KR20090044319A - Mobile communication system and method of power controlling for access probe - Google Patents

Abstract

A mobile communication system and an access probe transmission power control method thereof are disclosed.

According to an aspect of the present invention, there is provided a method for controlling access probe transmission power of a mobile communication system, the method comprising: receiving, at a mobile communication terminal, location information of a base station and radius information of the service area from a base station in a service area; Checking, by the mobile communication terminal, its location information; Calculating, by the mobile communication terminal, a distance from the base station using location information of the base station, radius information of a service area, and its own location information; Setting an initial transmit power of an access probe for accessing the base station according to the calculated distance from the base station.

According to the present invention, by optimizing the initial transmission power of the access probe according to the distance between the base station and the mobile communication terminal, it is possible to shorten the connection time between the base station and the mobile communication terminal and to reduce wasted power.

Description

Mobile communication system and method of power controlling for access probe

The present invention relates to a mobile communication system and a method for controlling access probe transmission power thereof, and more particularly, to control power of an initial access probe according to a distance between a mobile communication terminal and a base station, thereby controlling a base station and a mobile communication terminal. The present invention relates to a mobile communication system and a method for controlling access probe transmission power thereof, which can reduce connection time and reduce wasted power.

The mobile communication terminal performs a system access procedure for accessing a wireless network to receive services such as call transmission and reception and data transmission. Accordingly, the mobile communication terminal transmits an access probe to the base station through an access channel, and the access probe consists of a message transmitted from the terminal to the base station for the call request.

The transmit power of the access probe is transmitted with the minimum power that can be connected to the base station to minimize the impact on the call capacity and quality. Here, the transmission power of the access probe is determined according to an access parameter transmitted by the base station through a paging channel and controlled in an open loop power control scheme.

The access parameters provided by the base station include initial connection parameter power (INIT_PWR), power step size (PWR_STEP) for power increase, total number of steps (NUM_STEP), and values for correcting power received from all mobile communication terminals at the base station ( NOM_PWR) and the like.

1 is a graph of transmission power of a conventional access probe. As shown in FIG. 1, if a response is not received from the base station after transmitting the access probe, the mobile communication terminal retransmits the access probe by gradually increasing the transmit power by the step power. As such, a series of access probes that transmit while increasing the power level is called an access probe sequence.

Here, the initial transmission power of the conventional access probe is calculated using the following Equation 1.

Access probe initial transmit power

= Average received power-offset_power + NOM_PWR + INIT_PWR

If a response is not received from the base station within a predetermined time after transmitting the access probe, the mobile communication terminal continuously increases the transmit power of the access probe by the power step size (PWR_STEP) and retransmits the access probe by NUM_STEP times. .

Equation 2 below is an equation for calculating the transmission power of the access probe performed at the nth time.

nth access probe transmit power

= Average received power offset_power + NOM_PWR + INIT_PWR + PWR_STEP * n

  + Loop power control correction

According to the above equation, if the base station does not receive a response even after transmitting the access probe NUM_STEP times, the mobile communication terminal retries the access probe sequence process again after a predetermined time.

However, in the conventional access probe transmission process, the initial transmission power is set so that all terminals are set based on the same connection parameter regardless of the distance between the base station and the terminal. Therefore, since the initial transmission power is not enough in the case of a terminal far from the base station, connection with the base station is possible only when the optimum transmission power is found by gradually increasing the transmission power through repeated transmission of the access probe.

Accordingly, the access time between the base station and the mobile communication terminal may be delayed, and power consumption of the mobile communication terminal increases due to repeated transmission of the access probe.

Accordingly, the problem to be solved by the present invention, by optimizing the initial transmission power of the access probe according to the distance between the base station and the mobile communication terminal, to improve the problem of delay time between the bilateral connection caused by the distance between the base station and the mobile communication terminal The present invention provides a mobile communication system and an access probe transmission power control method thereof, which can reduce power consumption of a mobile communication terminal.

The present invention to solve the above problems, the base station for providing its own location information to the mobile communication terminal in the service area; Mobile communication for receiving the location information of the base station and confirming its own location information to calculate the distance from the base station, and to set the initial transmission power of the access probe for accessing the base station based on the distance from the base station It provides a mobile communication system comprising a terminal.

Here, the base station may transmit a system parameter message including latitude and longitude information of the base station and radius information of the service area to the mobile communication terminal.

