KR20130049652A - Apparatus and method for estimating mobility state of wireless user equipment - Google Patents

Abstract

PURPOSE: A device for estimating the movement state of a wireless terminal and a method thereof are provided to estimate the speed of the wireless terminal based on the conversion number of cells. CONSTITUTION: A cell conversion unit(1111) converts a cell based on a cell conversion parameter. A cell conversion determination unit(1112) determines whether the cell is converted regardless of the movement of the wireless terminal. A total calculation unit(1113) calculates the total of cell conversion numbers regarding to the movement of the wireless terminal during the set estimating time. When estimating timer is completed during the set estimating time, an estimation result updating unit(1114) updates a movement state estimation result based on the total of the cell conversion numbers related to the movement state of the wireless terminal. [Reference numerals] (1105) Terminal reception unit; (1110) Terminal processor; (1111) Cell conversion unit; (1112) Cell conversion determination unit regardless of the movement of a terminal; (1113) Total calculation unit; (1114) Estimation result updating unit; (1115) Terminal transmission unit; (1155) Base station transmission unit; (1160) Base station reception unit; (1170) Base station processor; (1171) Cell conversion control unit; (1172) Cell conversion parameter generation nit; (AA) Cell conversion parameter; (BB) Signal required for cell conversion

Description

Apparatus and method for estimating the movement state of a wireless terminal {APPARATUS AND METHOD FOR ESTIMATING MOBILITY STATE OF WIRELESS USER EQUIPMENT}

The present invention relates to wireless communications, and more particularly, to an apparatus and a method for estimating a moving state of a wireless terminal.

3rd generation partnership project (3GPP) long term evolution (LTE), an improvement of the Universal Mobile Telecommunications System (UMTS), uses orthogonal frequency division multiple access (OFDMA) multiplexing in downlink, and single carrier SC-FDMA in uplink -frequency division multiple access) Use multiplexing. MIMO (multiple input multiple output) with up to four antennas is adopted. Recently, 3GPP LTE-A (LTE-Advanced), an evolution of 3GPP LTE, is under discussion.

Particular areas, such as hotspots inside a cell, are particularly demanding for communication, and in certain areas, such as cell edges or coverage holes, the reception sensitivity of radio waves can be reduced. . With the development of wireless communication technology, small cells, such as pico cells, within a macro cell for the purpose of enabling communication in areas such as hot spots, cell boundaries, and coverage holes. ), A femto cell, a remote radio head (RRH), a relay, a repeater, etc. are installed together. Such a network is called a heterogeneous network (HetNet). In a heterogeneous network environment, when compared with a femto cell and a pico cell, a macro cell is a large coverage cell, and a femto cell and a pico cell are small coverage cells.

A terminal connected to a heterogeneous network can perform communication with an arbitrary cell or perform a cell change according to a channel environment or a moving state. For example, a terminal may disconnect from a macro cell and connect to another macro cell or picocell due to deterioration of a channel state in a state of being connected to a macro cell. Alternatively, for example, as the terminal moves in a state of being connected with the macro cell, the terminal may be disconnected from the macro cell and connected to another macro cell or pico cell.

There is a method using a GPS (Global Positioning System) when estimating a mobile state of the terminal, but there is a problem in that power consumption is large when it is desired to continuously maintain a communication connection state with a satellite.

The number of times the terminal changes the cell may be used as a parameter to estimate the mobile state of the terminal. In the conventional homogeneous network (HomoNet), the number of cell changes is calculated based on only cells of the same type (eg, macro cells). However, in heterogeneous networks, cells of various coverages are randomly scattered, and thus an error between the actual speed of the terminal and the estimated speed of the terminal may occur due to a cell change that is not related to the movement state of the terminal in calculating the number of cell changes. .

 Therefore, in order to increase the reliability of the estimated speed of the terminal calculated based on the number of cell changes, a cell change that is not related to the mobile state of the terminal should be considered.

In order to calculate the number of reliable cell changes, a case affecting the estimated speed of the terminal but not related to the movement state of the terminal should be considered, and the reliability of estimating the mobile state of the terminal can be increased only when the number of cell changes is reliable. .

There is a need for an apparatus and method for estimating a mobile state of a reliable terminal in a heterogeneous network system.

An object of the present invention is to provide an apparatus and method for estimating a moving state of a wireless terminal.

Another object of the present invention is to provide an apparatus and method for estimating the speed of a terminal based on the number of cell changes.

Another technical problem of the present invention is to provide a method and apparatus for excluding a case of being unrelated to a mobile state of a terminal among cell change times.

According to an aspect of the present invention, a method for estimating a mobile state by a wireless terminal includes receiving at least one cell change parameter from a base station, performing a cell change based on the cell change parameter, and performing the cell change. Determining whether the cell change is irrelevant to the movement state of the wireless terminal, calculating a total of the number of cell changes related to the movement state of the wireless terminal during a preset estimation time, and operating for the preset estimation time If the estimated timer expires, updating the mobile state estimation result based on the sum of the number of cell changes associated with the mobile state of the wireless terminal.

When the wireless terminal is in the RRC connection mode, the cell change parameter is received through an RRC connection reconfiguration message. When the wireless terminal is in the idle mode, the cell change parameter is a system information block. block: SIB).

The method may further include determining whether a movement state of the wireless terminal is high speed, medium speed, or low speed based on the cell change parameter.

When performing the cell change based on the cell change parameter, the method may further include scaling the cell change parameter according to a movement state of the wireless terminal estimated during a previous estimation time.

If the performed cell change is a cell change performed according to a mode change of the wireless terminal located in the cell extension region, it may be determined that the cell change is not related to the movement state of the wireless terminal.

A cell performed according to a difference between a reference signal received quality (RSRQ) of a source base station and an RSRQ of a target base station measured by the wireless terminal affected by in-device coexistence interference according to a preset cell change condition If it is a change, it can be determined as a cell change irrelevant to the mobile state of the wireless terminal.

A cell for receiving a service over a second frequency band when the performed cell change is moved to a closed subscriber group (CSG) cell region in which the wireless terminal receiving the service over a first frequency band from a macro base station is performed. If it is a change, it can be determined as a cell change irrelevant to the mobile state of the wireless terminal.

