KR101591585B1 - Method for allocating channel between primary user and secondary user in cognitive radio communication system - Google Patents

Abstract

The present invention relates to a method of allocating channels to a primary user and a secondary user in a wireless cognitive communication system, and more particularly, to a method of allocating channels to a primary user and a secondary user in a wireless cognitive communication system, If the secondary user fails to transmit / receive a packet while using the channel, the primary user monitors whether or not the channel is used, and resumes transmission / reception of the packet by assigning the channel to the secondary user at the end of the channel use of the primary user To a channel assignment method.

Description

[0001] The present invention relates to a method for allocating selective channels between a primary user and a secondary user in a wireless cognitive communication system,

The present invention relates to a method of allocating channels to a primary user and a secondary user in a wireless cognitive communication system, and more particularly, to a method of allocating channels to a primary user and a secondary user in a wireless cognitive communication system, Channel is used. If the secondary user fails to transmit / receive a packet while using the channel, the main user monitors whether the channel is used, allocates the channel to the secondary user at the time when the main user's use of the channel ends, The present invention relates to a method of allocating channels to be resumed. In addition, it is a method of simultaneously sensing the main user and the sub user by using a matching filter out of the method of monitoring the existence of the main user in the conventional fixed time slot. This makes it possible to judge the existence of the main user more quickly and to use the idle frequency more efficiently.

It is necessary to secure a sufficient frequency band in order to satisfy the user's demand for the gradually increasing wireless communication. However, since the radio frequency band available for communication is limited and most of them are already allocated to the existing wireless communication service (hereinafter referred to as "primary user"), securing the frequency band for the new communication service is very difficult .

In order to solve the problem due to lack of frequency, resource management researches that use limited frequency resources more efficiently, such as packet scheduling, transmission capacity adjustment, and multi-hop transmission, have been actively conducted. However, this study has limitations in that it can not solve the physical frequency shortage problem. Much of the frequency band allocated to the main user terminal is very low, and this tendency is particularly noticeable in urban outskirts or in areas with low population density. Cognitive radio has been proposed to maximize the utilization of radio resources by recognizing the use of continuously changing frequency bands and using the empty frequency bands.

The wireless cognitive technology can transmit and receive data even if the channel allocated to the main user terminal is not used for a certain time or in a specific area by using it for communication of an unauthorized secondary user (SU) Technology.

The wireless cognitive technology is largely divided into an overlay technique and an underlay technique. The underlay technique allows the cognitive communication network to transmit data at the same time even if the main user terminal is operating, By using power, the degree of interference experienced by the main user is so low that the communication is not interrupted. On the other hand, the overlay technique is a technique in which, in a channel in which a main user terminal is communicating, a sub user terminal can not transmit / receive data and only a channel having no main user terminal is utilized.

Since the overlay-based cognitive communication network can only use the frequency band after confirming that the main user terminal does not exist, the main user terminal has no obligation to notify its operation to the cognitive communication network, It is necessary to observe the channel status continuously for each time slot of the detection period to check whether the main user terminal starts transmission.

Therefore, in an overlay-based cognitive communication network, it is important not to interfere with the use of the channel of the main user terminal, and at the same time maximize the channel utilization efficiency. If the main user terminal signal is detected in the channel being used, Cease the use of the channel being used and hand off to another available channel.

A method of generating conventional channel prediction allocation information for handing off to a candidate usable channel using conventional channel prediction allocation information will be described below. In the method for generating conventional channel prediction allocation information, a secondary user terminal uses a channel usage of a main user terminal for each channel And allocates a channel usage estimate of the primary user terminal for each detected channel to the estimated time. Herein, the channel use estimation value is obtained by comparing the signal strength of each channel measured by the secondary user terminal with the estimated threshold value. When the signal strength of each channel is larger than the estimated threshold value, a bit value of 1 is assigned as the estimated value, When the intensity is smaller than the estimated threshold value, a bit value of 0 is assigned as the estimated value.

FIG. 1 illustrates an example of a channel use state of a main user terminal for each channel. FIG. 2 illustrates a use state of a channel detected in a detection timeslot of a channel detection period according to a channel use state of a main user terminal And FIG. 3 shows an example of a channel use estimation value allocated to an estimated time.

