KR20080020423A - Method of communicating in wireless network - Google Patents

Abstract

A communication method of a wireless network is provided to simply perform a recovery process by performing the recovery process without defining a new MAC(Media Access Control) command. A wireless network includes a coordinator(40) and at least one device. A first beacon is received from the coordinator. Whether a second beacon is received during a predetermined time interval from a reception timing of the first beacon is checked. When the second beacon is not received, a third beacon is broadcast as a new coordinator. The predetermined time interval includes at least one beacon integrator and a wait time. The wait time is determined by using a priority of the coordinator. The information on the new coordinator is added into the third beacon.

Description

Method of communicating in 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 view for explaining a preferred embodiment according to the present invention.

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

The present invention relates to wireless communication, and more particularly, to a method of performing communication for coordination function recovery 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 via 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. However, a situation may occur in which a power supply of the control device is suddenly stopped or the control device is moved and thus out of a distance where the network can be formed without performing the process of transferring the control function. In the above situation, if there is no device capable of continuously performing the control function, the device fails to respond to resource allocation requests of devices communicating in the network, and timing control cannot be performed. As a result, the devices communicating through the network can no longer transmit and receive data, and eventually there is a fatal problem that the network cannot be maintained.

The present invention has been made to solve the problems of the prior art as described above, and to provide a method for continuously maintaining the coordination function of the network so that smooth wireless communication can be performed.

In one aspect of the present invention, a method of performing communication in a specific device of a wireless network including a coordinator and one or more devices includes: receiving a first beacon from the coordinator and the first beacon; Checking whether a second beacon is received for a predetermined time from the beacon reception time point, and if the second beacon is not received, broadcasting a third beacon to the wireless network as a new coordinator.

In another aspect of the present invention, a method of performing communication in a wireless network including a coordinator and at least two or more devices includes the steps of the coordinator broadcasting a first beacon and the at least two or more devices receiving each first beacon. And checking whether to receive the second beacon during the device-by-device waiting time, and broadcasting a third beacon by a specific device of the at least two or more devices that has not received the second beacon during its waiting time.

In still another aspect of the present invention, a method of performing communication in a wireless network including a coordinator and at least one device comprises: receiving a first beacon from the coordinator and after at least one beacon interval; 2 If the beacon is not received, transmitting a control information request message to the coordinator within a predetermined time, checking whether or not the second beacon is received for a predetermined time from the message transmission time and the second beacon is received If not, then broadcasting a third beacon to the network as a new coordinator.

According to the present invention, if the apparatus for controlling communication resources of each device in the wireless network system does not perform the process of transferring the control function and terminates the function, a method for restoring the control function and continuing communication is disclosed. do. Hereinafter, when the control function is suddenly terminated, it is called recovery to allow the control function in the network to be maintained and restored.

As an example of the recovery method, a method of performing a recovery process based on a timer of the device may be referred to as a timer based coordinator recovery. Each device constituting the network may have information on a priority indicating the degree of suitability for performing the coordination function in consideration of characteristics of each device and network conditions. The recovery process may be performed using the priority information of each device. The higher the priority, the better suited to perform the adjustment, so if the current regulator can no longer perform the adjustment, the new control device may be determined based on the wait time set in consideration of the priority. have.

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. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to 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. HRP is highly directional and is used for isochronous data streams, asynchronous data, MAC commands and A / V control data transmission over unicast connections. 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. In addition, the device collects state information of each device, and includes a device management entity (DME) 320 that serves as a control interface (interface) between the host and the wireless device. Messages exchanged between the different layers are called primitives.

WVAN begins with the regulator broadcasting a beacon. The device performs communication by receiving a channel time block for data exchange through a subscription procedure with the coordinator.

4 is a view for explaining a preferred embodiment according to the present invention. The WVAN consists of a number of devices, any one of which acts as the coordinator 40. 4 is a time axis.

Referring to FIG. 4, the coordinator 40 broadcasts a beacon so that devices constituting the WVAN can receive (S400). If the power of the regulator 40 is suddenly cut off or out of the area of the WVAN, it is no longer possible to transmit beacons for the devices constituting the WVAN (S401). If the coordinator 40 no longer broadcasts the beacon (S401), and cannot perform the coordinating function, a new coordinator is needed to perform the coordinating function. As described above, when the coordinator does not broadcast the beacon, the devices are not able to receive the beacon.