The wireless terminal receiving the service through the second frequency band from the macro base station in the CSG cell region in which the cell change is performed does not move to receive the service through the first frequency band by moving out of the CSG cell region without membership. If it is a cell change, it can be determined as a cell change irrelevant to the mobile state of the wireless terminal.

The total number of cell changes related to the mobile state of the wireless terminal during the preset estimated time increases the counter by 1 if the cell change of the wireless terminal is a cell change related to the mobile state of the wireless terminal, If the cell change of the terminal is a cell change irrelevant to the movement state of the wireless terminal, it may be calculated by not increasing the counter.

The method may further include selecting a scaling index corresponding to the updated moving speed estimation result and scaling the cell change parameter by the selected scaling index.

According to another aspect of the present invention, a terminal for estimating a mobile state includes a receiver for receiving at least one cell change parameter from a base station, a cell change performing unit for performing cell change based on the cell change parameter, and performing the cell change. A terminal movement irrelevant cell change determination unit that determines whether the cell change is unrelated to the mobile state of the wireless terminal, and a total calculation unit that calculates a total of the number of cell changes related to the mobile state of the wireless terminal for a preset estimation time. And an estimation result update unit for updating the movement state estimation result based on the sum of the number of cell changes related to the movement state of the wireless terminal when the estimation timer operating for the preset estimation time expires.

According to the present invention, it is possible to increase the reliability of estimating the mobile state of the terminal by calculating the number of cell changes excluding cases not related to the mobile state of the heterogeneous network system. That is, the terminal may perform the cell change more successfully by scaling the cell change parameter.

1 schematically illustrates a concept of a heterogeneous network composed of a macro cell, a femtocell, and a picocell.
2 shows a distribution diagram of cells of various coverages in a heterogeneous network.
3 is a view for explaining a method of estimating a mobile state of a terminal in a heterogeneous network according to the present invention.
4 illustrates a cell change of a terminal in an extended region of a femto cell to which the present invention is applied.
5 is an explanatory diagram illustrating in-device coexistence interference to which the present invention is applied.
6 illustrates a cell change in consideration of coexistence interference in a device to which the present invention is applied.
7 shows a cell change of a terminal in a non-member CSG cell to which the present invention is applied.
8 is a flowchart illustrating a method of estimating a moving state of a terminal according to an embodiment of the present invention.
9 is a flowchart illustrating a method of estimating a moving state of a terminal according to another embodiment of the present invention.
10 is a flowchart illustrating a method for estimating a mobile state of a terminal by a base station according to an embodiment of the present invention.
11 is a block diagram illustrating a base station for managing a cell and a terminal for communicating with a cell according to an embodiment of the present invention.

Hereinafter, the contents related to the present invention will be described in detail with reference to exemplary drawings and embodiments, together with the contents of the present invention. It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In addition, in describing the embodiments of the present specification, when it is determined that the detailed description of the related well-known configuration or function may obscure the subject matter of the present specification, the detailed description thereof will be omitted.

In describing the components of the present specification, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. If a component is described as being "connected", "coupled", or "connected" to another component, that component may be directly connected or connected to that other component, but there is another component between each component. It will be understood that may be "connected", "coupled" or "connected".

In addition, the present invention will be described with respect to a wireless communication network. The work performed in the wireless communication network may be performed in a process of controlling a network and transmitting data by a system (e.g., a base station) Work can be done at a terminal connected to the network.

Simple cell division of macro and micro cells is difficult to meet the growing demand for data services. Accordingly, a data service for small indoor and outdoor areas can be provided by using a pico cell, a femto cell, a relay, or the like. Although the use of small cells is not particularly limited, in general, picocells can be used in a communication shadow area, which is not covered only by macro cells, or in an area where data service demand is high, that is, hotspots. Femtocells are generally available in indoor offices or homes. In addition, the wireless relay can compensate for the coverage of the macrocell. By configuring a heterogeneous network, not only the shadow area of the data service can be eliminated, but also the data transmission speed can be increased.

1 schematically illustrates a concept of a heterogeneous network composed of a macro cell, a femtocell, and a picocell. For the convenience of description, a heterogeneous network composed of a macro cell, a femto cell, and a pico cell has been described, but the heterogeneous network may include other types of cells. A femto cell is a low power wireless access point, which is a small base station for mobile communication used indoors such as a home or an office. A femto cell can access a mobile communication core network using DSL or cable broadband in a home or office.

Referring to FIG. 1, a macro base station 110, a femto base station 120, and a pico base station 130 are operated together in a heterogeneous network. The macro base station 110, the femto base station 120, and the pico base station 130 have unique cell coverage. The cell provided by the macro base station 110 is referred to as a macro cell 111 and the cell provided by the femto base station 120 is referred to as a femto cell 121 and the cell provided by the pico base station 130 is referred to as a pico cell 131. [

The femto base station 120 is a low power wireless access point, for example, a base station for a small mobile communication used in a room such as a home or an office. The femto base station 120 can access the mobile communication core network using a home or office DSL or cable broadband. The femto base station 120 is connected to a mobile communication network through a wired network such as the Internet. A terminal in a femtocell can access a mobile communication network or an Internet network through a femto base station. Although FIG. 1 illustrates a heterogeneous network composed of macro cells, femtocells, and picocells for convenience of description, the heterogeneous network may be configured to include relays or other types of cells.

2 shows a distribution diagram of cells of various coverages in a heterogeneous network.

Referring to FIG. 2, macro cells and small cells are distributed in horizontal and vertical planes in meters, and the degree of distribution may be expressed by the number of macro cells and small cells. One hexagon represents a macro cell, and three hexagons (ie, macro cells) are collectively called a site. Many small cells are densified in each macro cell. The small cell may be located at the boundary of multiple macro cells. Looking at the size of each cell, the diameter of one site is about 600m, the diameter of the macro cell is about 300m, and the diameter of the small cell is about 20-30m.

3 is a diagram illustrating a method of estimating a mobility state of a terminal in a heterogeneous network according to the present invention. The movement state of the terminal may include at least one of a movement path of the terminal, an estimated speed of the terminal, and an estimated speed of the terminal. That is, the scale indicating the movement state of the terminal may be the movement path or speed of the terminal.