As shown in FIG. 1, a radio network is composed of a plurality of channels (ch1, ch2, ..., chn), and a main user terminal uses a plurality of channels without being disturbed by a sub user terminal, The secondary user terminal does not interfere with the primary user terminal and selectively uses multiple channels in an overlay manner. Each channel is divided into a busy time (idle) and a busy time used by the main user terminal. During the time that the primary user terminal uses the channel, the channel operates as an unavailable channel, and during the time when the primary user terminal does not use the channel, the channel operates as an available channel. The time during which the main user terminal uses the channel in each channel is made when the signal of the main user terminal is terminated (PU departure) from the start time (PU arrival) of the signal of the main user terminal.

The secondary user terminal senses the signal strength RSSI of each channel during the sensing timeslot ts of the channel sensing period set for each channel to monitor whether each channel is being used by the primary user terminal, The channel use estimation value is allocated to the estimated timeslots of the estimated time te after the detection timeslot ts of each channel detection period. Referring to FIG. 2, which illustrates the channel detection period and the estimated time of each channel, the secondary user terminal detects the first channel (ch1) of the main user terminal during the detection timeslot of the channel detection period set for the first channel And monitors the channel use state of the channel based on the signal strength of the first channel. It is detected that the main user terminal does not use the first channel based on the signal strength of the first channel in the first detection timeslot (ts ₁ ) and the second detection timeslot (ts ₂ ) of the channel detection period, The main user terminal uses the first channel based on the signal strength of the first channel in the third detection timeslot (ts ₃ ), the fourth detection timeslot (ts ₄ ), and the fifth detection timeslot (ts ₅ ) And senses that the main user terminal does not use the first channel based on the signal strength of the first channel in the sixth detection timeslot (ts ₆ ) of the channel detection period again. Similarly, the secondary user terminal monitors whether the primary user terminal is using another channel for the other channels (ch2, ..., chn) based on the signal strength of the other channel during the detection timeslot of the set channel detection period do.

3, which illustrates an example of a channel use estimation value allocated to an estimated timeslot of each estimated time based on the signal strength of each channel detected in each detection timeslot of the channel detection period, It is determined that the main user terminal does not use the first channel in the first detection timeslot (ts ₁ ) and the second detection timeslot (ts ₂ ) of the channel detection period and the first estimation period (te ₁ ) A bit value 0 indicating an idle channel is allocated to a channel use estimation value at a time te ₂ and a third detection timeslot ts ₃ and a fourth detection timeslot ts ₄ ) and the fifth detection timeslots (ts _5), the primary user terminal the third estimated time is determined by using the first channel (te ₃ in), the fourth estimated time (te ₄₎ and the fifth estimation time (te ₅ (1) indicating a busy channel to a channel use estimation value . Similarly, the secondary user terminal estimates an estimation period of the other channels (ch2, ...., chn) according to the determination result of whether or not the primary user terminal uses another channel in each detection timeslot of the channel detection period A bit value (0, 1) indicating an available channel or an unavailable channel is allocated to a timeslot as a channel use estimation value.

The secondary user terminal generates and stores channel prediction allocation information of a bit stream constituted of bit values indicating available or unavailable states for each channel. The secondary user terminal predicts available available candidate channels using the channel prediction allocation information, And performs handoff to the selected candidate available channel to perform communication.

However, in the conventional wireless communication method described above, the secondary user terminal monitors the channel usage state of the first channel of the main user terminal, which is monitored in each detection timeslot of the channel detection period in the first channel (ch1) The channel usage state of the first channel and the channel usage state monitored in the first detection timeslot ts ₁ of the channel detection period in the first estimated time te ₁ are It is the same as not using one channel. However, in the second estimation period te ₂ , the actual usage state of the first channel is different from the channel usage state monitored in the second detection timeslot ts ₂ of the channel detection period. That is, in the second detection timeslot (ts ₂ ) of the channel detection period, the main user does not use the first channel, so that the estimated value of the available channel after the second detection timeslot (ts ₂ ) 0), but the actual main user terminal starts using the first channel in the middle of the second estimation time te ₂ after the second sensing timeslot ts ₂ of the channel sensing period. In this case, the secondary user terminal may determine that the first channel is an available channel at the second estimation time and handoff to the first channel, thereby disturbing the communication of the primary user terminal.

