KR101241905B1 - Medthod of handovering in the wireless network - Google Patents

Abstract

The present invention relates to a handover method in which a coordination function for controlling the network in a wireless network is transferred to another device configuring the network. The present invention relates to a method of causing an optimal device to be the adjuster using priority information determined by a predetermined evaluation criterion when selecting the other device. In addition, the present invention relates to a method that can simplify the procedure by transmitting the information required when transmitting the handover request message.

Wireless network, handover, priority information

Description

Handover method in wireless network {Medthod of handovering in the wireless network}

1 shows an example of a WVAN composed of multiple devices.

FIG. 2 is a diagram for explaining an example of the superframe structure used in the WVAN.

3 is a diagram illustrating a protocol hierarchy implemented in a device of a WVAN.

4 is a process flow diagram according to one preferred embodiment of the present invention.

The present invention relates to wireless communications, and more particularly, to a handover method in a wireless network.

There are many cases where various devices are used nearby, and it is necessary to use these devices in conjunction with each other. However, it is rather inconvenient to wire the plurality of devices to each other, and the applications of each device are often incompatible with each other, which is substantially difficult. Performing communication through wireless technology makes it possible to eliminate wires such as cables between the devices, and also, through a wireless network between devices, it is possible for the devices to form a network and directly exchange data information. Devices capable of communicating in the network include computers, PDAs, notebooks, digital TVs, camcorders, digital cameras, printers, microphones, speakers, headsets, bar code readers, displays, mobile phones, and the like. All digital devices can be used. have.

In order to perform communication via the wireless network, an apparatus for performing a control function of controlling and distributing resource allocation between devices configuring the network is required. If a control device is unable to perform the control function, a process of causing another device constituting the network to perform the control function is required. In addition, even when a device having a better condition to perform a control function than a current control device joins a network, a process of transferring a control function to the newly subscribed device is required.

The present invention has been made to solve the problems of the prior art as described above, and to provide a method in which the control function can be continuously maintained to perform a smooth wireless communication.

A device to communicate in a wireless network searches for channels in a band for performing communication and checks whether an existing network exists. The device may subscribe to an existing network and perform communication, or may configure a new network on its own. In the case of forming a new network, the network is configured while the device selects a good channel environment based on the information obtained during the search and investigation process, and broadcasts a control information packet through the selected channel.

Even if a network including a control device is already formed, a case may occur in which the control device cannot perform a control function due to a user's need or circumstances. In this case, the process of transferring the control function to another device is required to ensure smooth communication of the network. In addition, even when a device that is more suitable to perform a control function than a current control device joins a network, it is preferable to transfer a control function to the newly joined device for smoother communication. After the network is formed as described above, the control device transfers the control function to another device is called a handover. The present invention provides the handover method. In particular, when determining a device requesting the handover, a method of determining according to a priority for a predetermined control function is provided.

In one aspect of the present invention, a communication method in the coordinator of a wireless network including a coordinator and at least one device includes a handover method when performing a handover to a first device. Sending a message for requesting a first handover that includes the necessary information; receiving a response message that includes information for accepting handover for the first handover request message; and wherein the first device is a new coordinator. And broadcasting a first beacon including information informing that the message has been made.

In another aspect of the present invention, a handover method in a communication method in a coordinator of a wireless network including a coordinator and at least one or more devices comprises a first having the highest priority among the at least one or more devices. Transmitting, to the first device, a message for requesting a first handover including information necessary for performing a handover and a response including information for rejecting handover for the first handover request message; Receiving a message and transmitting a second handover request message to a second device having a second priority among the at least one or more devices.

In still another aspect of the present invention, a handover method in a communication method in a coordinator of a wireless network including a coordinator and at least one or more devices has a highest priority among the at least one or more devices. When the first device transmits a first handover request message including information necessary for performing a handover and a response message to the first handover request message is not received for a predetermined time, And transmitting a second handover request message to a second device having a second priority among the at least one or more devices.

In still another aspect of the present invention, a handover method in a wireless network including a coordinator may include receiving information on a priority of the device when the new device joins the network and the priority. Is higher than the priority of the coordinator, transmitting a handover request message including information necessary for performing a handover to the device and accepting the handover in response to the handover request message. Receiving a response message comprising information and boring a first beacon containing information indicating that the device has become a new coordinator.

The objects, structures and other features of the present invention described above will become apparent from the following detailed description taken in conjunction with the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. The embodiments described below are examples in which the technical features of the present invention are applied to a wireless video area network (WVAN), which is a kind of a wireless network. WVAN is a wireless network that can provide throughput of more than 4.5Gbps using a 60 GHz frequency band to transmit 1080p A / V streams without compression over a short range of 10 meters.