Referring to FIG. 3, the macro cell 1 and the macro cell 2 are adjacent to each other, and the small cell 1 and the small cell 2 are located in the macro cell 1. UE A and UE B move from macro cell 1 to macro cell 2 at the same (or similar) speed. However, the terminal A moves through the small cell 1 and the small cell 2, and the terminal B does not go through any small cell.

As the terminal A moves to the small cell 1, the terminal A may disconnect from the macro cell 1 and perform a cell change to the small cell 1. Here, the terminal A may be in an idle mode or may be in a radio resource control (RRC) connected mode. The idle mode is a state in which the terminal does not exchange data with the base station, and the RRC connection mode is a state in which the terminal exchanges data with the base station. As an example of cell change, when UE A is in the idle mode, UE A may perform cell reselection with small cell 1. As another example of cell change, if UE A is in the RRC connected mode, UE A may perform a handover to small cell 1. Hereinafter, "cell change" means that the UE in the idle mode performs reselection or the UE performs the handover in the RRC connected mode.

In either mode, the terminal A attempts to change the cell to the small cell 1. As the terminal performs cell change, the cell change count N _A of the terminal A increases by one. For example, in order to effectively increase the number of cell changes, it may be assumed that the terminal stays in the cell for more than k seconds. Where k = 1.

On the other hand, when the terminal A moves and changes the cell from the small cell 1 to the macro cell 1 again, N _A increases to 2. Similarly, when terminal A moves and changes the cell from macro cell 1 to small cell 2, N _A increases to 3, while terminal A changes cell from small cell 2 to macro cell 1 again, N _A increases to 4. . When UE A moves from macro cell 1 to macro cell 2, cell change is performed and N _A increases to five. Meanwhile, the terminal B does not pass any small cells and performs cell change as it moves from the macro cell 1 to the macro cell 2. The increase in the cell change number (N _B) of terminal B 1.

The estimated speed of the terminal is calculated based on the number of cell changes performed by the terminal per unit time (the number of cell changes). In this case, the estimated speed of the terminal may be classified into two or more levels based on whether the terminal is high or low relative to a specific reference value. As an example, the estimated speed of the terminal may be classified into two levels, high and low. As another example, the estimated speed of the terminal may be classified into three levels of high speed, medium speed, and low speed. As another example, the estimated speed of the terminal may be classified into three levels of high speed, medium speed, and normal.

For example, the medium speed is an estimated speed when the number of cell changes (N) exceeds the medium speed reference value (Th _M ) and does not exceed the high speed reference value (Th _H ) during a specific reference time (that is, Th _M <N ≤ Th _H ). The high speed is an estimated speed when the cell change count N exceeds the high speed reference value Th _H during a specific reference time (that is, N> Th _H ). The low speed is an estimated speed when the number of cell changes (N) does not exceed the medium speed reference value (Th _M ) during a specific reference time (i.e., N≤Th _M ), or when it is not judged to be medium speed or high speed during a specific reference time. to be. When the estimated speed of the terminal calculated based on the number of cell changes of the terminal is matched to the actual speed, the low speed is approximately 0 to 30 km / h (0 to 8.3 m / s), and the medium speed is approximately 30 to 60 km / h. (8.3 to 16.6 m / s), high speed can be defined as approximately 60 to 120 km / h (16.6 to 33.2 m / s).

The reason for the error between the actual speed of the terminal and the estimated speed of the terminal occurs because the case of a cell change that is not related to the movement state of the terminal is not considered in calculating the estimated speed. Therefore, in order to increase the reliability of the estimated speed of the terminal calculated based on the number of cell changes, a cell change that is not related to the mobile state of the terminal should be considered. Hereinafter, the present invention is disclosed on the assumption that the estimated speed of the terminal is three levels. Even if the number of levels of estimated speeds is different, it may be appropriately changed and applied.

Now, a scenario in which the cell change of the terminal is a cell change that is not related to the movement state of the terminal will be described. Cell change (scenario 1) according to cell area expansion, in-device coexistence interference (IDC) (scenario 2), and non member CSG cell (scenario 3).

Since scenarios 1 to 3 cause errors in the estimation of the mobile state of the terminal, eliminating these factors may increase the reliability of the estimation of the mobile state of the terminal. The scope of the present invention is not limited thereto, and although the cell change of the terminal is a cell change that is not related to the mobile state of the terminal even if it is not a scenario 1 to scenario 3, the method of estimating the mobile state of the wireless terminal according to the present invention is described. Applicable

Scenario 1. Cell Range Expansion (CRE)>

When the base station determines that the signal strength of the neighboring cell is more suitable for the terminal than the current serving cell based on a rule determined based on the information reported by the terminal, the base station may handover the terminal to the neighboring cell. Herein, the cell to be handed over may be another base station of the same frequency band (hereinafter, an intra-frequency base station), the same base station of another frequency band or another base station (hereinafter, an inter-frequency base station). ) Or a base station using another radio transmission scheme (hereinafter referred to as an inter-RAT (Radio Access Technologies) base station).

CRE refers to increasing the coverage of a micro cell in order to benefit from the load balancing of the network. As the coverage of the microcells increases, the number of acceptable terminals also increases. Here, load balancing may be performed when traffic loads of several cells are unevenly distributed. For example, when over-traffic occurs in a cell, a user may be sent from the cell where the over-traffic occurs to another cell through a handover or a cell reselection method.

4 illustrates a cell change of a terminal in an extended region of a femto cell to which the present invention is applied.

Referring to FIG. 4, one pico cell is present inside the macro cell. The picocell performs CRE to extend the existing region 121 of the picocell to the new region 122 of the picocell.

The terminal 200 located in the extended region 125 between the existing region 121 and the new region 122 of the picocell receives a service from the macro base station 110 of the macro cell before performing the CRE, but after performing the CRE. Receives a service from the pico base station 120 of the pico cell. Only the terminal in the RRC connected mode performs CRE. Accordingly, the terminal in the RRC connected mode after performing the CRE receives the service from the pico base station 120, while the terminal in the idle mode receives the service from the macro base station 110.

At this time, when the terminal located in the extended region 125 according to the CRE is changed from the idle mode to the RRC connection mode, the movement state of the terminal does not change, but the terminal performs cell change (handover) from the pico cell to the macro cell. .

