KR102345889B1 - Terminal device and control method thereof - Google Patents

Abstract

The present invention enables adaptive additional access considering the load of the frequency band instead of the unconditional additional access considering only the signal reception strength in the existing CA terminal when the CA terminal additionally accesses the auxiliary frequency band (SCell), We propose a terminal device and an operating method of the terminal device capable of uniformly improving the communication quality of both the terminal and the CA non-supporting terminal.

Description

Terminal device and method of operation of terminal device {TERMINAL DEVICE AND CONTROL METHOD THEREOF}

The present invention enables adaptive additional access in consideration of the load of the frequency band when the CA (Carrier Aggregation) terminal additionally accesses the secondary frequency band (SCell), so that the communication quality of both the CA terminal and the non-CA terminal is evenly It relates to a terminal device that can be improved and a method for operating the terminal device.

In the current LTE system, as the types of communication services and the transmission request speed are diversified, the demand for a higher speed communication system is increasing.

Accordingly, recently, in an LTE system environment in which a plurality of frequency bands coexist, a carrier aggregation (CA) technology is adopted to support a wider frequency band.

CA technology can secure a wider frequency band through the integration of multiple unit frequency bands (Component Carrier, CC), and each frequency band (CC) is used as an LTE frequency band for LTE terminals, so It also maintains compatibility.

A terminal supporting such a CA function (hereinafter, a CA terminal) first accesses the base station through one of a plurality of frequency bands (CC) through a primary cell (PCell), and thereafter, as necessary, a secondary frequency band ( By additionally (simultaneously) accessing the base station through Secondary Cell, SCell), it is possible to use communication services by integrating multiple frequency bands, that is, PCell and SCell.

In this case, the existing method in which the CA terminal additionally accesses the auxiliary frequency band (SCell) is a method of accessing as the auxiliary frequency band (SCell) when the signal reception strength of a candidate frequency band that can be additionally accessed satisfies only a predefined condition to be.

That is, the existing additional access method depends only on the signal reception strength of the candidate frequency band and can additionally access multiple secondary frequency bands (SCell) as long as the signal reception strength is good. can do.

Therefore, due to the unconditional additional access method of the CA terminal, from the standpoint of the non-CA terminal, which must share and use the frequency resource of the base station with the CA terminal, the usable frequency resource is reduced, so communication quality may deteriorate.

Therefore, in the present invention, when the CA terminal additionally accesses the secondary frequency band (SCell), instead of the existing unconditional additional access, it enables adaptive additional access considering the load of the frequency band, so that both the CA terminal and the CA non-supporting terminal We would like to propose a method to evenly improve the communication quality of

The present invention was created in view of the above circumstances, and an object of the present invention is to enable adaptive additional access in consideration of the load of the frequency band when the CA terminal additionally accesses the secondary frequency band (SCell) Accordingly, an object of the present invention is to provide a terminal device and an operating method of the terminal device capable of uniformly improving the communication quality of both the CA terminal and the non-CA terminal.

A terminal device according to a first aspect of the present invention for achieving the above object includes: a connection unit for connecting to a base station through a basic frequency band among a plurality of frequency bands; When additional access with the base station is required, a decision to determine an auxiliary frequency band that satisfies all of the additional access conditions defined in terms of signal reception strength and load among candidate frequency bands excluding the basic frequency band in the plurality of frequency bands wealth; and a control unit further accessing the base station through the determined auxiliary frequency band.

Preferably, the determination unit selects a candidate frequency band to be additionally accessed based on the measured signal reception strength among the candidate frequency bands, and a specific frequency band in which a load of the selected candidate frequency bands is equal to or greater than a predefined threshold load. After excluding from the additional access target, a candidate frequency band to be an additional access target may be determined as an auxiliary frequency band.

Preferably, the determination unit excludes a specific frequency band in which a load is greater than or equal to a predefined threshold load in the candidate frequency band, and then selects a frequency band to be additionally accessed based on the measured signal reception strength among the remaining candidate frequency bands. By selection, a candidate frequency band to be additionally accessed may be determined as an auxiliary frequency band.

Preferably, the determining unit is configured to, when an additional connection with the base station is required again in a situation in which the basic frequency band is the same, the remaining candidates excluding a specific frequency band excluded from the immediately preceding auxiliary frequency band determination process from the candidate frequency band Among the frequency bands, it is possible to determine an auxiliary frequency band in which the signal reception strength satisfies a predefined condition.

Preferably, the load amount may be a PRB usage rate checked for each frequency band from the base station.

According to a second aspect of the present invention, there is provided a method of operating a terminal apparatus for achieving the above object, comprising: an access step of connecting to a base station through a basic frequency band among a plurality of frequency bands; When additional access with the base station is required, a decision to determine an auxiliary frequency band that satisfies all of the additional access conditions defined in terms of signal reception strength and load among candidate frequency bands excluding the basic frequency band in the plurality of frequency bands step; and an additional access step of further accessing the base station through the determined auxiliary frequency band.

Preferably, in the determining step, a candidate frequency band to be additionally connected is selected based on the measured signal reception strength from among the candidate frequency bands, and a load of the selected candidate frequency band is greater than or equal to a predefined threshold load. After the band is excluded from the additional access target, a candidate frequency band that is an additional access target may be determined as an auxiliary frequency band.

Preferably, in the determining step, after excluding a specific frequency band in which a load is greater than or equal to a predefined threshold load from the candidate frequency band, a frequency band to be additionally accessed based on the measured signal reception strength among the remaining candidate frequency bands By selecting , a candidate frequency band to be additionally accessed can be determined as an auxiliary frequency band.