1 shows an example of a WVAN composed of multiple devices. The WVAN is a network configured for data exchange between devices located in a predetermined space. The WVAN consists of two or more devices 10-14, one of which acts as a coordinator 10. The coordinator 10 has a function of allocating and scheduling the radio resource in order to configure a radio network between the devices, in which a plurality of devices must share a radio resource, and communicate the devices without collision. It is a device to perform. The coordinator may transmit and receive data through at least one channel as a normal device, in addition to a function of allocating resources so that devices configuring the network can perform communication. In addition, functions such as clock synchronization, network association, and maintaining bandwidth resources may be performed.

WVAN supports two types of physical layers (PHYs). That is, WVAN supports a high-rate physical layer (HRP) and a low-rate physical layer (LRP) as a physical layer. HRP is a physical layer capable of supporting a data rate of 1Gb / s or more, LRP is a physical layer supporting a data rate of several Mb / s. The HRP is highly directional and is used for transmitting isochronous data streams, asynchronous data, MAC commands and A / V control data through a unicast connection. LRP supports directional or omni-directional modes and is used for sending beacons, asynchronous data, and MAC commands including beacons through unicast or broadcast. The HRP channel and the LRP channel share a frequency band and are used separately by the TDM method.

FIG. 2 is a diagram for explaining an example of the superframe structure used in the WVAN. Referring to FIG. 2, each superframe includes an area 20 through which a beacon is transmitted, a reserved channel time block 22 and an unreserved channel time block 21. time block). The beacon 20 is sent periodically to identify the beginning of every super frame. The beacon packet includes management and control information of the scheduled timing information WVAN. The device may exchange data in the network through timing information and management / control information included in the beacon. In addition, although not shown in FIG. 2, a contention-based control period (CBCP) next to the beacon is included to transmit an urgent control / management message. The interval length of the CBCP is set to set a certain threshold (mMAXCBCPLen) and not to exceed the threshold.

3 is a diagram illustrating a protocol hierarchy implemented in a device of a WVAN. Referring to FIG. 3, each device included in the WVAN may be divided into at least two layers according to its function, and generally includes a PHY layer 31 and a MAC layer 30. The device includes an entity managing each layer, the MAC layer management entity (MLME) 300 for the entity managing the MAC layer, and a PHY layer management entity (PLME) 310 for the entity managing the PHY layer. It is called. The device also includes a device management entity (DME) 320 that collects state information of each device and serves as a control interface between the host and the wireless device. Messages exchanged between the different layers are called primitives.

4 is a process flow diagram according to a preferred embodiment of the present invention. Hereinafter, a handover method will be described as an embodiment of the present invention with reference to FIG. 4.

Any device forms a network by broadcasting a beacon and becomes a coordinator in the network. The handover is performed when the coordinator leaves the network or the power is cut off so that the coordinator can no longer perform the coordinating function. The coordinator selects other devices that make up the network. The selected device should be able to at least perform the adjustment function.

When selecting a handover request from among the devices constituting the network, each device may be prioritized to be selected as a device in a better environment. That is, the coordinator receives the information on the priority of the coordination function of the devices included in the network, and uses the priority information of the coordination function when performing handover, so that the device in the optimal situation is a new coordinator. Select to perform the function. The priority for the adjustment function is determined by determining an evaluation criterion for the time and place and the like and considering the characteristics of the device with respect to the evaluation criterion. That is, each device has a long-life time feature, how much power is remaining, whether it is a battery or AC power, and how many devices each device can send control messages to (network-coverage). feature, etc., each device may determine a priority number for its own adjustment function. The coordinator receives priority information (number) of the coordinating function of each device, and constructs and stores a list. The list constructed through the priority information on the adjustment function is called a CCD (Coordinator Capable Device) list.

When the coordinator transmits the handover request message, it is preferable that the coordinator transmits the request message to the device having the highest priority as described above rather than transmitting the request message to any device. That is, if the handover request message is transmitted from the device having the higher priority according to the priority of the adjustment function, the optimal device may perform the adjustment function in the possible range.

The DME of the coordinator transmits an MLME-COORDINATOR-HANDOVER.req primitive to request a handover to the selected device to the MLME (S400). The MLME of the coordinator transmits a handover request message (Coordinator-Handover request) to the MLME of the selected device (S410).

When the handover request message is transmitted, the coordinator may include information necessary for handover. Channel time information reserved in the current network, information about the time remaining until the current coordinator passes the adjustment (eg, the number of remaining beacons or the number of beacon intervals), the specifications of the devices that make up the current network. Information on the characteristics and information on the priority of the adjustment function of each device may be transmitted together with the handover request message to the selected device for use in determining whether to handover. In addition to the above-mentioned information, information necessary for handover may be transmitted together with a message for requesting handover. Even when there is no request from the device, by transmitting a handover request message and information necessary to perform handover together, the amount of packets (data) to be transmitted can be reduced and the procedure can be simplified. An example of a MAC command format included in the handover request message is shown in Table 1 below.

