generated by the synchronization generation unit 424, the wireless backhaul packet temporarily stored in the second buffer unit 423-1 is transmitted to the second synchronization transmission unit 423-3.

The second buffer processor 423-2 notifies the synchronization generator 424 which buffer of the second buffer 423-1 is empty by setting register information indicating the presence or absence of data in each buffer to a bit value And stores it. When the wireless backhaul packet is processed by the second synchronization transmitting unit 423-3 and the changed register information is received, the stored register information is updated. This will be described in detail later.

The first synchronous transmission unit 422-3 receives the wireless backhaul packet from the first buffer processing unit 422-2 and transmits it to the modem (not shown) in the base station 200 and transmits it to the terminals 300 and 300 ' . When the wireless backhaul packet is transmitted, the controller 410 changes the register information to inform the processor unit 410 that the buffer in which the wireless backhaul packet has been stored is empty, and transmits the changed information to the first buffer processor 422-2.

The second synchronous transmission unit 423-3 receives the wireless backhaul packet from the second buffer processing unit 423-2 and transmits it to the modem (not shown) in the base station 200 and transmits it to the terminals 300 and 300 ' . When the wireless backhaul packet is transmitted, the controller 420 changes the register information to inform the processor unit 410 that the buffer in which the wireless backhaul packet was stored is empty, and transmits the changed information to the second buffer processor 423-2.

The operation flow of the processor unit 410 and the logic unit 420 will be described with reference to FIGS. 5 and 6. FIG.

FIG. 5 is an operation flowchart of a processor unit according to an embodiment of the present invention, and FIG. 6 is an operation flowchart of a logic unit according to an embodiment of the present invention.

5, the Ethernet processing unit 411 of the processor unit 410 determines whether Ethernet packets to be transmitted to the terminals 300 and 300 'are to be transmitted using Ethernet or through a wireless backhaul apparatus . The determination of the transmission means is already known, and a detailed description thereof will be omitted in the embodiment of the present invention. If it is determined that the packet is to be transmitted through the wireless backhaul device, the MAC processor 412 inserts a MAC header for the wireless backhaul into the Ethernet packet to generate a wireless backhaul packet (S100).

When a wireless backhaul packet is generated, the channel selector 413 transmits a wireless backhaul packet to the logic unit 420 at a preset period. Before transmitting the wireless backhaul packet to the logic unit 420, the channel selector 413 checks the register information stored in the two buffer processors 422-2 and 423-2 to determine which one of the buffer units 421 After confirming that the location is empty, a channel capable of transmitting a wireless backhaul packet to a buffer empty area is selected (S101). If the wireless backhaul packet is transmitted for the first time, the first channel is preferentially selected.

Assuming that the channel selector 413 selects the first channel, the channel selector 413 selects the first buffer 422-i of the first signal transmitter 422 to receive the wireless backhaul packet through the first channel, 1) (step S102). It is checked whether all the buffers of the first buffer unit 422-1 are occupied (S103). If the occupied state is not occupied, a storage location for storing the wireless backhaul packet is generated (S104) And transmits the packet to the logic unit 420 (S105).

However, if it is determined in step S103 that the entire buffer is occupied, the second buffer unit 423 of the second signal transmission unit 423, which receives the wireless backhaul packet through the second channel, -1) and confirms whether the buffers of the second buffer unit 423-1 are all occupied (S106, S107). As a result of checking in step S107, if all the buffers of the second buffer unit 423-1 are occupied, the channel selection unit 413 temporarily stores the wireless backhaul packet to be transmitted, and after a predetermined time, Re-execute the procedure of

However, if it is determined in step S107 that all the buffers of the second buffer unit 423-1 are not occupied, the storage location information is generated so that the wireless backhaul packet is stored in the empty buffer, and the wireless backhaul packet is transmitted to the logic unit 420 (S108, S109).

For example, if the first buffer unit 422-1 or the second buffer unit 423-1 including 64 buffers is occupied by a packet, the buffer occupancy in steps S103 and S107 will be described. If the register information is 111111 ... 111, respectively. At this time, one bit corresponds to one buffer. However, if any one of the buffers is empty, then 101110001 ... 110, the bit value is set to 0 instead of 1 at the position of the empty buffer. Therefore, the channel selection unit 413 can check the position of the empty buffer only by using the register information.

