KR100918848B1 - Method for wireless interface medium access control using multi channel through channel reservation in wireless ad hoc network - Google Patents

Abstract

The present invention relates to a wireless interface medium access control method using multiple channels through channel reservation in a wireless ad hoc network, wherein a Beacon message is transmitted from one node (A) to another node (B) in a wireless ad hoc network. Synchronizing the time, setting a synchronized time interval including a channel negotiation and a schedule interval and a data transmission interval; A channel negotiation and transmission schedule step of negotiating a channel and a transmission time of an N multichannel for a certain device pair in a channel negotiation and scheduling period during a predetermined period; And a data transmission step of transmitting / receiving desired data in a data transmission section at a specific time and a specific channel for which a certain device pair is scheduled. Thus, the present invention can improve network throughput between nodes using multiple channels in a wireless ad hoc network.

Description

Method for wireless interface medium access control using multi channel through channel reservation in wireless ad hoc network}

The present invention relates to a method of medium access control (MAC) in a wireless ad hoc network, and more particularly, to a medium access that improves throughput of a network by utilizing multiple channels in which nodes do not overlap in a wireless ad hoc network. A wireless interface medium access control method using multiple channels through channel reservation in a wireless ad hoc network providing a control protocol.

 The present invention is derived from a study performed as part of the IT Specialized Research Institute establishment project of the Korea Software Promotion Agency [Task Management No .: 2007-based-10, Title: Daegu Embedded S / W Technical Support Center established and operated].

The IEEE 802.11 standard basically operates in the infrastructure mode (Infrastructure Mode), and the network in this mode is called a wireless LAN (WLAN).

1 is a conceptual diagram of an IEEE 802.11 WLAN.

In an IEEE 802.11 WLAN, a mobile node within a transmission range of an access point (hereinafter referred to as an AP) can access the Internet through the access point. IEEE 802.11 WLAN provides multiple channels to avoid interference between APs. Each AP selects and uses one channel that does not overlap as much as possible.

2 is a conceptual diagram of an IEEE 802.11 ad hoc network.

Wireless Ad Hoc Network is a network composed of mobile nodes with limited wireless transmission range without the help of the underlying network. You can temporarily configure your network where it is unavailable.

Unlike a WLAN, each node provides a router function so that all mobile nodes within a transmission range can communicate with each other and with a node outside the transmission range. Taking the network of FIG. 2 as an example, Node A can communicate with Nodes B and C, and Node D can communicate with Nodes B, C, E, F and G. In order for node A to communicate with node D, either node B or C must provide a router function.

Also assume that nodes A and C want to communicate, and nodes B and D want to communicate. If communication is possible using only one channel in an ad hoc network, the communication between nodes A and C and the communication between nodes B and D cannot occur at the same time because they are in a transmission range of each other. This can cause delays in transmission. On the other hand, if the usage channels of the nodes A and C are the same, the usage channels of the nodes B and D are the same, and the usage channels of the nodes A and B are different, they can be transmitted simultaneously as in the previous example. As such, the method of increasing the capacity of the network by using the multi-channel is called a multi-channel method.

Existing methods using multi-channels include dynamic channel assignment (DCA) and multi-channel MAC (MMAC).

Dynamic Channel Assignment (DCA) uses two interfaces: an interface that listens to a common channel for channel negotiation, and an interface that transmits data by changing to a selected channel after channel negotiation. In DCA, every node maintains a channel usage list (CUL) and uses it for channel selection.

Multi-Channel Media Access Control (MMAC) modifies the synchronization and negotiation scheme of IEEE 802.11 PSM to negotiate the channel in the Announcement Traffic Indication Message (ATIM) window to determine the channel of the two nodes to communicate with. It transmits data by IEEE 802.11.

Dynamic channel allocation (DCA) has a problem in that a dedicated interface for channel negotiation is further required to utilize multiple channels.

Since multi-channel media access control (MMAC) transmits data after the ATIM window according to the existing IEEE 802.11 method, the efficiency of channel use decreases due to competition using back-off, etc., and fixed to the next beacon section in channel negotiation. The use of multiple channels reduces the efficiency of using multiple channels.

The present invention has been proposed to solve the above-mentioned problem. In the wireless ad hoc network, a medium access control (MAC) protocol that improves network throughput by using multiple channels in which nodes do not overlap is provided. It is an object of the present invention to provide a wireless interface medium access control method using multiple channels through channel reservation in a wireless ad hoc network.