In addition, the base station transmits an access parameter message including the initial access parameter power (INIT_PWR) of the access probe, the power step size (PWR_STEP) for power increase, and the total number of steps (NUM_STEP) to the mobile communication terminal. It is possible.

The mobile communication terminal may include a global positioning system (GPS) device for identifying its own location information.

The mobile communication terminal divides the service area into a plurality of subcells according to the distance from the base station, and initially transmits power of an access probe for accessing the base station based on a radius of a subcell to which the mobile station belongs. It is possible to set.

On the other hand, in order to solve the above problems, the present invention includes the steps of receiving the location information of the base station and the radius information of the service area from the base station in the service area in the mobile communication terminal; Checking, by the mobile communication terminal, its location information; Calculating, by the mobile communication terminal, a distance from the base station using location information of the base station, radius information of a service area, and its own location information; And setting an initial transmission power of an access probe for accessing the base station according to the calculated distance from the base station.

Receiving the location information of the base station and the radius information of the service area from the base station in the service area in the mobile communication terminal,

Receiving a system parameter message from the base station, and checking latitude and longitude information of the base station included in the system parameter message and radius information of the service area attached to the system parameter message. A method of controlling access probe transmission power in a communication system.

Here, the checking of the location information by the mobile communication terminal may include checking the location information through a global positioning system (GPS) device embedded in the mobile communication terminal.

The calculating of the distance from the base station by using the location information of the base station and the radius information of the service area and the location information of the base station may include: the location information of the base station and the radius of the service area. Based on the information, dividing the service area into a plurality of subcells having different service radii around the base station; It may be possible to include the step of identifying the sub-cell to which the current one belongs among the sub-cells based on the own location information.

The setting of the transmission power of the access probe for accessing the base station according to the calculated distance from the base station may include setting an initial transmission power of the access probe according to the subcell to which the base station belongs. It is possible to include.

In addition, the step of dividing the service area into a plurality of subcells having different service radii around the base station based on the location information of the base station and the radius information of the service area may be performed by the base station. Receiving an access parameter message comprising a parameter power (INIT_PWR), a power step size (PWR_STEP) for power increase, and a total number of steps (NUM_STEP); And dividing the service area into a number of subcells corresponding to the total number of steps NUM_STEP.

On the other hand, setting the transmission power of the access probe for access to the base station according to the calculated distance to the base station, the access probe in units of the power step size (PWR_STEP) included in the access parameter message It is possible to sequentially increase the initial transmit power of the to set the initial transmit power in each sub-cell.

When the response to the access probe transmitted according to the initial transmission power is not received, the transmission power of the access probe is sequentially increased based on the power step size PWR_STEP to increase the access probe to the total step. Performing an access sequence for repeatedly transmitting the number NUM_STEP; If no response is received from the base station for the access sequence, it is possible to include repeating the access sequence.

In addition, the object of the present invention comprises the steps of receiving, at a mobile communication terminal, location information of the base station and radius information of the service area from a base station within a service area; Receiving an access parameter message including an initial access parameter power (INIT_PWR), a power step size (PWR_STEP) for power increase, and a total number of steps (NUM_STEP) from the base station; Dividing the service area into a plurality of subcells having different service radii around the base station by using the location information of the base station and radius information of the service area by the mobile communication terminal; Sequentially setting the initial transmit power of each of the subcells by sequentially increasing the initial transmit power of the access probe based on the power step size (PWR_STEP) included in the access parameter message; Determining, by the mobile communication terminal, its location information to determine a sub-cell to which it belongs; Setting an initial transmission power of an access probe for accessing the base station according to an initial transmission power of the access probe set to the subcell to which the cell belongs; It can also be solved by the control method.

According to the mobile communication system and the method for controlling the access probe transmission power thereof, the initial transmission power of the access probe is optimized according to the distance between the base station and the mobile communication terminal, thereby reducing the connection time between the base station and the mobile communication terminal and wasting power. Can be reduced.

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

However, embodiments of the present invention illustrated below may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. Embodiments of the invention are provided to more fully illustrate the invention to those skilled in the art.

2 is a configuration diagram of a mobile communication system according to the present invention, which illustrates a service zone division state according to a distance between a mobile communication terminal and a base station.