Preferably, in the determining step, when an additional connection with the base station is required again in a situation in which the basic frequency band is the same, the candidate frequency band excludes a specific frequency band excluded from the immediately preceding auxiliary frequency band determination process. Among the candidate frequency bands, it is possible to determine an auxiliary frequency band in which the signal reception strength satisfies a predefined condition.

Accordingly, according to the terminal device and the method of operation of the terminal device according to the present invention, when the CA (Carrier Aggregation) terminal additionally accesses the secondary frequency band (SCell), it enables adaptive additional access in consideration of the load of the frequency band. , it derives the effect of uniformly improving the communication quality of both the CA terminal and the non-CA terminal.

1 is a block diagram showing a communication system including a terminal device according to a preferred embodiment of the present invention.
2 is a block diagram showing the configuration of a terminal device according to a preferred embodiment of the present invention.
3 is a control flowchart of a communication system including a terminal device according to a preferred embodiment of the present invention.
4 is an operation flowchart illustrating a method of operating a terminal device according to a preferred embodiment of the present invention.

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

1 is a diagram illustrating a communication system including a terminal device according to a preferred embodiment of the present invention.

In the present invention, as shown in FIG. 1 , in a communication system including the terminal device 100 of the present invention, a plurality of frequency bands coexist in the same area.

For example, referring to FIG. 1 , the base station 10 includes three frequency bands, that is, a first cell C1 according to the first frequency band, a second cell C2 according to the second frequency band, and a third The third cell C3 according to the frequency band may be formed.

Of course, in the communication system to which the present invention is applied, the base station may form four or more cells in four or more frequency bands, which are more than three, but hereinafter, for convenience of explanation, three frequency bands/three cells are I will mention and explain.

On the other hand, the present invention is an invention related to a carrier aggregation (CA) technology to support a wider frequency band.

Here, the CA technology can secure a wider frequency band through the integration of multiple component carrier (CC), and each unit frequency band (CC) is used as an LTE frequency band for the LTE terminal. It also maintains compatibility with the system.

Accordingly, the base station 10 communicates with a terminal connected through any one of a plurality of frequency bands (eg, the first frequency band, the second frequency band, and the third frequency band) as shown in FIG. 1 above. It will be a CA support base station that can provide a communication service using the CA function, that is, a communication service by integrating two or more frequency bands, especially for a terminal operating with a CA function.

And, it is assumed that the terminal device 100 of the present invention shown in FIG. 1 is a terminal supporting the CA function.

That is, the terminal device 100 is a terminal capable of using the communication service utilizing the CA function described above on the premise that two or more frequency bands are supported.

Hereinafter, for convenience of description, it is assumed that the terminal device 100 is a CA terminal supporting all of the first frequency band, the second frequency band, and the third frequency band.

And, for convenience of description, the first frequency band C1 is referred to with reference to the reference number C1 of the first cell C1 according to the first frequency band, and the second cell C2 according to the second frequency band. It will be described as a second frequency band C2 with reference to C2, and a third frequency band C3 with reference to C3 of a third cell C3 according to the third frequency band.

When the terminal device 100 is powered on, it accesses the base station 10 through one of a plurality of frequency bands.

At this time, since the terminal device 100 is a terminal supporting the CA function, it accesses the base station 10 through a frequency band designated with a high priority in the priority information for each frequency band, that is, a frequency band designated for initial access. The band corresponds to a primary frequency band (Primary Cell, PCell).

After the terminal device 100 accesses the base station 10 through the basic frequency band (PCell) as described above, when additional access with the base station 10 is required, the base station through the secondary cell (SCell) In addition (simultaneous) access to (10), various frequency bands, that is, PCell and SCell will be integrated to use communication service.

At this time, the existing method in which the CA terminal accesses the base station 10 through the basic frequency band (PCell) and then additionally accesses the secondary frequency band (SCell) is a signal reception strength in a candidate frequency band to which the CA terminal can additionally access It is a method of additionally accessing all of the candidate frequency bands in which the signal reception strength satisfies a predefined condition among the candidate frequency bands as auxiliary frequency bands (SCells).

That is, in the existing additional access method, since the CA terminal additionally accesses all candidate frequency bands satisfying the condition of the signal reception strength depending on the signal reception strength only to the auxiliary frequency band (SCell), only the position of the CA terminal is considered. It can be called an unconditional additional access method.

In this way, even if the CA terminal feels that the communication quality is sufficiently good from the point of view of the user of the CA terminal just by additionally accessing a relatively small number (eg, one) of the secondary frequency band (SCell), the CA terminal is unnecessarily A situation in which a large number of auxiliary frequency bands (SCell) is additionally accessed, in other words, a situation in which a large number of frequency resources of the base station 10 are used (occupies) unnecessarily may occur.

Therefore, due to the unconditional additional access method of the CA terminal, from the standpoint of the non-CA terminal, which must share and use the frequency resource of the base station 10 with the CA terminal, the usable frequency resource is reduced, so communication quality may deteriorate.

Therefore, in the present invention, when the CA terminal additionally accesses the secondary frequency band (SCell), instead of the existing unconditional additional access, it enables adaptive additional access considering the load of the frequency band, so that both the CA terminal and the CA non-supporting terminal We would like to propose a method to evenly improve the communication quality of

To this end, the terminal device 100 according to the present invention connects to a base station through a basic frequency band (PCell) among a plurality of frequency bands, and then, when additional access with the base station 10 is required, a plurality of frequency bands Among the candidate frequency bands excluding the basic frequency band (PCell), the secondary frequency band (SCell) that satisfies all of the additional access conditions defined in terms of signal reception strength and load is determined.

