KR20120023575A - System and method for managing resource in communication system - Google Patents

Abstract

PURPOSE: A resource management system in a communication system and a method thereof are provided to define an interface for the share of frequency and to transmit a signal according to the defined interface. CONSTITUTION: If the usable frequency bands of systems are searched in a first frequency wideband, a CM(Coexistence Manager)(120) manages a plurality of systems. A CE(Coexistence Enabler)(150) transmits system information. A CDIS(Coexistence Discovery and Information Server)(110) supports the control of the CE about the systems.

Description

System and method for managing resource in communication system

The present invention relates to a communication system, and more particularly, to a resource management system and method for managing to share a plurality of frequency resources in a communication system.

In the current communication system, active researches are being conducted to provide users with services of various quality of service (QoS) having a high transmission speed (hereinafter referred to as 'QoS'). In such a communication system, studies are being actively conducted to provide a large capacity service having various QoS using limited resources, for example, frequency resources. In particular, with the development of radio communication technology and the emergence of new wireless communication services, there is a need to use finite frequency resources more efficiently.

In order to increase the utilization efficiency of the limited frequency resources in the communication system, it is possible to optimize the performance of the communication system, for example, to maximize the spectral efficiency through multiple access, encoding, modulation, information compression, etc. Minimized interference has been proposed, and a frequency sharing scheme has been proposed to increase the efficiency of use of frequency resources by using a frequency band usable in a frequency band already in use, such as a TV band.

Here, frequency sharing in a frequency band usable in a frequency band already in use, such as the aforementioned TV band, is a frequency that can be used without interfering with a primary incumbent having preferential use rights for the TV band. Since the band should be used, it is important to detect the usable frequency band by checking whether the primary license holder uses the frequency band in the TV band. In addition, when there are a plurality of different systems that want to use the available frequency band detected in the TV band, the available frequency may be due to a difference in a communication method, for example, a wireless connection method, between the plurality of different systems. There is a problem in coexistence for using the band.

In other words, in the current communication system, when there are a plurality of different systems that want to use the available frequency band detected by the TV band as described above, the plurality of different systems efficiently uses the detected available frequency band. There is no specific resource management scheme for use, and in particular, there are no schemes for efficiently using frequency resources because different communication systems coexist to use the available frequency band.

Therefore, after detecting a usable frequency band in a frequency band that is already in use, such as a TV band in a communication system, a plurality of different systems, for example, systems of different communication schemes, coexist to efficiently detect the available usable frequency band. A resource management plan is needed to use it.

Accordingly, an object of the present invention is to provide a resource management system and method in a communication system.

It is another object of the present invention to provide a resource management system and method for efficiently using a plurality of systems coexist (coexistence) in the frequency band available in the frequency band already in use in the communication system.

In addition, another object of the present invention is a system for managing frequency resources to coexist through transmission and reception of signals according to an interface for sharing and frequency sharing of a plurality of systems in a communication system to use a frequency band usable in a TV band; In providing a method.

A system of the present invention for achieving the above objects is a resource management system in a communication system including a plurality of systems that do not have a right to use a first frequency band, wherein the plurality of systems in the first frequency band A coexistence manager (CM) for managing the plurality of systems for coexistence and frequency sharing of the plurality of systems in the usable frequency band when a usable frequency band is found; A coexistence enabler (CE) for transmitting and receiving the information of the plurality of systems and the information of the coexistence manager; And a coexistence discovery and information server (CDIS) for supporting control of the coexistence manager for the plurality of systems; Information of the plurality of systems is between the coexistence manager, the coexistence enabler, and the coexistence discovery and information server, according to an interface defined between the coexistence manager, the coexistence enabler, and the coexistence discovery and information server. Transmitted and received; The plurality of systems use the available frequency band by coexistence and frequency sharing by transmitting and receiving information according to the interface.

According to an aspect of the present invention, there is provided a method of managing a resource of a first frequency band in a communication system including a plurality of systems that do not have a right to use a first frequency band. Defining an interface between objects in the usable frequency band for coexistence and frequency sharing of the plurality of systems in the usable frequency band if a frequency band available for the plurality of systems is found in the frequency band; Transmitting and receiving information between the plurality of systems by transmitting and receiving a message between the objects according to the interface; And transmitting and receiving information of the plurality of systems to coexist and share the frequencies in the usable frequency band to use the available frequency band.

The present invention defines an interface for coexistence and frequency sharing of a plurality of systems in a communication system, and transmits and receives a signal according to the defined interface, thereby allowing the plurality of systems to coexist with the TV band through coexistence and frequency sharing. Likewise, the frequency resources are managed to use the available frequency bands in the frequency bands that are already in use. Accordingly, the limited efficiency of the frequency resources can be improved by more efficiently using the limited frequency resources.

1 is a view schematically showing the structure of a resource management system in a communication system according to an embodiment of the present invention.
2 to 4 are diagrams for explaining the interface definition between the CM and the CE of the resource management system in the communication system according to an embodiment of the present invention.
5 to 7 are diagrams for explaining the interface definition between the CM and CDIS of the resource management system in the communication system according to an embodiment of the present invention.
8 to 12 are diagrams for explaining an interface definition between CMs of a resource management system in a communication system according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that in the following description, only parts necessary for understanding the operation according to the present invention will be described, and descriptions of other parts will be omitted so as not to distract from the gist of the present invention.

The present invention relates to a frequency band already in use, such as in a TV band in a communication system, such as a Cognitive Radio (CR) system, an IEEE 802.19 based system, or an IEEE 802.22 based system. We propose a resource management system and method for detecting and efficiently using available frequency bands. Here, in the embodiment of the present invention, a CR system and a system based on IEEE 802.19 and IEEE 802.22 are described as an example, but the resource management scheme proposed by the present invention can be applied to other communication systems.

In addition, in an embodiment of the present invention, an interface for coexistence and frequency sharing of a plurality of different systems in a communication system is defined, and the plurality of systems coexist by transmitting and receiving signals according to the defined interface. And a resource management system and method for efficiently sharing a frequency band available in a TV band by performing frequency sharing. Here, in the embodiment of the present invention, an interface between each object of the resource management system for sharing the frequency band usable in the communication system is defined, and each object of the resource management system according to the defined interface By transmitting and receiving a signal, a plurality of different systems, in particular, systems of different communication schemes, such as wireless access schemes, coexist, sharing a frequency band that is available in the frequency band already in use, such as in a TV band. Improve the efficiency of use of frequency resources.

That is, the embodiment of the present invention proposes an interface of a resource management system for coexistence and frequency sharing between a plurality of different systems in a communication system, and uses limited frequency resources by sharing a frequency band available through such an interface. Improve the efficiency. Here, in the embodiment of the present invention, a frequency in a frequency band that can be used in a frequency band that is already in use, such as a TV band, is shared, and at this time, to a primary incumbent who has preferential use rights for the TV band. Since the available frequency band should be used without interference, it is necessary to check whether the primary license holder uses the frequency band in the TV band, to detect the available frequency band, and to use the available frequency band detected in the TV band. A plurality of different systems uses the detected available frequency bands through coexistence and frequency sharing. Next, a resource management system in the communication system according to an exemplary embodiment of the present invention will be described in more detail with reference to FIG. 1.

