JP5688007B2 - Cell selection method of hierarchical cell structure based on cell quality - Google Patents

Abstract

Method to select cell in hierarchical cellular structure based on cell quality. The method comprises the steps of: performing measurement of the cell; determining whether a hierarchical cellular structure (HCS) is used in the service cell; if the HCS is used in the service cell, rating is performed for the measured cells meeting a first standard and a second standard; and performing cell reselection for the optimal cell in the rating of the measured cells meeting the first standard and the second standard, wherein the first standard is used for selecting the measured cell meeting the lowest quality condition, and the second standard is used for determining whether to use a rating with priority according to a hierarchical cell reselection rule.

Description

  The present invention relates to a cell selection method of a hierarchical cell structure (HCS) based on cell quality.

  In the prior art, cell selection is performed, but radio resources are consumed unnecessarily. Thus, the prior art does not adequately address such problems and does not provide an appropriate solution.

As a result of tests on the out-of-service situation, the present inventors have recognized the drawbacks of the prior art as described above. Based on such recognition, various features to be described later have been devised to present a cell selection method having a hierarchical cell structure based on cell quality, and as a result, more efficient use of radio resources has been enabled.
This specification provides the following items, for example.
(Item 1)
Checking whether a hierarchical cell structure (HCS) is used;
Loading parameters relating to the H reference value from the system information;
Measuring the cell;
Identifying a cell satisfying an S reference value from the measured cells;
Confirming whether or not the H reference value is satisfied for a cell satisfying the S reference value;
Selecting a cell having the highest R reference value from among cells satisfying all of the S reference value and the H reference value;
A cell selection method for a user equipment (UE), comprising:
(Item 2)
The user equipment (UE) according to item 1, wherein the HCS defines overlapping cells of different sizes forming a plurality of cell hierarchies, and is used when the serving cell of the UE belongs to the HCS. Cell selection method.
(Item 3)
The S reference value is a selection or qualification reference value used for confirming whether the reception quality of the target cell is sufficient, and the H reference value is an HCS reference used when the HCS is used. Value, which is a positive or negative value calculated based on information sent in the system information, and the R reference value is used by the UE to rank a list of cells that satisfy the S reference value A cell selection method for a user equipment (UE) according to item 1, wherein the cell selection method is a ranking reference value.
(Item 4)
After determining the measured cell by performing a signal measurement procedure with a base station in all frequency bands that can be searched, the cell having the strongest signal characteristic value is selected from the cells satisfying a specific cell selection condition, and the selected cell is selected. 2. A cell selection method for a user equipment (UE) according to item 1, wherein the cell is accessed.
(Item 5)
When the hierarchical cell structure (HCS) is used in the serving cell of the user equipment (UE),
If the mobility of the UE is low, the ranking procedure is performed for all measured cells having the highest HCS priority among the cells satisfying the reference value S and the reference value H ≧ 0. If no cell satisfies the value H ≧ 0, the ranking procedure is performed on all measured cells regardless of the HCS priority;
If the UE has high mobility, the ranking procedure is performed on all measured cells, and among the measured cells, the reference value S and the reference value H ≧ 0 are satisfied, and the serving cell If there is a cell having a lower HCS priority, all the cells having the highest HCS priority among the cells having the lower HCS priority than the serving cell and satisfying the reference value S and the reference value H ≧ 0. If there is a cell that satisfies the reference value S and the reference value H ≧ 0 and has the same or higher HCS priority as the serving cell, the HCS is the same as or higher than the serving cell. Among the cells having the priority order, all the cells having the lowest HCS priority order among the cells satisfying the reference value S and the reference value H ≧ 0 are compared. It performs a ranking procedure, otherwise, and performing the ranking procedure regardless of the HCS priority
A cell selection method for a user equipment (UE), comprising:
(Item 6)
The cell selection method for a user equipment (UE) according to item 5, wherein the hierarchical cell structure (HCS) defines overlapping cells of different sizes forming a plurality of cell hierarchies.
(Item 7)
6. The user equipment (UE) according to item 5, wherein whether the mobility of the user equipment is low or high is determined based on the number of cell reselections in a specific period or based on RRC signaling from the network. Cell selection method for.
(Item 8)
After determining the measured cell by performing a signal measurement procedure with a base station in all frequency bands that can be searched, the cell having the strongest signal characteristic value is selected from the cells satisfying a specific cell selection condition, and the selected cell is selected. 6. The cell selection method for a user equipment (UE) according to item 5, wherein the access to the selected cell is performed.
(Item 9)
9. The cell selection method for user equipment (UE) according to item 8, wherein at least one of CPICH RSCP, CPICH Ec / No, and Carrier RSSI is used for the signal measurement procedure.
(Item 10)
In the ranking procedure, when selecting a target cell for the ranking, the ranking indicating the relative signal strength of the measured cell or the range superposition degree between the cells is considered in consideration of all the H reference value and the S reference value. 6. The cell selection method for user equipment (UE) according to item 5, wherein the cell selection method is obtained.
(Item 11)
The item of claim 10, wherein the ranking procedure is performed based on the R reference value, and cell selection or reselection is performed on one or more cells ranked as having the highest quality. A cell selection method for a user equipment (UE).
(Item 12)
6. The cell selection method for a user equipment (UE) according to item 5, wherein the HCS priority order defines in which cell hierarchy of the HCS the UE should exist.
(Item 13)
The HCS priority is transmitted as part of the cell broadcast information in the form of a system information block, or alternatively, for neighboring cells, the HCS priority is as part of the RRC measurement control message. 13. The cell selection method for user equipment (UE) according to item 12, wherein the cell selection method is transmitted.
(Item 14)
The S reference value is a selection or qualification reference value used for confirming whether the reception quality of the target cell is sufficient, and the H reference value is an HCS reference used when the HCS is used. 6. The user apparatus according to item 5, wherein the user apparatus is a positive value or a negative value calculated based on information sent by system information and measurement from CPICH / P-CPCCH of the target cell. Cell selection method for (UE).

It is a figure which shows an example of the network structure of UMTS (Universal Mobile Telecommunications System). It is a figure which shows an example of the radio | wireless protocol stack used by UMTS. It is a figure which shows an example of the formula which defines the conditions which a mobile terminal uses in order to select the cell which has signal strength and quality higher than the specific value defined in the system. It is a flowchart which shows an example of the cell selection (reselection) method in WCDMA. FIG. 6 is a diagram illustrating a formula for calculating an R reference value used by a mobile terminal for a cell ranking process; It is a figure which shows the concept of an example of hierarchical cell structure. It is a figure which shows an example of the calculation procedure of H reference value.

  Hereinafter, the concept and features of the invention relating to the cell selection method of the hierarchical cell structure based on the cell quality of the present invention will be described from the viewpoint of an LTE (Long Term Evolution) system advanced from the current 3GPP technology or a so-called 4G communication system. However, the details do not limit the various features described herein and can be applied to other types of mobile and / or wireless communication systems and schemes.

  Hereinafter, the term “mobile terminal” refers to various types such as mobile communication terminals, user equipment (UE), mobile equipment (ME), and other devices that support various types of wireless communication technologies. Used to indicate the user device.