In order to achieve the object of the present invention, the present invention provides a wireless interface medium access control method using multiple channels through channel reservation in a wireless ad hoc network, (a) at least one receiving node at a transmitting node in a wireless ad hoc network; A time synchronization step of setting a synchronized time interval including a channel negotiation and a schedule period and a data transmission period by transmitting a beacon message to the mobile station, and (b) a predetermined period in the channel negotiation and schedule period. A channel negotiation and transmission scheduling step in which any device pair negotiates a channel and data transmission period and transmission start time to be used among N multi-channels, and (c) the data transmission interval at a specific channel and a specific time at which any device pair is scheduled; A data transmission step of transmitting and receiving desired data; It includes.

In the step (a), the channel use reservation time and the interface use reservation time are initialized to zero at the start of the synchronized time interval (Beacon interval).

The step (b) is characterized in that the channel for the next data transmission, the data transmission period and the transmission start time using the scheduled channel use time and the scheduled interface use time.

In step (b), the arbitrary device pairs transmit and receive a channel negotiation (CN) message, a channel selection (CD) message, and a channel announcement (CA) message. A transmission period, a transmission start time, and a change channel are set and scheduled.

The step (b) comprises: (b1) as soon as the channel negotiation and schedule interval enters, the transmitting node back-off for a random time; (b2) after back-off (C3) transmitting a channel negotiation (CN) message to a node receiving the beacon message from the transmitting node, (b3) the node receiving the CN message determines a channel, a transmission start time, and a data transmission period, (b4) After determining the channel and transmission start time, the receiving node switches to the channel determined from (data transmission section start time + transmission start time) to (data transmission section start time + transmission start time + data transmission period) to receive data. (B5) the receiving node is scheduled to use the interface (transmission start time + data transmission period) and scheduled channel usage time of the selected channel. (B6) transmitting the channel selection (CD) message including the determined channel, the transmission start time, and the data transmission period to the transmitting node; (b7) transmitting the channel selection (CD) message. The receiving node schedules the data to be transmitted like the receiving node according to the channel included in the CD message, the transmission start time, and the data transmission period, and updates the interface transmission time and the channel transmission time of the selected channel. And (b8) the transmitting node receiving the CD message includes broadcasting a channel notification (CA) message including a channel included in the CD message, a transmission start time, and a data transmission period.

In step (b2), the CN message may include a data transmission period, an estimated time of using N channels of the transmitting node, and an estimated time of using an interface.

Preferably, in the wireless ad hoc network, a wireless interface medium access control method using multiple channels through channel reservation, (b9) a node overhearing a CD message and a CA message around the transmitting node and the receiving node is a channel. The method further includes updating the scheduled use time.

The transmitting node and the receiving node may transmit initialization, channel negotiation and schedule, and data using one of N multiple channels used in a wireless ad hoc network.

As described above, the present invention can utilize a multi-channel even though a single interface between node devices in a wireless ad hoc network, and unlike the existing multi-channel MAC protocol, it uses the concept of data transmission reservation to improve channel usage efficiency. It is effective to maximize.

1 is a conceptual view of a general IEEE 802.11 WLAN.

2 is a conceptual diagram of an IEEE 802.11 ad hoc network.

FIG. 3 is a diagram illustrating a synchronized time interval that is obtained through a time synchronization process. FIG.

4 is a diagram illustrating an operation process in a channel negotiation and a schedule period of a common channel merchant according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention first makes the following assumptions. There are N channels in the wireless network that do not interfere with the transmission of different channels.

In the wireless ad hoc network according to the present invention, a wireless interface medium access control (MAC) method using multiple channels through channel reservation includes a time synchronization process, a channel negotiation and transmission schedule process, and a data transmission process.

The time synchronization process is a process for all devices participating in the wireless ad hoc network to synchronize the start time of the channel negotiation and scheduling process and the data transmission process, which is possible through existing technologies such as IEEE 802.11 TSF or GPS. In case of IEEE 802.11 TSF, a beacon message is transmitted to attempt synchronization. Therefore, in the present invention, the synchronized time interval is referred to as a beacon interval.

3 illustrates a synchronized beacon period that all devices have through a time synchronization process. The beacon section is divided into a channel negotiation and scheduling section for performing channel negotiation and scheduling process and a data transmission section for data transmission process.