1 is a diagram schematically illustrating a structure of a resource management system in a communication system according to an exemplary embodiment of the present invention.

Referring to FIG. 1, when the plurality of systems want to use a frequency band usable in a frequency band that is already in use, such as a TV band, the resource management system uses frequency sharing in the plurality of different systems. The sharing devices 140 and 160 to improve the frequency sharing efficiency between the sharing devices that want to use the available frequency band, for example, the sharing device 1 140 and the sharing device 2 160 and the sharing devices 140 and 160. Coexistence Managers (CMs), which are referred to as CMs hereinafter, for example, are included in the CM1 120 and the CM2 130 and the shared devices 140 and 160, respectively. Coexistence Enabler (CE), which serves as a path between the CMs 120 and 130, ie, CE1 140 and CE2 170. And a server supporting control of the shared devices 140 and 160 of the CMs 120 and 130, such as a coexistence discovery and information server (CDIS).

As described above, the sharing devices 140 and 160 may have a primary license holder (hereinafter, referred to as a “primary system”) that has a priority to use the TV band. When not using the frequency band of other users who do not have a preferential use rights for the TV band (hereinafter referred to as 'Secondary System') that can use a predetermined frequency band in the TV band It refers to devices of a plurality of different systems, that is, sub-systems to be detected and used in the frequency band. Here, the sharing devices 140 and 160 share and use the predetermined frequency band through coexistence and frequency sharing in order to use limited frequency resources more efficiently.

As described above, the CEs 150 and 160 are included in the shared devices 140 and 160, respectively, to transmit and receive the information of the shared devices 140 and 160 and the information of the CMs 120 and 130. Here, in the embodiment of the present disclosure, for convenience of description, the CEs 150 and 160 are included in the shared devices 140 and 160, but the CEs 150 and 160 exist as independent objects or It may be included in the CMs 120 and 130.

In addition, the CEs 150 and 160 may include context information related to corresponding shared devices 140 and 160 requested by the CMs 120 and 130, for example, a wireless access scheme, transmission power, and spectrum sensing threshold of the shared devices 140 and 160. Information such as a value, a location, and the like are extracted from the shared devices 140 and 160 and transmitted to the CMs 120 and 130. That is, the CEs 150 and 160 obtain context-related information of different sub-systems and transmit the communication related information of the respective sub-systems to the CMs 120 and 130.

The CEs 150 and 160 may request a request of the CMs 120 and 130 for managing the shared devices 140 and 160, for example, a request for context information and configuration of the shared devices 140 and 160. And, upon request, to update context information of the shared devices 140 and 160 and to reset, or reconfigure, the configuration of the shared devices 140 and 160. In other words, the CEs 150 and 160 receive the changed information of the context information, that is, the event information of the shared devices 140 and 160 as a request for the context information of the shared devices 140 and 160, and the event information. The context information of the shared devices 140 and 160 is updated accordingly. In addition, the CEs 150 and 160 receive a component reset of the shared devices 140 and 160 as a request for configuration of the shared devices 140 and 160, and the shared devices 140 and 160 according to the component reset. ), That is, reconfigure.

The CMs 120 and 130 determine an operation frequency allocation, a transmission power allocation, and a transmission time allocation to improve frequency sharing efficiency between the sharing devices 140 and 160. In other words, the CMs 120 and 130 may use the shared devices 140 and 160 in the usable frequency band to improve the frequency sharing efficiency between the shared devices 140 and 160 for the frequency band available in the aforementioned TV band. The operating frequency allocation, the transmission power allocation, and the transmission time allocation.

Here, the CMs 120 and 130 may transmit and receive information with CMs of shared devices that do not correspond to them, for example, context information and events of shared devices, in order to further improve frequency sharing efficiency between the shared devices 140 and 160. Information is transmitted and received to perform operation frequency allocation, transmission power allocation, and transmission time allocation of the corresponding shared device in the usable frequency band. In this case, the CMs 120 and 130 obtain and transmit and receive context information and event information of shared devices that do not correspond to other CMs directly, or transmit and receive with other CMs through the CDIS 110. In addition, the CMs 120 and 130 obtain information on spectrum use in the main system through an external database, or request other CMs to reset components of shared devices corresponding to them.

As described above, the CDIS 110 supports a control operation of the CMs 120 and 130 for frequency sharing of the sharing devices 140 and 160 with respect to a frequency band usable in the TV band. That is, the CDIS 110 receives and stores the context information and the event information of the shared devices 140 and 160 from the CMs 120 and 130, and the shared devices according to the request of the CMs 120 and 130. Context information and event information of 140 and 160 are transmitted to the CMs 120 and 130. In addition, the CDIS 110 obtains and stores information about spectrum use in the main system through an external database.

In the communication system according to the exemplary embodiment of the present invention, the resource management system may share a frequency band usable in a frequency band already used in the main system, such as a TV band, that is, use of the shared devices 140 and 160. The CDIS 110, the CMs 120 and 130, and the CEs 140 and 160 are included for coexistence and frequency sharing. Here, the shared devices 140 and 160, as described above, are devices of secondary systems for sharing and using the available frequency band. (AP: Access Point, hereinafter referred to as "AP"), Service Access Point (SAP: Service Access Point, hereinafter referred to as "SAP"), and the terminal. In addition, the sub-systems are a plurality of different systems to share the usable frequency band as described above, and may be systems of different communication methods, for example, an IEEE 802.19 based system and an IEEE 802.22 based system. .

In addition, the resource management system in the communication system according to an embodiment of the present invention, for the coexistence and frequency sharing of the shared devices 140,160 for the frequency band available in the frequency band that is already in use, that is, of different communication schemes A reference model is defined to be shared and used by a plurality of systems, and in particular, each reference model for coexistence and frequency sharing of different systems for each of the CDIS 110, the CMs 120 and 130, and the CEs 140 and 160. Define. In addition, the resource management system, as described above, for the coexistence and frequency sharing of the shared devices (140, 160), that is, a plurality of systems of different communication schemes to use the CM (120,130), and An interface for each of the CEs 140 and 160 is defined.

Here, in the communication system according to an embodiment of the present invention, an interface between each object defined by the resource management system, that is, the CDIS 110, the CMs 120 and 130, and the CEs 140 and 160 is the CM. Interfaces 120 and 130 and CEs 140 and 160, interfaces between the CMs 120 and 130 and the CDIS 110, and interfaces between the CMs 120 and 130, respectively. In this case, the interface between the CM (120, 130), as described above, by using a plurality of different systems share the available frequency band, there is a CM to manage each of the shared devices of the plurality of systems, respectively Accordingly, the resource management system defines an interface between a plurality of CMs respectively corresponding to the plurality of systems. In particular, a master CM in which any CM controls the remaining CMs in the plurality of CMs, and a slave CM controlled by the master CM, and the resource management system includes: Defines the interface between the CM and the slave CM. The resource management system also defines an interface between any CM in the plurality of CMs and a neighbor CM adjacent to the any CM.