  In mobile communication, cell selection means a process in which a mobile terminal searches for an appropriate cell (target cell). If any cell is selected as a result of cell selection, the selected cell is referred to as a camp-on cell. When camping on a cell, the mobile terminal periodically searches for a better cell according to various cell reselection criteria (described below), and if a better cell is searched, the better cell is selected.

  Typically, a large cell (eg, a macro cell) cannot support many users, but can support users that move at high speed. Typically, small cells (eg, microcells or picocells) can support many users, but cannot support users that move at high speed. This problem can be solved by defining a plurality of overlapping cells having various sizes and using a hierarchical cell structure (HCS) in which a plurality of cell hierarchies are formed. This type of cell structure allows the network to effectively utilize the geographical area to support more users.

  An HCS priority (HCS_PRIO) is defined to determine in which cell hierarchy of the HCS the user equipment should be present. Such priority information can be transmitted as part of the cell broadcast information (that is, SIB11 and SIB12 are used for neighboring cells and SIB13 and SIB14 are used for serving cells). For neighboring cells, such priority information can also be transmitted as part of the RRC measurement control message. HCS cells can be given priorities from 0 to 7, where 0 is the lowest priority and 7 is the highest priority. The highest priority can be given to the cell adjacent to the serving cell.

  The cell reselection criterion is an H reference value (ie, an HCS reference value used when HCS is used, based on information transmitted in the system information or for measurement from the CPICH / P-CPCCH of the target cell. Positive or negative value calculated on the basis of), an S reference value (ie, a selection or qualification reference value used to check whether the reception quality of the target cell is sufficient), and an R reference value ( That is, there is a ranking reference value used by the mobile terminal to rank a list of cells that satisfy the S reference value.

  The present invention was devised to improve the cell selection (reselection) procedure in order to reduce the occurrence of a denial of service situation. The so-called unserviceable state means a state in which the mobile terminal cannot receive a specific service from the mobile communication network for various reasons. In order to resolve the denial of service situation, the mobile terminal must perform a general cell search procedure, which consumes battery power and introduces a delay that can be perceived by the user.

  In the procedure for cell selection (reselection), various conditions including an H reference value and an S reference value are used. The inventors have recognized that the prior art cell selection (reselection) procedure has several drawbacks. This is because the prior art mainly considers the H reference value and then considers the S reference value incidentally or ignores the S reference value completely. In the present invention, as a result of emphasizing the S reference value over the H reference value based on recognition of such a problem, cell selection and reselection have been improved.

  The present invention relates to a method for a mobile terminal to select a cell to be served in UMTS, which is a European IMT-2000 system. In particular, the present invention relates to a method for considering the quality of each cell when a mobile terminal selects a specific cell to be served.

  FIG. 1 is a diagram illustrating a network structure of the UMTS 100. The UMTS system basically includes a user equipment (UE) 130, a UMTS radio access network (UMTS Terrestrial Radio Access Network; UTRAN) 120, and a core network (Core Network; CN) 110. The UTRAN 120 is composed of one or more radio network subsystems (RNS) 122, and each RNS is managed by one radio network controller (RNC) 124 and an RNC 124. It consists of one or more Node B 126s. One Node B has one or more cells 128.

  FIG. 2 is a diagram showing a radio protocol stack used in UMTS. The radio protocol layer exists in pairs between the mobile terminal and the UTRAN, and is responsible for data transmission via the radio interface. Such a radio protocol stack is roughly divided into three layers, L1 (first layer), L2 (second layer), and L3 (third layer).

  L1 (first layer) is a physical layer (PHY) that transmits reliable data through a wireless interface using various wireless transmission technologies. The PHY layer is connected to an upper layer (MAC layer) via a transport channel, and the transport channel is divided into a dedicated transport channel and a common transport channel.

  L2 (second layer) is composed of four sublayers, MAC, RLC, PDCP, and BMC. Each sublayer will be described in more detail below.

  A MAC (Media Access Control) layer performs mapping of various logical channels to various transport channels, and also performs logical channel multiplexing of a plurality of logical channels to one transport channel. The MAC layer is connected to an upper layer (RLC layer) via one or more logical channels. The logical channel is divided into a control channel used for transmission of control plane information and a traffic channel used for transmission of user plane information according to the type of information to be transmitted. The MAC layer is divided into a MAC-b sublayer, a MAC-c / sh sublayer, a MAC-d sublayer, a MAC-hs sublayer, and a MAC-e sublayer depending on the type of transport channel to be managed. The MAC-b sublayer is in charge of managing a BCH (Broadcast Channel) that is a transport channel used for broadcasting system information. The MAC-c / sh sublayer manages a common transport channel such as FACH (Forward Access Channel) and DSCH (Downlink Shared Channel) shared with other mobile terminals. The MAC-d sublayer is responsible for managing a dedicated transport channel such as a DCH (Dedicated Channel) for a specific mobile terminal. In order to support high-speed data transmission in the downlink and uplink, the MAC-hs sublayer manages HS-DSCH (High Speed Downlink Shared Channel), which is a transport channel for high-speed downlink data transmission. The e sublayer manages E-DCH (Enhanced Dedicated Channel) which is a transport channel for high-speed uplink data transmission.

  The RLC (Radio Link Control) layer is responsible for guaranteeing QoS (Quality of services) of each radio bearer (RB) and data transmission based on the guarantee. RLC has one or two independent RLC entities per RB to guarantee RB-specific QoS, and three RLC modes (Transparent Mode (TM)) to support various QoS. , Unacknowledged mode (UM), and acknowledged mode (AM)). In addition, the RLC adjusts the data size so that the lower layer is suitable for transmission over the radio interface, and thus performs a function of dividing and concatenating data received from the upper layer.

  The PDCP (Packet Data Convergence Protocol) layer is located above the RLC layer, and can efficiently transmit data transmitted using IP packets (such as IPv4 and IPv6) over a relatively low bandwidth wireless interface. Like that. For this reason, the PDCP layer performs a header compression function, which improves the transmission efficiency of the wireless interface by transmitting only the essential information in the header portion of the data. Since the header compression is a basic function, the PDCP layer exists only in the PS (Packet Switched) domain, and there is one PDCP entity for each RB in order to provide an effective header compression function for each PS service. .

  A BMC (Broadcast / Multicast Control) layer exists above the RLC layer, and performs a function of scheduling a cell broadcast message (Cell Broadcast Message) and broadcasting it to a mobile terminal located in a specific cell.

  L3 (layer 3) has an RRC (Radio Resource Control) layer located at the lowest layer, which is defined only in the control plane. L3 and L2 are related to radio bearer setup, reconfiguration, and release. Control parameters and control logical, transport, and physical channels. Here, the radio bearer means a logical path provided by radio protocols L1 and L2 for data transmission between the mobile terminal and the UTRAN. In general, the setting of a radio bearer means a procedure for setting characteristics of a radio protocol layer and a channel necessary for providing a specific service, and setting specific parameters and operation methods thereof.

  Hereinafter, a procedure in which a mobile terminal in the idle mode selects a cell will be described in detail.

  Basically, the reason for selecting a cell is to register with the network so that it can receive service from the base station. Here, when the strength or quality of the signal between the mobile terminal and the base station is reduced due to the mobility of the mobile terminal, the mobile terminal reselects another cell in order to maintain the data transmission quality. Hereinafter, physical signal characteristics such as signal strength and noise-to-interference ratio are simply referred to as signal characteristics.

