KR20150069213A - Method of multi-channeltrafic distribution for management of hybrid cloud system - Google Patents

Abstract

Disclosed is a multi-channel traffic distribution method for an integrated management of a hybrid cloud environment. More particularly, provided are a hybrid cloud-based mobile enterprise application platform service and a method thereof wherein there is no risk of exposure of corporate confidential information. In addition, in order to address the aforementioned object, a dynamic traffic distribution method in a channel boding-type wireless LAN system of the present invention comprises: (A) a flow classification step of extracting flow information from an arriving packet and of classifying the packet by flow units based on the information; (B) a channel state monitoring step of monitoring a state of each of bonded channels; (C) a flow allocation step of allocating the flows classified in the step (A) by referring to the channel state information obtained in the step (B) to an optimal channel wherein the channel bonding-type wireless LAN system is a system which has bonded a wireless LAN having different wireless encryption methods and wherein in the step (A), the arriving packets are classified according to an encryption method associated with each LAN and flow information is extracted from the classified packets.

Description

METHOD OF MULTI-CHANNELTRAFIC DISTRIBUTION FOR MANAGEMENT OF HYBRID CLOUD SYSTEM FOR INTEGRATED MANAGEMENT OF HYBRID CLOUD ENVIRONMENT [0002]

The disclosed technology relates to a multi-channel traffic distribution method for integrated management of a hybrid cloud environment, and more particularly, to a hybrid cloud-based mobile enterprise application platform service and a method thereof without risk of confidential disclosure of the enterprise.

A wireless LAN is a LAN technology that supports the 802.11a / b / g standard established by the IEEE, and is a technology for wirelessly connecting a terminal such as a notebook PC, a PDA, or a mobile phone with a wireless LAN interface to an access point And devices. The wireless LAN supports an infrastructure mode in which an access point can communicate with a plurality of wireless LAN devices, or an ad hoc mode in which devices equipped with a wireless LAN interface temporarily connect and communicate with each other.

The 802.11a / b / g standard allows unlicensed use of the 2.4GHz and 5GHz radio bands, making it easy to build a wireless LAN environment. 802.11a supports maximum speed 54Mbps using 5GHz bandwidth, 802.11b supports maximum speed 11Mbps using 2.4GHz bandwidth, and 802.11g supports maximum speed 54Mbps using 2.4GHz bandwidth. The current 802.11n will support 2.4GHz and 5GHz to support up to 300Mbps.

In 802.11, the available bandwidth is divided into several channels. 13 channels can be used in the 2.4 GHz bandwidth, and 19 channels in the 5 GHz band. There are three non-overlapping channels that can be used simultaneously in 802.11b / g without interference, and there are 12 in 802.11a. With this feature, 802.11n supports channel bonding function that uses several non-overlapping channels at the same time, thus improving transmission speed.

In a wireless communication device, a plurality of wireless LAN cards may be grouped into one IP in a node for fault tolerance against a failure of a network card (wireless LAN card) or for improving the wireless communication speed (load balance) This is commonly referred to as channel bonding.

The use of the channel bonding function improves the transmission speed, but it is difficult to always expect stable signal quality due to the characteristics of the radio wave. That is, when a channel is used in a wireless LAN and is used, each channel uses different radio wave bands. Therefore, the state of the radio signal of each channel may be different for each channel. Also, the radio signal of each channel is directly related to the amount of traffic assigned to the channel. That is, if a lot of traffic flows to a specific channel, the radio signal state of the channel may be deteriorated. In particular, when traffic is transmitted in the environment of channel bonding, packets belonging to the same flow must use the same radio channel. Packets belonging to the same flow have different channels

The transmission order is reversed, and the performance of the application is deteriorated.

As a technique disclosed to overcome such drawbacks, there is a method and apparatus for dynamic distribution of traffic in a channel-bonding type wireless LAN system disclosed in Korean Patent Publication No. 10-2009-0114806, but there is a limitation in improving the overall transmission efficiency It is true.

It is an object of the present invention to provide a hybrid cloud-based mobile enterprise application platform service and a method thereof that improves the overall transmission efficiency and has no risk of confidential exposure of the enterprise.