The cell change performed by the terminal in the cell extension area is a cell change irrelevant to the mobile state of the terminal. Therefore, in order to estimate the movement state of a reliable terminal, it is required to calculate the number of cell changes excluding cases not related to the movement state of the terminal.

Scenario 2. In-Device Coexistence interference (IDC)>

5 is an explanatory diagram illustrating in-device coexistence interference to which the present invention is applied.

Referring to FIG. 5, the terminal 200 includes an LTE RF 201, a GPS RF 202, and a Bluetooth / WiFi RF 203. Transmit and receive antennas 204, 205, and 206 are connected to each RF. That is, several kinds of RFs are closely mounted in one device platform. Here, the transmit power of one RF may be much greater than the receive power level to another RF receiver. If the frequency spacing between RFs is not sufficient and the filtering technique is not supported, then a transmission signal of one RF may cause significant interference to a receiver of another RF in the device. For example, (a) is an example in which a transmission signal of the LTE RF 201 causes in-device coexistence interference with respect to the GPS RF 202 and the Bluetooth / WiFi RF 203, and (b) is a Bluetooth / WiFi RF ( The transmission signal of 203 is an example of causing in-device coexistence interference with respect to the LTE RF 201. As another example, in-device coexistence interference occurs when the transmission signal of the ISM transmitter for the Industrial, Scientific and Medical (ISM) band, which is a band freely used in the industrial science medical field, overlaps with the signal received at the LTE receiver. do. As such, interference caused by one RF transmission signal to another RF reception signal in the device is referred to as in-device coexistence interference.

6 shows a cell change (handover) in consideration of coexistence interference in a device to which the present invention is applied.

Referring to FIG. 6, a (600) shows a reference signal received quality (RSRQ) of a base station A measured by a terminal before in-device coexistence interference occurs, according to a change in distance. Reference numeral 610 illustrates an RSRQ of the base station A measured by the terminal after the in-device coexistence interference occurs according to a change in distance. In addition, b 620 indicates the RSRQ of the base station B measured by the terminal according to the change of the distance.

If the in-device coexistence interference does not exist, the RSRQ of the base station A and the RSRQ of the base station B become equal at the point where a (600) and b 620 meet, so that the RSRQ of the base station B is The UE initiates a procedure of performing cell change (handover) from the base station A to the base station B at the position of the M 650 which is a point larger than the RSRQ by a preset measurement report reference value. On the other hand, if there is in-device coexistence interference, since the RSRQ of the base station A and the RSRQ of the base station B become equal at the point where a '610 and b 620 meet, the RSRQ of the base station B coexists in the device. The UE initiates a procedure of performing a cell change (handover) from the base station A to the base station B at the position of M '660 which is a point larger than the RSRQ of the base station A considering the interference by a preset measurement report reference value. That is, if there is co-existence interference in the device, the terminal stationary at the position of M 'also changes the cell.

In this case, the cell change performed by the terminal at the position of M 'is a cell change that is not related to the movement state of the terminal. Therefore, in order to estimate the movement state of a reliable terminal, it is required to calculate the number of cell changes excluding cases not related to the movement state of the terminal.

Scenario 3. Non member CSG cell>

The femtocell can distinguish registered users from unregistered users and allow access only to registered users. A cell that allows access only to registered users is called a Closed Subscriber Group (CSG) cell. On the other hand, allowing access to general users is also called an Open Subscriber Group (hereinafter referred to as "OSG") cell. Since the CSG cell is a femtocell, that is, a small cell, it is mainly present inside the macro cell. CSG cells are used in homes and small offices.

Each CSG has a unique identifier, which is called a CSG identity (CSG identity). A terminal can have a list of CSGs belonging to itself as a member. Such a CSG list is also called a whitelist. The inclusion of the CSG corresponding to the CSG ID in the whitelist of the terminal that reads the CSG ID means that the terminal is a member of the corresponding CSG cell, and the terminal regards the cell as being allowed to access the corresponding CSG cell. And from the point of view of the CSG cell, the ID of the terminal must be included in the access control list (access control list) of the CSG cell, the CSG cell allows the access of the terminal.

A non member CSG cell is a cell in which the ID of the corresponding CSG cell is not included in the CSG white list of the terminal, and a cell in which the ID of the terminal is not included in the access control list of the non-member CSG cell. That is, the terminal refers to a cell that does not have membership for the non-member CSG cell. At this time, the UE cannot wirelessly access the non-member CSG cell to receive a service.

7 shows a cell change of a terminal in a non-member CSG cell to which the present invention is applied.

Referring to FIG. 7, the macro base station supports the first frequency (f1) and the second frequency (f2), there are CSG cells that transmit a service using a first frequency band in the macro cell, the CSG cell The UE is a non-member CSG cell with no membership. Assume that the priority of the first frequency band is higher than the second frequency band.

For example, when a terminal receiving a service through a first frequency band having a higher priority from the macro base station moves into a non-member CSG cell region, the terminal does not have membership in the non-member CSG cell, and thus the first frequency band is received from the macro base station. The service cannot be received through. This is because interference occurs in the first frequency band. In this case, the terminal receives a service from the macro base station through a second frequency band in which interference does not occur. That is, the terminal performs cell change (handover) from the first frequency band to the second frequency band.

The cell change from the first frequency band to the second frequency band is a cell change irrelevant to the mobile state of the terminal. Therefore, in order to estimate the movement state of a reliable terminal, it is required to calculate the number of cell changes excluding cases not related to the movement state of the terminal.

As another example, when the terminal receiving the service from the macro base station through the second frequency band continues to move out of the non-member CSG cell area, the terminal receives the service from the macro base station through the first frequency band having a higher priority again. . That is, the terminal performs cell change (handover) from the second frequency band to the first frequency band.

The cell rechange from the second frequency band to the first frequency band is a cell change that is not related to the mobile state of the terminal. Therefore, in order to estimate the movement state of a reliable terminal, it is required to calculate the number of cell changes excluding cases not related to the movement state of the terminal.

Now, a moving state estimation method of a terminal according to the present invention will be described. The reason for estimating the movement state of the terminal is that the terminal _{scales a} cell change parameter Q _hyst , T _reselection , and a trigger time (TTT) based on the estimated movement state of the terminal. This is because it is possible to derive a new cell change parameter that makes the cell change more successful.