  As described above, there is a method of selecting a cell based on signal characteristics corresponding to a wireless environment. In addition, the mobile terminal uses a cell selection procedure based on reasons such as terminal capability (UE capability), subscriber information (Subscriber Information), camp load balancing, and traffic load balancing (Traffic load balancing). Sometimes it is necessary.

  Hereinafter, a method and procedure for selecting a cell by WCDMA will be described.

  First, when the mobile terminal is turned on, it selects PLMN and RAT for wireless communication, performs a signal measurement procedure with the base station in all frequency bands that can be searched by the mobile terminal, and then satisfies the conditions of FIG. A cell having the strongest signal characteristic value is selected from the cells, and a connection to the cell is made. In the WCDMA system, CPICH RSCP, CPICH Ec / No, and Carrier RSSI are used as values for the signal measurement procedure.

  As can be seen from FIG. 3, the mobile terminal selects a cell whose signal strength and quality are greater than a specific value defined by the system (strength: Qrxlevmin + Pcompensation, quality: Qqualmin). Here, these values (Qrxlevmin, Pcompensation, quality: Qqualmin) are notified from the base station to the mobile terminal by system information (SI). In addition, the mobile terminal waits in an idle mode in order to request a service from the network (for example, Originating Call) or to receive a service from the network (for example, an incoming call (Terminating Call)). The mobile terminal in the idle mode measures the signal of the cell adjacent to the cell currently being serviced and repeats the procedure of reselecting the cell having better signal characteristics.

  FIG. 4 is a flowchart showing an example of a cell selection (reselection) method in WCDMA. As shown in step S401, the mobile terminal in the idle mode, with respect to the signal characteristic value (Rs) of the cell receiving the service among the cells satisfying the condition of FIG. 3, and the signal characteristic value (Rn) of the neighboring cell Perform the measurement procedure periodically. As shown in step S403, the signal strength and quality of the cell corresponding to Rn are compared according to a ranking procedure or process that satisfies the condition of Rn> Rs for a specific time (Teleselection). As a result, as shown in step S405, the cell having the highest (or largest) characteristic value is selected. That is, another cell having the best signal characteristics compared to the cell currently receiving service is selected.

  The values of Rs and Rn are obtained using the mathematical formula of FIG. Treselection is a value notified from the base station to the mobile terminal by system information (SI), and prevents a specific cell from being repeatedly selected by applying a restriction that the cell selection condition must be satisfied for a specific time or more. Used for.

  FIG. 5 is a diagram illustrating a formula for calculating an R reference value used by a mobile terminal for a cell ranking process. Here, Rs indicates the ranking of serving cells, and Rn indicates the ranking of neighboring cells. Qmeas, s indicates the CPICH Ec / No value measured for the cell currently being serviced by the mobile terminal, and Qmeas, n indicates the CPICH Ec / No value measured for the neighboring cell by the mobile terminal. . While using Qhyts to apply weights to the services that the mobile terminal is currently receiving, Qoffsets, n is used to reduce the bias between the currently connected cell and the cell whose connection is being changed. Or use Qoffmbms to apply weights to cells that support one-to-many services (such as MBMS).

  Similar to the WCDMA cell selection method, the cell selection method based on signal characteristics is such that the mobile terminal selects a cell with good reception signal characteristics and receives a service from the base station, so that the signal sent by the sender is received by the receiver. Is the method of interpretation with the least error. The mobile terminal performs ranking after obtaining the R reference value for selectable cells, and selects (or reselects) the cell with the best signal through the ranking process.

  However, WCDMA can be used if the HCS function is required.

  FIG. 6 is a diagram showing an example of a cell structure for HCS. That is, a plurality of cells exist in one area (or area), and the radius (or size) of each cell is different. In FIG. 6, the frequencies O, N, and M may be the same or different, and this is an example. In FIG. 6, the cell of Priority C has the largest radius, and the cell of Priority A has the lowest priority.

  The HCS described in FIG. 6 is used, for example, to reduce a change according to the speed of a mobile terminal moving at a different speed between cells. For example, it is assumed that there is a mobile terminal A moving at a speed of 5 km / h and a mobile terminal B moving at a speed of 50 km / h from right to left in FIG. If both of the two mobile terminals select a Priority A cell, the mobile terminal B changes the cell 10 times more than the mobile terminal A at a given time. When the mobile terminal changes the cell frequently, power consumption of the mobile terminal and waste of radio resources occur due to frequent cell updates. Therefore, in this situation, the base station causes a mobile terminal with a high speed to select a cell of Priority C (that is, a cell with a large radius) and a mobile terminal with a low speed to a cell with Priority A (that is, a cell with a small radius). By selecting a cell, the mobile terminal is operated efficiently.

When using the feature of HCS in such a situation, it is necessary to change the operation of the mobile terminal. FIG. 7 shows the process of calculating the H reference value. Therefore, the cell selection procedure when HCS is used is as follows.
1. If the current serving cell indicates that HCS is used, the mobile terminal determines a cell that meets the following conditions.
a. If your mobile device moves slowly:
i. Among the cells satisfying H> = 0, all measured cells having the highest HCS_PRIO value ii. If no cell satisfies H> = 0, all measured cells regardless of HCS_PRIO value b. When the mobile terminal moves at high speed:
i. Among cells satisfying H> = 0, when there is a cell having an HCS priority lower than that of the current serving cell (condition 1):
1. Among the cells with HCS priority lower than the current serving cell, all measured cells ii. With the highest HCS_PRIO value among the cells satisfying H> = 0. In other cases (that is, when condition 1 is not satisfied):
1. When there is a cell satisfying H> = 0 among the cells having the same HCS priority as the current serving cell or higher than the current serving cell (condition 2):
a. Among the cells having the same or higher HCS priority than the current serving cell, the cell having the lowest HCS_PRIO value among all measured cells satisfying H> = 0. Other cases (that is, when condition 2 is not satisfied)
a. 1. All measured cells without considering HCS priority 1 above. The mobile terminal performs a ranking process based on the R reference value to select the cell with the highest quality for the cells determined in the above procedure, and selects the cell for the cell (re-selection). Select).

  The S reference value mentioned in the above description is used by the mobile terminal to determine whether some cells satisfy the minimum quality assurance condition. That is, the S reference value is used when determining whether or not a specific cell satisfies the minimum condition necessary for performing paging or RRC connection.

  The cell reselection procedure of the mobile terminal when the HCS is set has been described above. However, according to the above procedure, the mobile terminal cannot select a cell that can be camped depending on the case, and the service is normal. Situations that cannot be received may occur. For example, the following cell configuration is assumed.

従来技術によれば、移動端末は次の動作を行う。
ステップ１：必要な測定を行う。
セルＡ、セルＢ、及びセルＣを測定する。
ステップ２：基準値Ｈ＞＝０を満たすセルがあるか否かを確認する。
セルＡ及びセルＣがＨ基準値を満たす。

According to the prior art, the mobile terminal performs the following operations.
Step 1: Make necessary measurements.
Cell A, cell B, and cell C are measured.
Step 2: Check whether there is a cell that satisfies the reference value H> = 0.
Cell A and cell C satisfy the H reference value.

  Step 3: Identify the highest HCS_PRIO value from the cells identified in Step 2.

  Among cells A and C, cell A has 4 which is the highest HCS_PRIO value.