In addition, the resource management system, the CDIS (110), the CM (120, 130) to define the interface between the CDIS (110), the CM (120, 130), and the CE (140, 160) that is each object And a state machine of the CEs 140 and 160. In this defined state machine, an interface is defined by transmitting and receiving a message between the CDIS 110, the CMs 120 and 130, and the CEs 140 and 160. Here, in the state machine of the CDIS 110, the CMs 120, 130, and the CEs 140, 160, the state is inactive, active, waiting engagement, engagement (engaged), request sent, and request received.

The inactive means a state before the initialization of each object and the interface setup with another object is impossible, and the active indicates a state prepared to enable interface setup with another object. it means. The weighting engagement may refer to a state of waiting for a response of the request from the counterpart object after requesting an interface setup from the counterpart object, and the engagement may be completed by setting up an interface with the counterpart object. This means that a message can be sent and received. In addition, the request transmission refers to a state of waiting for a response of the transmitted message from the counterpart object after transmitting a message including a request item to the counterpart object, and receiving the request from the counterpart object. After receiving the included message, it refers to a state of processing a request item of the counterpart object. Next, the interface definition between the CM and the CE of the resource management system in the communication system according to an embodiment of the present invention will be described in more detail with reference to FIGS. 2 to 4.

2 to 4 are diagrams for explaining the interface definition between the CM and the CE of the resource management system in the communication system according to an embodiment of the present invention. 2 is a diagram schematically illustrating a state diagram of the CM in the interface definition between the CM and the CE of the resource management system, and FIG. 3 illustrates the interface between the CM and the CE of the resource management system. FIG. 4 is a diagram schematically illustrating a state diagram of the CM, and FIG. 4 is a diagram schematically illustrating a message transmission / reception procedure between the CM and the CE for defining an interface between the CM and the CE of the resource management system.

First, the state of the CM will be described with reference to FIG. 2. In the interface definition between the CM and the CE of the resource management system, the CM is in an active state through an initialization process 224 in an inactive state 202. Switch to 204. The CM transitions to the inactive state 202 through a shutdown 222 in the active state 204.

In addition, when the CM receives a connection request from the CE in the active state 204, the CM transmits a connection response to the CE in response to the connection request. send connection response) 216, and transitions to engagement state 200.

In addition, the CM, the context information (CI: Context Information) / event information (EV: EVENT infromation) / reconfiguration (RC) request (CI / EV /) of the shared device from the engagement state 200 to the CE Send (RC request) (send CI / EV / RC request) 218, and switch to the request transmission state 206, and in response to the request transmission, context information / event information / reconfiguration response (CI / EV / RC). When a response is received from the CE (receive CI / EV / RC response) 220, the state is switched to the engagement state 200. Herein, the CM transmits the reconfiguration request to the CE according to a coexistence decision of the CM in the engagement state 200 (218), and switches to the request transmission state 206. Receiving a reconfiguration response response from CE (220), it switches to the engagement state 200.

In addition, the CM, when there is no request of the CM in the engagement state 200, when a specific event predetermined by the CM occurs in the CE, an event response response (EV response) corresponding to the generated event is generated. Receive 212 from the CE. In addition, the CM periodically receives a engagement-engagement request from the CE in the engagement state 200 (receive being-engagement request 210), and the engagement state 200 Keep it.

In addition, the CM may receive a disconnection request from the CE in the engagement state 200, or periodically a engagement-engagement request from the CE in the engagement state 200. If it is not received (receive disconnection request or fail to receive being-engagement request) 214, the connection to the CE is terminated, and then the active state 204 is switched.

Next, the state of the CE will be described with reference to FIG. 3. In the interface definition between the CM and the CE of the resource management system, the CE is activated through an initialization process 328 in an inactive state 302. The state 304 is switched. The CE is then switched to the inactive state 302 through a shutdown 326 in the active state 304.

In addition, the CE transitions to a weighting gauge state 308 after sending a connection request 320 to the CM in the active state 304. When the CE does not receive a connection response from the CM within a predetermined time in the weighting engagement state 308 (no connection response) 322, the CE switches to the active state 304. On the other hand, when the CE receives a connection response from the CM within the predetermined time in the weighting engagement state 308 (receive connection response) 324, it is switched to the engagement state 300.

In addition, when the CE receives the context information / event information / reconfiguration request of the shared device from the CM in the engagement state 300 (receive CI / EV / RC request) 316, the request reception state 306. In response to the request reception, context information, event information, and reconfiguration response are transmitted to the CM (send CI / EV / RC response) 318 and the engagement state 300 is switched.

The CE transmits an event information response corresponding to the generated event to the CM when a specific event predetermined by the CM occurs in the CE even if there is no request of the CM in the engagement state 300. Send EV response 312. In addition, the CE periodically sends an engagement maintenance request 310 to the CM in the engagement state 300 to maintain the engagement state 300.

In addition, the CE sends a disconnection request 314 to the CM in the engagement state 300, terminates the connection with the CM, and then switches to the active state 304. do.

4, the message transmission / reception between the CM and the CE for the interface between the CM and the CE will be described. In the disengaged state 470, for example, the CE 405 in the active state, the non-gauge state In operation 410, for example, a connection request message is transmitted to the CM 400 that is active. At this time, the CE 405, after transmitting the access request message, timer 1 (472) of the CE (405) for checking whether the response to the access request from the CM (400) within a predetermined time. ) Is activated and the CE 405 is switched to the weighting gauge state.

The CM 400 receives a connection request message from the CE 405 and transmits a connection response message to the CE 405 in response to the connection request message (step 412). . At this time, the CM 400 is switched from the non-gauge state 440 to the engagement state 450 by transmitting the message, the response response message, the CM 400 in the engagement state 450, A period for maintaining is set, and the timer 1 452, the timer 2 454, and the timer 3 456 of the CM 400 are operated for each period for the engagement gauge in the engagement state 450.

In addition, the CE 405 receives the connection response message from the CM 400 while the timer 1 472 of the CE 405 is operating, that is, within a predetermined time period, and the CE 405 is non-gauge. The state 470 is switched to the engagement state 480 and the timer 2 482 of the CE 405 in the engagement state 480 according to the period for maintaining the engagement set in the CM 400. Timer 3 484 and timer 4 486 are operated.

Herein, the CE 405 requests an engagement maintenance when the timer 1 452 of the CM 400 and the timer 2 482 of the CE 405 are terminated according to the period for maintaining the engagement. message (step 422), and the CE 405 at the time when timer 2 454 of CM 400 and timer 3 484 of CE 405 expire. An engagement maintenance request message is transmitted to the CM 400 (step 428).