Through the 'Breaking-in period' field of Table 1, information on the time remaining until the device receiving the handover request message starts operation with a new coordinator may be known. In addition, the 'timeout' field may be used to know information about a predetermined time at which the device receiving the handover request message should transmit a handover response message to the handover request message. In addition, the information on the reserved channel time through the 'Reserved Schedule' field of Table 1, the information on the devices constituting the network through the 'Device List' field, the adjustment function through the 'CCD List' field Priority information about can be found.

The MLME of the device receiving the handover request message transmits an MLME-COORDINATOR-HANDOVER.ind primitive to the DME to inform that the request message has been received (S420). The selected device determines whether to perform an adjustment function on the handover request message and transmits a handover response message. That is, the DME of the selected device transmits an MLME-COORDINATOR-HANDOVER.rsp primitive to the MLME (S430). The MLME of the selected device transmits the handover response message (Coordinator-Handover reponse) to the MLME of the coordinator (S440). An example of the format of the MAC command included in the handover response message is shown in Table 2 below.

The command format for the handover response message of Table 2 includes a 'Reason code' field. The reason code indicates information on whether to accept a new coordinator for the handover request message. The coordinator may know whether the handover request message succeeds or fails using the reason code.

The handover request message is transmitted and a corresponding handover response message is preferably received within a predetermined time. Therefore, the coordinator transmits a handover request message and operates the timer for which the predetermined time is set, and stops the operation of the timer if a response message is received before the timer is completed (S450). The coordinator may transmit a handover request message including the information on the predetermined time so that the device receiving the handover request message transmits a handover response message within the predetermined time (see Table 1). However, if a response message is not received until the timer is completed, the handover request will be failed and will send a handover request message back to other devices constituting the network. The MLME of the coordinator transmits an MLME-COORDINATOR-HANDOVER.cfm primitive to inform the DME that the handover response message has been received (S460).

The DME of the coordinator transmits the MLME-BEACON.req primitive for beacon transmission to the MLME (S470). The MLME of the coordinator broadcasts a beacon to the network (S480). When the handover request is successful, the coordinator transmits information including a new coordinator, a CCD list, and performance of devices constituting the current network when the next beacon is transmitted.

An example of an information element (IE) format for information included in the beacon and transmitted will be described. According to the configuration of the MAC command or beacon, it can be transmitted including information on which IE to use, and the message is transmitted in the defined IE format. IE format indicating information (CCD list) indicating the priority number, IE format indicating device capability information (Device Capability list) constituting the current network, information about the device determined by the new coordinator (New Coordinator) An example of an IE format indicating Information) will be described with the following table.

Table 3 shows an example of the IE format indicating information (Prioritized CCD list) indicating the priority number.

The IE format representing the Prioritized CCD list includes an IE length indicating the length of the IE format, and the length is n * 2 if the number of coordinator capable devices (CCDs) is n. can be (octets). Table 4 shows an example of the configuration of the CCD list block field in detail.

Referring to Table 4, the CCD list block field includes a CCD list block including identification information (CCD ID) of each CCD and information about a priority number of the corresponding CCD.

Table 5 is an example of an IE format indicating information on a device capability list constituting the current network.

The IE format of Table 5 also includes an IE length indicating the length of the IE format, which is n * 3 if the number of coordinator capable devices (CCDs) is n. can be (octets). In Table 6 below, an example of the MAC Capability Block field configuration is shown in detail.

Referring to Table 6, the MAC Capability Block field includes a MAC Capability Bitmap including device identification information and device capability information for devices constituting the network. Hereinafter, an example of configuration of the MAC Capability Bitmap will be described in detail with reference to Table 7.

Referring to Table 7, the MAC Capability Bitmap is allocated by 1 bit for indicating channel time reservation information and fast link recommendation information. Each bit is allocated to indicate a transmitting / receiving side of HRP (High Rate PHY) channel communication.

Table 8 shows an example of an IE format indicating information about a device (New Coordinator Informarion) determined as a new coordinator.

In the case of the IE format, information indicating the length of the IE format (IE length), identification information (New coordinator ID) of the device determined by the new coordinator, and information on the time remaining until the current coordinator transmits the last beacon (for example, For example, this may include a remaining breaking-in period.

The beacon contains information about the time remaining until the new regulator is operated so that the device determined by the new regulator can know when to perform the adjustment, or when the new regulator performs the adjustment. Can be transmitted. In this case, the 'Remaining breaking-in period' field may be used. If the remaining break-in period is n until the coordinator receives the handover response message and terminates the coordinating function, the coordinator transmits a beacon including information of 'breaking-in period = n', and then the beacon is 'breaking'. Sends a beacon containing information of -in period = n-1 '. The last beacon includes information of 'breaking-in period = 0' and the new coordinator receiving the information transmits the beacon from the next beacon transmission timing.