  Step 4: Identify the cell having the HCS_PRIO value identified in Step 3.

  Cell A is the only cell with the highest HCS_PRIO value.

  Step 5: Confirm cells satisfying the S reference value from among the cells identified in Step 4.

  Cell A does not meet the S criterion.

  Step 6: Ranking is performed on the cells identified in Step 5.

  There is no target cell for ranking.

  In Table 1 above, the mobile terminal should select cell C, but according to the prior art, the mobile terminal cannot select any cell. That is, according to the related art, the mobile terminal first selects a cell that satisfies the H reference value, and then selects the best cell among the cells that satisfy the S reference value. Accordingly, there is a problem that the mobile terminal sets an inappropriate HCS_PRIO value when there is a cell that does not satisfy the S reference value but satisfies the H reference value in a procedure that operates according to the H reference value. In this case, since the mobile terminal cannot find a cell to be provided with service, there is a problem that it cannot start or receive a call.

  Therefore, the present invention is a system that uses the HCS function, in which a mobile terminal effectively and appropriately transmits data generated in a cell to which a service is provided by a wireless protocol that supports only a PS network or a PS service. Present the methods you can do.

  For this purpose, in the procedure of selecting a cell from which the mobile terminal is to receive service, particularly when notifying that the current serving cell uses HCS, the mobile terminal sets the H reference value for the cell to be measured. It is proposed to consider the S reference value when defining a list of selectable cells.

  In the present invention, when the mobile terminal applies the H reference value, the cell to which the H reference value is applied is a cell that already satisfies the S reference value.

  In the present invention, when the mobile terminal applies the H reference value, if each cell satisfies the H reference value, the mobile terminal further checks whether or not the S reference value is satisfied, and the cell satisfies both the S reference value and the H reference value. A ranking process is performed on the results.

Next, an example of the operation of the mobile terminal of the present invention will be described. The cell selection procedure when HCS is used is as follows.
1. A mobile terminal discriminate | determines the cell which satisfy | fills S reference value with respect to the cell which measured. Then, the next step 2 is performed only for the determined cell.
2. The mobile terminal determines a cell that further satisfies the following condition from among the cells that satisfy Step 1, that is, the cells that satisfy the S reference value.
a. If your mobile device moves slowly:
i. Among the cells satisfying H> = 0, all measured cells having the highest HCS_PRIO value ii. If no cell satisfies H> = 0, all measured cells regardless of HCS_PRIO value b. When the mobile terminal moves at high speed:
i. Among cells satisfying H> = 0, when there is a cell having an HCS priority lower than that of the current serving cell (condition 1):
1. Among the cells with HCS priority lower than the current serving cell, all measured cells ii. With the highest HCS_PRIO value among the cells satisfying H> = 0. In other cases (that is, when condition 1 is not satisfied):
1. When there is a cell satisfying H> = 0 among the cells having the same HCS priority as the current serving cell or higher than the current serving cell (condition 2):
a. Among the cells having the same or higher HCS priority than the current serving cell, the cell having the lowest HCS_PRIO value among all measured cells satisfying H> = 0. Other cases (that is, when condition 2 is not satisfied)
a. 2. All cells measured without considering HCS priority For the cell determined in step 2, the mobile terminal performs a ranking process based on the R reference value, selects the cell with the highest quality, and performs cell selection (reselection) for the cell.

The cell selection procedure when HCS according to another embodiment of the present invention is used is as follows.
1. When notifying that the current serving cell uses HCS, the mobile terminal determines a cell that satisfies the following conditions.
a. If your mobile device moves slowly:
i. All measured cells with the highest HCS_PRIO value among cells satisfying both H> = 0 and the S reference value ii. If no cell satisfies both H> = 0 and the S reference value, all measured cells that satisfy the S reference value regardless of the HCS_PRIO value b. When the mobile terminal moves at high speed:
i. Among cells satisfying both H> = 0 and the S reference value, there is a cell having an HCS priority lower than that of the current serving cell (condition 1):
1. Of the cells with HCS priority lower than the current serving cell, all measured cells ii. With the highest HCS_PRIO value among cells that satisfy both H> = 0 and the S reference value. In other cases (that is, when condition 1 is not satisfied):
1. When there is a cell that satisfies both H> = 0 and the S reference value among cells having the same HCS priority as the current serving cell or higher than the current serving cell (Condition 2):
a. Cell 2 with the lowest HCS_PRIO value among all measured cells that meet both H> = 0 and S criterion among cells having the same or higher HCS priority than the current serving cell . Other cases (that is, when condition 2 is not satisfied)
a. 1. All measured cells that do not consider HCS priority and meet S criteria For the cell determined in step 1, the mobile terminal performs a ranking process based on the R reference value, selects the cell with the highest quality, and performs cell selection (reselection) for the cell.
According to the example shown in Table 1, the result of the operation according to the present invention is as follows.
Step 1: Make necessary measurements.
Cell A, cell B, and cell C are measured.
Step 2: Check whether there is a cell that satisfies the reference value S.
Cell B and cell C satisfy the S reference value.
Step 3: Check whether there is a cell satisfying the reference value H> = 0 among the cells confirmed in Step 2.
Among the cells B and C, the cell C satisfies the H reference value.
Step 4: Identify the highest HCS_PRIO value from the cells identified in Step 3.
Cell C has 3 which is the highest HCS_PRIO value.
Step 5: Identify the cell having the HCS_PRIO value identified in Step 4.
Cell C is the only cell with the highest HCS_PRIO value.
Step 6: Ranking is performed on the cells identified in Step 5.
Cell C is the target cell for ranking.

  The results of the present invention are as follows. As described above, according to the cell structure using the HCS function of the present invention, when the mobile terminal selects a cell, the mobile terminal is more stable and stable by appropriately using the H reference value and the S reference value. Be able to receive services in an effective manner.

  Details regarding the concepts and features of the present invention are described below.

Details # 1
If HCS is not used in the serving cell, the ranking target for all cells where the UE meets the S criterion:
-If HCS is used in all measured cell serving cells, the ranking target for all cells where the UE meets the S criterion:
1. When mobility is low • Among cells satisfying the reference value H> = 0, all the cells with the highest HCS_PRIO are measured. • If there is no cell satisfying the reference value H> = 0, measurement without considering the HCS priority level As described above, if the mobility of the UE is low and the condition of H> = 0 is satisfied, the UE performs the following steps.
Step 1: Make necessary measurements.
Step 2: Check whether there is a cell that satisfies the reference value H> = 0.
Step 3: Identify the highest HCS_PRIO value from the cells identified in Step 2.
Step 4: Identify the cell having the HCS_PRIO identified in Step 3.
Step 5: Identify cells satisfying the S reference value from among the cells identified in Step 4.
Step 6: Ranking is performed on the cells identified in Step 5.

  In general, the procedure can be performed when the cell with the highest HCS_PRIO and H> = 0 satisfies the S criterion. However, if the cell with the highest HCS_PRIO and H> = 0 does not meet the S criterion, the UE cannot select any cell.

  Examples and features of the cells (A, B, C) are as follows.