In the engagement state 450, the CM 400 sends a context info. Request message for requesting context information of a shared device to the CE 405 of the engagement state 480. (Step 414). Then, the CE 405 receives the context information request message and receives a context info. Response message including context information in response to the context information request message. Send to the CM 400 (step 416).

In addition, in the engagement state 450, the CM 400 transmits an event request message for requesting event information of a shared device to the CE 405 of the engagement state 480. (Step 418). Then, the CE 405 receives the event information request message and includes an event information response including event information corresponding to an event generated by the CE 405 in response to the event information request message. Message) is transmitted to the CM 400 in the engaged state 450 (step 420). Here, the CE 405 of the engagement state 480 may generate an event predetermined by the CM 400 in the CE 405 even if the CE 405 does not receive an event information request message from the CM 400. If so, an event response message including event information corresponding to the generated event is transmitted to the CM 400 in the engagement state 450 (step 430).

In addition, in the engagement state 450, the CM 400 sends a reconfiguration request message for reconfiguring, i.e., reconfiguring, a shared device, and the CE 405 of the engagement state 480. (Step 424). Then, the CE 405 receives the reconfiguration request message, reconfigures the configuration of the shared device in response to the event information request message, and then includes a reconfiguration response message including information about the reconfiguration. Transmits to the CM 400 in the engaged state 450 (step 426).

In this case, when the CE 405 of the engagement state 480 intends to terminate the connection with the CM 400, the CE 405 may disconnect from the engagement state 480. ) Message is transmitted to the CM 400 in the engaged state 450 (step 432), the CE 405 in the engaged state 480 terminates the connection with the CM 400. And the non-gauge state 490, i.e., the active state. In addition, the CM 400 of the engaged state 450 receives the non-connection request message and terminates the connection with the CE 405, and then transitions to the non-gauge state 460, that is, the active state. . Then, the interface definition between the CM and the CDIS of the resource management system in the communication system according to an embodiment of the present invention will be described in more detail with reference to FIGS. 5 to 7.

5 to 7 are diagrams for explaining the interface definition between the CM and CDIS of the resource management system in the communication system according to an embodiment of the present invention. 5 is a diagram schematically illustrating a state diagram of the CM in the interface definition between the CM and the CDIS of the resource management system, and FIG. 6 is a diagram illustrating the CDIS in the interface definition between the CM and the CDIS of the resource management system. FIG. 7 is a diagram schematically illustrating a state diagram, and FIG. 7 schematically illustrates a procedure of transmitting and receiving a message between the CM and the CDIS for defining an interface between the CM and the CDIS of the resource management system.

First, the state of the CM will be described with reference to FIG. 5. In the interface definition between the CM and the CDIS of the resource management system, the CM is in an active state through an initialization process 544 in an inactive state 502. Switch to 504. In addition, the CM transitions from the active state 504 to the inactive state 502 through a shutdown 542.

In addition, the CM transitions to a weighting engagement state 508 after sending a connection request 536 to the CDIS in the active state 504. If the CM does not receive a connection response from the CDIS within a predetermined time in the weighting engagement state 508 (no connection response) 538, the CM switches to the active state 504. Meanwhile, when the CM receives a connection response from the CDIS within the predetermined time in the weighting engagement state 508 (receive connection response) 540, the CM switches to the engagement state 500.

In addition, when the CM receives a context information / event information request (CI / EV request) of a shared device from the CDIS in the engagement state 500 (receive CI / EV request) 528, the request reception state ( 506), and transmits a context information / event information response (CI / EV response) to the CDIS (send CI / EV response) 530 in response to receiving the request, and returns to the engagement state 500. Is switched.

The CM transmits an event information response corresponding to the generated event to the CDIS when a specific event predetermined by the CDIS occurs in the CM even if the CDIS request is not received in the engagement state 500. A send EV response 524. In addition, the CM periodically sends an engagement maintenance request to the CDIS in the engagement state 500 (send being-engagement request) 520 to maintain the engagement state 500.

In addition, the CM transmits the context information / event information request of the shared device to the CDIS in the engagement state 500 (send CI / EV request) 532, and then transitions to the request transmission state 510. In response to the request transmission, a context information / event information response is received from the CDIS (receive CI / EV response) 534, and the engagement state 500 is switched.

The CM receives an event information response corresponding to the generated event from the CDIS when a specific event predetermined by the CM occurs in the CDIS even when there is no request of the CM in the engagement state 500. Receive EV response 522. In addition, the CM transmits a disconnect connection request to the CDIS in the engagement state 500 (send disconnection request) 526, and terminates the connection with the CDIS, and then switches to the active state 504. .

Next, the state of the CDIS will be described with reference to FIG. 6. In the interface definition between the CM and the CDIS of the resource management system, the CDIS is activated through an initialization process 630 in an inactive state 602. Switch to state 604. The CDIS transitions to the inactive state 602 through a shutdown 628 in the active state 604.

In addition, when the CDIS receives a connection request from the CM in the active state 604, after transmitting a connection response to the CM in response to the connection request (receive connection request and send connection response) 618, The state of engagement 600 is entered.

In addition, when the CDIS receives a context information / event information request of a shared device from the CM in the engagement state 600 (receive CI / EV request) 620, the CDIS is switched to the request reception state 606. In response to receiving the request, a context information / event information response is transmitted to the CM (send CI / EV response) 622 to be switched to the engagement state 600.

The CDIS transmits an event information response corresponding to the generated event to the CM when a specific event predetermined by the CM occurs in the CDIS even if there is no request of the CM in the engagement state 600. Send EV response 614.

In addition, the CDIS transmits the context information / event information request of the shared device to the CM in the engagement state 600 (send CI / EV request) 624, and then transitions to the request transmission state 608. In response to the request transmission, a context information / event information response is received from the CM (receive CI / EV response) 626, and is switched to the engagement state 600.

In addition, the CDIS, when there is no request of the CDIS in the engagement state 600, when a specific event predetermined by the CDIS occurs in the CM, receives the event information response corresponding to the generated event from the CM (receive EV response) (612).

In addition, the CDIS periodically receives an engagement maintenance request from the CM in the engagement state 600, and maintains the engagement state 600.

In addition, when the CDIS receives a disconnection request from the CM in the engagement state 600 or periodically does not receive an engagement maintenance request from the CM in the engagement state 600 (receive disconnection request) or fail to receive being-engagement request) 616, and terminates the connection with the CE, and then transitions to the active state 604.

7, the message transmission / reception between the CM and the CDIS for the interface between the CM and the CDIS is described. In the non-gauge state 770, for example, the CM 705 in the active state, the non-gauge state 740 is described. For example, a connection request message is transmitted to the active CDIS 700 (step 710). At this time, the CM 705 transmits the access request message, and then the timer 1 772 of the CM 705 for checking whether the response to the access request is received from the CDIS 700 within a predetermined time. ) Is operated and the CM 705 is switched to the weighting gauge state.