And 101110001 ... Based on register information like 110, 0, 2, 3, 4, ... , The 62nd buffer is occupied and 1, 5, 6, 7, ... If it is confirmed that the 63rd buffer is empty, the channel selection unit 413 generates the storage location information, i.e., BD_VALID (1), to store the wireless backhaul packet in the first buffer. And transmits the created storage location information, channel information to be used when transmitting the packet, and the wireless backhaul packet to the logic unit 420. In the embodiment of the present invention, the channel information is '00' for the first channel and '01' for the second channel. However, the present invention is not limited thereto.

The operational flow of the logic unit 420 receiving the wireless backhaul packet, the channel information, and the storage location information will be described with reference to FIG.

As shown in FIG. 6, when a synchronization signal is generated based on a signal transmitted from a GPS in the synchronization generation unit 424 (S200), each of the buffer processing units 422-2 and 423-2 generates register information and channel information (S211, S221). Then, based on the confirmed channel information and the register information, the position information of the buffer whose bit value is set to 1 is confirmed (S212, S222). When the bit value is set to 1, it means that there is a packet to be transmitted to the buffer.

Accordingly, the wireless backhaul packet stored in the buffer whose bit value is set to 1 is received from the buffer units 422-1 and 423-1, and the received wireless backhaul packet is synchronized with the synchronization signal generated by the synchronization generator 424 And transmits it to the modem 300 and 300 '(S213 and S223). The register information is updated (S214, S215, S224, and S225) so that the processor unit 410 can recognize that the buffer in which the transmitted wireless backhaul packet is stored is empty.

That is, if the wireless backhaul packet stored in the buffer # 1 is transmitted, the synchronous transmission units 422-3 and 423-3 update the register information for the buffer # 1 set to 1 to 0, -2, 423-2. This procedure is repeated when the state in which the packet can be transmitted by the synchronous signal is ON, and ends when the packet transmission state is changed to OFF.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

Claims (11)