8 is a flowchart illustrating a method of estimating a moving state of a terminal according to an embodiment of the present invention.

Referring to FIG. 8, the terminal receives at least one cell change parameter from the base station (S800). The cell change parameter may be received through another type of message according to the mode of the terminal. As an example, when the terminal is in the RRC connection mode, the cell change parameter may be received through an RRC connection reconfiguration message. As another example, when the terminal is in the idle mode, the cell change parameter may be received through a system information block (SIB), and in particular, a system information block type 3 information message. Can be received via

The cell change parameter is a parameter based on estimating the mobile state of the terminal. The terminal determines whether the estimated speed of the terminal is high speed, medium speed, or low speed based on the cell change parameter. The cell change parameter received from the base station is a value defined in the corresponding system and may be transmitted by the base station of the macro cell or the base station of the picocell. In addition, the cell change parameter is control information used to reduce cell change failure when the UE performs cell change from the current cell to another cell.

The cell change parameter may be defined differently according to a mode (eg, idle mode or RRC connection mode) of the terminal.

First, when the terminal is in the idle mode, the cell change parameters include Q _hyst , T _reselection , scaling index, medium speed reference value (Th _M ) and high speed reference value (Th _H ), estimation time for estimating the speed of the terminal, and low speed determination time. It includes.

Q _hyst is a value that adds or subtracts a value indicating the good or bad state of the radio state of the current cell, and controls the good or bad of the radio state relative to the new cell. T _reselection is a time during which a new cell must maintain a radio state superior to a current cell in order for the idle mode terminal to _{reselect a} new cell.

A scaling factor is a value that is multiplied to scale T _reselection or added to scale Q _hyst according to the estimated speed of the terminal. It may have a different value depending on the speed level of the terminal. If the estimated speed of the UE in the idle mode is high speed, the UE scales the T _reselection and Q _hyst values so that the cell _reselection can be performed quickly, and if the estimated speed is low, the UE increases the T _reselection and Q _hyst values. To scale.

For example, Q _hyst scaling Q _hyst The scaling index may be -6 dB, -4 dB, -2 dB or 0 dB. The scaling index of each Q _hyst may be set to correspond to any one of a high speed, a medium speed, and a low speed estimated speed. The following table is an example of the scaling index of Q _hyst corresponding to the estimated speed.

Estimated speed Scaling index of Q _hyst high speed -6 dB Medium speed -4 dB or -2 dB sleaze 0 dB

In this case, the scaling of Q _hyst is carried out by following the further scaling factor for Q _hyst as the mathematical expression.

Referring to Equation 1, when a scaling factor is added to the previous Q _hyst (old Q _hyst ), a new Q _hyst (new Q _hyst ) reflecting an estimated speed is obtained.

As another example, a T _reselection that scales a T _reselection The scaling index can be 0.25, 0.5, 0.75 or 1. The scaling index of each T _reselection may be set to correspond to any one of a high speed, a medium speed, and a low speed estimated speed. The following table is an example of the scaling index of T _reselection corresponding to the estimated speed.

Estimated speed Scaling index for T _reselection high speed 0.25 Medium speed 0.5 or 0.75 sleaze One

In this case, the scaling of the T _reselection is performed by multiplying the scaling factor then the T _reselection as mathematical expression of.

Referring to Equation 2, multiplying a previous T _reselection (old T _reselection ) by a scaling index to obtain a new T _reselection (new T _reselection ) reflecting an estimated speed.

Meanwhile, both the medium speed reference value and the high speed reference value included in the cell change parameter may be integer values between 1 and M. Here, M = 16. For example, when the medium speed reference value is 5 and the high speed reference value is 10, when the number of cell changes is 1 to 5, the estimated speed is low, and when the number of cell changes is 6 to 10, the estimated speed is medium speed and the number of cell changes is 11 ~. If it is 16, the estimated speed is high.

Estimating time for estimating the speed of the terminal may have a value of 30 seconds, 60 seconds, 180 seconds, 240 seconds. The terminal cumulatively increases the number of cell changes before the estimation time expires. The terminal may use a timer that operates until the estimated time expires (hereinafter, referred to as an "estimation timer").

The low speed determination time is a specific time value for determining the speed of the terminal as a low speed when the estimated speed of the terminal is not determined to be medium speed or high speed for a predetermined time, and may have values such as 30 seconds, 60 seconds, 180 seconds, 240 seconds, and the like. Can be.

Second, when the terminal is in RRC connected mode, the cell change parameter includes a trigger time, a scaling index, a medium speed reference value (Th _M ) and a high speed reference value (Th _H ), an estimated time for estimating the speed of the terminal, and a low speed determination time. do.

The trigger time is a handover preparation such as the UE starting a measurement report when the radio state is maintained for the trigger time after the radio state of the new cell is greater than a certain reference value than the current cell. The parameter used to initiate the step.

The scaling index is a value multiplied to scale the trigger time according to the estimated speed of the terminal. It may have a different value depending on the speed level of the terminal. If the estimated speed of the UE in the RRC connection mode is a high speed, the UE scales so that the trigger time is short so that handover is made quickly. If the estimated speed is low, the UE scales the trigger time to be large.

For example, a scaling index that scales the trigger time may be 0.25, 0.5, 0.75, or 1. Each scaling index may be set to correspond to any one of a high speed, a medium speed, and a low speed estimated speed. The following table is an example of the scaling index of the trigger time corresponding to the estimated speed.

Estimated speed Scaling Index of Trigger Time high speed 0.25 Medium speed 0.5 or 0.75 sleaze One

Table 3 assumes that the scaling index of the trigger time is 0.25 when the estimated speed is high, but this is only an example and the scaling index corresponding to each speed may be variously modified.

In this case, scaling of the trigger time is performed by multiplying the triggering time by a scaling index as in the following equation.

Referring to Equation 3, multiplying a previous trigger time by a scaling factor to obtain a new trigger time reflecting an estimated speed.

