KR101112005B1 - Synchronizing apparatus and method of asynchronous ethernet network - Google Patents

Abstract

The present disclosure relates to a synchronization device and a method thereof in an asynchronous Ethernet network, and includes a switch supporting a network connection and a network data including 3G and WiBro of a lower network terminal connected to each port provided in the switch through a 1588 processor. One or more femtocells that support transmission and reception, a GPS receiver that receives GPS signals, a 1588 grandmaster that generates and outputs IEEE 1588 sync packets based on GPS time information input from the GPS receiver, and each port of the switch Connected between the femtocells described above, the IEEE 1588 sync packet received from the 1588 grandmaster is converted into a broadcast sync packet and output to the switch, and the input time information of the IEEE 1588 sync packet received from the 1588 grandmaster and the switch IEEE 1588 Sink Packets from Each Port Calculate the residence time value delayed in the switch and the internal time by using the output time information of, and update the residence time value calculated for each port by adding it to the correction area value of the IEEE 1588 sync packet received from the 1588 grandmaster. And a 1588 processor for outputting the IEEE 1588 sync packet to one or more femtocells to synchronize time with the GPS receiver.
Therefore, the present invention configures a network supporting IEEE 1588 by attaching a 1558 processor to a non-IEEE 1588 network device, thereby eliminating the need for additional expensive GPS equipment in order to synchronize the time of the network. Synchronous network can be constructed inexpensively and conveniently around master GPS without changing equipment.

Description

Synchronizing apparatus and method of asynchronous ethernet network

The present invention relates to an apparatus and a method for synchronizing in an asynchronous Ethernet network.

In general, the femto cell, which is a small mobile communication base station installed inside a home or office and connected to a mobile communication core network through a broadband network, expands indoor coverage, improves call quality, and efficiently provides various wired / wireless convergence services. It has the advantage of being able to provide.

Accurate time information is required to construct a femtocell, which is such a small mobile repeater. That is, as shown in FIG. 2 in a general network structure in which a wide area network (WAN) 2 and a local area network (LAN) 3 are connected through a switch device 1 as shown in FIG. As described above, a method of configuring a femtocell network by connecting the GPS receiver 4 to each of the femtocells 5 and receiving accurate time information from the GPS receiver 4 is a general method of configuring a femtocell network based on a synchronization signal.

As such, in order to support the time synchronization function, which is the most basic function in a mobile communication network, a GPS interworking function is required in femtocell units. However, femtocells, which have the advantage of being able to receive various services at low rates while using existing terminals, have a problem in that an expensive GPS antenna and a GPS-based time synchronization module need to be installed in each femtocell. As a result, the cost is increased and the femtocell service is not activated despite the many advantages of the femtocell.

In addition, since the Ethernet network for the existing Internet service is an asynchronous network, synchronization-based services such as femtocells are not possible. In order to solve this problem, expensive GPS equipment should be installed for each device requiring service or Ethernet-based network should be changed to a network supporting synchronous protocol. However, in order to change the network itself in the conventional manner, it is necessary to replace the various network equipment installed for each network layer, and in this case, there is a problem in that a lot of costs are incurred, which impedes service provision.

And because of its inherent asynchronous nature, Ethernet networks cannot handle accurate synchronization events at remote locations. To address this problem, the Institute of Electrical and Electronics Engineers (IEEE) has released a time synchronization standard adopted by some industrial control companies and equipment vendors. Called IEEE 1588, the standard provides a protocol that allows devices to utilize the most precise and accurate clocks on the network. However, even if the end-to-end device supporting the IEEE 1588 function is used to construct a network supporting the IEEE 1588 function, the time delay caused by the network equipment that does not support the IEEE 1588 function existing on the network cannot be calculated. Therefore, there was a realistic problem that the function of IEEE 1588 could not be supported.

An object of the present invention is to solve the above problems, the time caused by non-IEEE 1588 network equipment (existing switches, routers, etc.) when attempting to change the asynchronous network Ethernet network to a synchronous network conforming to the IEEE 1588 standard The present invention provides a synchronization device and method for an asynchronous Ethernet network that corrects an error to conform to the IEEE 1588 standard without changing an existing network.