A synchronous signal transmission system for interworking with a GPS satellite and at least one terminal,
If it is confirmed that the Ethernet packet to be transmitted to one or more terminals is transmitted through the wireless backhaul device, the Ethernet packet is generated as a wireless backhaul packet, a channel to transmit the generated wireless backhaul packet is selected, A processor for transmitting the wireless backhaul packet through the selected channel; And
A logic unit for controlling the wireless backhaul packet transmitted from the processor unit to be transmitted to the at least one terminal through the selected channel using a synchronization signal generated based on a signal transmitted from the GPS satellite;
/ RTI >
The processor unit,
A packet processor for determining whether to transmit an Ethernet packet to be transmitted to the one or more terminals through an Ethernet device or a wireless backhaul device;
A MAC processor for inserting a MAC header for a wireless backhaul into the Ethernet packet to generate a wireless backhaul packet when the packet processor determines that the Ethernet packet is to be transmitted using a wireless backhaul device; And
A wireless base station for temporarily storing the wireless backhaul packet generated by the MAC processor, selecting a channel for transmitting the wireless backhaul packet among the at least one channel, and interworking with the logic unit to transmit the wireless backhaul packet as a packet to an unoccupied buffer And to transmit the storage location information and the wireless backhaul packet to the logic unit to transmit the selected location information through the selected channel,
Lt; / RTI >
The logic unit includes:
A wireless backhaul packet interworking with the channel selection unit and including a MAC header transmitted through a plurality of channels is received and a wireless backhaul packet is temporarily stored in a buffer location where the received wireless backhaul packet is to be stored ; A first signal transmission unit for storing a wireless backhaul packet transmitted through a first channel, which is one of the plurality of channels, and transmitting the stored wireless backhaul packet to the plurality of terminals using the synchronization signal; A synchronization generator for generating a synchronization signal for transmitting the wireless backhaul packet using a clock signal synchronized with a signal transmitted from the GPS satellite; And a second signal transmission unit configured to store a wireless backhaul packet transmitted through a second channel, which is one of the plurality of channels, and transmit the stored wireless backhaul packet to the plurality of terminals using a synchronization signal generated in the synchronization generation unit And a synchronous signal transmission section.
delete The method according to claim 1,
Wherein the first signal transmitter comprises:
A first buffer unit for storing the wireless backhaul packet received from the channel selection unit in a buffer corresponding to the storage location information;
When a synchronization signal is generated from the synchronization generation unit, checks the stored register information to confirm a buffer in which a wireless backhaul packet is stored, and receives a wireless backhaul packet stored in the checked buffer from the first buffer unit A first buffer processor; And
A controller for controlling to transmit the wireless backhaul packet transmitted from the first buffer processor to one of the one or more terminals through the first channel and for transmitting the wireless backhaul packet to the terminal, A first synchronous transfer unit for updating the bit value of the register information and transferring the bit value to the buffer processor,
And a synchronous signal transmission system. The method of claim 3,
Wherein the second signal transmission unit comprises:
A second buffer for storing the wireless backhaul packet received from the channel selector in a buffer corresponding to the storage location information;
When a synchronization signal is generated from the synchronization generation unit, confirms the stored register information and confirms the buffer in which the wireless backhaul packet is stored, and receives the wireless backhaul packet stored in the checked buffer from the second buffer unit A second buffer processing unit for performing a second decoding process; And
And a controller for controlling to transmit the wireless backhaul packet transmitted from the second buffer processor to one of the one or more terminals through the second channel and to transmit the wireless backhaul packet to the buffer, A second synchronous transfer unit for updating the bit value of the register information and transmitting the updated bit value to the buffer processor,
And a synchronous signal transmission system. 5. The method of claim 4,
Wherein the first buffer unit and the second buffer unit are multiple buffers each comprising one or more buffers,
Wherein the first buffer processing unit and the second buffer processing unit store and update register information set to a bit value so that the channel selection unit can confirm whether the at least one buffer is occupied by a packet. A method for a synchronous signal transmission system in a wireless backhaul apparatus to transmit a synchronization signal to one or more terminals,
Wherein the processor unit of the synchronous signal transmission system generates a wireless backhaul packet to be transmitted to the one or more terminals and selects a first channel to transmit the generated wireless backhaul packet;
Confirming first register information to receive a wireless backhaul packet through the selected first channel among a plurality of registers of a logic unit interlocked with the processor unit to confirm whether the first buffer unit is occupied;
Confirming second register information to receive a wireless backhaul packet through a second channel different from the first channel if the entire first buffer is occupied, and checking whether the second buffer is entirely occupied;
Transmitting location information for storing the wireless backhaul packet and channel information for the second channel to the logic unit together with the wireless backhaul packet if the empty buffer is present in the second buffer unit; And
The logic unit stores the received wireless backhaul packet in a buffer corresponding to the location information, and when a synchronization signal is generated using a clock signal synchronized with a signal transmitted from a GPS satellite, And transmitting the synchronous signal to the terminal while the synchronous signal is generated using two channels
And transmitting the synchronization signal. The method according to claim 6,
Wherein the step of checking whether the entire first buffer unit is occupied,
Generating position information to be stored in the empty buffer when the buffer is empty in the first buffer unit and transmitting the generated position information to the logic unit together with the first channel information and the wireless backhaul packet;
And transmitting the synchronization signal. The method according to claim 6,
Wherein the step of checking whether the entire second buffer unit is occupied,
If the entire second buffer is occupied, the processor temporarily stores the wireless backhaul packet
And transmitting the synchronization signal. The method according to claim 6,
The method of claim 1,
Confirming register information stored in the logic unit and checking whether a wireless backhaul packet to be transmitted to the terminal is stored when the synchronization signal is generated;
When a wireless backhaul packet is stored, transmitting a wireless backhaul packet to the terminal through a channel selected by a processor unit of the synchronous signal transmitting system interlocked with the logic unit while the synchronous signal is generated; And
Updating the register information stored in the logic unit so that the bit value of the register information corresponding to the buffer in which the wireless backhaul packet is stored is updated
And transmitting the synchronization signal. 10. The method of claim 9,
Before the step of verifying that the wireless backhaul packet is stored,
Storing the wireless backhaul packet transmitted from the processor unit in a buffer corresponding to the location information; And
Updating the register information stored in the logic unit so that the register information of the buffer in which the wireless backhaul packet is stored is updated according to the positional information
And transmitting the synchronization signal. The method according to claim 6,
Before the step of selecting the first channel,
Determining whether to transmit a packet to be transmitted to the terminal through a wireless backhaul apparatus; And
If it is determined that the packet is to be transmitted through the wireless backhaul device, generating a wireless backhaul packet by inserting a MAC header for a wireless backhaul into the packet
And transmitting the synchronization signal.

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