According to an aspect of the present invention, there is provided a method for dynamic distribution of traffic in a channel-bonded WLAN system, the method comprising: (A) extracting flow information from an arriving packet and classifying the packet into flow units based on the extracted flow information; step; (B) monitoring a state of each of the bonded channels; And (C) allocating a flow classified in the step (A) to an optimal channel by referring to the channel state information obtained in the step (B), wherein the channel- And a LAN system tone, wherein the step (A) comprises classifying the received packet according to an encryption scheme of each wireless LAN and extracting flow information from the classified packet A method for dynamic distribution of traffic in a channel-bonded wireless LAN system is provided.

According to the present invention, when a wireless LAN access point or a host using a plurality of channels of a wireless LAN uses channel bonding, a method of encrypting each wireless LAN access point is applied differently so that an encryption method can stably The traffic can be transmitted stably through other multi-channels. Therefore, it is possible to dynamically allocate the traffic to lower the error rate, thereby increasing the overall traffic transmission rate.

Also, when channel bonding is used, the ad hoc mode is set to dynamically allocate traffic according to the quality of a wireless signal when connecting a wireless link between an access point and an access point or between a host and a host or a mesh node in a wireless LAN mesh network Thereby enabling stable and efficient traffic transmission.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram illustrating three scenarios in which a dynamic traffic distribution method and apparatus in a channel-bonded WLAN system according to the present invention can be applied.
FIG. 2 is an exemplary schematic diagram of a traffic dynamic distribution apparatus for a channel-bonded wireless LAN according to the present invention, and shows an apparatus for dynamically distributing traffic at a host, an access point, or a wireless LAN mesh node when using wireless LAN channel bonding will be.
3 is a schematic diagram illustrating a structure for transmitting a packet in a traffic dynamic distribution apparatus for a channel-bonded wireless LAN according to the present invention.

In the present invention, the flow classifying step (or the flow classifying unit) inputs five fields such as a sender IP address, a receiver IP address, a sender port number, a receiver port number, and a protocol among header information of input packets to a hash function, And records it in the flow information DB.

If the flow information of the newly arrived packet does not exist in the flow information DB, the flow information for the packet is stored in the flow information DB. The flow information DB stores the flow start time, the last update time, five fields of the header, the number of packets, the number of bytes, the input interface, and the output interface information. When the existing flow information is retrieved, the corresponding flow information DB is updated. If the packet of the corresponding flow does not arrive after a predetermined time, the corresponding flow information is deleted from the flow information DB.

In the present invention, the channel state monitoring step (or the channel state monitoring unit) periodically monitors the states of the maximum transmission rate, the recent transmission rate, the link utilization rate, and the recent transmission error rate of a plurality of wireless LAN channels and stores them in the channel state DB.

In the present invention, in the flow allocation step (or the flow allocation unit), the classified flow information is allocated to an appropriate channel among the plurality of channels to transmit the traffic. For a newly started flow, a packet is transmitted to a channel having a low link utilization rate and a recent transmission error rate among a plurality of channels, thereby increasing a link utilization rate of a channel, thereby improving the overall throughput.

Also, by periodically comparing the recent transmission error rate and the link utilization rate of each channel with the set reference value, the flows assigned to the channel having a recent transmission error rate or a high link utilization rate are moved to a channel having a low transmission error rate and a low link utilization rate . In other words, some of the flows allocated to the channels with high link utilization rates are moved to other channels.

The condition for moving the flow can be set to a case where the latest transmission error rate of a specific channel is greater than a preset reference value or the link utilization rate of the channel becomes larger than a set reference value. The larger one is preferentially selected based on the bit rate of the flows allocated to the channel to be moved and is moved to another channel. The condition for moving the specific flow is that the sum of the link utilization rate of the channel to be moved and the bit rate value of the moving flow must be smaller than a predetermined value. If there is a channel satisfying this condition, the flow continues to move the link utilization rate of the channel in which the problem occurs to a value smaller than the set value.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail with reference to the accompanying drawings. However, these drawings are only for illustrating the contents and scope of the technical idea of the present invention, and the technical scope of the present invention is not limited or changed. It will be apparent to those skilled in the art that various changes and modifications can be made within the scope of the technical idea of the present invention based on these examples.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram illustrating three scenarios in which a dynamic traffic distribution method and apparatus in a channel-bonded WLAN system according to the present invention can be applied.

As shown in the drawing, (1) when connecting to a plurality of wireless LAN hosts 100 and one wireless LAN access point 101 in a channel bonding type wireless LAN infrastructure mode, (2) in ad hoc mode, It is possible to apply the method and apparatus according to the present invention so as to increase the transmission rate when the wireless LAN mesh node 102 is connected to the wireless LAN host 100 and the packet is wirelessly transmitted.