Another object of the present invention is to support the IEEE 1588 function, which is a time synchronization standard for the Ethernet network, thereby minimizing the cost and service disconnection problems caused by the installation of the GPS facility or the change of the network facility itself, and the existing network at a low cost. To provide an apparatus and method for synchronizing in an asynchronous Ethernet network to support IEEE 1588.

Synchronization apparatus in an asynchronous Ethernet network according to an embodiment of the present invention for achieving this object, the switch is provided with a plurality of ports to support the network connection, connected to each port provided in the switch through the 1588 processor lower One or more femtocells that support the transmission and reception of network data including 3G and WiBro of the network terminal, a GPS receiver that receives GPS signals from satellites, and a GPS receiver connected to the GPS receiver, based on GPS time information input from the GPS receiver. A 1588 grandmaster that generates and outputs an IEEE 1588 sync packet, and is connected between each port of the switch and one or more femtocells, and converts the IEEE 1588 sync packet received from the 1588 grandmaster into a broadcast sync packet. To the 1588 Grandmaster. Based on the received time information of the received IEEE 1588 sink packet and the time information of the output time of the IEEE 1588 sink packet input from each port of the switch, the delayed residence time value is calculated in the switch and internally. A value added to the correction range value of the IEEE 1588 sync packet received from the 1588 grandmaster, and a 1588 processor for outputting the updated IEEE 1588 sync packet to one or more femtocells to synchronize with the GPS receiver. Can be.

In addition, the synchronization method in an asynchronous Ethernet network according to an embodiment of the present invention, (1) 1588 port provided in the switch and 1588 processor connected between a plurality of LAN ports and one or more femtocells, 1588 connected to the GPS receiver Storing input time information of the IEEE 1588 sync packet received from the grandmaster; and (2) the 1588 processor is configured to broadcast the IEEE 1588 sync packet of the unicast type received from the 1588 grandmaster. Converting to a sync packet and outputting the same to the 1588 port of the switch, and (3) the switch broadcasts an IEEE 1588 sink packet in a broadcast form input from the 1588 processor to each LAN port included in the switch, Outputting an IEEE 1588 sync packet to each 1588 processor through each LAN port, and (4) the 1588 processor is the IEEE 15 stored in step (1). From the GPS receiver, using the input time information of the 88 sync packet and the output time information of one or more femtocells requiring time synchronization of the IEEE 1588 sync packet inputted from each LAN port of the switch through step (3). Calculating residence time value for each LAN port from input point to just before output to femtocell through switch, and (5) 1588 processor calculates residence time value for each LAN port calculated through (4). After updating the correction area value in addition to the correction area value of the IEEE 1588 sync packet received from the 1588 grandmaster, the updated IEEE 1588 sink packet is output to each femtocell connected to the lower level to synchronize the time with the GPS receiver. May include a step of fitting.

As described above, according to the synchronization device and the method of the asynchronous Ethernet network of the present invention, when configuring a network that supports the IEEE 1588 standard made to support the synchronization function in the asynchronous Ethernet network, non-IEEE 1588 network equipment The 1558 processor is built in the network to support IEEE 1588, which provides an IEEE 1588 network without changing the structure and equipment of non-IEEE 1588 networks such as switches and routers. There is no need to install additional.

In addition, the 1588 processor that supports IEEE 1588 functionality can support IEEE 1588 functionality without changing the existing network and related equipment, so when applied to larger-scale backbone networks composed of time-synchronous small networks such as femtocells In addition, it is possible to construct a synchronous network inexpensively and conveniently around a master GPS without changing existing networks and related equipment.

1 is a diagram illustrating a general network structure.
2 is a diagram illustrating a general synchronization signal based femtocell network structure.
3 is a view showing in detail the configuration of a synchronization device in an asynchronous Ethernet network according to the present invention.
4 is a diagram illustrating a structure of a unicast sync packet according to the present invention.
5 is a flowchart illustrating in detail the operation of the synchronization method in the asynchronous Ethernet network according to the present invention.

Hereinafter, a synchronization apparatus and a method thereof in an asynchronous Ethernet network of the present invention will be described in detail with reference to the accompanying drawings.

3 is a view showing in detail the configuration of a synchronization device in an asynchronous Ethernet network according to the present invention, Figure 4 is a view showing the structure of a unicast sync packet applied to the present invention.