前記ステップを適用した結果は次の通りである。
ステップ１：必要な測定を行う。
セルＡ、セルＢ、及びセルＣを測定する。
ステップ２：基準値Ｈ＞＝０を満たすセルがあるか否かを確認する。
セルＡ及びセルＣがＨ基準値を満たす。
ステップ３：ステップ２で確認されたセルの中から最も高いＨＣＳ＿ＰＲＩＯを識別する。
セルＡ及びセルＣのうち、セルＡが最も高いＨＣＳ＿ＰＲＩＯである４を有する。
ステップ４：ステップ３で識別されたＨＣＳ＿ＰＲＩＯを有するセルを識別する。
セルＡが最も高いＨＣＳ＿ＰＲＩＯを有する唯一のセルである。
ステップ５：ステップ４で識別されたセルの中からＳ基準値を満たすセルを確認する。
セルＡがＳ基準値を満たさない。
ステップ６：ステップ５で識別されたセルに対してランキングを行う。
ランキングのための対象セルがない。

The result of applying the above steps is as follows.
Step 1: Make necessary measurements.
Cell A, cell B, and cell C are measured.
Step 2: Check whether there is a cell that satisfies the reference value H> = 0.
Cell A and cell C satisfy the H reference value.
Step 3: Identify the highest HCS_PRIO among the cells confirmed in Step 2.
Among cells A and C, cell A has 4 which is the highest HCS_PRIO.
Step 4: Identify the cell having the HCS_PRIO identified in Step 3.
Cell A is the only cell with the highest HCS_PRIO.
Step 5: Confirm cells satisfying the S reference value from among the cells identified in Step 4.
Cell A does not meet the S criterion.
Step 6: Ranking is performed on the cells identified in Step 5.
There is no target cell for ranking.

  That is, in the scenario, there are cells that satisfy the S reference value, but there are no cells in the ranking list. Therefore, there arises a problem that the UE cannot reselect the highest quality cell.

  The prior art is generally described on the assumption that there is always a cell to rank, and there is no specific mention about the case where there is no cell to rank. Therefore, the operation of the UE after step 6 in the scenario is not clear. Therefore, it results in UE behavior that is not unified. The following interpretation is possible.

  Option 1: As a result of Step 6, after recognizing that there is no cell to be ranked, the UE judges “no network”. Eventually, the UE makes an initial cell selection resulting in long interruption times.

  Option 2: The UE does nothing. That is, since there is no cell to rank, camping continues to the current serving cell. However, this is problematic because the serving cell is usually considered to be included in the target cell for the ranking process. If the serving cell does not meet the S criterion, the UE continues to camp on a non-highest cell.

  As one method of solving this, when selecting a target cell for ranking, the UE considers all of the H reference value and the S reference value. In this way, it is possible to effectively prevent a situation in which there are no target cells for ranking even though there are cells that satisfy the S reference value.

Details # 2
Interpretation A
Due to the foregoing, a possible first realization is that the UE first checks the H reference value and then the S reference value.
In this implementation, if the UE has low mobility and there is a cell that satisfies H> = 0, the UE performs the following steps.
Step 1: Make necessary measurements.
Step 2: Check whether there is a cell that satisfies the reference value H> = 0.
Step 3: Identify the highest HCS_PRIO among the cells confirmed in Step 2.
Step 4: Identify the cell having the HCS_PRIO identified in Step 3.
Step 5: Identify cells satisfying the S reference value from among the cells identified in Step 4.
Step 6: Ranking is performed on the cells identified in Step 5.

Interpretation B
Another possible realization is that the UE first checks the S reference value and then the H reference value.
In this implementation, if the UE has low mobility and there is a cell that satisfies H> = 0, the UE performs the following steps.
Step 1: Make necessary measurements.
Step 2: Check whether there is a cell that satisfies the S reference value.
Step 3: Check whether there is a cell that satisfies the reference value H> = 0 among the cells confirmed in Step 2.
Step 4: Identify the highest HCS_PRIO among the cells confirmed in Step 3.
Step 5: Identify the cell having the HCS_PRIO identified in Step 4.
Step 6: Ranking is performed on the cells identified in Step 5.
Hereinafter, the operation of the UE according to the interpretation A and the interpretation B will be analyzed. Consider the following scenario example:

解釈Ａによるセル再選択
前述の手順により次のステップが発生し得る。
ステップ１：必要な測定を行う。
セルＡ、セルＢ、及びセルＣを測定する。
ステップ２：基準値Ｈ＞＝０を満たすセルがあるか否かを確認する。
セルＡ及びセルＣがＨ基準値を満たす。
ステップ３：ステップ２で確認されたセルの中から最も高いＨＣＳ＿ＰＲＩＯを識別する。
セルＡ及びセルＣのうち、セルＡが最も高いＨＣＳ＿ＰＲＩＯである４を有する。
ステップ４：ステップ３で識別されたＨＣＳ＿ＰＲＩＯを有するセルを識別する。
セルＡが最も高いＨＣＳ＿ＰＲＩＯ値を有する唯一のセルである。
ステップ５：ステップ４で識別されたセルの中からＳ基準値を満たすセルを確認する。
セルＡがＳ基準値を満たさない。
ステップ６：ステップ５で識別されたセルに対してランキングを行う。
ランキングのための対象セルがない。
解釈Ｂによるセル再選択
前述の手順により次のステップが発生し得る。
ステップ１：必要な測定を行う。
セルＡ、セルＢ、及びセルＣを測定する。
ステップ２：基準値Ｓを満たすセルがあるか否かを確認する。
セルＢ及びセルＣがＳ基準値を満たす。
ステップ３：ステップ２で確認されたセルの中から基準値Ｈ＞＝０を満たすセルがあるか否かを確認する。
セルＢ及びセルＣのうち、セルＣがＨ基準値を満たす。
ステップ４：ステップ３で確認されたセルの中から最も高いＨＣＳ＿ＰＲＩＯを識別する。
セルＣが最も高いＨＣＳ＿ＰＲＩＯである３を有する。
ステップ５：ステップ４で識別されたＨＣＳ＿ＰＲＩＯを有するセルを識別する。
セルＣが最も高いＨＣＳ＿ＰＲＩＯを有する唯一のセルである。
ステップ６：ステップ５で識別されたセルに対してランキングを行う。
セルＣがランキングのための対象セルである。
異なる動作の修正
前記シナリオからＵＥがキャンプする対象セルがあることは明らかである。セルＣはＨ基準値及びＳ基準値を全て満たす。しかし、解釈Ｂではランキングするセルがあるのに対して、解釈Ａではランキングするセルがない。解釈Ａによる動作は、ＵＥが該当セルを再選択できないという問題がある。ＵＥは「ネットワークなし」と判断して全体の検索を行い、長い中断時間をもたらす。
実現Ａの主な問題は、最も高いＨＣＳ＿ＰＲＩＯ値を選択する際、Ｓ基準値を正しく考慮しないことである。（すなわち、Ｓ基準値を満たさないがＨ基準値は満たすセルは最も高いＨＣＳ＿ＰＲＩＯの決定過程に影響を及ぼす。）従って、従来技術の手順を修正して、Ｈ基準値関連ステップでＳ基準値も考慮すべきである。
提案１：Ｈ基準値関連過程でＳ基準値を満たすセルを考慮する。
前記内容は一般にランキングするセルが常にあるという前提で説明される。しかし、従来技術では、ランキングするセルがない場合については具体的な言及がない。よって、ランキングするセルがない場合、ＵＥの動作は明確でない。従って、統一されていないＵＥの動作をもたらす。