That is, the terminal device 100 according to the present invention determines and additionally accesses the auxiliary frequency band (SCell) in consideration of the load of the frequency band instead of the existing unconditional additional access when additionally accessing the auxiliary frequency band (SCell). can

Hereinafter, the configuration of a terminal device according to a preferred embodiment of the present invention will be described in detail with reference to FIG. 2 . For convenience of description, the description will be made using the aforementioned reference numerals.

The terminal device 100 according to the present invention includes a connection unit 110 that connects to the base station 10 through a basic frequency band (PCell) among a plurality of frequency bands, and additional connection with the base station 10 is required, In a plurality of frequency bands, the determining unit 120 determines an auxiliary frequency band (SCell) that satisfies all of the additional access conditions defined in terms of signal reception strength and load among candidate frequency bands excluding the basic frequency band (PCell); and a control unit 130 additionally connected to the base station 10 through a secondary frequency band (SCell).

Here, the plurality of frequency bands provided by the base station 10 are, as shown in FIG. 1 , a first frequency band (C1), a second frequency band (C2), and a third frequency band (C3). In the description, the terminal device 100 of the present invention will be described assuming that it is a CA terminal supporting all of the first frequency band, the second frequency band, and the third frequency band.

Of course, as described above, the base station 10 will be a CA supporting base station capable of providing a communication service utilizing the CA function, that is, a communication service by integrating two or more frequency bands, for a terminal operating with the CA function.

The connection unit 110 connects to the base station 10 through a basic frequency band (PCell) among a plurality of frequency bands.

The terminal device 100, which is a CA terminal, is powered on, and based on the priority information for each frequency band preset therein, accesses the base station 10 through a frequency band with a high priority and registers the location. and access to the communication system such as radio resource allocation.

At this time, since the terminal device 100 is a terminal supporting the CA function, a frequency band designated with a high priority in the priority information for each frequency band, that is, a frequency band designated for initial access, is a primary frequency band designated by the CA function (Primary Cell, PCell).

Hereinafter, for convenience of description, a frequency band set as the basic frequency band PCell of the terminal device 100 will be described as an example of the first frequency band C1. That is, in the following description, the basic frequency band PCell and the first frequency band C1 used by the terminal device 100 when initially accessing the base station 10 will be the same.

Accordingly, the connection unit 110 connects to the base station 10 through a basic frequency band (PCell, for example, C1) among the plurality of frequency bands C1, C2, and C3.

The determination unit 120 receives a signal from among the candidate frequency bands except for the basic frequency band (PCell, eg, C1) in a plurality of frequency bands (C1, C2, C3) when an additional connection with the base station 10 is required. A secondary frequency band (SCell) that satisfies all of the additional access conditions defined in strength and load is determined.

Here, the candidate frequency bands excluding the basic frequency band (PCell, for example, C1) from the plurality of frequency bands (C1, C2, C3) are, as described above, the terminal device 100 in the first frequency band and the second frequency band. Since both the band and the third frequency band are supported, the second frequency band C2 and the third frequency band C3 may be used.

Alternatively, in the process of performing the above-described access procedure in which the terminal device 100 accesses the base station 10 through a base frequency band (PCell, for example, C1), the base station 10 may Auxiliary for identifying frequency band information (eg, the first frequency band (C1)) and designating a candidate frequency band that the terminal device 100 can access simultaneously (additionally) together with the basic frequency band (PCell, eg, C1) The frequency band information may be informed to the terminal device 100 .

In this case, the candidate frequency bands excluding the basic frequency band (PCell, for example, C1) from the plurality of frequency bands (C1, C2, C3) are the first frequency band, the second frequency band, and the third Even if all frequency bands are supported, it may be at least one of a frequency band according to the auxiliary frequency band information informed by the base station 10 , that is, the second frequency band C2 and the third frequency band C3 .

Hereinafter, for convenience of explanation, it will be described that the candidate frequency bands are the second frequency band C2 and the third frequency band C3.

That is, when additional connection with the base station 10 is required, the determiner 120 determines a candidate frequency band (PCell, eg, C1) from a plurality of frequency bands C1, C2, C3 Among C2 and C3), a secondary frequency band (SCell) that satisfies both the signal reception strength and the amount of the additional access condition defined in advance is determined.

In this case, when an additional connection with the base station 10 is required, when the type of communication service used in the terminal device 100 or the data transmission amount and/or transmission speed of the communication service reaches a level for CA function activation would.

Of course, in addition to this, the case in which additional connection with the base station 10 is required may be variously changed according to predefined definition.

Hereinafter, a process in which the determination unit 120 determines the auxiliary frequency band SCell among the candidate frequency bands C2 and C3 will be described in detail.

First, according to the first embodiment, the determiner 120 selects a candidate frequency band to be additionally accessed based on the measured signal reception strength among the candidate frequency bands, and a load amount of the selected candidate frequency bands is predefined. After excluding a specific frequency band equal to or greater than the specified threshold load from the additional access target, it is possible to determine a candidate frequency band to be an additional access target as an auxiliary frequency band.

More specifically, when an additional connection with the base station 10 is required, the determination unit 120 is a candidate frequency to be additionally accessed based on the signal reception strength measured among the candidate frequency bands C2 and C3. Select a band.

In other words, the determiner 120 measures the signal reception strength in the candidate frequency bands C2 and C3, respectively, and among the candidate frequency bands C2 and C3, the signal reception strength of the candidate frequency band that satisfies a predefined condition. may be selected as a candidate frequency band to be additionally accessed.