Upon receipt of the cell change parameter, the UE performs a cell change based on the cell change parameter (S805). Here, the UE in the idle mode performs cell selection (or cell reselection) and the UE in the RRC connected mode is a hand. Detect Over

When the terminal performs cell change, the scaling index value may be applied to the cell change parameter according to the movement state of the terminal estimated during the previous estimation time. That is, the terminal in the idle mode scales as shown in Equations 1 and 2 by using the scaling index values of Table 1 and Table 2 in the Q _hyst value and the T _reselection value. The UE of the RRC connected mode scales the trigger time value as shown in Equation 3 by using the scaling index values of Table 3.

The terminal determines whether the performed cell change is a cell change (hereinafter referred to as "terminal mobile change cell change") irrelevant to the mobile state (S810). If the performed cell change corresponds to one of the following Embodiments 1 to 4, the terminal determines that the cell change is a terminal change irrelevant cell change irrelevant to the terminal movement state. Additionally, when the UE in the RRC connected mode receives a service from the pico cell in the cell extension area and then changes to the idle mode, the UE may perform cell reselection from the pico cell to the macro cell. The cell reselection may be performed from one frequency band to the second frequency band, or the cell reselection may be performed from the second frequency band to the first frequency band.

For example, if the performed cell change is a cell change performed as the UE located in the cell extension region changes from the dormant mode to the RRC connection mode as shown in FIG. 4, the performed cell change is determined to be a UE change irrelevant cell change. (Example 1).

As another example, the cell change performed as the difference between the RSRQ of the source base station and the RSRQ of the target base station measured by the terminal affected by the coexistence interference in the device as shown in FIG. 6 meets a preset handover execution condition. If so, the performed cell change is determined to be a mobile terminal irrelevant cell change (Example 2).

As shown in FIG. 7, the terminal receives a service from the macro base station through the first frequency band f1 and the second frequency band f2 (provided that the priority of the first frequency band is higher than the second frequency band). Assume that the UE has no membership (non-member CSG cell) for a CSG cell using a first frequency band existing in a macro cell. For example, if a terminal receiving a service through a first frequency band from a macro base station moves to the non-member CSG cell region and performs a cell change to receive a service through a second frequency band, the performed cell change is performed. It is determined that the terminal movement irrelevant cell change (Example 3). As another example, if a terminal receiving a service through the second frequency band from the macro base station in the non-member CSG cell region moves to the non-member CSG cell region and performs a cell change to receive the service through the first frequency band. In addition, it is determined that the performed cell change is a UE change irrelevant cell change (Example 4).

The terminal calculates the sum of the number of cell changes (cell change count, not cell movement irrelevant cell change) related to the mobile state of the terminal during the estimated time (S815). In this case, the terminal may calculate using the "cell change count counter". If the cell change of the terminal is not a mobile terminal irrelevant cell change, the cell change count counter is increased by one. If the cell change of the terminal is a mobile terminal irrelevant cell change, the cell change count counter is not increased. The terminal applies a cell change count counter to all the cell changes that are performed to calculate the sum of the cell change counts rather than the UE change irrelevant cell change.

The terminal determines whether the estimation timer has expired (S820). That is, it is determined whether the preset movement state estimation time of the terminal has expired. If the estimation timer has not expired, the terminal performs a cell change again (S805), and determines whether or not the terminal movement irrelevant cell change and calculates the total number of cell changes related to the mobile state of the terminal.

On the other hand, if the estimation timer expires, the terminal updates the mobile state estimation result of the terminal on the basis of the cell change count counter (S825). The existing movement speed estimation result is updated with a new movement speed estimation result based on the sum of the number of cell changes during the estimation time.

Meanwhile, the terminal may select a scaling index corresponding to the updated moving speed estimation result (not shown). For example, the terminal in the idle mode may select a scaling index of Q _hyst and T _reselection based on Tables 1 and 2 above. As another example, the UE in the RRC connected mode may select the scaling index of the trigger time based on Table 3 above.

Meanwhile, the terminal may scale a cell change parameter using the selected scaling index (not shown). By scaling the cell change parameter, a new cell change parameter is derived. As an example, the terminal in the idle mode obtains new Q _hyst and T _reselection by scaling Q _hyst and T _reselection based on Equation 1 and Equation 2. As another example, the UE in the RRC connected mode obtains a new trigger time by scaling the trigger time based on Equation 3 above.

Although FIG. 8 illustrates that the calculation of the estimated speed is performed by the terminal, this may be performed in the base station that manages the macro cell.

9 is a flowchart illustrating a method of estimating a moving state of a terminal according to another embodiment of the present invention.

Referring to FIG. 9, the terminal receives at least one cell change parameter from the base station (S900). The cell change parameter may be received through another type of message according to the mode of the terminal. As an example, when the terminal is in the RRC connection mode, the cell change parameter may be received through an RRC connection reconfiguration message. As another example, when the terminal is in the idle mode, the cell change parameter may be received through a system information block, and in particular, may be received through a system information block type 3 information message.

Upon receiving the cell change parameter, the UE performs a cell change based on the cell change parameter (S905). The terminal in the idle mode performs cell reselection or the terminal in the RRC connected mode performs handover. When the terminal performs cell change, the scaling index value may be applied to the cell change parameter according to the movement state of the terminal estimated during the previous estimation time. That is, the terminal in the idle mode is scaled as shown in Equation 1 and Equation 2 using the scaling index values of Tables 1 and 2 to the Q _hyst value and the T _reselection value, and the terminal in the RRC connected mode is the trigger time. The value is scaled as in Equation 3 using the scaling index values in Table 3.

The UE determines whether the performed cell change is a UE change irrelevant cell change (S910). If the performed cell change corresponds to one of the first to fourth embodiments, the terminal determines the cell change as a mobile terminal irrelevant cell change irrelevant to the mobile station's mobile state.

The terminal determines whether the estimation timer has expired (S915). That is, it is determined whether the preset movement state estimation time of the terminal has expired. If the estimation timer has not expired, the terminal performs a cell change again (S905), and determines whether or not the terminal movement irrelevant cell change.

On the other hand, if the estimation timer expires, the terminal calculates the sum of the number of cell changes associated with the mobile state of the terminal (S920). First, the terminal calculates a total of the total number of cell changes, and then excludes the sum of the number of cell changes corresponding to the determined mobile terminal irrelevant cell change (the total number of cell changes minus the number of cell change irrelevant cell changes).