As shown in FIG. 2, the mobile communication system includes mobile communication terminals 10 and 20 and a base station 1 for providing a wireless communication service to each of the mobile communication terminals 10 and 20.

When the base station 1 detects that the mobile communication terminals 10 and 20 are turned on in the service area, information about the mobile communication terminals 10 and 20 through identification numbers of the corresponding mobile communication terminals 10 and 20. If necessary, the terminal may determine whether the terminal user is an allowed user by performing an authentication process. When sensing the mobile communication terminals 10 and 20 that are powered on, the base station 1 transmits a system parameter message so that the corresponding mobile communication terminals 10 and 20 can use the communication service.

Here, the system parameter message includes a base station number (ID) and latitude (BASE_LAT) / longitude (BASE_LONG) information of the base station 1, so that the mobile communication terminals 10 and 20 can determine the location of the base station 1. . In addition, the base station 1 can transmit by adding a cell area radius (CELL-RADIUS) field to the system parameter message for control according to the present invention.

The mobile communication terminals 10 and 20 receive a system parameter message from the base station 1 at power on, store the system parameter message in the terminal, and set up an internal system for communication with the base station 1. The mobile communication terminals 10 and 20 should receive system parameter messages from the new base station 1 again and update the stored information whenever the base station 1 changes due to the movement. Here, the mobile communication terminals 10 and 20 may recognize the location of the base station 1 through the latitude / longitude information of the base station 1 included in the system parameter message. In addition, when the base station 1 transmits cell area radius information together, the mobile communication terminals 10 and 20 can accurately recognize not only the location of the base station 1 but also the radius of the serving cell. In addition, the mobile communication terminals 10 and 20 use initial access parameter power (INIT_PWR), power step size (PWR_STEP) for power increase, and total number of steps through an access parameter provided by the base station 1. (NUM_STEP), the base station 1 obtains information such as a value NOM_PWR for correcting power received from all the mobile communication terminals 10 and 20.

Accordingly, the mobile communication terminals 10 and 20 divide the entire service cell area into sub cells (Zone1, Zone2, ... Zone N) according to the distance based on the base station 1 as shown in FIG. Each subcell is given a number (i). The number of subcells starts from 1 and can be increased by 1 from the subcell close to the base station 1 toward the outside, and the total number of subcells is equal to the number of power increasing steps (NUM_STEP) included in the access probe. It is preferable to set the same. Accordingly, FIG. 2 assumes the case where the number of power increase steps (NUM_STEP) is set to N, and all subcells are divided into N cells.

Equation 3 below is a formula for calculating the radius of each sub-cell region.

Radius of the subcell area i = (radius of the entire service cell / NUM_STEP) * i

Here, the number NUM_STEP of the power increase step is a value that can be reset during operation of the base station 1, so that whenever the value is changed and set, the mobile communication terminals 10 and 20 must reset the division of the subcells. .

In addition, the mobile communication terminal 10, 20 periodically checks its position. In order to check its own location, the mobile communication terminals 10 and 20 may use a GPS system, and may check the location information using a nearby sensor node or an RFID communication network having the location information. Accordingly, the mobile communication terminals 10 and 20 calculate the distance from the base station 1 using the location information of the base station 1 and its own location information, and calculate which sub-cell belongs to the calculated distance. Serve

The mobile communication terminals 10 and 20 set and transmit initial transmission power of the access probe according to the sub-cells to which they belong. That is, the initial transmission power of the access probe is set according to the distance from the base station 1, and as the distance from the base station 1 increases, the initial transmission power of the access probe increases, and the initial transmission power of each subcell is increased. The size is equal to the power step size PWR_STEP. For example, in the case of the mobile communication terminal 20 belonging to the sub cell 1 (Zone 1), the initial transmission power is set to the minimum value, and in the case of the mobile communication terminal belonging to the sub cell 2 (Zone 2), the power step size is smaller than the minimum transmission power. Set the access probe initial transmit power to a transmit power as large as (PWR_STEP). In the same principle, the mobile communication terminal belonging to the subcell 5 may set the initial transmission power of the access probe with a power step size (PWR_STEP) × 5 rather than the minimum transmission power. In the case of the terminal, the initial transmission power of the access probe is set to the maximum transmission power.

Accordingly, the initial transmission power of the access probe of the mobile communication terminal located in the subcell i may be calculated by Equation 4 below.