As shown in FIG. 3, the synchronization device of the present invention installs a 1588 processor 30 supporting IEEE 1588 in an existing network and each femtocell 50 from one GPS receiver 10 through a 1588 processor 30. A network that transmits a synchronization signal to the network is configured as a GPS receiver 10, a 1588 grandmaster 20, a 1588 processor 30, a switch 40, a first to n-th femtocell 50, and the like. .

The GPS receiver 10 receives the GPS signal from the satellite and outputs the GPS signal to the 1588 grandmaster.

The 1588 grandmaster 20 is connected to the GPS receiver 10 and generates an unicast IEEE 1588 sync packet based on the GPS time information input from the GPS receiver 10 and outputs it to the 1588 processor 30.

The 1588 processor 30 is connected between a 1588 input / output port and a plurality of LAN ports and one or more femtocells 50 provided in the switch 40, and is a unicast IEEE 1588 received from the 1588 grandmaster 20. The sync packet is converted into a broadcast sync packet, and then output to the 1588 port of the switch 40 to be broadcast to each LAN port of the switch 40. Then, by using the input time information of the IEEE 1588 sync packet received from the 1588 grandmaster 20 and the output time information of the IEEE 1588 sync packet input from each port of the switch 40 to each femtocell 50. The residence time value delayed in the switch 40 and internally is calculated, and the residence time value calculated for each port is added to the correction region value of the IEEE 1588 sync packet received from the 1588 grandmaster 20, and updated. The 1588 sync packet is output to one or more femtocells 50 to synchronize with the GPS receiver 10.

The switch 40 is provided with a 1588 input and output ports and a plurality of LAN ports, and supports a network connection.

The first to n th femtocells 50 are 1588 slave devices, and are connected to each port provided in the switch 40 through the 1588 processor 30 so that 3G (3 Generation) of the lower network terminal is moved to the third generation of the International Telecommunication Union. Communication technology standard), and supports transmission and reception of network data including WiBro. In this case, the first to nth femtocells 50 update the original timestamp value recorded in the IEEE 1588 sink packet input from the 1588 processor 30 by the updated IEEE 1588 input from the 1588 processor 30 for each port. The final correction area value is obtained by adding the correction area value of the sync packet, the local time information progressed by the previous IEEE 1588 sync packet is compared, and the local time information is updated based on the comparison result to synchronize the time with the GPS receiver. Fit.

In addition, the above-described 1588 processor 30 includes a master module 32 and first to nth submodules 34.

The master module 32 is connected to the 1588 grandmaster 20, stores the input time information of the IEEE 1588 sync packet received from the 1588 grandmaster 20, and receives from the 1588 grandmaster 20. A unicast IEEE 1588 sync packet is converted into a broadcast IEEE 1588 sync packet and output to the 1588 port of the switch 40 to be broadcast to each LAN port of the switch 40. Inside the switch 40 and the master module 32 using the input time information of the IEEE 1588 sync packet received from the 20 and the output time information of the IEEE 1588 sync packet input from the specific LAN port of the switch 40. Calculates the delayed dwell time value and updates the calculated dwell time value by adding it to the correction range value of the IEEE 1588 sync packet received from the 1588 grandmaster 20. The 1588 sink packet is outputted to the corresponding femtocell 50 connected below.

At this time, the master module 32 stores the input time information of the IEEE 1588 sync packet received from the 1588 grandmaster 20, and the unicode received from the 1588 master input / output unit 32a. A 1588 switch input / output unit 32b for converting the cast-type IEEE 1588 sync packet into a broadcast-type IEEE 1588 sync packet, and outputting the converted broadcast-type IEEE 1588 sync packet to the 1588 port of the switch 40; LAN switch input / output unit 32c for distinguishing the normal packet and the IEEE 1588 sync packet inputted through a specific LAN port of the switch 40 and the input time time of the IEEE 1588 sync packet stored in the 1588 master input / output unit 32a. The switch 40 and the mask by using the information on the output time of the IEEE 1588 sync packet input from the specific LAN port of the switch 40 to the specific femtocell 50 through the LAN switch input / output unit 32c. The module 32 calculates the delayed residence time value, updates the calculated residence time value to the correction area value of the IEEE 1588 sink packet stored in the 1588 master input / output unit 32a, and updates the updated IEEE 1588 sink packet. It is composed of a 1588 slave input and output unit (32d) for outputting to a specific femtocell (50) connected to.