In the fifth detection timeslot (ts ₅ ) of the channel detection period, the main user uses the first channel to detect the bit value of the unavailable channel at every fifth estimation time after the fifth detection timeslot (ts ₅ ) (1), but the actual primary user terminal uses only a fraction of the fifth estimated time. In this case, the secondary user terminal determines all of the fifth estimated time as an unavailable channel and wastes frequency resources because it can not use the first channel during the fifth estimated time.

Also, in the wireless perception communication system, the secondary user terminal must separately allocate a detection timeslot of the channel detection period in order to monitor whether the primary user uses the channel, and the secondary user terminals are synchronized with each other, Should be monitored. Therefore, communication resources are wasted due to allocation of detection timeslots, and all secondary user terminals must be synchronized with each other.

Hereinafter, the main user terminal and the secondary user terminal will be referred to as a primary user and a secondary user.

It is an object of the present invention to monitor whether or not a main user's channel is used in a detection timeslot and to monitor whether a main user's channel is used at a time when a packet to be transmitted / And to provide a method of assigning a channel to a user.

Another object of the present invention is to allocate a separate detection timeslot to monitor whether or not a main user uses a channel for each detection timeslot and allocate a signal search interval only when a packet to be transmitted / And to prevent a waste of communication resources.

It is another object of the present invention to provide a channel allocation method in which all secondary users do not need to be synchronized in order to monitor whether a channel is used in a detection timeslot.

In order to accomplish the object of the present invention, in a channel allocation method of a wireless perception communication system according to the present invention, when transmission / reception of a packet fails during transmission / reception of a packet through a channel allocated to a secondary user, Monitoring if the channel is in use by a primary user; monitoring the time when the channel is transitioning to a dormant state; and if the channel is in use by a primary user, And transmitting and receiving a packet.

Preferably, the channel assignment method of the wireless aware communication system according to the present invention determines whether the channel is in a use state or a dormant state according to whether a channel is used by a main user or a peripheral user, And assigning a channel to a secondary user if the secondary channel is not available.

If there is a packet to be transmitted or received by the secondary user in the channel assignment method of the wireless aware communication system according to the present invention, a first signal search interval is allocated to determine whether the channel is in use state or idle state, And allocates the channel to the secondary user when the channel is in the idle state.

Here, when the channel is determined to be in the use state during the first signal search interval, the secondary user is maintained in the sleep mode for the set time.

The first signal search interval is reallocated after the sleep mode is terminated to determine whether the channel is in the use state or the idle state.

In the channel allocation method of the wireless perception communication system according to the present invention, when transmission / reception of a packet fails during transmission and reception of a packet through a channel allocated to a secondary user, a second signal search interval is allocated to determine whether the channel is being used by the primary user .

In the channel allocation method of the wireless perception communication system according to the present invention, when a channel is being used by a main user, a third signal search interval is allocated to monitor a time point when the channel is converted into a dormant state.

Preferably, the first signal search interval, the second signal search interval, and the third signal search interval comprise at least two timeslots.

Herein, the channel allocation method of the wireless cognitive communication system according to an embodiment of the present invention determines that the channel is in the use state when the average value of the signal strength of the channel exceeds the state threshold value, The channel is determined to be in a rest state.

In the channel assignment method of the wireless cognitive communication system according to an embodiment of the present invention, the main user and the sub user transmit and receive packets in different communication standard formats. Whether the channel is being used by the main user is determined by using a matching filter .

Meanwhile, the channel allocation apparatus of the wireless perception communication system according to an embodiment of the present invention determines whether a channel is in a use state or a dormant state according to whether a channel is used by a main user or a neighbor user, A channel assignment unit for assigning a channel to a secondary user when the terminal is idle during a first signal search interval, a transmission / reception monitoring unit for monitoring whether or not the transmission / reception of the packet is successful over the allocated channel, A main user determination unit for stopping transmission and reception of a packet through the channel and determining whether the channel is being used by the main user during the second signal search interval; A conversion judging unit for monitoring a time point of conversion from the use state to the dormant state; When, in succession over a channel it characterized in that it comprises a transmission control unit for transmitting and receiving control packets.

Here, the channel allocation unit maintains the sleep mode for a predetermined time when the channel is determined to be in the use state during the first signal search interval, reassigns the first signal search interval after the sleep mode ends, It is determined which state it is.