That is, the determination unit 120 primarily selects a candidate frequency band having a good signal reception strength among the candidate frequency bands C2 and C3 as an additional connection target.

Hereinafter, for convenience of explanation, it is assumed that the signal reception strength of all of the candidate frequency bands C2 and C3 satisfies a predefined condition, and all of the candidate frequency bands C2 and C3 are selected as additional access targets. would.

In addition, the determination unit 120 excludes, from the additional access target, a specific frequency band in which the load is greater than or equal to a predefined threshold load among the candidate frequency bands C2 and C3 primarily selected in the previous description, and then becomes the additional access target. A candidate frequency band may be determined as an auxiliary frequency band.

Here, the load may be a PRB (Physical Resource Block) usage rate checked by the base station 10 for each frequency band, and the critical load may be a numerical value (eg, 50%) predefined by the operator.

In the base station 10, frequency resources, for example, resource blocks (RBs) that can be allocated (used) per bandwidth are determined, and the base station 10 determines how many RBs for each of the first, second, and third frequency bands (C1, C2, C3). is allocated to the terminal and the usage ratio of whether it is being used, that is, the PRB usage ratio is identified.

Accordingly, the determination unit 120, if necessary, can check the PRB usage rate for each frequency band (C1, C2, C3) from the base station 10, and as this PRB usage rate, the load amount for each frequency band (C1, C2, C3) can figure out

Therefore, the determination unit 120 adds a specific frequency band in which the load amount, ie, the PRB usage rate, of the candidate frequency bands C2 and C3 primarily selected in the previous description is greater than or equal to a predefined threshold load amount (eg, 50%) from the additional access target. can be excluded.

Hereinafter, for convenience of explanation, in the case where the PRB usage rate of the second frequency band C2 among the candidate frequency bands C2 and C3 is equal to or greater than a critical load amount (eg, 50%), the second frequency band C2 is a specific frequency band I will explain that

In this case, the determiner 120 will exclude a specific frequency band, ie, the second frequency band C2, from among the candidate frequency bands C2 and C3 primarily selected in the above description from the additional access target.

That is, the determiner 120 secondarily excludes a candidate frequency band having a heavy load among the candidate frequency bands C2 and C3 primarily selected as the additional access target from the additional access target.

In this way, the determination unit 120 secondarily excludes a candidate frequency band having a heavy load from among the candidate frequency bands C2 and C3 primarily selected as an additional connection target from the additional connection target, and then a candidate to be an additional connection target. The frequency band C3 is determined as an auxiliary frequency band SCell.

In summary, in the case of the first embodiment, a candidate frequency band having a good signal reception strength is primarily selected from among the candidate frequency bands C2 and C3, and a candidate frequency band having a large load is secondarily selected from among the first selected candidate frequency bands. By excluding , a secondary frequency band (SCell) that satisfies all of the additional access conditions in terms of signal reception strength and load among the candidate frequency bands (C2 and C3) is determined.

On the other hand, according to the second embodiment, the determiner 120 excludes a specific frequency band in which the load is greater than or equal to a predefined threshold load in the candidate frequency band, and then adds it based on the measured signal reception strength among the remaining candidate frequency bands. By selecting a frequency band to be accessed, a candidate frequency band to be additional access may be determined as an auxiliary frequency band.

More specifically, when an additional connection with the base station 10 is required, the determination unit 120 excludes a specific frequency band in which the load is greater than or equal to a predefined threshold load in the candidate frequency bands C2 and C3.

For example, the determination unit 120 excludes a specific frequency band in which the load amount, that is, the PRB usage rate, is greater than or equal to a predefined threshold load amount (eg, 50%) from among the candidate frequency bands C2 and C3.

Hereinafter, for convenience of explanation, in the case where the PRB usage rate of the second frequency band C2 among the candidate frequency bands C2 and C3 is equal to or greater than a critical load amount (eg, 50%), the second frequency band C2 is a specific frequency band I will explain that

In this case, the determiner 120 will exclude a specific frequency band, that is, the second frequency band C2, from among the candidate frequency bands C2 and C3.

That is, the determination unit 120 is to fundamentally block the candidate frequency band with a heavy load among the candidate frequency bands C2 and C3 from becoming an additional access target.

And, after excluding the candidate frequency band C2 having a large load primarily among the candidate frequency bands C2 and C3 in the previous description, the determiner 120 receives the measured signal among the remaining candidate frequency bands C3 Based on the strength, a frequency band to be additionally accessed is selected.

In other words, the determiner 120 selects only the remaining candidate frequency bands C3 that remain after excluding the candidate frequency band C2 having a large load from among the candidate frequency bands C2 and C3. By measuring the signal reception strength in the band C3, a candidate frequency band in which the signal reception strength satisfies a predefined condition among the candidate frequency band C3 may be selected as a candidate frequency band to be additionally accessed.

That is, the determination unit 120, secondarily, selects, as an additional connection target, a candidate frequency band having a good signal reception strength only from the remaining candidate frequency bands C3 that are not primarily excluded due to the load.

Hereinafter, for convenience of explanation, it is assumed that the signal reception strength of the candidate frequency band C3 satisfies a predefined condition and the candidate frequency band C3 is selected as an additional access target.

In this way, the determination unit 120, the candidate frequency band (C2, C3), the second selected candidate frequency band additional access target because the signal reception strength is good among the remaining candidate frequency bands (C3) that are not primarily excluded due to the load in the candidate frequency bands (C2, C3) ( C3) is determined as an auxiliary frequency band (SCell).