Cell Reselection by Interpretation A The following steps may occur according to the above procedure.
Step 1: Make necessary measurements.
Cell A, cell B, and cell C are measured.
Step 2: Check whether there is a cell that satisfies the reference value H> = 0.
Cell A and cell C satisfy the H reference value.
Step 3: Identify the highest HCS_PRIO among the cells confirmed in Step 2.
Among cells A and C, cell A has 4 which is the highest HCS_PRIO.
Step 4: Identify the cell having the HCS_PRIO identified in Step 3.
Cell A is the only cell with the highest HCS_PRIO value.
Step 5: Confirm cells satisfying the S reference value from among the cells identified in Step 4.
Cell A does not meet the S criterion.
Step 6: Ranking is performed on the cells identified in Step 5.
There is no target cell for ranking.
Cell Reselection by Interpretation B The following steps may occur with the above procedure.
Step 1: Make necessary measurements.
Cell A, cell B, and cell C are measured.
Step 2: Check whether there is a cell that satisfies the reference value S.
Cell B and cell C satisfy the S reference value.
Step 3: Check whether there is a cell satisfying the reference value H> = 0 among the cells confirmed in Step 2.
Among the cells B and C, the cell C satisfies the H reference value.
Step 4: Identify the highest HCS_PRIO among the cells confirmed in Step 3.
Cell C has 3 which is the highest HCS_PRIO.
Step 5: Identify the cell having the HCS_PRIO identified in Step 4.
Cell C is the only cell with the highest HCS_PRIO.
Step 6: Ranking is performed on the cells identified in Step 5.
Cell C is the target cell for ranking.
Modification of different behavior From the above scenario it is clear that there is a target cell for the UE to camp on. Cell C satisfies all H and S reference values. However, there are cells that rank in interpretation B, whereas there are no cells that rank in interpretation A. The operation according to the interpretation A has a problem that the UE cannot reselect the corresponding cell. The UE determines “no network” and performs an entire search, resulting in long interruption times.
The main problem of Realization A is that it does not correctly consider the S reference value when selecting the highest HCS_PRIO value. (That is, cells that do not meet the S reference value but do meet the H reference value will affect the process of determining the highest HCS_PRIO.) Therefore, the prior art procedure is modified so that the S reference value is also changed in the H reference value related step. Should be considered.
Proposal 1: Consider a cell that satisfies the S reference value in the H reference value related process.
The content is generally explained on the assumption that there are always cells to rank. However, in the prior art, there is no specific mention when there is no cell to rank. Therefore, when there is no cell to rank, UE operation is not clear. Therefore, it results in UE behavior that is not unified.

  Proposal 2: Propose to consider whether it is necessary to specify details about the case where there is no cell to rank.

  The simplest way to solve this is to have the UE consider all H and S reference values when selecting the target cell for ranking. In this way, it is possible to prevent a situation in which there are no target cells for ranking even though there are cells that satisfy the S reference value.

Cell Reselection Evaluation Process Cell reselection criteria below cell reselection criteria are used for intra-frequency cells, inter-frequency cells, and inter-RAT cells.
The quality level limit reference value H for the hierarchical cell structure is used when determining whether to apply the priority ranking based on the hierarchical cell reselection rule, and is defined as follows.

システム情報（ＳＩ）にＨＣＳが用いられないことが示される場合、品質レベル限界基準値Ｈは適用されない。
セルランキング基準値Ｒは次のように定義される。

When the system information (SI) indicates that HCS is not used, the quality level limit reference value H is not applied.
The cell ranking reference value R is defined as follows.

ここで、シグナリングされた値ＱｏｆｆｍｂｍｓはＭＢＭＳ ＰＬに属するセル（サービングセル又は隣接セル）にのみ適用され、次の通りである。

Here, the signaled value Qoffmbms is applied only to a cell (serving cell or neighboring cell) belonging to the MBMS PL and is as follows.

ＴＥＭＰ＿ＯＦＦＳＥＴｎは、ＰＥＮＡＬＴＹ＿ＴＩＭＥｎ期間に隣接セルに対してタイマーＴｎをスタートした後、Ｈ基準値及びＲ基準値にオフセットを適用する。

TEMP_OFFSETn applies an offset to the H reference value and the R reference value after starting the timer Tn for the neighboring cells during the PENALTY_TIMEn period.

TEMP_OFFSETn and PENALTY_TIMEn are applied only when the system information indicates that HCS is used.
Timer Tn is applied to each neighboring cell. Tn starts from 0 if one of the following conditions is true:
HCS_PRIOn <> HCS_PRIOS and Qmeas, n> = Qhcsn
Or
HCS_PRIOn = HCS_PRIOS, and for serving FDD cells and neighboring FDD cells, Qmeas, n> Qmeas, s + Qoffset1s, n when quality measurement for cell selection and reselection is set to CPICH RSCP in the serving cell
Qmeas, n> Qmeas, s + Qoffset2s, n when the quality measurement for cell selection and reselection is set to CPICH Ec / No in the serving cell for the serving FDD cell and neighboring FDD cells
Qmeas, n> Qmeas, s + Qoffset1s, n for all other serving cells and neighboring cells
The Tn for the associated neighboring cell stops as soon as any one of the above conditions is not met. Only valid when all value-related timers Tn calculated for TOn are running, otherwise TOn is set to zero.

  At the time of cell reselection, the timer Tn stops if the cell is not a neighbor cell of the new serving cell or if the criteria for starting the timer Tn are not met as parameters of the new serving cell. At the time of cell reselection, the timer Tn continues to operate for the corresponding cell, but if the corresponding cell is a neighbor cell of the new serving cell, the given criterion is evaluated with parameters broadcast to the new serving cell.

セル再選択パラメータはシステム情報でブロードキャストされて提供される。
セル再選択に用いられるセル選択基準値Ｓは以下の状況で満たされる。

The cell reselection parameter is broadcast and provided in the system information.
The cell selection reference value S used for cell reselection is satisfied in the following situation.

ここで、

here,

ＵＥのサービングセルでＨＣＳが用いられない場合、ＵＥがＳ基準値を満たすセルに対してランキングを行う対象は、
・測定された全てのセルである。
ＵＥのサービングセルでＨＣＳが用いられる場合、ＵＥがランキングを行う対象は、
１．移動性が低い場合は、
・基準値Ｓ及び基準値Ｈ＞＝０を満たすセルのうち、ＨＣＳ＿ＰＲＩＯが最も高い測定された全てのセルであり、
・基準値Ｓ及び基準値Ｈ＞＝０を全て満たすセルがなければ、ＨＣＳ優先順位を考慮しない測定された全てのセルである。

If HCS is not used in the serving cell of the UE, the target that UE ranks against the cell that satisfies the S reference value is
• All measured cells.
When HCS is used in the serving cell of the UE, the target that the UE ranks is
1. If mobility is low,
Among the cells satisfying the reference value S and the reference value H> = 0, all the measured cells with the highest HCS_PRIO are:
If there are no cells that satisfy all of the reference value S and the reference value H> = 0, then all the measured cells that do not take into account the HCS priority.