The CDIS 700 receives a connection request message from the CM 705 and transmits a connection response message to the CM 705 in response to the connection request message (step 712). . In this case, the CDIS 700 is transmitted from the non-gauge state 740 to the engagement state 750 by transmitting the response message, the CDIS 700 in the engagement state 750, the engagement A period for maintaining is set, and the timer 1 752, the timer 2 754, and the timer 3 756 of the CDIS 700 are operated for each period for the engagement maintenance in the engagement state 750.

In addition, when the CM 705 receives the connection response message from the CDIS 700 while the timer 1 772 of the CM 705 is operating, that is, within a predetermined time, the CM 705 is non-gauge. The timer 2782 of the CM 705 is changed from the state 770 to the engagement state 780 and the engagement state 780 according to the interval for maintaining the engagement set by the CDIS 700. Timer 3 784 and timer 4 786 are operated.

In this case, the CM 705 requests an engagement maintenance when the timer 1 752 of the CDIS 700 and the timer 2 782 of the CM 705 expire according to the period for maintaining the engagement. message (step 722) to the CDIS 700, and at the time when timer 2 754 of the CDIS 700 and timer 3 784 of the CM 705 expire, the CM 705 An engagement maintenance request message is transmitted to the CDIS 700 (step 732).

In addition, in the engagement state 780, the CM 705 may send a context info. Request message for requesting context information of a shared device from the CDIS 700 of the engagement state 750. (Step 714). Then, the CDIS 700 receives the context information request message and receives the context info. Response message including the context information in response to the context information request message. Send to the CM 705 (step 716).

In addition, in the engagement state 750, the CDIS 700 sends a context info. Request message for requesting context information of a shared device to the CM 705 of the engagement state 780. (Step 718). Then, the CM 705 receives the context information request message and includes a context info. Response message including context information in response to the context information request message. Transmit to the CDIS 700 (step 720).

In the engaged state 750, the CDIS 700 transmits an event request message for requesting event information of a shared device to the CM 705 of the engaged state 780. (Step 724). Then, the CM 705 receives the event information request message and includes an event information response including event information corresponding to an event generated in the CM 705 in response to the event information request message. Message is transmitted to the CDIS 700 in the engaged state 750 (step 726). In this case, the CM 705 in the engagement state 780 may generate an event designated by the CDIS 700 in the CM 705 even if the CM 705 does not receive an event information request message from the CDIS 700. If so, an event response message including event information corresponding to the generated event is transmitted to the CDIS 700 in the engagement state 750 (step 736).

In addition, in the engagement state 780, the CM 705 sends an event request message for requesting event information of a shared device to the CDIS 700 of the engagement state 750. Transmit (step 728). Then, the CDIS 700 receives the event information request message, and includes an event information response including event information corresponding to an event generated in the CDIS 700 in response to the event information request message. Message is transmitted to the CM 705 in the engaged state 780 (step 730). In this case, the CDIS 700 in the engagement state 750 does not receive an event information request message from the CM 705, but an event predetermined by the CM 705 occurs in the CDIS 700. If so, an event response message including event information corresponding to the generated event is transmitted to the CM 705 in the engagement state 780 (step 734).

At this time, when the CM 705 in the engagement state 780 wants to terminate the connection with the CDIS 700, the CM 705 in the engagement state 780, a disconnection request (disconnection request) ) Message is transmitted to the CDIS 700 in the engaged state 750 (step 738), the CM 705 in the engaged state 780 terminates the connection with the CDIS 700. The non-gauge state 790 is switched to the active state. In addition, the CDIS 700 in the engaged state 750 receives the disconnected request message and terminates the connection with the CM 705, and then switches to the non-engaged state 760, that is, the active state. . Then, the interface definition between the CMs of the resource management system in the communication system according to an embodiment of the present invention will be described in more detail with reference to FIGS. 8 to 12.

8 to 12 are diagrams for explaining an interface definition between CMs of a resource management system in a communication system according to an exemplary embodiment of the present invention. In particular, FIGS. 8 to 10 are diagrams illustrating an interface definition between a master CM and a slave CM of the resource management system, and FIGS. 11 and 12 illustrate an interface definition between an arbitrary CM and an adjacent CM of the resource management system. It is a figure explaining. 8 is a diagram schematically illustrating a state diagram of the master CM in the interface definition between the master CM and the slave CM of the resource management system, and FIG. 9 is an interface between the master CM and the slave CM of the resource management system. FIG. 10 is a diagram schematically illustrating a state diagram of the slave CM in a definition, and FIG. 10 schematically illustrates a message transmission / reception procedure between the master CM and the slave CM for defining an interface between a master CM and a slave CM of the resource management system. One drawing. FIG. 11 is a diagram schematically illustrating a state diagram of a CM in an interface definition between an arbitrary CM and an adjacent CM of the resource management system, and FIG. 12 is an interface between an arbitrary CM and an adjacent CM of the resource management system. A diagram schematically illustrating a message transmission / reception procedure between the arbitrary CM and the neighbor CM for definition.

In the communication system according to an embodiment of the present invention, when one master CM and a plurality of slave CMs are connected when defining an interface between CMs of the resource management system, that is, a plurality of slave CMs are connected to one master CM. When connected and the centralized topology between the CMs (centralized topology), the resource management system controls the slave CMs to be controlled by the master CM for coexistence and frequency sharing of the slave CMs. In this case, the resource management system defines the interface between the CMs, as shown in FIG. Also, when a plurality of CMs are connected to each other without a predetermined rule, that is, when a plurality of CMs are in a distributed topology, the resource management system controls one CM to coexist and share frequency among CMs in cooperation with neighboring CMs. In addition, the resource management system defines an interface between CMs as shown in FIGS. 11 and 12.

First, the state of the master CM will be described with reference to FIG. 8. In the interface definition between the master CM and the slave CM of the resource management system, the master CM is initialized in an inactive state 802. Transitions to the active state 804. The master CM transitions to the inactive state 802 through a shutdown 826 in the active state 804.

In addition, when the master CM receives a connection request from the slave CM in the active state 804, after receiving a connection response to the slave CM in response to the connection request (receive connection request and send connection response) ( 816, transition to engagement state 800.

In addition, when the master CM receives a context information request of a shared device from the slave CM in the engagement state 800 (receive CI request) 818, the master CM switches to a request reception state 806, and receives the request. A context information response is sent to the slave CM in response to (send CI response) 820, and the state is switched to the engagement state 800.

In addition, the master CM transmits the context information / event information / reconfiguration request of the shared device to the slave CM in the engagement state 800 (send CI / EV / RC request) 822. 808, and when the context information / event information / reconfiguration response is received from the slave CM in response to the request transmission (receive CI / EV / RC response) 824, the state transitions to the engagement state 800. do. Here, the master CM transmits the reconfiguration request to the slave CM according to the coexistence determination of the master CM in the engagement state 800 (822), and switches to the request transmission state 808, and the slave Upon receipt of the reconfiguration response response from the CM (824), the state transitions to the engagement state 800.