The first to nth submodules 34 simultaneously store input time information of the IEEE 1588 sync packets stored in the master module 32, and input time of the IEEE 1588 sync packets received from the 1588 grandmaster 20. The delayed residence time value is calculated in the switch 40 and each submodule 34 by using the time information and time information of the output time of the IEEE 1588 sync packet input from each LAN port of the switch 40, and the calculated residence time is calculated. The time value is added to the correction region value of the IEEE 1588 sync packet received from the 1588 grandmaster 20, and updated, and then the updated IEEE 1588 sync packet is output to each of the femtocells 50 connected below.

At this time, each of the first to n-th submodules 34 includes a 1588 master input / output unit 34a for simultaneously storing input time information of the IEEE 1588 sync packet stored in the master module 32, and a master of the switch 40. IEEE 1588 stored in the LAN switch input / output unit 34c and 1588 master input / output unit 34a for distinguishing the normal packet and the IEEE 1588 sync packet inputted through each LAN port other than the LAN port connected to the module 32. Each femtocell 50 of the IEEE 1588 sync packet inputted from each LAN port other than the LAN port connected to the master module 32 of the switch 40 via the input time information of the sync packet and the LAN switch input / output unit 34c. The delayed residence time value is calculated in the switch 40 and each submodule 34 by using the output time point information of the furnace. Up in addition to area value After the byte is composed of 1588 slave output section (34d) for outputting to each of the femtocell 50 which is connected to the updated packet to the IEEE 1588 sinks lower. Here, the first to nth submodules 34 are the same chip set as the master module 32, but the 1588 switch input / output unit 34b does not perform a function.

Next, an embodiment of a synchronization method in an asynchronous Ethernet network according to the present invention configured as described above will be described in detail with reference to FIG.

5 is a flowchart illustrating in detail the operation of the synchronization method in the asynchronous Ethernet network according to the present invention.

First, the 1588 port provided in the switch 40 and the 1588 processor 30 connected between the plurality of LAN ports and one or more femtocells 50 are connected to the GPS receiver 10 via the master module 32. An IEEE 1588 sync packet in a unicast form is received from the master device 20 (S10), and input time information T1 of the received IEEE 1588 sync packet is stored (S20).

At this time, the input time information T1 of the IEEE 1588 sync packet stored in the master module 32 of the 1588 processor 30 through the step S20 is simultaneously stored in the first to nth submodules 34.

After storing the input time information T1 of the IEEE 1588 sync packet through step S20, the 1588 processor 30 receives the unicast IEEE 1588 received from the 1588 grandmaster 20 through the master module 32. The sync packet is converted into a broadcast type IEEE 1588 sync packet (S30), and the converted broadcast type IEEE 1588 sync packet is output to the 1588 port of the switch 40 (S40).

The switch 40 which receives the broadcast type IEEE 1588 sink packet from the master module 32 of the 1588 processor 30 receives each broadcast LAN port (LAN) included in the switch 40. Broadcasted to # 0 to LAN #N (S50), and the broadcasted IEEE 1588 sink packet is transmitted through each LAN port to the master module 32 and the first to nth submodules 34 of the 1588 processor 30. It is output as (S60).

The master module 32 and the first to nth submodules 34 of the 1588 processor 30 that receive the IEEE 1588 sync packet from each LAN port included in the switch 40 are configured to perform time synchronization of the IEEE 1588 sync packet. The output time point information T2 to the one or more femtocells 50 required are checked (S70).

Thereafter, the master module 32 and the first to n-th submodules 34 of the 1588 processor 30 use the GPS receiver 10 by using the time point information T2 outputting the IEEE 1588 sync packet to the femtocell 50. Inside the master module 32 and the first to nth submodules 34 of each LAN port of the switch and the 1588 processor 30 from the time point inputted from the input point to the femtocell 50 via the switch 40. Calculate the residence time value (RT) spent at (S80).