Devices constituting the WVAN each wait for a predetermined wait time when the beacon is lost (S410 and S420). If the beacon transmitted from another device is not received during the waiting time, the beacon is broadcasted by itself (S430).

The priority for the coordination function of each device constituting the WVAN is determined by the device characteristics of each device (e.g., the type of power supply, remaining power, etc.) and the network situation (e.g., the number of accessible devices). ) May be determined according to the evaluation criteria established. The wait time for each device is preferably determined using the priority for the adjustment function. That is, if the priority of the adjustment function is different for each device, the waiting time is also set differently. For example, it is preferable to set the waiting time to be shorter as the priority of the adjustment function is higher.

In FIG. 4, it is assumed that priorities of the adjustment functions of the first device 41 and the second device 42 configuring the WVAN are determined to be 20 and 10, respectively. Here, it is assumed that the higher the priority for the adjustment function, the more suitable as the adjuster. When a beacon loss occurs, a device having a higher priority may first establish a relationship between the waiting time and the priority by various methods in order for the waiting time to end first and broadcast the beacon to become a new controller. When the devices on the network receive the beacon broadcasted by another device during the waiting time, the waiting state is terminated (S440).

5 is a process flow diagram according to one preferred embodiment of the present invention. Hereinafter, the recovery process will be described in more detail with reference to FIG. 5.

The DME of the coordinator transmits an MLME-BEACON.req primitive to request a beacon transmission to the coordinator's MLME (S500). The MLME of the coordinator broadcasts the beacon so that devices belonging to the WVAN region can receive the signal (S510). The MLME of each device that receives the broadcast beacon transmits an MLME-BACON.ind primitive to inform the DME of the device that the beacon has been received (S520 and S521).

A condition in which the coordinator, which was broadcasting the beacon, can no longer broadcast the beacon occurs (S530). In this case, each device will not receive the beacon at the timing when the beacon should be received. When a beacon loss occurs, each device checks whether or not the beacon is received for a predetermined waiting time. A timer may be used to know if the predetermined waiting time has passed. That is, the timer is operated in the case of the beacon loss (S540, S550). The timer is used to check whether a predetermined time has elapsed, and the timer may be used without being limited to the name as long as it functions as described above.

The start timing of the timer operation may be immediately after the beacon loss occurs. When the beacon is transmitted periodically, the timer is preferably operated at the next beacon transmission timing immediately after the beacon is lost. If the beacons are sent periodically, it is desirable to set the time at which the timer can start operation by an integer multiple of the beacon interval. For example, when the beacon transmission interval is 50ms, the timer operation time may be set to 50 * n (ms). It is desirable to start operation at the closest timing after the beacon loss has occurred.

For each of the devices, it is necessary to define what reference to the waiting time to be set in the timer. The wait time may be determined according to the priority of the adjustment function of each device. The priority of each device indicates the degree to which each device is suitable to be a regulator, and is determined in consideration of device characteristics, network conditions, and the like. The priority may be set to have a higher number of devices that are more suitable as coordinators (first case), or may be set to have lower numbers as more suitable (second case).

In the first case, the relationship between the waiting time and the priority number must be set in inverse relationship so that a more suitable device can be determined as a new coordinator. An example of a method of determining the waiting time will be described below using Equation 1.

mMaxBeaconMiss (m) = (255-priority (m)) * nConst

In Equation 1, mMaxBeaconMiss (m) denotes a waiting time of the m-th device, priority (m) denotes the priority information of the m-th device as a decimal number, and nConst denotes a predetermined constant value. That is, when the waiting time of the timer is set according to Equation 1, the higher the priority number, the smaller the waiting time.

In the case of the second case, a more suitable device can be determined as a new coordinator only when the relationship between the waiting time and the priority number is set in proportion. The above-described method of determining the waiting time can be applied without being limited to the above-described method as long as a device that is more suitable as a regulator can be implemented to have a shorter waiting time set.