The channel allocation method of the wireless cognitive communication system according to the present invention has the following various effects.

First, the channel allocation method of the wireless perception communication system according to the present invention monitors whether or not the main user's channel is used in the detection timeslot, Thus, the channel can be allocated to the secondary user depending on whether the actual channel is used or not.

Second, in the channel allocation method of the wireless perception communication system according to the present invention, a separate detection timeslot is allocated to monitor whether the main user's channel is used for each detection timeslot, and only when a sub- By monitoring the use of the channel by allocating the interval, waste of communication resources due to the allocation of the repeated detection timeslot can be prevented.

Thirdly, since the channel allocation method of the wireless perception communication system according to the present invention does not need to be synchronized in order to monitor whether or not the channels are used in the detection timeslots of all the sub users, a channel can be allocated to the sub users in a simple structure.

FIG. 1 shows an example of a channel use state of a main user terminal for each channel.
2 illustrates a state of use of a channel detected in the detection timeslot of the channel detection period according to the channel use state of the main user terminal.
FIG. 3 shows an example of a channel use estimation value allocated to an estimated time.
FIG. 4 is a functional block diagram of a channel allocation apparatus of a wireless LAN system according to the present invention.
5 is a flowchart illustrating a method of allocating channels in a wireless cognitive communication system according to the present invention.
FIG. 6 is a flowchart illustrating a method for assigning a channel to a secondary user in the channel allocation method of the wireless cognitive communication system according to the present invention.
FIG. 7 is a flowchart for explaining a step of determining whether a channel is used by a main user in a channel allocation method of a wireless local area communication system according to the present invention.
8 is a diagram for explaining an example of a method of assigning a channel to a secondary user in a wireless cognitive communication system according to the present invention.
9 is a diagram for explaining an example of a method for selectively allocating a channel to a primary user and a secondary user in the wireless cognitive communication system according to the present invention.

Hereinafter, a method of allocating channels in a wireless communication system according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 4 is a functional block diagram of a channel allocation apparatus of a wireless LAN system according to the present invention.

4, the channel usage determination unit 110 allocates a first signal search interval when a packet to be transmitted by a secondary user is present, and detects a signal strength of the channel during a first signal search interval Whether the channel is used by a main user or a neighboring user determines that the channel is in a use state used by a main user or a neighboring user or a dormant state that the main user or the neighboring user is not using.

The channel allocation unit 120 allocates and controls the channel to the secondary user when the channel is in the idle state during the first signal search period. The transmission / reception unit 130 transmits the packet to the counterpart terminal through the allocated channel.

The transmission / reception monitoring unit 140 monitors whether a packet is successfully transmitted to the counterpart terminal through the transmission / reception unit 130. When it is determined that a packet has not been successfully transmitted to the counterpart terminal through the transmission / reception monitoring unit 140, And transmits a transmission disable message to the transmission / reception control unit 170. The transmission / reception control unit 170, which has received the transmission disable message, stops transmission of the packet through the transmission / reception unit 130.

On the other hand, when receiving the transmission disable message from the transmission / reception monitoring unit 140, the main user determination unit 150 determines whether the channel is being used by measuring the signal strength of the channel during the second signal search interval, If so, it is determined whether the channel is being used by the main user again. Here, it is assumed that the primary user and the secondary user transmit and receive packets according to different communication standards, and the packet formats according to the communication standard used by the primary user and the secondary user are different from each other.

When the channel is being used by the main user, the conversion determination unit 170 allocates consecutive timeslots to determine whether the channel is being used by the main user. The main user monitors the point at which the channel changes from the use state to the dormant state during the third signal search period because the channel is not used. The conversion determination unit 170 generates a conversion detection message and provides the conversion detection message to the transmission / reception control unit 170 when the time when the channel is changed from the use state to the rest state is detected during the third signal search interval.

Upon receiving the conversion detection message from the conversion determination unit 160, the transmission / reception control unit 170 controls the transmission / reception unit 130 to continuously transmit and receive the remaining packets.

5 is a flowchart illustrating a method of allocating channels in a wireless cognitive communication system according to the present invention.