All devices maintain Channel Schedule Time for N channels during channel negotiation and scheduling. The scheduled use time of the channel is the length of the interval from the start time of the data transmission interval to the time reserved for use by the peripheral devices, and is used for the next data transmission reservation. All devices also maintain an Interface Schedule Time. The scheduled use time of the interface indicates the length of the interval of time when the use of the interface is reserved from the start time of the data transmission interval. Devices in the wireless ad hoc network use the scheduled channel usage time and the scheduled interface usage time to schedule a channel to transmit the next data, a transmission start time and a data transmission period.

The scheduled time to use the channel and the scheduled time to use the interface are initialized to zero at the beginning of each beacon interval.

In the channel negotiation and schedule interval, all devices use the same predetermined channel. This same channel is called a common channel and is one of the N channels used in a wireless ad hoc network.

In order to transmit data to a specific channel at a specific time in a data transmission interval, the transmitter negotiates a channel, data transmission period, and transmission start time with at least one receiving node that has received a beacon message in the preceding channel negotiation and schedule interval.

4 is a diagram illustrating an operation process in a channel negotiation and a schedule interval of a common channel merchant according to an embodiment of the present invention. In the embodiment of FIG. 4, the transmitting node is node A, and the node B receives the beacon message from node A. The operation performed between node A and node B is described as an embodiment, but the beacon message is received. Of course, it works the same in other nodes. In addition, the device corresponding to the transmitting node is called device A, and the device corresponding to the receiving node is called device B.

It is assumed that there is data to be transmitted to a specific device (node B) by a specific device (node A) before entering the channel negotiation and schedule interval.

Upon entering the channel negotiation and schedule interval, device A (node A) backs off for a random time. Here, the back-off process is the same as the back-off of the IEEE 802.11 standard.

When the back-off ends, the device A (node A) sends a channel negotiation (CN) message to the device B (node B). The CN message includes the data transmission period, the N channel scheduled use time of the node A), and the interface scheduled use time.

The data transmission period can be obtained as follows.

ㆍ Data transmission period = T _sw + (length of transmission data received in CN message) / transmission rate + T _SIFS + T _ACK

(T _sw : Channel Switching Time, T _SIFS : SIFS Time, T _ACK : ACK Message Transmission Period)

  Upon receiving the CN message, the device B (node B) determines the channel, transmission start time, and data transmission period according to the following procedure.

Interface Transferable Time = max (Expected Time to Use Interface of Devices A and B)

ㆍ Channel c transmission available time = max (Scheduled use time of channel c of device A and B)

                            (c = {1, ..., N})

ㆍ Transmission start time = Condition 1. If c satisfies (interface transmittable time <= channel c transmittable time), then min (channel c transmittable time | interface transmittable time <= channel c transmittable time) value

       Condition 2. otherwise,

           max (channel c transmittable time) value

Channel = channel with transmission start time value as channel I transmission available time

 After determining the channel and the transmission start time, the device B receives data by switching to the channel determined from (data transmission interval start time + transmission start time) to (data transmission interval start time + transmission start time + data transmission period). Schedule to do it.

The device B (node B) then updates the scheduled time of use of the interface and the estimated time of use of the channel of the selected channel as follows.

ㆍ Expected time to use interface = Transfer start time + Data transfer period

ㆍ Channel transmission time of the selected channel = Transmission time + Data transmission period

Device B then sends a Channel Decision (CD) message to the device A (node A) that includes the determined channel and the transmission start time and the data transmission period.

Receiving this message, Device A (Node A) schedules the data to be sent, as with Device B (Node B), according to the channel included in the CD message, the transmission start time, and the data transmission period. Update the channel transmission time of the channel.

The device A (node A) receiving the CD message broadcasts a channel announcement (CA) message including a channel included in the CD message, a transmission start time, and a data transmission period.

The device overhearing the CD message and the CA message around the device A (node A) and the device B (node B) updates the channel usage time as follows.

ㆍ Scheduled channel use time for the selected channel = transfer start time + data transfer period

When the device enters the data transmission section after the channel negotiation and the schedule section are finished, each device transmits the scheduled data in the scheduled channel and time.

The present invention, by using a medium access control protocol to improve network throughput using multiple channels in a wireless ad-hoc network, all the channels used by the wireless ad-hoc network peripheral device to identify all the correct channel allocation information, that is, assigned channel number and allocation Share channel time.