In summary, in the case of the second embodiment, candidate frequency bands with a large load are primarily excluded from the candidate frequency bands C2 and C3, and candidate frequencies having good signal reception strength among the remaining candidate frequency bands after the primary exclusion The secondary frequency band (SCell) that satisfies all of the additional access conditions in terms of signal reception strength and load among the candidate frequency bands (C2 and C3) is determined by secondary selection of the band.

That is, the determination unit 120, according to the first or second embodiment, instead of the unconditional additional connection considering only the existing signal reception strength, an adaptive additional connection considering not only the signal reception strength but also the load of the frequency band. To make this possible, an auxiliary frequency band (SCell) is determined.

The control unit 130 additionally accesses the base station 10 through the auxiliary frequency band (SCell) determined by the determination unit 120 .

That is, the controller 130 may additionally access the base station 10 through the secondary frequency band (SCell, eg, C3) determined by the determiner 120 according to the first or second embodiment described above.

Accordingly, the terminal device 100 uses a communication service through a base frequency band (PCell, eg, C1) connected to the base station 10 , and when additional access with the base station 10 is required, that is, the CA function is activated. When is necessary, it operates as a CA function and additionally (simultaneously) accesses the base station 10 through a secondary frequency band (SCell, eg, C3) that is adaptively determined in consideration of not only the signal reception strength but also the load of the frequency band.

Accordingly, the terminal device 100 simultaneously accesses the base station 10 through a basic frequency band (PCell) and a secondary frequency band (SCell) during the CA function operation, and the basic frequency band (PCell) connected to the base station 10 ) and a secondary frequency band (SCell), it becomes possible to use a communication service.

At this time, in the present invention, even if the terminal device 100 additionally accesses a relatively small number (eg, one) of the secondary frequency band (SCell), the user of the terminal device 100 will feel that the communication quality is sufficiently good, There will be no problem in the user's sense of communication quality.

On the other hand, in the above-described first and second embodiments, if additional access to the secondary frequency band (SCell) is additionally accessed through an unconditional additional access method that considers only the signal reception strength from the standpoint of the existing CA terminal, the terminal device 100, hereinafter CA terminal), while using a communication service through a basic frequency band (PCell, for example: C1), adds (simultaneous) access to the base station 10 by using all of the candidate frequency bands (C2, C3) as the secondary frequency band (SCell) would have done

In this case, since the CA terminal uses (occupies) a lot of frequency resources by using all of the frequency bands (C2, C3) as the secondary frequency band (SCell), from the standpoint of the non-CA terminal connected to the base station 10 , because the available frequency resources are reduced, communication quality may deteriorate.

However, since the terminal device 100 of the present invention additionally (simultaneously) accesses the base station 10 only in the secondary frequency band (SCell) that is adaptively determined in consideration of not only the signal reception strength but also the load of the frequency band, frequency resources There is no unnecessary use (occupying) of a lot, and therefore, it is possible to improve a situation in which communication quality deteriorates from the standpoint of a non-CA terminal connected to the base station 10 .

On the other hand, the terminal device 100 of the present invention, through the secondary frequency band (SCell) determination process of the present invention as described above, adaptively determined not only the signal reception strength but also the load of the frequency band, the secondary frequency band (SCell, Example: After additional (simultaneous) access to the base station 10 through C3), the CA function may be deactivated while using communication services through the basic frequency band (PCell) and the secondary frequency band (SCell).

That is, the terminal device 100 operates as a CA function and uses a communication service through a basic frequency band (PCell) and a secondary frequency band (SCell). A frequency band (SCell, eg, C3) is disconnected and a communication service can be used only through a basic frequency band (PCell, eg, C1).

As such, after the terminal device 100 operates as the CA function and the CA function is deactivated, the terminal device 100 again requires an additional connection with the base station 10, that is, a case of reactivating the CA function may occur. .

The terminal device 100 of the present invention, in particular, the determination unit 120, as described above, when additional connection with the base station 10 is required again, that is, in the case of CA function re-activation, the basic frequency band (PCell, eg: C1) ) in the same situation, among the remaining candidate frequency bands (eg C3) excluding a specific frequency band (eg C2) excluded in the immediately preceding secondary frequency band (SCell) determination process in the candidate frequency bands (C2, C3), the signal It is possible to determine a secondary frequency band (SCell) that satisfies a condition in which the reception strength is predefined.

That is, as long as the base frequency band (PCell, for example, C1) connected to the base station 10 does not change, the determination unit 120 performs the auxiliary frequency band (SCell) determination process of the present invention as described above to determine the auxiliary frequency band. When determining (SCell, eg: C3), it is desirable to remember the candidate frequency band (= specific frequency band) excluded based on the load.

And, the determination unit 120, in the case of CA function reactivation in a situation in which the basic frequency band (PCell, eg, C1) is the same, a specific excluded frequency band stored in the process of determining the immediately preceding secondary frequency band (SCell) (eg, : Among the remaining candidate frequency bands (eg, C3) after excluding C2) from the candidate frequency bands (C2, C3) from the beginning, the secondary frequency band (SCell) in which the signal reception strength satisfies the predefined condition is immediately determined. can

As long as the base frequency band (PCell, eg, C1) to which the terminal device 100 is connected to the base station 10 does not change, that is, there is no large positional movement, the wireless environment of the place where the terminal device 100 is located is greatly increased. This is due to the fact that changes rarely occur.

In this case, the terminal device 100 of the present invention adaptively selects the secondary frequency band (SCell) in consideration of both the signal reception strength and the load while simplifying the secondary frequency band (SCell) determination process in case of CA function reactivation. By determining, through this, it is possible to additionally (simultaneously) access the base station 10 .