5, when there is a packet to be transmitted by the secondary user, the secondary user determines whether or not the channel is used by measuring the signal strength of the channel, and when the packet is in the idle state in which the current channel is not used, A channel is allocated to the user (S110). Preferably, if the current channel is being used by a main user or a peripheral user, the secondary user may measure the signal strength of the channel, calculate the average signal strength during the measurement period, and if the average signal strength is greater than the threshold strength It is determined that the channel is in the use state used by the main user or the peripheral user. If the average signal strength is smaller than the threshold strength, the channel is determined to be in the idle state in which the channel is not used.

If transmission / reception of a packet fails during transmission / reception of a packet using a channel allocated by the secondary user, transmission / reception of the packet is stopped through the channel and a second signal detection interval is allocated to determine whether the channel is used by the main user S120). Since the primary user has usage priority over the channel, the primary user transmits the packet over the channel if there is a packet to send / receive without monitoring whether the channel is being used by the secondary user. By this transmission of the main user, the secondary user fails to transmit / receive the packet during transmission / reception.

From the time when the channel is used by the main user, the secondary user allocates a third signal search interval to measure the signal strength of the channel, and when there is a signal of a threshold strength or more in the channel, it is determined that the channel is being used by the main user (S130). A third signal search interval is repeatedly assigned to determine whether the channel is being used by the main user and the signal of the channel is measured during the third signal search interval, It is determined that it has been converted into the idle state which is no longer used (S140).

When the channel is changed to the dormant state, the secondary user continuously transmits and receives the remaining packets including the packet that failed to transmit / receive (S150).

FIG. 6 is a flowchart illustrating a method for assigning a channel to a secondary user in the channel allocation method of the wireless cognitive communication system according to the present invention.

More specifically, referring to FIG. 6, it is determined whether there is a packet to be transmitted by the secondary user (S111). If there is a packet to be transmitted by the secondary user, a first signal search interval is allocated (S112), and it is determined whether the channel is in use during the allocated first signal search interval (S113). In the present invention, instead of monitoring whether a channel is used periodically for each detection timeslot even when there is no packet to be transmitted, a first signal search interval is allocated only when a packet to be transmitted by a secondary user exists, By monitoring status, it is possible to prevent channel resources and energy wastage, and it is not necessary for all the sub users to be synchronized in order to monitor the channel use status per detection timeslot. If the channel is idle during the first signal search period, the channel is allocated to the secondary user so that the secondary user can transmit the packet (S115).

Meanwhile, if it is determined that the channel is in use during the first signal search interval, the sub-user enters the sleep mode for the set time even if there is a packet to be transmitted (S117). The secondary user does not perform operations such as monitoring the use state of the channel, transmitting / receiving a packet, etc. during the sleep mode. In step S119, it is determined whether the sleep mode for the set time has ended. If the sleep mode for the set time is ended, a first signal search interval is allocated again to determine whether the channel is in the use state do.

FIG. 7 is a flowchart for explaining a step of determining whether a channel is used by a main user in a channel allocation method of a wireless local area communication system according to the present invention.

More specifically, referring to FIG. 7, in step S121, it is determined whether a sub-user has failed to transmit a packet while a channel is allocated and a packet is being transmitted. Since the primary user has priority over the channel even though the secondary user is transmitting the packet through the channel, the primary user transmits the packet through the channel without monitoring the use state of the channel. In this case, due to the signals transmitted from the secondary user and the primary user, they interfere with each other, and the secondary user can not successfully transmit the packet. The determination of whether the secondary user has failed to transmit the packet determines that the transmission of the packet is failed if the secondary user fails to receive a reception complete message (ACK) from the other terminal after transmitting the packet to the counterpart terminal.

If the packet transmission fails, the transmission of the packet is stopped even before the sub-user completes the packet transmission (S123), and it is determined whether the channel is currently being used by the main user (S125). In the cognitive radio communication system according to the present invention, the primary user and the secondary user communicate with each other using a communication scheme of different communication standards. For example, the primary user communicates according to a 3G mobile communication standard, The secondary user performs communication according to the fourth-generation mobile communication standard, and can distinguish the primary user's signal from the secondary user's signal based on the format of the packet transmitted by the primary user and the secondary user according to each communication standard. Preferably, in one embodiment of the present invention, whether a main user is using a channel is determined using a matching filter corresponding to a communication specification of the main user.