The information is included in the beacon transmitted by the current coordinator using the IE format described above. An example of a beacon message format including the above information is shown in Table 9 below.

Referring to Table 9, the beacon message may transmit the necessary information including not only the beacon control information and the information on the end point of the CBCP, but also IE format information about the information required for the remaining fields. For example, by inserting the IE shown in Table 8 into the IE1 field, information about a device determined as a new coordinator (New Coordinator Informarion) can be transmitted. In addition, by inserting the suggestion IE in Table 3 in the IEm field to transmit the priority number (Prioritized CCD list), the device configuring the current network by inserting the IE shown in Table 5 in the IEn field The device capability list may be transmitted.

The MLME of the device receiving the beacon transmits an MLME_BEACON.ind primitive to inform the DME that the beacon has been received (S490 and S550). After receiving the last beacon transmitted by the current coordinator, the DME of the new coordinator transmits the MLME-BEACON.req primitive to the MLME to transmit the beacon in the next beacon transmission interval (S570). The MLME of the new coordinator broadcasts a beacon to the network (S570). The current coordinator receiving the beacon transmits an MLME-BEACON.ind primitive to the DME to inform that the beacon has been received (S580).

 For stable handover, the current coordinator remains in the network for some time after transmitting the last beacon to confirm that the new coordinator receives the beacon. That is, the beacon broadcast by the new coordinator after transmitting the last beacon is preferably received within a certain time. Therefore, if the coordinator transmits the last beacon and operates a timer for which a predetermined time is set, and if a beacon message is received before the timer is completed, the coordinator stops the operation of the timer and ends the coordinator role (S590). However, if the beacon message is not received until the timer is completed, the handover process is failed, and the handover request message is transmitted again to another device configuring the network to perform the handover process again. Even when the handover request or the handover process fails, it is preferable to select the other device using the information on the priority. That is, it is preferable to send a handover request message back to the next higher priority device.

During the time after receiving the handover permission response message and sending the last beacon, the current coordinator preferably rejects the request message (e.g., channel time allocation request message, subscription request message, etc.) sent by other devices. .

The terms used above may be replaced with others. For example, the device may be changed to a user device (or appliance), a station, etc., and the coordinator may be a coordinator (or control) device, a coordinator (or control) device, a coordinator (or control) station, a coordinator ), Piconet coordinator (PNC) and the like.

Those skilled in the art to which the present invention described above belongs will understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features. Therefore, the embodiments described above are to be understood as illustrative in all respects and not as restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and from the same concept are to be construed as being included in the scope of the present invention will be.

According to the present invention, communication can be performed smoothly in a wireless network. In particular, there is an effect that can be communicated seamlessly without being significantly affected by the situation of a particular device. The device that performs the adjustment function is not limited to any particular device, and there is an effect that can be flexibly changed according to the situation. In addition, there is an effect that the optimum device can operate as a new regulator by selecting a new regulator in consideration of the priority of the adjustment function.

Claims (13)

A communication method in a coordinator of a wireless network comprising a coordinator and at least one device, Transmitting a message requesting a first handover including information required when performing a handover to a first device; Receiving a response message including information for accepting a handover for the first handover request message; And Broadcasting a first beacon including information indicating that the first device has become a new coordinator, the first beacon remaining until the coordinating function of the coordinator and the information for the new coordinator are terminated; Handover method, characterized in that it comprises at least one of the information on the time. The method of claim 1, The information required when performing the handover is, And at least one of reserved channel time information, information on time remaining until the coordinating function of the coordinator is terminated, information on device characteristics constituting the network, and information on priority of each device. Handover method. The method of claim 2, Receiving a second beacon broadcast by the first device after the last beacon is broadcast among the beacons broadcast for the remaining time until the adjustment function of the regulator is terminated Handover method characterized in that it further comprises. The method of claim 2, If the second beacon broadcast by the first device is not received for a predetermined time after the last beacon is broadcast among the beacons broadcast for the remaining time until the adjustment function of the regulator is terminated, the second device is sent to the second device. Sending a handover request message Handover method characterized in that it further comprises. The method of claim 1, The first device is a handover method, characterized in that the highest priority device for the adjustment function of the at least one or more devices. delete The method of claim 1, Rejecting a predetermined request message transmitted by a device constituting a network, from the time when the coordinator transmits the first beacon to the time when the first device transmits the second beacon. Way. delete A communication method in a coordinator of a wireless network comprising a coordinator and at least one device, Transmitting a first handover request message to a first device having the highest priority among the at least one or more devices, the first handover request message including information necessary for performing a handover; And If a response message to the first handover request message is not received for a predetermined time, transmitting a second handover request message to a second device having a second priority among the at least one or more devices; / RTI > delete delete delete delete

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