As described above, in the terminal device 100 of the present invention, when the CA terminal additionally accesses the secondary frequency band (SCell) in a multiple frequency band environment, only the signal reception strength in the existing CA terminal is taken into consideration. By enabling adaptive additional access in consideration of the load of the frequency band instead of access, the communication quality of both the CA terminal and the non-CA terminal can be improved evenly.

Hereinafter, a method of operating a terminal device according to the present invention will be described with reference to FIGS. 3 to 4 . For convenience of description, reference will be made to reference numerals in FIGS. 1 to 2 described above.

First, a control flow of a communication system including a terminal device according to the present invention will be described with reference to FIG. 3 . In addition, a control flow according to the first embodiment will be described with reference to FIG. 3 .

First, when the terminal device 100 is powered on (S10), the priority among a plurality of frequency bands (eg, C1, C2, C3) is based on the priority information for each frequency band preset therein. By accessing the base station 10 through a highly designated frequency band, an access procedure for the communication system such as location registration and radio resource allocation will be performed (S20).

At this time, since the terminal device 100 is a terminal supporting the CA function, a frequency band designated with a high priority in the priority information for each frequency band, that is, a frequency band designated for initial access, is a basic frequency band (PCell) designated by the CA function. it can be said

Hereinafter, for convenience of description, a frequency band set as the basic frequency band PCell of the terminal device 100 will be described as an example of the first frequency band C1.

Accordingly, the terminal device 100 may use a communication service through a basic frequency band (PCell, for example, C1) connected to the base station 10 (S40).

On the other hand, the base station 10, when the terminal device 100 is connected, grasps the basic frequency band information to which the terminal device 100 is connected (eg, the first frequency band C1), and the terminal device 100 Secondary frequency band information for designating a candidate frequency band capable of simultaneous (additional) access together with the basic frequency band (PCell, for example, C1) may be informed to the terminal device 100 (S30).

In this case, the terminal device 100 determines which of the plurality of frequency bands C1, C2, and C3 are candidate frequency bands that can be simultaneously accessed with the basic frequency band (PCell, eg, C1) based on the auxiliary frequency band information. Able to know.

Hereinafter, for convenience of description, it will be described that the candidate frequency bands are the second frequency band C2 and the third frequency band C3.

On the other hand, the terminal device 100, while using a communication service through a basic frequency band (PCell, for example: C1), when additional connection with the base station 10 is required, that is, when CA function activation is required (S50) Yes), in multiple frequency bands (C1, C2, C3), except for the basic frequency band (PCell, e.g. C1), all of the additional connection conditions for which the signal reception strength and load are predefined among the candidate frequency bands (C2, C3) A satisfactory secondary frequency band (SCell) is determined (S60, S70, S80)

More specifically, the terminal device 100 selects a candidate frequency band to be additionally accessed based on the measured signal reception strength among the candidate frequency bands C2 and C3 ( S60 ).

In other words, the terminal device 100 receives a reference signal in the candidate frequency bands C2 and C3 and measures the signal reception strength, respectively, and the signal reception strength among the candidate frequency bands C2 and C3 is predefined. A candidate frequency band that satisfies the specified condition may be selected as a candidate frequency band to be additionally accessed.

That is, the terminal device 100 primarily selects a candidate frequency band having a good signal reception strength among the candidate frequency bands C2 and C3 as an additional access target.

Hereinafter, for convenience of explanation, it is assumed that the signal reception strength of all of the candidate frequency bands C2 and C3 satisfies a predefined condition, and all of the candidate frequency bands C2 and C3 are selected as additional access targets. would.

In addition, the terminal device 100 excludes a specific frequency band having a load greater than or equal to a predefined threshold load among the candidate frequency bands C2 and C3 primarily selected in the above description from the additional access target (S70).

That is, the terminal device 100 adds a specific frequency band in which the load amount, that is, the PRB usage rate, of the candidate frequency bands (C2, C3) primarily selected in the previous description is greater than or equal to a predefined threshold load amount (eg 50%) from the additional access target. can be excluded.

Hereinafter, for convenience of explanation, in the case where the PRB usage rate of the second frequency band C2 among the candidate frequency bands C2 and C3 is equal to or greater than a critical load amount (eg, 50%), the second frequency band C2 is a specific frequency band I will explain that

In this case, the terminal device 100 will exclude a specific frequency band, that is, the second frequency band C2, from the additional access target among the candidate frequency bands C2 and C3 primarily selected in the above description.

That is, the terminal device 100 secondarily excludes, from the additional access target, the candidate frequency band having a heavy load among the candidate frequency bands C2 and C3 first selected as the additional access target.

In this way, after the terminal device 100 excludes a candidate frequency band having a heavy load from the additional access target among the candidate frequency bands C2 and C3 first selected as the additional access target, the candidate frequency band as the additional access target is secondarily excluded from the additional access target. The frequency band C3 is determined as the auxiliary frequency band SCell (S80).

In summary, the terminal device 100 primarily selects a candidate frequency band having a good signal reception strength among the candidate frequency bands C2 and C3 ( S60 ), and secondarily, from among the first selected candidate frequency bands, a heavy load By excluding the candidate frequency band (S70), the auxiliary frequency band (SCell) that satisfies all of the additional access conditions in terms of signal reception strength and load among the candidate frequency bands (C2, C3) is determined (S80).

The terminal device 100 additionally accesses the base station 10 through the secondary frequency band (SCell, eg, C3) determined in step S80 (S90).

Accordingly, the terminal device 100 uses a communication service through a base frequency band (PCell, eg, C1) connected to the base station 10 , and when additional access with the base station 10 is required, that is, the CA function is activated. When is required, it operates as a CA function and additionally (simultaneously) accesses the base station 10 through a secondary frequency band (SCell, eg, C3) that is adaptively determined in consideration of not only the signal reception strength but also the load of the frequency band.