2. If mobility is high,
All measured cells, and of all the measured cells,
If there is a cell that satisfies all of the reference value S and the reference value H> = 0 and has a lower HCS priority than the serving cell,
All cells having the highest HCS_PRIO among the cells having the HCS priority lower than the serving cell and satisfying all of the reference value S and the reference value H> = 0.
·Otherwise,
If there is a cell that satisfies all of the reference value S and the reference value H> = 0 having the same or higher HCS priority as the serving cell,
Among all cells having the same or higher HCS priority as the serving cell, all cells having the lowest HCS_PRIO among the cells satisfying the reference value S and the reference value H> = 0,
·Otherwise,
All cells that satisfy the reference value S that do not consider the HCS priority level.

  The cells are ranked according to the aforementioned R reference value, but Qmeas, n and Qmeas, s are obtained, and CPICH RSCP, P-CCPCH RSCP, and average received signal are obtained for each of the FDD cell, TDD cell, and GSM cell. The R reference value is calculated using the level.

  The offset value Qoffset1s, n is used for Qoffsets, n to calculate Rn, and the hysteresis value Qhyst1s is used for Qhysts to calculate Rs. When the UE operates in the RRC connection mode state CELL_PCH or URA_PCH, when provided by the SIB4, the hysteresis value Qhysts calculates Rs with the Qhyst1s and PCH values. When the UE operates in the RRC connection mode state CELL_FACH, when provided by the SIB4, the hysteresis value Qhysts calculates Rs with Qhyst1s and FACH values.

  If the system information indicates that HCS is used, TEMP_OFFSET1n is used for TEMP_OFFSETn to calculate Ton. If the system information indicates that HCS is not used, TEMP_OFFSETn is not used when calculating Rn. The cell with the highest R value is the highest ranked cell.

  If a TDD cell or GSM cell is ranked as the highest cell, the UE performs cell reselection for that TDD cell or GSM cell.

  If the FDD cell is ranked as the highest cell and the quality measurement for cell selection and reselection is set to CPICH RSCP, the UE performs cell reselection for that FDD cell. If it is determined that this cell is not appropriate, the UE operates accordingly.

  If the FDD cell is ranked as the highest cell and the quality measurement for cell selection and reselection is set to CPICH Ec / No, the UE will determine the second for the FDD cell based on the aforementioned R reference value. Although ranking is performed, Qmeas, n and Qmeas, s are obtained using the measured amount CPICH Ec / No, and the R value of the FDD cell is calculated. The offset value Qoffset2s, n is used for Qoffsets, n to calculate Rn, and the hysteresis value Qhyst2s is used for Qhysts to calculate Rs. When the UE operates in the RRC connection mode state CELL_PCH or URA_PCH, when provided by the SIB4, the hysteresis value Qhysts calculates Rs by Qhyst2s and PCH. When the UE operates in the RRC connection mode state CELL_FACH, when provided by the SIB4, the hysteresis value Qhysts calculates Rs with Qhyst2s and FACH values. When the system information indicates that HCS is used, Ton is calculated using the TEMP_OFFSET2n value. If the system information indicates that HCS is not used, TEMP_OFFSETn is not applied when calculating Rn. After performing such second ranking, the UE performs cell reselection for the highest ranked FDD cell. If it is determined that this cell is not appropriate, the UE operates accordingly.

In all cases, the UE reselects a new cell only when the following conditions are met:
The new cell has a better ranking than the serving cell during the time interval Treselection. When the UE operates in the RRC connected mode state CELL_PCH or URA_PCH, the time interval Treselections, PCH applies when provided in the SIB4, and when the UE operates in the RRC connected mode state CELL_FACH, the time The section Treselections, FACH is applied. If no high mobility state is detected, all ranked cells are considered to have a better ranking than the serving cell if the serving cell is not ranked based on HCS rules in the hierarchical cell structure.

Further, the UE applies the following scaling rules to Treselections, Treselections _{, PCH} or Treselections _{, FACH} .
If no intra-frequency cell and high mobility state are detected,
・ Do not apply scaling.
If an intra-frequency cell and a high mobility state are detected,
If the system information is sent to the Treselections, Treselections _{, PCH} or Treselections _{, FACH} value, it is multiplied by IE “Speed dependent ScalingFactor_Reselection”.
If no inter-frequency cell and high mobility state are detected,
When the system information is sent to the Treselections, Treselections _{, PCH} or Treselections _{, FACH} value, it is multiplied by IE “Inter-Frequency ScalingFactor for Selection”.
If an inter-frequency cell and a high mobility state are detected,
• If sent in system information to Treselections, Treselections _{, PCH} or Treselections _{, FACH} values, IE “Speed dependent ScalingFactor for_Treselection”, and if sent in system information, IE “Inter-Frequency Correcting Multiply all “Teleselection”.
If inter-RAT cell and high mobility are not detected,
If the system information is sent to the Reselections, Reselections _{, PCH} or Reselections _{, FACH} value, it is multiplied by the IE “Inter-RAT ScalingFactor for_Reselection” value.
If inter-RAT cell and high mobility are detected,
If the system information is sent to the Treselections, Treselections _{, PCH} or Treselections _{, FACH} values, the IE “Speed dependent ScalingFactor for_Trection”, and if sent in the system information, the IE “Inter-RAT Sort Scoring Scale ] Are all multiplied.
If scaling is applied to Treselections or Treselections, PCH, the UE rounds the result value to the nearest second after performing all scaling. When scaling is applied to Treselections _{, FACH} , the UE rounds all the scaling and then rounds the result value to the nearest 0.2 seconds.
-If more than 1 second has elapsed since the UE camps on the current cell.

  As described above, various embodiments of the present invention relate to a cell selection method having a hierarchical cell structure based on cell quality, which enables more effective radio resources to be used.

  The present invention includes a step of confirming whether or not a hierarchical cell structure (HCS) is used, a step of reading a parameter relating to an H reference value from system information, a step of measuring a cell, and the measuring cell. Identifying a cell satisfying the S reference value, checking whether or not the cell satisfying the S reference value satisfies the H reference value, and a cell satisfying all of the S reference value and the H reference value Selecting a cell having the highest R reference value from among the cell selection methods for a user equipment (UE).

  The HCS defines overlapping cells of different sizes forming a plurality of cell hierarchies, and is used when the serving cell of the UE belongs to the HCS. The S reference value is a selection or qualification reference value used for confirming whether the reception quality of the target cell is sufficient, and the H reference value is an HCS reference used when the HCS is used. Value, which is a positive or negative value calculated based on information sent in the system information, and the R reference value is used by the UE to rank a list of cells that satisfy the S reference value Ranking reference value. After determining the measured cell by performing a signal measurement procedure with a base station in all frequency bands that can be searched, the cell having the strongest signal characteristic value is selected from the cells satisfying a specific cell selection condition, and the selected cell is selected. Access to the selected cell.

  In addition, when a hierarchical cell structure (HCS) is used in a serving cell of a user equipment (UE), the present invention is the most among cells that satisfy the reference value S and the reference value H ≧ 0 when the mobility of the UE is low. Perform a ranking procedure for all measured cells with high HCS priority and if there is no cell that satisfies the reference value S and the reference value H ≧ 0, all measured cells will be considered regardless of the HCS priority. Performing a ranking procedure for the UE, and performing a ranking procedure for all measured cells when the UE has high mobility, and the reference value S and the reference value of the measured cells. If there is a cell that satisfies the value H ≧ 0 and has an HCS priority lower than that of the serving cell, among the cells having an HCS priority lower than that of the serving cell, the reference value S and the reference value H ≧ The ranking procedure is performed for all cells having the highest HCS priority among the cells satisfying, otherwise, the HCS satisfying the reference value S and the reference value H ≧ 0 and equal to or higher than the serving cell If there is a cell having a priority, among the cells having the same or higher HCS priority as the serving cell, all cells having the lowest HCS priority among the cells satisfying the reference value S and the reference value H ≧ 0. Performing a ranking procedure for the user equipment (UE), and otherwise performing the ranking procedure regardless of the HCS priority.