8 is a diagram for explaining an example of a method of assigning a channel to a secondary user in a wireless cognitive communication system according to the present invention. Carrier Sense Multiple Access / Collision Avoidance (CSMA / CA) is basically used in order to allocate channels in the wireless aware communication system according to the present invention.

8, the sub-user SU1 having a packet to be transmitted monitors whether a channel is being used during a backoff (t1), which is an arbitrary number of timeslots (ED) before transmission of a packet, do. If it is determined that the channel is in use during the backoff (t1), a backoff composed of an arbitrary number of timeslots is again allocated to determine whether the channel is being used.

However, if the channel is in the idle state during the backoff t1, the first signal search interval DIFS and the DCF interframe space t2 are again allocated to determine whether the channel is idle during the first signal search interval t2. Here, the first signal search period t2 is composed of a short interframe space (SIFS) and at least two or more timeslots (ED), so that the channel should be continuously monitored in a dormant state in two or more timeslots It is judged to be in a rest state. And allocates a channel to the secondary user SU1 when the channel is in the idle state during the first signal search period t2.

The sub-user SU1 transmits a request to send (RTS) message to the counterpart terminal when the channel is allocated, and receives a clear response message (CTS) in response to the transmission request message from the counterpart terminal The packet is transmitted to the counterpart terminal.

The sub-user SU2 located adjacent thereto monitors whether a channel is being used during a back-off t6 composed of an arbitrary number of timeslots when there is a packet to be transmitted, and the sub- When the channel is being monitored in use, it enters the sleep mode (t7) of the set time. If the sleep mode is terminated, it is monitored whether a channel is in use during a backoff (t8) consisting of an arbitrary number of timeslots. If the channel is in a rest state during backoff (t8), a first signal search interval t9 is allocated, Is in a rest state during the first signal search period t9. And allocates a channel to the secondary user SU2 when it is in the idle state during the first signal search period t9.

9 is a diagram for explaining an example of a method for selectively allocating a channel to a primary user and a secondary user in the wireless cognitive communication system according to the present invention.

9, when the primary user PU transmits a packet through the channel while the secondary user SU1 receives a channel and receives and transmits a packet, the signal of the secondary user SU1 and the primary user PU The sub user SU1 can not successfully transmit the packet to the counterpart terminal. Because the primary user (PU) has priority over the channel, the primary user (PU) repeatedly tries to transmit the packet even if the packet transmission fails, while the secondary user (SU1) stops transmitting the packet if the packet transmission fails.

The secondary user SU1 stops transmission of the packet and then allocates the second signal search period t3-1 to determine whether the channel is being used by the primary user PU. Here, the second signal search interval is composed of at least two timeslots (ED) and a matching interval (MF), and the channels are continuously monitored in two or more timeslots in use state, and the main user's signal And judges that the channel is used by the main user (PU) when judged.

If it is determined that the channel is used by the primary user PU, the secondary user SU1 allocates a third signal search period t3-2 to monitor whether the channel is used by the primary user PU If the main user PU leaves the channel after the lapse of the third signal search period and does not use the channel, the first signal search interval is allocated as in the method described with reference to FIG. 8 to determine whether or not the channel is used, . Here, the third signal search period t3-2 is composed of at least two consecutive time slices.

On the other hand, the peripheral user SU2 also monitors whether the channel is in use by terminating the sleep mode while the subscriber SU1 is in the sleep mode until a packet to be transmitted exists and the packet transmission of the subscriber SU1 is completed (t6 ) When the channel is judged to be in the use state by the main user (PU), it enters the sleep mode (t7) of the set time again. The peripheral user SU2 monitors whether the channel is in use again after the sleep mode t7 is ended (t8). If the channel is still used by the main user PU, (t9). When the sub-user SU1 transmits the remaining packets after the sleep mode t9 ends, the fourth signal search period t10 is allocated without entering the sleep mode and the packet transmission of the sub-user SU1 is completed Monitor the time.

Preferably, in the present invention, the first signal search section, the second signal search section and the third signal search section include at least two or more timeslots, It is possible to more accurately determine whether the channel is used or not, and determine whether the channel is in the idle state.

The above-described embodiments of the present invention can be embodied in a general-purpose digital computer that can be embodied as a program that can be executed in a computer and operates the program using a computer-readable recording medium.