Accordingly, the terminal device 100 simultaneously accesses the base station 10 through a basic frequency band (PCell) and a secondary frequency band (SCell) during the CA function operation, and the basic frequency band (PCell) connected to the base station 10 ) and a secondary frequency band (SCell) to use a communication service (S100).

Meanwhile, a method of operating a terminal device according to the present invention will be described in detail below with reference to FIG. 4 . However, in FIG. 4 , in order to describe the embodiment in various ways, the control flow will be described according to the second embodiment, unlike in FIG. 3 .

First, when the terminal device 100 according to the present invention is powered on, it connects to the base station 10 through a base frequency band (PCell, eg, C1) ( S110 ), and the base frequency band connected to the base station 10 . Communication service can be used through (PCell, eg: C1).

In this situation, the method of operating the terminal device 100 according to the present invention determines whether an additional connection with the base station 10 is required, that is, a case where CA function activation is required (S120).

In the operating method of the terminal device 100 according to the present invention, when a case where CA function activation is required occurs (S120 Yes), the secondary frequency band (SCell) is determined through a previously secondary frequency band (SCell) determination process. and it is determined whether the basic frequency band (PCell, eg, C1) is the same (S130).

If the secondary frequency band (SCell) has not been previously determined through the secondary frequency band (SCell) determination process, or if the primary frequency band (PCell, eg, C1) is not the same (S130 No), this time is the current basic It means that it is a secondary frequency band (SCell) determination process in order to perform the CA function for the first time in a frequency band (PCell, eg, C1).

In this case (S130 No), the operating method of the terminal device 100 according to the present invention excludes a specific frequency band in which the load is greater than or equal to a predefined critical load in the candidate frequency bands C2 and C3.

Specifically, in the method of operating the terminal device 100 according to the present invention, the load amount for each of the candidate frequency bands C2 and C3, that is, the PRB usage rate is checked from the base station 10 (S140), and the candidate frequency band C2, Among C3), a specific frequency band greater than or equal to a predefined critical load amount (eg, 50%) is excluded (S150).

Hereinafter, for convenience of explanation, in the case where the PRB usage rate of the second frequency band C2 among the candidate frequency bands C2 and C3 is equal to or greater than a critical load amount (eg, 50%), the second frequency band C2 is a specific frequency band I will explain that

In this case, the operating method of the terminal device 100 according to the present invention will exclude a specific frequency band, that is, the second frequency band C2, from among the candidate frequency bands C2 and C3.

That is, the method of operating the terminal device 100 according to the present invention primarily blocks the candidate frequency band with a heavy load among the candidate frequency bands C2 and C3 from becoming an additional access target.

And, in the method of operating the terminal device 100 according to the present invention, after excluding the candidate frequency band C2 having a heavy load from among the candidate frequency bands C2 and C3 in the previous description (S150), the remaining candidates Among the frequency bands C3, a frequency band to be additionally connected is selected based on the measured signal reception strength (S160).

In other words, in the method of operating the terminal device 100 according to the present invention, the remaining candidate frequency bands C3 after excluding the candidate frequency band C2 having a large load primarily among the candidate frequency bands C2 and C3. ), the signal reception strength is measured in the candidate frequency band C3, and the candidate frequency band that satisfies the predefined condition among the candidate frequency band C3 is used as a candidate frequency band to be additionally accessed. You can choose.

That is, in the method of operating the terminal device 100 according to the present invention, secondarily, only a candidate frequency band having a good signal reception strength from among the remaining candidate frequency bands C3 that is not primarily excluded due to a load is used as an additional access target. is to choose

Hereinafter, for convenience of explanation, it is assumed that the signal reception strength of the candidate frequency band C3 satisfies a predefined condition and the candidate frequency band C3 is selected as an additional access target.

As described above, in the method of operating the terminal device 100 according to the present invention, the signal reception strength is good among the remaining candidate frequency bands C3 that are not primarily excluded due to the amount of load in the candidate frequency bands C2 and C3, and thus additional access target The second selected candidate frequency band C3 is determined as an auxiliary frequency band SCell (S170).

In summary, in the method of operating the terminal device 100 according to the present invention, a candidate frequency band with a large load is primarily excluded from among the candidate frequency bands C2 and C3, and among the remaining candidate frequency bands after the first exclusion. By secondarily selecting a candidate frequency band having a good signal reception strength, a secondary frequency band (SCell) that satisfies both the signal reception strength and the load among the candidate frequency bands (C2, C3) is determined.

Accordingly, in the method of operating the terminal device 100 according to the present invention, the base station 10 is additionally connected through the secondary frequency band (SCell, eg, C3) determined in step S170 (S180).

Accordingly, the terminal device 100 uses a communication service through a base frequency band (PCell, eg, C1) connected to the base station 10 , and when additional access with the base station 10 is required, that is, the CA function is activated. When is necessary, it operates as a CA function and additionally (simultaneously) accesses the base station 10 through a secondary frequency band (SCell, eg, C3) that is adaptively determined in consideration of not only the signal reception strength but also the load of the frequency band.

Accordingly, the terminal device 100 simultaneously accesses the base station 10 through a basic frequency band (PCell) and a secondary frequency band (SCell) during the CA function operation, and the basic frequency band (PCell) connected to the base station 10 ) and a secondary frequency band (SCell), it becomes possible to use a communication service.