In some cases, two or more devices having the same priority number may be generated because some or all of the conditions for determining the priority of the adjustment function may match. If the priority number is the same, the waiting time will be set to the same, so if no action is taken, multiple devices will broadcast beacons. In this case, the waiting time is determined by considering other information in addition to the priority of the adjustment function. In addition to the above priority, a device identifier designated at the time of network subscription may be further considered. When a device joins a network, it is assigned a predetermined ID. The device ID is used to prevent a plurality of beacons from being broadcast at the same time by making a difference in the waiting time. For example, if the priority is the same, a device having a large device ID may be a coordinator.

If the timer set to the waiting time is activated and the beacon is not transmitted from another device until the timer is completed after the waiting time has passed, the DME of the first device having completed the timer requesting to broadcast a beacon by itself as a new controller to the MLME. In order to transmit the MLME-BEACON.req primitive (S560). The MLME of the first device broadcasts the beacon (S570). The beacon preferably includes information that the first device is a new regulator.

The MLME of the second device transmits an MLME-BEACON.ind primitive to the DME of the second device to inform that it has received the beacon (S580). Since the beacon has been received, the timer operating in the second device stops the operation of the timer before the waiting time is completed (S590).

In another embodiment, when the beacon loss occurs (S530), each device may transmit a message requesting the beacon to the coordinator. The coordinator may use a superframe structure in which timing control for the channel time resource is shown. If a device does not receive the beacon at the timing at which the beacon is to be transmitted, it may send a timing information request message to the coordinator during CBCP to request timing information transmitted through the not received beacon. If the beacon is not transmitted even though the request message is transmitted using the CBCP, each device starts a timer having a waiting time set. The dash time is likewise determined with a value corresponding to the priority for the adjustment function. The timing at which the timer operates is immediately after the CBCP elapses. When the beacon is transmitted periodically, the timer is preferably operated at the next beacon transmission timing immediately after the beacon is lost.

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 exemplary embodiments described above are to be understood as illustrative and not restrictive in all respects. The scope of the present invention is indicated by the following claims rather than the detailed description, and the meaning and scope of the claims and All changes or modifications derived from the same concept will be construed as being included in the scope of the present invention.

According to the present invention, communication can be performed smoothly in a wireless network. In particular, there may be an effect capable of continuous communication without being affected by the situation of a particular device. In addition, there may be an effect that a device more suitable as a coordinator may be determined as a new coordinator by using priority information. Furthermore, it would be desirable to perform a recovery operation without defining a new MAC command, in which case the recovery operation can be performed more simply.

Claims (10)

A method of performing communication in a particular device of a wireless network comprising a coordinator and one or more devices, Receiving a first beacon from the coordinator; Checking whether a second beacon is received for a predetermined time from the first beacon reception time; And If the second beacon is not received, broadcasting a third beacon to the wireless network as a new coordinator; Communication performing method comprising a. The method of claim 1, Wherein the predetermined time includes at least one beacon interval and a wait time. The method of claim 2, And the wait time is determined using a priority for an adjustment function. The method of claim 1, And transmitting information including the new coordinator to the third beacon. A method of performing communication in a wireless network comprising a coordinator and at least two or more devices, the method comprising: The coordinator broadcasting a first beacon; Checking whether the at least two devices receive the second beacon during the waiting time for each device after receiving the first beacon; And Broadcasting a third beacon by a specific device of the at least two devices that has not received a second beacon during its waiting time; Communication performing method comprising a. The method of claim 5, wherein And the wait time is determined using a priority for an adjustment function. The method of claim 6, And wherein the third beacon includes information about a second device acting as the new coordinator. In a wireless network comprising a coordinator and at least one device, Receiving a first beacon from the coordinator; If a second beacon is not received after at least one beacon interval, transmitting a control information request message to the coordinator within a predetermined time; Checking whether a second beacon is received for a predetermined time from the message transmission time; And If the second beacon is not received, broadcasting a third beacon to the network as a new coordinator Communication performing method comprising a. The method of claim 11, And the predetermined time is a contention-based control period (CBCP). The method of claim 11, And said predetermined time comprises a waiting time determined according to a priority for an adjustment function.

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