The computer-readable recording medium may be a magnetic storage medium (e.g., ROM, floppy disk, hard disk, etc.), an optical reading medium (e.g. CD ROM, Lt; / RTI > transmission).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

110: channel use determination unit 120: channel allocation unit
130: Transmitting / receiving unit 140: Transmitting /
150: main user judgment unit 160: conversion judgment unit
170: Transmitting /

Claims (17)

A method for allocating channels to a primary user and a secondary user in a wireless aware communication system,
When the secondary user fails to transmit / receive a packet during transmission / reception of a packet through the channel to which the secondary user is allocated, the secondary user interrupts transmission / reception of the packet through the channel and determines whether the channel is being used by the primary user;
Monitoring a time point at which the channel transitions to a dormant state when the channel is in use by a primary user; And
And transmitting and receiving the packet continuously through the channel when the channel is switched to the dormant state. 2. The method of claim 1,
Determining whether the channel is in a use state or a dormant state according to whether the channel is used by the main user or a peripheral user and allocating a channel to the sub user when the channel is in a dormant state Channel allocation method. 3. The method of claim 2,
If a packet to be transmitted / received by the secondary user exists, a first signal search interval is allocated to determine whether the channel is in use state or idle state,
And allocating a channel to the secondary user when the channel is idle during the first signal search interval. 4. The method of claim 3,
Wherein if the channel is determined to be in use during the first signal search interval, the secondary user remains in a sleep mode for a predetermined time. 5. The method of claim 4,
And reassigning the first signal search interval after the sleep mode is terminated to determine whether the channel is in a use state or a dormant state. 4. The method of claim 3,
Wherein when the secondary user fails to transmit / receive a packet during transmission / reception of a packet through the channel allocated to the secondary user, a second signal search interval is allocated to determine whether the channel is being used by the primary user. 7. The method of claim 6,
And when the channel is being used by a main user, allocating a third signal search interval and monitoring a time point at which the channel is converted into a dormant state. The method of claim 7, wherein the first signal search interval, the second signal search interval, and the third signal search interval comprise at least two timeslots. 9. The method according to any one of claims 1 to 8,
When the average value of the signal strength of the channel exceeds the state threshold value, the channel is determined to be in the use state, and when the average value of the signal strength of the channel is less than the state threshold value, Channel assignment method. 9. The method of any one of claims 1 to 8, wherein the primary user and the secondary user transmit and receive packets in different communication standard formats. 11. The method of claim 10,
Wherein the determining whether the channel is in use by a primary user is performed using a matching filter. An apparatus for allocating channels to a primary user and a secondary user in a wireless cognitive communication system,
A channel use judging unit for judging whether the channel is in a use state or a rest state according to whether a channel is used by a main user or a neighboring user;
A channel assignment unit for assigning and controlling the channel to the sub-user when the mobile station is idle during a first signal search interval;
A transmission / reception monitoring unit for monitoring a transmission / reception success of a packet through the channel allocated to the sub user;
A main user judging unit for suspending transmission / reception of a packet through the channel and determining whether the channel is being used by a main user during a second signal search interval when transmission / reception of the packet fails;
A conversion determination unit for monitoring a time point at which the channel changes from a use state to a rest state during a third signal search interval when the channel is being used by a main user; And
And a transmission / reception controller for controlling transmission / reception of the packet continuously through the channel when the channel is converted into a dormant state. 13. The apparatus of claim 12, wherein the channel assigning unit
And maintains the sleep mode for a predetermined time when the channel is determined to be in use during the first signal search interval. 14. The apparatus of claim 13, wherein the channel assignment unit
Wherein the controller determines whether the channel is in a use state or a dormant state by reallocating the first signal search interval after the sleep mode is terminated. The apparatus as claimed in any one of claims 12 to 14, wherein the first signal search section, the second signal search section and the third signal search section comprise at least two timeslots. Allocation device. 15. The apparatus as claimed in any one of claims 12 to 14,
When the average value of the signal strength of the channel exceeds the state threshold value, the channel is determined to be in the use state, and when the average value of the signal strength of the channel is less than the state threshold value, Channel assignment device. 15. The method according to any of claims 12 to 14, wherein the main user and the sub user transmit and receive packets in different communication standard formats,
Wherein the main user determination unit determines whether the channel is being used by the main user using a matching filter.

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