The terminal updates the mobile state estimation result of the terminal based on the sum of the number of cell changes related to the mobile state of the terminal (S925). The existing movement speed estimation result is updated with the new movement speed estimation result based on the sum of the number of cell changes related to the movement state of the terminal during the estimation time.

Meanwhile, the terminal may select a scaling index corresponding to the updated moving speed estimation result (not shown). For example, the terminal in the idle mode may select a scaling index of Q _hyst and T _reselection based on Tables 1 and 2 above. As another example, the UE in the RRC connected mode may select the scaling index of the trigger time based on Table 3 above.

Meanwhile, the terminal may scale a cell change parameter using the selected scaling index (not shown). By scaling the cell change parameter, a new cell change parameter is derived. As an example, the terminal in the idle mode obtains new Q _hyst and T _reselection by scaling Q _hyst and T _reselection based on Equation 1 and Equation 2. As another example, the UE in the RRC connected mode obtains a new trigger time by scaling the trigger time based on Equation 3 above.

In FIG. 9, the estimation speed is calculated by the terminal, but this may be performed by the base station that manages the macro cell.

10 is a flowchart illustrating a method for estimating a mobile state of a terminal by a base station according to an embodiment of the present invention.

Referring to FIG. 10, the base station transmits a cell change parameter to the terminal through an RRC connection reconfiguration message or a system information block (S1000).

The base station performs a cell change procedure with the UE in the RRC connected mode based on the cell change parameter (S1005). For example, the base station hands over the UE in the RRC connected mode to another cell. However, the terminal in the idle mode determines the terminal itself and performs cell reselection regardless of the base station. Meanwhile, in the idle mode, the S1005 procedure may be omitted because the terminal determines the cell by itself.

11 is a block diagram illustrating a base station for managing a cell and a terminal for communicating with a cell according to an embodiment of the present invention.

Referring to FIG. 11, the terminal 1100 includes a terminal receiver 1105, a terminal processor 1110, and a terminal transmitter 1115. The terminal processor 1110 includes a cell change execution unit 1111, a mobile terminal irrelevant cell change determination unit 1112, a total calculation unit 1113, and an estimation result update unit 1114.

The terminal receiver 1105 receives a cell change parameter from the base station 1150. The cell change parameter is control information used to reduce cell change failure when the UE 1100 performs cell change from the current cell to another cell. The cell change parameter is a parameter based on estimating the speed of the terminal 1100. The terminal 1100 determines whether the estimated speed of the terminal 1100 is high speed, medium speed, or low speed based on the cell change parameter. The cell change parameter may be defined differently according to the mode of the terminal 1100. As an example, when the terminal 1100 is in the idle mode, the cell change parameter is an estimate for estimating the medium speed reference value Th _M , the high speed reference value Th _H , Q _hyst , T _reselection , and the speed of the terminal 1100. At least one of time, low speed determination time, small cell density, and scaling index. In this case, the cell change parameter is included in the system information block and received. As another example, when the UE 1100 is in the RRC connection mode, the cell change parameter may include a medium speed reference value Th _M and a high speed reference value Th _H , a trigger time, an estimation time, a low speed determination time, a density of a small cell, and the like. At least one of the scaling indices. In this case, the cell change parameter is included in the RRC connection reconfiguration message.

The cell change execution unit 1111 performs a cell change of the terminal 1100.

The terminal movement irrelevant cell change determination unit 1112 determines whether the cell change of the terminal 1100 performed by the cell change execution unit 1111 is a cell change irrelevant to the movement state of the terminal 1100.

The terminal movement irrelevant cell change determination unit 1112 may change the cell that is not related to the movement state of the terminal 1100 if the performed cell change is a cell change performed according to a mode change of the terminal 1100 located in a cell extension region. Judging by.

The UE mobility irrelevant cell change determination unit 1112 may determine a difference between a reference signal received quality (RSRQ) of a source base station and an RSRQ of a target base station measured by the terminal 1100 affected by coexistence interference in a device. If it is a cell change performed according to a preset cell change condition, it is determined that the cell change is not related to the movement state of the terminal 1100.

The UE change irrelevant cell change determination unit 1112 may move the UE 1100 that receives the service through the first frequency band from the macro base station to a closed subscriber group (CSG) cell region without membership. When the cell change for receiving the service through the second frequency band is determined to be a cell change that is not related to the mobile state of the terminal 1100.

The mobile terminal irrelevant cell change determination unit 1112 may perform the CSG cell in which the terminal 1100 that receives the service through the second frequency band from the macro base station in the CSG cell region in which the cell change is performed does not have a membership. If the cell change for receiving the service through the first frequency band by moving out of the area is determined to be a cell change irrelevant to the mobile state of the terminal 1100.

The sum calculator 1113 calculates a sum of the number of cell changes related to the movement state of the terminal 1100 during the estimation time. For example, in calculating the total number of cell changes related to the mobile state of the terminal 1100 during the estimation time, if the cell change of the terminal 1100 is a cell change related to the mobile state of the terminal 1100, the cell change is performed. The counter is incremented by 1, and if the cell change of the terminal 1100 is a cell change irrelevant to the movement state of the terminal 1100, the counter is calculated by not increasing the number of cell changes. As another example, after calculating the total number of cell changes, the total number of cell changes related to the mobile state of the terminal 1100 may be calculated by excluding the number of cell changes that are not related to the mobile state of the terminal 1100. .

When the estimation timer expires, the estimation result update unit 1114 updates the movement state estimation result based on the total number of cell changes related to the movement state of the terminal 1100.

The estimation result updater 1114 determines whether the movement state of the terminal 1100 is high speed, medium speed, or low speed based on the cell change parameter.

The estimation result updater 1114 scales the cell change parameter according to the movement state of the terminal 1100 estimated during the previous estimation time.

The estimation result updater 1114 selects a scaling index corresponding to the updated moving speed estimation result, and scales the cell change parameter by the selected scaling index.

The transmission unit 1115 of the terminal 1100 transmits a signal for cell change to the base station 1550 based on the updated movement state measurement result.

The base station 1150 includes a base station transmitter 1155, a base station receiver 1160, and a base station processor 1170. The base station processor 1170 also includes a cell change controller 1171 and a cell change parameter generator 1172.