And, even if there is no request of the master CM in the engagement state 800, the master CM, if a specific event predetermined by the master CM occurs in the slave CM, the event information response corresponding to the generated event Receive from the slave CM (receive EV response) (812). In addition, the master CM periodically receives an engagement maintenance request from the slave CM in the engagement state 800 (receive being-engagement request) 810 to maintain the engagement state 800.

In addition, when the master CM receives a connectionless request from the slave CM in the engagement state 800 or fails to periodically receive an engagement maintenance request from the slave CM in the engagement state 800 ( receive disconnection request or fail to receive being-engagement request) 814, and after the connection with the slave CM is terminated, transitions to the active state 804.

Next, the state of the slave CM will be described with reference to FIG. 9. In the interface definition between the master CM and the slave CM of the resource management system, the slave CM is initialized in an inactive state 902 (initialization) 942. Transitions to the active state 904. The slave CM transitions to the inactive state 902 through a shutdown 940 in the active state 904.

In addition, the slave CM transitions to a weighting gauge state 910 after transmitting a connection request from the active state 904 to the master CM (send connection request) 934. When the slave CM does not receive a connection response from the master CM within a predetermined time in the weighting engagement state 910 (no connection response) 935, the slave CM switches to the active state 904. Meanwhile, when the slave CM receives a connection response from the master CM within the predetermined time in the weighting engagement state 910 (receive connection response) 938, the slave CM switches to the engagement state 900.

In addition, when the slave CM transmits a context information request of a shared device to the master CM in the engagement state 900 (send CI request) (930), the slave CM switches to the request transmission state (908) and transmits the request. In response to the context information response is received from the master CM (receive CI response) (932), it is switched to the engagement state (900).

In addition, when the slave CM receives the context information / event information / reconfiguration request of the shared device from the master CM in the engagement state 900 (receive CI / EV / RC request) 926, the request reception state ( 906, and transmits context information, event information, and reconfiguration response to the master CM (send CI / EV / RC response) 928 in response to receiving the request, and then switches to the engagement state 900. do.

In addition, the slave CM, when there is no request of the master CM in the engagement state 900, when a specific event previously designated by the master CM occurs in the slave CM, an event information response corresponding to the generated event is generated. Send to the master CM (send EV response) (922). In addition, the slave CM periodically sends an engagement maintenance request to the master CM in the engagement state 900 to maintain the engagement state 900.

In addition, the slave CM transmits a disconnection request to the master CM in the engagement state 900 (send disconnection request) 924, and terminates the connection with the master CM. Is converted to).

Then, referring to FIG. 10, when the message transmission / reception between the master CM and the slave CM for the interface between the master CM and the slave is described, the non-gauge state 1070, for example, the slave CM 1005 in the active state, is non-gauge. In step 1010, a connection request message is transmitted to the master CM 1000 that is in the state 1040. At this time, the slave CM (1005), after transmitting the connection request message, the timer of the slave CM (1005) for checking whether the response to the connection request from the master CM (1000) within a predetermined time. 1 1072 is operated and the slave CM 1005 transitions to the weighting gauge state.

In addition, the master CM 1000 receives a connection request message from the slave CM 1005 and transmits a connection response message to the slave CM 1005 in response to the connection request message ( Step 1012). In this case, the master CM 1000 is switched from the non-gauge state 1040 to the engagement state 1050 by transmitting the call response message, the master CM 1000 in the engagement state 1050, The interval for maintaining the gauge is set, and the timer 11052, the timer 21054, and the timer 3 1056 of the master CM 1000 are set for each period for the engagement maintenance in the engagement state 1050. It works.

In addition, when the slave CM 1005 receives the connection response message from the master CM 1000 while the timer 1 1072 of the slave CM 1005 is operating, that is, within a predetermined time, the slave CM 1005. ) Is switched from the non-gauge state 1070 to the engagement state 1080, and the slave CM 1005 in the engagement state 1080 according to the period for maintaining the engagement set in the master CM 1000. Timer 2 1082, Timer 3 1084, and Timer 4 1086 are operated.

Here, the slave CM 1005 requests an engagement maintenance at a time point at which timer 1 1052 of the master CM 1000 and timer 2 1082 of the slave CM 1005 expire according to the period for maintaining the engagement. (being-engagement request) message to the master CM (1000) (step 1022), and at the time when timer 2 (1054) of master CM (1000) and timer 3 (1084) of slave CM (1005) end. The slave CM 1005 transmits an engagement maintenance request message to the master CM 1000 (step 1032).

In addition, in the engagement state 1050, the master CM 1000 sends a context info. Request message for requesting context information of a shared device to the slave CM in the engagement state 1080. Transmit to step 1005 (step 1014). Then, the slave CM 1005 receives the context information request message and receives a context info. Response message including context information in response to the context information request message. (Step 1016).

In addition, in the engagement state 1080, the slave CM 1005 sends a context info. Request message for requesting context information of a shared device, in the master CM of the engagement state 1050. And transmits to 1000 (step 1018). Then, the master CM 1000 receives the context information request message and transmits a context info. Response message including context information in response to the context information request message to the engagement state 1080. In step 1020, it transmits to the slave CM 1005.

In addition, in the engagement state 1050, the master CM 1000 sends an event request message for requesting event information of a shared device to the slave CM 1005 in the engagement state 1080. (Step 1024). Then, the slave CM 1005 receives the event information request message, and includes an event information response including event information corresponding to an event generated in the slave CM 1005 in response to the event information request message. event response) is transmitted to the master CM 1000 in the engaged state 1050 (step 1026). Here, the slave CM 1005 in the engaged state 1080 may receive an event specified by the master CM 1000 even if the master CM 1000 does not receive an event information request message from the master CM 1000. In step 1005, an event response message including event information corresponding to the generated event is transmitted to the master CM 1000 in the engagement state 1050 (step 1034).

In addition, in the engaged state 1050, the master CM 1000 sends a reconfiguration request message for reconfiguring, i.e., reconfiguring, the shared device. (Step 1028). Then, the slave CM 1005 receives the reconfiguration request message, reconfigures the configuration of the shared device in response to the event information request message, and then reconfigures a response including information on the reconfiguration. The message is transmitted to the master CM 1000 in the engaged state 1050 (step 1030).

In this case, when the slave CM 1005 in the engaged state 1080 wants to terminate the connection with the master CM 1000, the slave CM 1005 in the engaged state 1080 requests for disconnection. (step 1036) after the message (disconnection request) is sent to the master CM 1000 in the engagement state 1050, the slave CM 1005 in the engagement state 1080, the master CM (1000) Is terminated and the state is switched to the non-gauge state 1090, that is, the active state. In addition, the master CM 1000 of the engaged state 1050 receives the non-connection request message and terminates the connection with the slave CM 1005, and then enters the non-gauge state 1060, that is, the active state. Is switched.