In addition, the master module 32 and the first to n-th submodules 34 of the 1588 processor 30 receive the residence time value RT calculated through the step S80 and the IEEE 1588 received from the 1588 grandmaster 20. Update the correction area value C2 of the IEEE 1588 sync packet by adding the current correction area value C1 of the sync packet (S90), and output the updated IEEE 1588 sync packet to each femtocell 50 connected to the lower part. (S100).

Each femtocell 50 that receives the IEEE 1588 sync packet including the updated correction area value C2 from the 1588 processor 30 is the first time stamp recorded in the IEEE 1588 sync packet input from the 1588 processor 30. origin timestamp) value is checked (S110).

After confirming the initial time stamp value, each femtocell 50 obtains the final correction area value by adding the confirmed initial time stamp value and the correction area value C2 of the updated IEEE 1588 sync packet input from the 1588 processor 30. Thereafter, it compares the local time information progressed by the previous IEEE 1588 sync packet (S120).

Each femtocell 50 updates local time information based on the comparison result of step S120 to synchronize time with the GPS receiver 10 (S130).

Accordingly, by installing only one additional master GPS device in a network that does not support IEEE 1588, GPS time information is transmitted through the existing network where GPS and time synchronization are required, so that the network time synchronization can be made inexpensively and conveniently. It becomes possible.

Herein, while the present invention has been described with reference to the preferred embodiments, those skilled in the art will variously modify the present invention without departing from the spirit and scope of the invention as set forth in the claims below. And can be changed.

10: GPS receiver
20: 1588 Grandmaster
30: 1588 processor
32: master module
34: first to nth submodule
32a, 34a: 1588 master input / output unit
32b, 34b: 1588 switch input and output
32c, 34c: LAN switch input and output
32d, 34d: 1588 slave I / O
40: switch
50: 1st to nth femtocell

Claims (7)