The base station transmitter 1155 transmits the cell change parameter to the terminal 1100. The base station receiver 1160 receives a signal for cell change from the terminal 1100. The cell change controller 1171 performs a cell change procedure with the terminal 1100. The cell change parameter generator 1172 generates a cell change parameter.

In the above-described exemplary system, the methods are described on the basis of a flowchart as a series of steps or blocks, but the present invention is not limited to the order of the steps, and some steps may occur in different orders or simultaneously . It will also be understood by those skilled in the art that the steps shown in the flowchart are not exclusive and that other steps may be included or that one or more steps in the flowchart may be deleted without affecting the scope of the invention.

The above-described embodiments include examples of various aspects. While it is not possible to describe every possible combination for expressing various aspects, one of ordinary skill in the art will recognize that other combinations are possible. Accordingly, it is intended that the invention include all alternatives, modifications and variations that fall within the scope of the following claims.

Claims (20)

In the method for estimating the mobile state of the wireless terminal,
Receiving at least one cell change parameter from a base station;
Performing a cell change based on the cell change parameter;
Determining whether the performed cell change is a cell change irrelevant to a movement state of the wireless terminal;
Calculating a number of cell changes related to a movement state of the wireless terminal during a preset estimation time; And
And when the estimation timer operating for the preset estimation time expires, updating the movement state estimation result based on the sum of the number of cell changes related to the movement state of the wireless terminal. . The method of claim 1,
When the wireless terminal is in the RRC connection mode, the cell change parameter is received through an RRC connection reconfiguration message,
And the cell change parameter is received through a system information block (SIB) when the wireless terminal is in an idle mode. The method of claim 1,
And determining whether the state of movement of the wireless terminal is high speed, medium speed, or low speed based on the cell change parameter. The method of claim 1,
And when performing the cell change based on the cell change parameter, scaling the cell change parameter according to the movement state of the wireless terminal estimated during a previous estimation time. The method of claim 1,
And if the cell change is a cell change performed according to a mode change of the wireless terminal located in a cell extension region, determining that the cell change is a cell change irrelevant to the mobile state of the wireless terminal. The method of claim 1,
A cell performed according to a difference between a reference signal received quality (RSRQ) of a source base station and an RSRQ of a target base station measured by the wireless terminal affected by in-device coexistence interference according to a preset cell change condition And if the change is determined to be a cell change irrelevant to the mobile state of the wireless terminal. The method of claim 1,
A cell change for receiving a service over a second frequency band when the cell change is moved from a macro base station to a closed subscriber group (CSG) cell region in which the wireless terminal receiving a service over a first frequency band has no membership; And if it is determined that the cell change is irrelevant to the movement state of the wireless terminal. The method of claim 1,
The wireless terminal receiving the service through the second frequency band from the macro base station in the CSG cell region in which the cell change is performed does not move to receive the service through the first frequency band by moving out of the CSG cell region without membership. And if the cell is to be changed, determine that the cell is irrelevant to the mobile state of the wireless terminal. The method of claim 1,
The sum of the number of cell changes related to the mobile state of the wireless terminal during the preset estimation time is
If the cell change of the wireless terminal is a cell change related to the mobile state of the wireless terminal, the counter is incremented by 1. If the cell change of the wireless terminal is a cell change not related to the mobile state of the wireless terminal, the counter is not increased. Moving state estimation method. The method of claim 1,
Selecting a scaling index corresponding to the updated moving speed estimation result; And
And scaling the cell change parameter by the selected scaling index. In the terminal for estimating the movement state,
A receiver for receiving at least one cell change parameter from a base station;
A cell change performer which performs a cell change based on the cell change parameter;
A terminal movement irrelevant cell change determination unit that determines whether the performed cell change is a cell change irrelevant to a movement state of the wireless terminal;
A total calculation unit for calculating a total of the number of cell changes related to the movement state of the wireless terminal during a preset estimation time; And
And an estimation result update unit for updating the movement state estimation result based on the sum of the number of cell changes related to the movement state of the wireless terminal when the estimation timer operating for the preset estimation time expires. The method of claim 11,
The receiver may further comprise:
When the wireless terminal is in the RRC connection mode, the cell change parameter is received through an RRC connection reconfiguration message,
And the cell change parameter is received through a system information block (SIB) when the wireless terminal is in idle mode. The method of claim 11,
The estimation result update unit,
And determining whether the movement state of the wireless terminal is high speed, medium speed, or low speed based on the cell change parameter. The method of claim 11,
The estimation result update unit
And scaling the cell change parameter according to the movement state of the wireless terminal estimated during the previous estimation time. The method of claim 11,
The terminal movement irrelevant cell change determination unit,
And if the performed cell change is a cell change performed according to a mode change of the wireless terminal located in a cell extension region, determining that the cell change is not related to a movement state of the wireless terminal. The method of claim 11,
The terminal movement irrelevant cell change determination unit,
If the cell change performed is a cell change performed by a difference between an RSRQ of a source base station and an RSRQ of a target base station measured by the wireless terminal affected by in-device coexistence interference, the cell change is performed. Terminal determined by the cell change irrelevant to the movement state. The method of claim 11,
The terminal movement irrelevant cell change determination unit,
If the performed cell change is a cell change for receiving a service through a second frequency band when the wireless terminal receiving a service through a first frequency band from a macro base station moves to a CSG cell region having no membership, the wireless terminal. The terminal characterized in that it is determined to change the cell irrelevant to the state of movement. The method of claim 11,
The terminal movement irrelevant cell change determination unit,
The wireless terminal receiving the service through the second frequency band from the macro base station in the CSG cell region in which the cell change is performed does not move to receive the service through the first frequency band by moving out of the CSG cell region without membership. If the cell change to the terminal characterized in that it is determined that the cell change irrelevant to the movement state of the wireless terminal. The method of claim 11,
The total calculation unit,
If the cell change of the wireless terminal is a cell change related to the mobile state of the wireless terminal, the counter is increased by one, and the total of the number of cell changes related to the mobile state of the wireless terminal during the preset estimated time is increased. And if the cell change of the cell change is irrelevant to the movement state of the wireless terminal, calculating by not incrementing the counter. The method of claim 11,
The estimation result update unit,
And selecting a scaling index corresponding to the updated moving speed estimation result, and scaling the cell change parameter by the selected scaling index.

Images