Next, referring to FIG. 11, a state of an arbitrary CM in the distributed topology is described. In the interface definition between a CM and an adjacent CM of the resource management system, the CM is initialized in an inactive state 1102. 1146 is switched to the active state 1104. In addition, the CM switches to the inactive state 1102 through a shutdown 1144 in the active state 1104.

In this case, when the CM requests a connection to the neighbor CM, the CM transmits a connection request from the active state 1104 to the neighbor CM (send connection request) 1138, and a weighting gauge state 1110. Is switched to. When the CM does not receive a connection response from the adjacent CM within a predetermined time in the weighting engagement state 1110 (no connection response) 1140, the CM switches to the active state 1104. On the other hand, when the CM receives a connection response from the neighboring CM within the predetermined time in the weighting engagement state 1110 (receive connection response 1142), it is switched to the engagement state 1100.

On the other hand, when the neighbor CM requests a connection to the CM, when receiving the connection request from the neighbor CM in the active state 1104, after transmitting a connection response to the neighbor CM in response to the connection request, (receive connection request and send connection response) (1128), it is switched to the engagement state (1100).

In addition, when the CM receives a context information / event information request of a shared device from the neighbor CM in the engagement state 1100 (receive CI / EV request) 1130, the CM is switched to the request reception state 1106. In response to receiving the request, a context information / event information response is transmitted to the adjacent CM (send CI / EV response) 1132, and the state is switched to the engagement state 1100. Here, the CM, when there is no request of the CM in the engagement state 1100, when a specific event predetermined by the CM occurs in the neighbor CM, the CM informs the event information response corresponding to the generated event to the neighbor CM. Receive from (receive EV response) 1122.

In addition, the CM transmits a context information / event information request of a shared device to the neighbor CM in the engagement state 1100 (send CI / EV request) 1134 and is switched to the request transmission state 1108. When a context information / event information response is received from the neighbor CM in response to the request transmission (receive CI / EV response) 1136, the state is switched to the engagement state 1100. Here, the CM, when there is no request of the neighbor CM in the engagement state 1100, when a specific event predetermined by the neighbor CM occurs in the CM, the event information response corresponding to the generated event is the neighbor Send to CM (send EV response) 1124. In addition, the CM maintains the engagement state 1100 by periodically transmitting and receiving an engagement maintenance request with the neighboring CM in the engagement state 1100 (send / receive being-engagement request) 1120. .

In addition, the CM transmits / receives a non-connection request with the neighbor CM in the engagement state 1100, or the CM requests a connection request to periodically maintain an engagement gauge from the neighbor CM in the engagement state 1100. If it does not receive (send / receive disconnection request or fail to receive being-engagement request) (1126), after the connection with the adjacent CM is terminated, it is switched to the active state (1104).

As described above, when the CM requests a connection, the CM periodically transmits an engagement maintenance request to the adjacent CM in the engagement state 1100 (1120), and the engagement state 1100. In addition, the connection state 1100 transmits a connectionless request to the adjacent CM in the engagement state 1100, terminates the connection with the master CM, and then switches to the active state 1104. When the neighbor CM requests access, the CM periodically receives an engagement maintenance request from the neighbor CM in the engagement state 1100 (1120), and maintains the engagement state 1100. In addition, when the connection state 1100 receives a connectionless request from the neighbor CM or does not receive an engagement maintenance request (1126), the connection to the slave CM is terminated and then switched to the active state 1104. do.

Then, referring to FIG. 12, when the message transmission / reception between the CM and the neighbor CM for the interface between the arbitrary CM and the neighbor CM is described, the neighbor CM 1205 in the non-gauge state 1270, for example, the active state, A connection request message is transmitted to the non-gauge state 1240, for example, the CM 1200 that is active (step 1210). Here, in the interface definition between the arbitrary CM and the neighboring CM, as described above, the CM requests the access and the neighboring CM requests the connection, but the detailed description thereof has been described in detail with reference to FIG. 11. In the following description, a case where the CM requests a connection for convenience of description will be described.

After transmitting the access request message, the neighbor CM 1205 that transmits the access request message to the CM 1200 receives whether a response to the access request is received from the CM 1200 within a predetermined time. Timer 1 1272 of adjacent CM 1205 is operated to confirm that the adjacent CM 1205 is switched to the weighting gauge state.

The CM 1200 receives a connection request message from the neighbor CM 1205 and transmits a connection response message to the neighbor CM 1205 in response to the connection request message (1212). step). In this case, the CM 1200 is transmitted from the non-gauge state 1240 to the gage state 1250 by transmitting the response message, the CM 1200 in the gage state 1250, the gage A period for maintaining is set, and the timer 11252, the timer 21254, and the timer 3 1256 of the CM 1200 are operated for each period for the engagement gauge in the engagement state 1250.

In addition, when the neighbor CM 1205 receives the connection response message from the CM 1200 while the timer 1 1272 of the neighbor CM 1205 is operating, that is, within a predetermined time, the neighbor CM 1205 Is changed from the non-gauge state 1270 to the engagement state 1280, and the timer of the adjacent CM 1205 in the engagement state 1280 according to the period for maintaining the engagement set in the CM 1200. 2 (1282), timer 3 (1284), and timer 4 (1286) are operated.

Herein, when the timer 11252 of the CM 1200 and the timer 21282 of the neighbor CM 1205 are terminated according to the period for maintaining the engagement, the neighbor CM 1205 requests an engagement maintenance request ( and transmits a being-engagement request message to the CM 1200 (step 1222) and the neighbor CM at the time when timer 21254 of CM 1200 and timer 3 1284 of neighbor CM 1205 expire. 1205 transmits an engagement maintenance request message to the CM 1200 (step 1228).

In addition, in the engagement state 1280, the adjacent CM 1205 may send a context info. Request message for requesting context information of a shared device. 1200) (step 1214). Then, the CM 1200 receives the context information request message, and receives the context info. Response message including the context information in response to the context information request message in the engagement state 1280. Transmits to the adjacent CM 1205 in step 1216.

In the engagement state 1250, the CM 1200 sends a context info. Request message for requesting context information of a shared device to the adjacent CM of the engagement state 1280. 1205) (step 1218). Then, the adjacent CM 1205 receives the context information request message, and receives the context info. Response message including context information in response to the context information request message. In step 1220, it transmits to the CM 1200.

In addition, in the engagement state 1250, the master CM 1200 sends an event request message for requesting event information of a shared device to the adjacent CM 1205 of the engagement state 1280. (Step 1224). Then, the neighbor CM 1205 receives the event information request message and includes an event information response including event information corresponding to an event generated in the neighbor CM 1205 in response to the event information request message. event response) is transmitted to the CM 1200 in the engaged state 1250 (step 1226). Here, the neighbor CM 1205 of the engagement state 1280 is configured to receive an event specified by the CM 1200 even if the event information request message is not received from the CM 1200. When generated in step 1130, an event response message including event information corresponding to the generated event is transmitted to the CM 1200 in the engaged state 1250 (step 1230).