Switch with multiple ports to support network connections,
One or more femtocells connected to each port provided in the switch through a 1588 processor to support transmission and reception of network data including 3G (3 Generation, 3rd generation mobile communication technology standard) and WiBro of lower network terminals;
A GPS receiver for receiving GPS signals from satellites,
A 1588 grandmaster connected to the GPS receiver for generating and outputting a unicast IEEE 1588 sync packet based on GPS time information input from the GPS receiver, and
Connected between each port of the switch and the one or more femtocells, converts an IEEE 1588 sync packet received from the 1588 grandmaster into a broadcast sync packet, outputs the broadcast sync packet to the switch, and receives from the 1588 grandmaster Based on the time information of the IEEE 1588 sync packet and the time information of the IEEE 1588 sink packet input from each port of the switch, the delay time value of the switch and the internal delay is calculated, and the residence calculated for each port. 1588 for updating the time value to the correction area value of the IEEE 1588 sync packet received from the 1588 grandmaster, and outputting the updated IEEE 1588 sync packet to the one or more femtocells to synchronize with the GPS receiver. Handler
Synchronizer in asynchronous Ethernet network, including. The method of claim 1,
The one or more femtocells,
A final correction region value is obtained by adding an original timestamp value recorded in the IEEE 1588 sink packet input from the 1588 processor to the correction region value of the updated IEEE 1588 sink packet input from the 1588 processor for each port, And comparing the local time information progressed by the previous IEEE 1588 sync packet, and updating the local time information based on the comparison result to synchronize the time with the GPS receiver. The method of claim 1,
The 1588 processor,
Is connected to the 1588 grandmaster, stores input time information of the IEEE 1588 sync packet received from the 1588 grandmaster, and broadcasts the unicast IEEE 1588 sync packet received from the 1588 grandmaster. After converting into IEEE 1588 sync packet, it outputs to the 1588 port of the switch to be broadcast to each LAN port of the switch, and input time information of the IEEE 1588 sync packet received from the 1588 grandmaster and the switch Based on the output time information of the IEEE 1588 sync packet input from a specific LAN port, the residence time value delayed in the switch and the inside is calculated, and the calculated residence time value of the IEEE 1588 sync packet received from the 1588 grandmaster. Updated IEEE 1588 Sink Packet after Update in addition to Calibration Area Value A master module for outputting to the corresponding femtocell connected below;
Input time information of the IEEE 1588 sync packet stored in the master module at the same time, and input time information of the IEEE 1588 sync packet received from the 1588 grandmaster and IEEE 1588 sink input from each LAN port of the switch. Calculates the residence time value delayed in the switch and the internal time using the output time point information of the packet, and updates the calculated residence time value by adding it to the correction region value of the IEEE 1588 sync packet received from the 1588 grandmaster. One or more submodules to output the IEEE 1588 sink packet to each femtocell
Synchronizer in asynchronous Ethernet network, including. The method of claim 3, wherein
The master module,
A 1588 master input / output unit for storing input time information of the IEEE 1588 sync packet received from the 1588 grandmaster;
A 1588 switch input / output unit for converting the unicast IEEE 1588 sink packet received by the 1588 master input / output unit into a broadcast type IEEE 1588 sink packet and outputting the same to the 1588 port of the switch;
A LAN switch input / output unit that distinguishes normal packets and IEEE 1588 sink packets that are mixed and input through a specific LAN port of the switch, and
The switch by using the input time information of the IEEE 1588 sync packet stored in the 1588 master input / output unit and the output time information of the IEEE 1588 sync packet input from a specific LAN port of the switch to the femtocell through the LAN switch input / output unit. And calculating a delayed residence time value internally, updating the calculated residence time value by adding it to a correction range value of the IEEE 1588 sync packet stored in the 1588 master input / output unit, and then updating the updated IEEE 1588 sync packet below. 1588 slave I / O part output to femtocell
Synchronizer in asynchronous Ethernet network, including. The method of claim 3, wherein
The one or more submodules,
A 1588 master input / output unit for simultaneously storing input time information of IEEE 1588 sync packets stored in the master module;
A LAN switch input / output unit for distinguishing normal packets and IEEE 1588 sink packets that are mixed and input through each LAN port other than the LAN port connected with the master module of the switch, and
Input time information of the IEEE 1588 sync packet stored in the 1588 master input / output unit and each femtocell of the IEEE 1588 sync packet input from each LAN port other than the LAN port connected to the master module of the switch through the LAN switch input / output unit. Calculates the residence time value delayed in the switch and the internal time using the output time time information of the controller, and updates the calculated residence time value by adding it to the correction region value of the IEEE 1588 sync packet stored in the 1588 master input / output unit. 1588 slave I / O unit for outputting 1588 sink packets to each femtocell connected below
Synchronizer in asynchronous Ethernet network, including. (1) a 1588 processor provided between the 1588 port and a plurality of LAN ports and one or more femtocells in the switch, storing input time information of IEEE 1588 sync packets received from a 1588 grandmaster connected to a GPS receiver; ,
(2) the 1588 processor converting the unicast IEEE 1588 sink packet received from the 1588 grandmaster into a broadcast type IEEE 1588 sync packet and outputting the same to the 1588 port of the switch;
(3) The switch broadcasts the broadcast type IEEE 1588 sink packet input from the 1588 processor to each LAN port included in the switch, and broadcasts the broadcasted IEEE 1588 sink packet through each LAN port. Output to,
(4) The 1588 processor needs time synchronization of the IEEE 1588 sync packet stored in step (1) and the IEEE 1588 sync packet input from each LAN port of the switch through step (3). Calculating residence time values for each LAN port from the time point input from the GPS receiver to the time immediately before being outputted to the femtocell through the switch, using output time time information to the at least one femtocell, and
(5) The 1588 processor updates the correction region value by adding the residence time value for each LAN port calculated in the step (4) to the correction region value of the IEEE 1588 sync packet received from the 1588 grandmaster. And outputting the updated IEEE 1588 sync packet to each femtocell connected to the lower layer to synchronize time with the GPS receiver.
Synchronization method in asynchronous Ethernet network including. The method according to claim 6,
After the step (5),
(6) the one or more femtocells perform a final correction by adding the initial time stamp value recorded in the IEEE 1588 sink packet input from the 1588 processor to the correction region value of the updated IEEE 1588 sink packet input from the 1588 processor for each port. Obtaining an area value, comparing the local time information progressed by the previous IEEE 1588 sync packet, and updating the local time information based on the comparison result to synchronize the time with the GPS receiver. How to sync on

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