Initial transmission power of access probe of terminal belonging to subcell i

= Average received power offset_power + NOM_PWR + INIT-PWR + PWR_STEP * (i-1)

On the other hand, if a response is not received from the base station 1 after the access probe transmission, the mobile communication terminal continuously increases the power value of the access probe by the power step size PWR_STEP and retransmits it according to the power increase step number NUM_STEP. . Accordingly, the access probe retransmission power of the mobile communication terminal located in the subcell i may be calculated by Equation 5 below.

Nth access probe transmit power of terminal belonging to subcell i

= Average received power offset_power + NOM_PWR + INIT-PWR + PWR_STEP * {X + (i-1)}

  + Loop power control correction

(if X = n when if N <n + 2, X = N-i when N> = n + 2, N = number of subcells)

When retransmitting the access probe, the maximum transmit power of the mobile communication terminals 10 and 20 does not exceed the maximum transmit power according to the power step size PWR_STEP and the power increase step number NUM_STEP. If the base station 1 does not receive a response even after transmitting the access probe NUM_STEP times, the mobile communication terminals 10 and 20 retry the access probe sequence process again after a predetermined time.

3 is a flowchart illustrating a method for controlling initial access probe transmission power of a mobile communication terminal according to the present invention.

When the power of the mobile communication terminals 10 and 20 is turned on or the service cell is moved, the mobile communication terminals 10 and 20 obtain location information of the base station 1 (S10). When the base station 1 detects the mobile communication terminals 10 and 20 in the corresponding service cell, the base station 1 transmits a system parameter message so that the mobile communication terminals 10 and 20 can use the communication service. The system parameter message includes latitude (BASE_LAT) / longitude (BASE_LONG) information of the base station 1, and thus, the mobile communication terminals 10 and 20 can determine the location of the base station 1. In addition, the base station 1 can transmit by adding a cell area radius (CELL-RADIUS) field to the system parameter message for control according to the present invention.

The mobile communication terminals 10 and 20 divide the service cell area into subcells according to distances through an access parameter provided by the base station 1 (S12). The connection parameter includes information such as initial connection parameter power INIT_PWR, power step size PWR_STEP for power increase, total number of steps NUM_STEP, power correction value NOM_PWR, and the like. Accordingly, the mobile communication terminals 10 and 20 use the location information and cell area radius of the base station 1 acquired in step S10 and the total number of service cell areas using the total number of steps (NUM_STEP) provided through the access parameter. Subcells are divided by the total number of steps (NUM_STEP).

The mobile communication terminals 10 and 20 periodically check their positions (S14). Here, the mobile communication terminals 10 and 20 may check the current position using a GPS system, and may also check the position information using a nearby sensor node or RFID communication network having the position information. Do.

When the current positions of the mobile communication terminals 10 and 20 are confirmed, the mobile communication terminals 10 and 20 check which cell among the sub-cells separated in the step S12 (S16).

The mobile communication terminals 10 and 20, which have identified the subcell to which they belong, calculate the transmission power of the access probe in the corresponding subcell (S18). Accordingly, the access probe initial transmission powers of the mobile communication terminals 10 and 20 are set differently according to the distance from the base station 1.

The mobile communication terminals 10 and 20 transmit an access probe according to the calculated initial transmission power (S20), and receive a response signal from the base station 1 to check whether the connection is successful (S22).

If the response signal is not received from the base station 1, the access probe sequence procedure of repeatedly transmitting the access probe is performed by gradually increasing the transmission power. If this fails, the access probe sequence procedure is returned to step S18. Retry

When the response signal is received from the base station 1, the call proceeds as if the connection is successful (S24).

 With this configuration, the mobile communication terminals 10 and 20 can optimize the initial transmission power of the access probe according to the distance from the base station 1. Accordingly, it is possible to improve a connection time delay problem between the base stations 1 and the mobile communication terminals 10 and 20, and to prevent unnecessary access probe transmission repetition. Can reduce power consumption.

4 and 5 are graphs of the access probe transmission power of the mobile communication terminals 10 and 20 according to an embodiment of the present invention, respectively, in sub-cell 1 and sub-cell 3 of FIG. It is a graph of the access probe transmission power of the mobile communication terminal (10, 20) to belong. Here, a case in which four subcells Zone 1, Zone 2, Zone 3, and Zone 4 exist by setting the total number of steps NUM_STEP and N to 4 will be described.