At this time, when the neighbor CM 1205 in the engagement state 1280 is to terminate the connection with the CM 1200, in the engagement state 1280, the neighbor CM 1205, the connectionless request ( After a disconnection request) message is transmitted to the CM 1200 in the engaged state 1250 (step 1232), the adjacent CM 1205 in the engaged state 1280 terminates the connection with the master CM. And the non-gauge state 1290, that is, the active state. In addition, the CM 1200 of the engaged state 1250 receives the non-connection request message and terminates connection with a slave CM, and then transitions to a non-engaged state 1260, that is, an active state.

Thus, in the communication system according to an embodiment of the present invention, the resource management system detects a frequency band that can be used by a plurality of systems in a frequency band that the main system is already using, such as a TV band, and the plurality of systems in the usable frequency band. Interfaces are defined as described above for coexistence and frequency sharing of systems, that is, interfaces between CEs, CMs, and CDIS, respectively, and context information of the plurality of systems through transmission and reception of signals according to the interfaces, Event information and reconfiguration related information are transmitted and received, thereby allowing a plurality of systems to share and use the available frequency band through coexistence and frequency sharing.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the scope of the following claims, but also by the equivalents of the claims.

Claims (20)

A resource management system in a communication system including a plurality of systems that do not have a right to use a first frequency band,
A coexistence manager (CM) that manages the plurality of systems for coexistence and frequency sharing of the plurality of systems in the usable frequency band when the frequency band available for the plurality of systems is found in the first frequency band. );
A coexistence enabler (CE) for transmitting and receiving the information of the plurality of systems and the information of the coexistence manager; And
A coexistence discovery and information server (CDIS) supporting control of the coexistence manager for the plurality of systems;
Information of the plurality of systems is between the coexistence manager, the coexistence enabler, and the coexistence discovery and information server, according to an interface defined between the coexistence manager, the coexistence enabler, and the coexistence discovery and information server. Transmitted and received;
The plurality of systems, the transmission and reception of the information according to the interface, the resource management system, characterized in that to use the available frequency band by coexistence and frequency sharing.
The method of claim 1,
And the information of the plurality of systems includes context information, event information, and reconfiguration related information.
The method of claim 2,
The interface is defined between the coexistence manager and the coexistence enabler;
The coexistence enabler, via the interface, transmits to the coexistence manager a response message including a connection request message and the context information, the event information, and the reconfiguration related information in the coexistence enabler. Resource management system characterized by.
The method of claim 3,
The coexistence manager, via the interface, transmits a connection response message and a request message requesting the context information, the event information, and the reconfiguration related information in the coexistence enabler to the coexistence enabler. Resource management system characterized by.
The method of claim 4, wherein
The coexistence enabler, through the interface, the resource management system, characterized in that for transmitting and receiving the state maintaining request message to the coexistence manager.
The method of claim 2,
The interface is defined between the coexistence manager and the coexistence discovery and information server;
The coexistence manager may include a connection request message, a request message for requesting the context information and the event information from the coexistence discovery and information server, and the context information and the event information from the coexistence manager through the interface. And transmit an included response message to the coexistence discovery and information server.
The method of claim 6,
The coexistence discovery and information server, through the interface, a connection response message, a request message for requesting the context information and the event information in the coexistence manager, the context information in the coexistence discovery and information server and the And sending a response message including event information to the coexistence manager.
The method of claim 7, wherein
The coexistence manager, via the interface, the resource management system, characterized in that for transmitting and receiving the state maintaining request message to the coexistence discovery and information server.
The method of claim 2,
The coexistence manager includes a plurality of coexistence managers corresponding respectively to the plurality of systems;
The interface is defined between a master coexistence manager and a slave coexistence manager in the plurality of coexistence managers;
And the interface is defined between a first coexistence manager and a neighbor coexistence manager in the plurality of coexistence managers.
10. The method of claim 9,
The slave coexistence manager, through the interface, a connection request message, a request message for requesting the context information in the master coexistence manager, the context information, the event information, and the reconfiguration related in the slave coexistence manager And transmitting a response message including information to the master coexistence manager.
The method of claim 10,
The master coexistence manager, through the interface, a request message for requesting a connection response message, the context information, the event information, and the reconfiguration-related information in the slave coexistence manager, and the context in the master coexistence manager And transmitting a response message including information to the slave coexistence manager.
The method of claim 1,
The slave coexistence manager, through the interface, the resource management system, characterized in that for transmitting and receiving the state maintaining request message to the master coexistence manager.
10. The method of claim 9,
The neighbor coexistence manager, through the interface, a response including a connection request message, a request message for requesting the context information in the first coexistence manager, the context information and the event information in the neighbor coexistence manager Transmitting a message to the first coexistence manager.
The method of claim 13,
The first coexistence manager, through the interface, a request message for requesting a connection response message, the context information and the event information in the adjacent coexistence manager, the context information and the event in the first coexistence manager And transmitting a response message including information to the neighbor coexistence manager.
The method of claim 14,
The first coexistence manager, via the interface, send a transmit / receive state maintaining request message to the neighbor coexistence manager;
The neighbor manager transmits the transceivable state maintaining request message to the first coexistence manager through the interface.
The method of claim 1,
The coexistence manager, the coexistence enabler, and the coexistence discovery and information server are inactive, active, waiting engagement, engaged, and request sent. And state transition to request received.
The method of claim 1,
The coexistence manager determines an operating frequency allocation, a transmission power allocation, and a transmission time allocation of the plurality of systems in the usable frequency band, and receives the context information and the event information of the plurality of systems. Management system.
The method of claim 17,
The coexistence enabler transmits context information and event information of the plurality of systems to the coexistence manager in the usable frequency band;
The context information of the plurality of systems, the resource management system, characterized in that including information on the radio access method, transmission power, spectrum sensing threshold value, and location of the plurality of systems.
A method of managing resources of a first frequency band in a communication system including a plurality of systems that do not have a right to use a first frequency band,
When a frequency band in which the plurality of systems is available in the first frequency band is found, defining an interface between objects in the usable frequency band for coexistence and frequency sharing of the plurality of systems in the usable frequency band. step;
Transmitting and receiving information between the plurality of systems by transmitting and receiving a message between the objects according to the interface; And
And transmitting and receiving information of the plurality of systems, using the available frequency band by coexisting and sharing the frequency in the available frequency band in the usable frequency band.
20. The method of claim 19,
The information of the plurality of systems includes context information, event information, and reconfiguration related information;
The interface may be defined between a coexistence manager (CM), a coexistence enabler (CE), and a coexistence discovery and information server (CDIS).

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