Meanwhile, in step S130, if the secondary frequency band (SCell) has been previously determined through the secondary frequency band (SCell) determination process, and the basic frequency band (PCell, eg, C1) is the same (S130 Yes), this time This means that this is the secondary frequency band (SCell) determination process when the CA function is activated -> deactivated and then activated again in the current basic frequency band (PCell, eg, C1).

In this case (S130 Yes), the operating method of the terminal device 100 according to the present invention directly enters step S160, and excludes a specific frequency band (eg: After excluding C2) from the candidate frequency bands (C2, C3) from the beginning, from among the remaining candidate frequency bands (eg, C3), the secondary frequency band (SCell) in which the signal reception strength satisfies a predefined condition can be immediately determined. There is (S160, S170).

As described above, in the method of operating the terminal device 100 according to the present invention, when the CA terminal additionally accesses the secondary frequency band (SCell), the existing CA terminal uses a frequency instead of an unconditional additional access considering only the signal reception strength. By enabling adaptive additional access in consideration of the load of the band, it is possible to evenly improve the communication quality of both the CA terminal and the non-CA terminal.

The method of operating a terminal device according to an embodiment of the present invention may be implemented in the form of a program command that can be executed through various computer means and recorded in a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, etc. alone or in combination. The program instructions recorded on the medium may be specially designed and configured for the present invention, or may be known and available to those skilled in the art of computer software. Examples of the computer-readable recording medium include magnetic media such as hard disks, floppy disks and magnetic tapes, optical media such as CD-ROMs and DVDs, and magnetic media such as floppy disks. - includes magneto-optical media, and hardware devices specially configured to store and execute program instructions, such as ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine language codes such as those generated by a compiler, but also high-level language codes that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

Although the present invention has been described in detail with reference to preferred embodiments so far, the present invention is not limited to the above-described embodiments, and without departing from the gist of the present invention as claimed in the following claims, the technical field to which the present invention pertains It will be said that the technical spirit of the present invention extends to a range where various modifications or modifications can be made by anyone with ordinary knowledge in the present invention.

According to the terminal device and the method of operation of the terminal device according to the present invention, when the CA terminal additionally accesses the auxiliary frequency band (SCell), it enables adaptive additional access considering not only the signal reception strength but also the load of the frequency band, In that it leads to a result of uniformly improving the communication quality of both CA terminals and non-CA terminals, as it overcomes the limitations of existing technologies, there is a sufficient possibility of marketing or sales of the applied device, not just the use of the related technology. Rather, it is an invention that has industrial applicability because it can be clearly implemented in reality.

10: base station
100: terminal device
110: connection part 120: decision part
130: control unit

Claims (9)

a connection unit for connecting to a base station through a basic frequency band among a plurality of frequency bands;
When additional access with the base station is required, a decision to determine an auxiliary frequency band that satisfies all of the additional access conditions defined in terms of signal reception strength and load among candidate frequency bands excluding the basic frequency band in the plurality of frequency bands wealth; and
A control unit additionally accessing the base station through the determined auxiliary frequency band,
The determining unit is
When additional access with the base station is requested again in the same situation in the base frequency band, the signal reception strength of the remaining candidate frequency bands excluding a specific frequency band excluded from the immediately preceding auxiliary frequency band determination process in the candidate frequency band A terminal device, characterized in that it determines an auxiliary frequency band that satisfies a predefined condition. The method of claim 1,
The determining unit is
Selecting a candidate frequency band to be additionally accessed based on the measured signal reception strength among the candidate frequency bands,
A terminal device, characterized in that after excluding a specific frequency band having a load greater than or equal to a predefined threshold load among the selected candidate frequency bands from the additional access target, a candidate frequency band that is an additional access target is determined as an auxiliary frequency band. The method of claim 1,
The determining unit is
After excluding a specific frequency band in which the load is greater than or equal to a predefined threshold load from the candidate frequency band, a frequency band to be additional access is selected based on the measured signal reception strength among the remaining candidate frequency bands, and becomes an additional access target A terminal device, characterized in that the candidate frequency band is determined as an auxiliary frequency band. delete The method of claim 1,
The load is
The terminal device, characterized in that the PRB (Physical Resource Block) usage rate checked by the base station for each frequency band. an access step of accessing a base station through a basic frequency band among a plurality of frequency bands;
When additional access with the base station is required, a decision to determine an auxiliary frequency band that satisfies all of the additional access conditions defined in terms of signal reception strength and load among candidate frequency bands excluding the basic frequency band in the plurality of frequency bands step; and
and an additional access step of further accessing the base station through the determined auxiliary frequency band,
The decision step is
When additional access with the base station is requested again in the same situation in the base frequency band, the signal reception strength of the remaining candidate frequency bands excluding a specific frequency band excluded from the immediately preceding auxiliary frequency band determination process in the candidate frequency band A method of operating a terminal device, comprising determining an auxiliary frequency band that satisfies a predefined condition. 7. The method of claim 6,
The decision step is
Selecting a candidate frequency band to be additionally accessed based on the measured signal reception strength among the candidate frequency bands,
Operation of a terminal device, characterized in that after excluding a specific frequency band having a load greater than or equal to a predefined threshold load among the selected candidate frequency bands from the additional access target, a candidate frequency band to be additionally accessing is determined as an auxiliary frequency band Way. 7. The method of claim 6,
The decision step is
After excluding a specific frequency band in which the load is greater than or equal to a predefined threshold load from the candidate frequency band, a frequency band to be additional access is selected based on the measured signal reception strength among the remaining candidate frequency bands, and becomes an additional access target A method of operating a terminal device, comprising determining a candidate frequency band as an auxiliary frequency band. delete

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