  The hierarchical cell structure (HCS) defines overlapping cells of different sizes that form a plurality of cell hierarchies. It is determined whether the mobility of the user equipment is low or high based on the number of cell reselections in a specific period or based on RRC signaling from the network. After determining the measured cell by performing a signal measurement procedure with a base station in all frequency bands that can be searched, the cell having the strongest signal characteristic value is selected from the cells satisfying a specific cell selection condition, and the selected cell is selected. Access to the selected cell. For the signal measurement procedure, at least one of CPICH RSCP, CPICH Ec / No, and Carrier RSSI is used.

  In the ranking procedure, when selecting a target cell for the ranking, the ranking indicating the relative signal strength of the measured cell or the range superposition degree between the cells is considered in consideration of all the H reference value and the S reference value. obtain. The ranking procedure is performed based on the R reference value, and cell selection or reselection is performed on one or more cells ranked as having the highest quality. The HCS priority defines in which cell hierarchy of the HCS the UE should be present. The HCS priority is transmitted as part of the cell broadcast information in the form of a system information block, or alternatively, for neighboring cells, the HCS priority is as part of the RRC measurement control message. Is transmitted. The S reference value is a selection or qualification reference value used for confirming whether the reception quality of the target cell is sufficient, and the H reference value is an HCS reference used when the HCS is used. The value is a positive or negative value calculated based on the information sent in the system information and the measurement from the CPICH / P-CPCCH of the target cell.

  Various features and concepts described herein may be implemented by software, hardware, or a combination thereof. For example, a computer program (executed by a computer, terminal, or network device) for a method and system for processing a cell selection method of a hierarchical cell structure based on cell quality is one or more of performing various functions. You may comprise with the above program code part. A software tool (executed by a computer, terminal, or network device) for processing a cell selection method of a hierarchical cell structure based on cell quality is a program code portion that performs various functions. It may be configured.

  The method and system for processing the cell selection method of hierarchical cell structure based on cell quality according to the present invention is compatible with various technologies and standards. Some features described herein relate to various standards such as GSM, 3GPP, LTE, IEEE, 4G. However, it is not limited to these exemplary standards, and other related standards and techniques can be applied to the various features and concepts described herein.

  Various features and concepts described herein are different types of user devices (eg, mobile terminals, handsets, wireless communication devices) that can be configured to support a cell selection method of hierarchical cell structure based on cell quality. And / or can be applied and implemented in network entities.

  The various concepts and features described in this specification can be implemented in various forms without departing from the characteristics thereof, and the embodiments of the present invention are limited by the detailed contents of the above-described detailed description of the invention. It should be understood that this should not be construed as broadly defined within the scope of the appended claims, unless otherwise specified. Accordingly, all modifications and variations made within the scope of the present invention, or equivalents thereof, are included in the scope of the appended claims.

Claims (13)

A method of cell selection for a user equipment (UE) comprising:
The method
And determining whether hierarchical cell structure (HCS) is used,
And reading the parameter related to the reference value H from the system information,
And measuring the cell,
And that identifies the cells that fulfill the criterion S among the measured cell,
Ascertaining the reference value H for the cell that meets the reference value S,
See containing and selecting a cell having the highest reference value R from the cells that satisfy all of the reference value S and the reference value H,
The reference value S is a selection or qualification reference value used to confirm whether the reception quality of a candidate cell is sufficient, and the reference value H is an HCS reference used when the HCS is used. A value calculated based on information sent in the system information, wherein the reference value R is a ranking reference value used by the UE to rank a list of cells that satisfy the reference value S Is that way. The HCS defines the size of overlapping cells having different forms a plurality of cells hierarchy, serving cell the UE is used belongs to the HCS, The method of claim 1. After determining the measured cell by performing a signal measurement procedure with a base station in all frequency bands that can be searched, the cell having the strongest signal characteristic value is selected from the cells satisfying a specific cell selection condition, and the selected cell is selected. The method of claim 1 , wherein access is made to a cell. A method of cell selection for a user equipment (UE) comprising:
The method
When a hierarchical cell structure (HCS) is used in the serving cell of the UE ,
Wherein the low mobility UE, performs a ranking procedure for all cells measured with a highest HCS priority among those cells that fulfill the criterion value H ≧ 0 in the following satisfy the standard value S, the reference if any cell that fulfills the criterion value H ≧ 0 in the following satisfy the values S, regardless of HCS priorities, and to perform the ranking procedure for all measured cells,
A high mobility of the UE, the method comprising: for all measured cells performing the ranking procedure of the measured cell, wherein the reference value H ≧ the next meet the reference value S 0 the filled, and if there is a cell having a lower HCS priority than the serving cell, among the cells having a lower HCS priority than the serving cell, among the cells that satisfy the reference value H ≧ 0 the next meet the reference value S in it performs the ranking procedure for all cells having the highest HCS priority, otherwise, meets the reference value H ≧ 0 the next meet the reference value S, and the same or higher HCS and the serving cell if there is a cell having a priority among the cells having the same or higher HCS priority and the serving cell, the reference value H ≧ the next meet the reference value S 0 It performs the ranking procedure for all cells having the lowest HCS priority among those cells that fulfill, otherwise, including and performing the ranking procedure for all cells regardless of HCS priorities Mu, how. The hierarchical cell structure (HCS) defines a cell overlapping different sizes to form a plurality of cells hierarchy The method of claim 4. Based on the cell reselection number for a specific period, or based on RRC signaling from the network, the low or high mobility UE or not is determined, The method of claim 4. After determining the measured cell by performing a signal measurement procedure with a base station in all frequency bands that can be searched, the cell having the strongest signal characteristic value is selected from the cells satisfying a specific cell selection condition, and the selected cell is selected. The method of claim 4 , wherein access is made to a cell. Wherein the signal measurement procedures, CPICH RSCP, CPICH Ec / No , and at least one of Carrier RSSI is used, the method of claim 7. When selecting candidate cells for ranking according to the ranking procedure, the ranking indicating the relative signal strength of the measured cells or the range superposition degree between cells in consideration of all of the reference value H and the reference value S. the obtained a method according to claim 4. The ranking procedure is performed based on the R criterion values, cell selection or reselection is performed on one or more of the cells that are ranked as having the highest quality The method of claim 9. The HCS priority, the UE defines whether to present in the cell layer of the HCS throat The method of claim 4. The HCS priority is transmitted as part of cell broadcast information in the form of system information blocks, The method of claim 11. The reference value S is a selection or qualification reference value used to confirm whether the reception quality of a candidate cell is sufficient, and the reference value H is an HCS reference used when the HCS is used. 5. The method of claim 4 , wherein the value is a positive or negative value calculated based on information sent in system information and measurements from CPICH / P-CPCCH of the candidate cell.

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