The present invention shares channel usage information with peripherals to schedule the appropriate channel and time for each transmission data. The method exchanges CN messages, CD messages, and CA messages related to channel usage in advance in a common channel that all devices can hear in the same time interval, and allows peripheral devices to overhear the information to confirm channel usage information. After confirming the channel usage information, the device can select the appropriate channel and transmit it at the appropriate time due to the accurate channel information.

Thus, the present invention can improve network throughput by appropriately using multiple channels to handle increased network traffic as the use of wireless ad hoc networks increases.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art without departing from the spirit and scope of the present invention described in the claims In the present invention can be carried out by various modifications or variations.

Claims (8)

A wireless interface medium access control method using multiple channels through channel reservation in a wireless ad hoc network, (a) a time for synchronizing time by broadcasting a beacon message from a transmitting node to at least one receiving node in a wireless ad hoc network, and setting a synchronized time interval including a channel negotiation and a schedule interval and a data transmission interval; A synchronization step; (b) a channel negotiation and transmission schedule step of negotiating a channel and a data transmission period and a transmission start time to be used among N multi-channels by a pair of devices in the channel negotiation and schedule period; And (c) a data transmission step of transmitting / receiving desired data in the data transmission interval at a specific time and a specific channel scheduled by a pair of devices; A wireless interface medium access control method utilizing multiple channels through channel reservation in a wireless ad hoc network comprising a. The method of claim 1, Step (a) is, 18. A method for controlling a media access to a wireless interface utilizing multiple channels through channel reservation in a wireless ad hoc network, wherein the channel use reservation time and interface use reservation time are initialized to zero at the start of a synchronized time interval. The method of claim 1, Step (b) is, Wireless interface media access using multiple channels through channel reservation in a wireless ad hoc network, characterized by using the scheduled channel usage time and the scheduled interface usage time to schedule the next data transmission period, data transmission period, and transmission start time. Control method. The method of claim 1, Step (b) is, The arbitrary device pairs transmit and receive a channel negotiation (CN) message, a channel selection (CD) message, and a channel announcement (CA) message to transmit and receive a data transmission period and a transmission start time in a data transmission interval. And accessing a channel using a multiple channel through a channel reservation in a wireless ad hoc network, characterized in that for setting and scheduling a change channel. The method of claim 1, Step (b) is, (b1) the transmitting node back-off for an arbitrary time as soon as it enters the channel negotiation and schedule interval; (b2) after back-off, transmitting a channel negotiation (CN) message from the transmitting node to the node that has received the beacon message; (b3) the node receiving the CN message, determining a channel, a transmission start time, and a data transmission period; (b4) After determining the channel and the transmission start time, the receiving node switches the data by switching from the (data transmission section start time + transmission start time) to (data transmission section start time + transmission start time + data transmission period). Setting a schedule to receive; (b5) the receiving node updating an interface use time (transmission start time + data transmission period) and a channel use time scheduled transmission time + data transmission period of the selected channel; (b6) the receiving node transmitting a channel selection (CD) message to the transmitting node including the determined channel, a transmission start time, and a data transmission period; (b7) The transmitting node receiving the channel selection (CD) message is scheduled to transmit data similarly to the receiving node according to the channel included in the CD message, the transmission start time, and the data transmission period. Updating a channel transmittable time of a selected channel; And (b8) the transmitting node receiving the CD message, broadcasting a channel notification (CA) message including a channel included in the CD message, a transmission start time, and a data transmission period; A wireless interface medium access control method utilizing multiple channels through channel reservation in a wireless ad hoc network comprising a. The method of claim 5, wherein In step (b2) the CN message, And a data transmission period, an estimated time of using N channels of the transmitting node, and an estimated time of using an interface, wherein the method of claim 1 uses multiple channels through channel reservation in a wireless ad hoc network. The method of claim 5, wherein (b9) The node overhearing the CD message and the CA message around the transmitting node and the receiving node further includes updating a channel use time, and utilizing the multiple channels through channel reservation in a wireless ad hoc network. Interface medium access control method. The method of claim 1, The transmitting node and the receiving node, A wireless interface medium that utilizes multiple channels through channel reservation in a wireless ad hoc network, characterized in that initialization, channel negotiation, scheduling, and data transmission are performed using one of N multiple channels used in the wireless ad hoc network. Access control method.