In this case, the channel bonding type wireless LAN system tone is a system in which a wireless LAN having different wireless encryption schemes is bonded. The received packet is classified according to the encryption scheme of each wireless LAN and the flow information is extracted from the classified packet.

FIG. 2 is an exemplary schematic diagram of a traffic dynamic distribution apparatus for a channel-bonded wireless LAN according to the present invention, and shows an apparatus for dynamically distributing traffic at a host, an access point, or a wireless LAN mesh node when using wireless LAN channel bonding will be.

When a plurality of channels are bonded, they are recognized as one virtual wireless LAN channel. The packet arriving at the wireless LAN channel is applied to the flow information DB 240 by applying the five fields including the packet sender IP address, the receiver IP address, the sender port number, the receiver port number, and the protocol to the hash function by the flow classifying unit 210 The flow information is newly generated / recorded, or when the flow information is the same as the existing flow, the flow information is updated. The flow information DB 240 stores flow information including flow start time, last update time, five fields among the header, the number of packets, the number of bytes, the input interface, and the output interface information of each flow. When the flow information DB 240 retrieves the existing flow information using the flow information of the arrived packet, the corresponding flow information is updated. If the packet of the corresponding flow does not arrive after a predetermined time, the flow information DB 240 deletes the corresponding flow information.

The channel status monitoring unit 230 periodically monitors the channel status and records the maximum transmission rate, recent transmission rate, link utilization rate, recent transmission error rate, and the like for each channel in the channel status DB 250.

The flow assigning unit 220 refers to the channel state DB 250 and allocates recent flows recorded in the flow information DB 240 to an appropriate WLAN channel. For a newly arriving flow, a channel having a low link utilization rate and a low transmission error rate among a plurality of channels is selected to transmit a packet, thereby improving the link utilization rate of the channel and improving the overall throughput.

However, since the packet transmission rate and the bit transmission rate of each flow are not the same, and the flow duration is also different, it is necessary to monitor the channel status to perform traffic redistribution. At the time of re-adjustment, the latest transmission error rate and link utilization rate of each channel are compared with preset reference values using the channel status DB 250, which is a result of periodical monitoring of the channel status, Move assigned flows to channels with low recent transmission error rates and low link utilization. In this case, the sum of the flow rate of the moving flow and the latest link utilization rate should be smaller than the set reference value.

3 is a schematic diagram illustrating a structure for transmitting a packet in a traffic dynamic distribution apparatus for a channel-bonded wireless LAN according to the present invention.

When a packet arrives in the channel-bonding-type wireless LAN node, the destination address of the packet is retrieved from the routing table 310 and the interface information to be transmitted is obtained. In this case, the interface is a virtual logical interface, and a plurality of physical LAN channels are combined into one IP address. Accordingly, the virtual logical interface through which the packet is transmitted is mapped to one of a plurality of physical interfaces in the wireless LAN channel bonding traffic dynamic distributor 320. Each physical interface is assigned WLAN channel information.

100: Wireless LAN host
101: Wireless LAN access point

Claims (4)

A method of dynamic traffic distribution in a channel-bonded wireless LAN system,
(A) a flow classification step of extracting flow information from an arrived packet and classifying the packet into flow units based on the flow information;
(B) monitoring a state of each of the bonded channels; And
(C) allocating a flow classified in the step (A) to an optimal channel by referring to the channel state information obtained in the step (B)
Wherein the channel bonding type wireless LAN system voice is a system in which a wireless LAN having different wireless encryption schemes is bonded,
Wherein the step (A) classifies the received packet according to an encryption scheme of each wireless LAN, and extracts flow information from the classified packet. The method according to claim 1,
The flow information in the step (A)
Wherein the information includes information on a sender IP address, a receiver IP address, a sender port number, a receiver port number, a protocol, a flow start time, a last update time, a packet number, A Dynamic Dividing Method of Traffic in Wireless LAN System. 3. The method according to claim 1 or 2,
In the step (B)
Wherein status information including a maximum transmission rate, a recent transmission rate, a latest link utilization rate, and a recent transmission error rate for each channel is periodically monitored. The method of claim 3,
In the step (C)
Wherein a flow is allocated to a channel having a maximum transmission rate, a recent transmission rate, a latest link utilization rate, or a recent transmission error rate.

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