4 is a graph illustrating an access probe transmission power of the mobile communication terminal 20 located in the sub cell 1 (Zone 1). Subcell 1 (Zone 1) is located at the closest distance to the base station 1, the mobile communication terminal 20 transmits the access probe at the lowest transmission power. In this case, when the response from the base station 1 is not received, the mobile communication terminal sequentially increases the transmission power by the power step size PWR_STEP and performs the access probe sequence of transmitting the access probe four times.

Meanwhile, FIG. 5 is a graph of access probe transmission power of the mobile communication terminal 10 located in the subcell 3 (Zone 3). The mobile communication terminal 10 located in the subcell 3 (Zone 3) performs an access probe sequence by setting the initial transmission power of the access probe to a value increased by a power step size (PWR_STEP) × 2. Here, the maximum access probe transmit power is limited to a value obtained by increasing the power step size PWR_STEP by the total number of steps NUM_STEP. Therefore, before performing the entire access probe sequence, the transmission power is set to the maximum value, so the remaining steps NUM_STEP repeatedly attempt to access the base station 1 by repeatedly transmitting the access probe at the maximum transmission power.

As described above, the present invention increases the initial transmission power of the access probe as the distance between the base station and the mobile communication terminal increases, thereby allowing a remote mobile communication terminal to quickly connect with the base station and accessing with insufficient transmission power. It is possible to prevent the pro part from being repeatedly transmitted unintentionally to reduce power consumption of the mobile communication terminal.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, the technical configuration of the present invention described above may be modified in other specific forms by those skilled in the art to which the present invention pertains without changing its technical spirit or essential features. It will be appreciated that it may be practiced. Therefore, the embodiments described above are to be understood as illustrative and not restrictive in all aspects. In addition, the scope of the present invention is shown by the claims below, rather than the above detailed description. Also, it is to be construed that all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts are included in the scope of the present invention.

1 is a graph of transmission power of a conventional access probe.

2 is a block diagram of a mobile communication system according to the present invention.

3 is a flowchart illustrating a method for controlling initial access probe transmission power of a mobile communication terminal according to the present invention.

4 is a graph illustrating access probe transmission power of a mobile communication terminal according to an embodiment of the present invention.

5 is a graph illustrating an access probe transmission power of a mobile communication terminal according to another embodiment of the present invention.

*** Explanation of symbols for the main parts of the drawing ***

10, 20: mobile communication terminal

Claims (16)

A base station providing its location information to a mobile communication terminal in a service area; Mobile communication for receiving the location information of the base station and confirming its own location information to calculate the distance from the base station, and to set the initial transmission power of the access probe for accessing the base station based on the distance from the base station A mobile communication system comprising a terminal. The method of claim 1, The base station, And a system parameter message including latitude and longitude information of the base station and radius information of the service area to the mobile communication terminal. The method of claim 1, The base station, And transmitting an access parameter message including the initial access parameter power (INIT_PWR) of the access probe, the power step size (PWR_STEP) for power increase, and the total number of steps (NUM_STEP) to the mobile communication terminal. system. The method of claim 1, The mobile communication terminal, And a global positioning system (GPS) device for confirming its own location information. The method of claim 1, The mobile communication terminal, The service area is divided into a plurality of subcells according to the distance from the base station, and the initial transmission power of the access probe for accessing the base station is set based on a radius of the subcell to which the base station belongs. Communication system. Receiving, by a mobile communication terminal, location information of the base station and radius information of the service area from a base station in a service area; Checking, by the mobile communication terminal, its location information; Calculating, by the mobile communication terminal, a distance from the base station using location information of the base station, radius information of a service area, and its own location information; And setting an initial transmission power of an access probe for accessing the base station according to the calculated distance from the base station. The method of claim 6, Receiving the location information of the base station and the radius information of the service area from the base station in the service area in the mobile communication terminal, Receiving a system parameter message from the base station, and checking latitude and longitude information of the base station included in the system parameter message and radius information of the service area attached to the system parameter message. A method of controlling access probe transmission power in a communication system. The method of claim 6, The step of checking the location information of the mobile communication terminal, And confirming the location information through a global positioning system (GPS) device embedded in the mobile communication terminal. The method of claim 6, Computing the distance with the base station by the mobile communication terminal using the location information of the base station and the radius information of the service area, and its own location information, Dividing the service area into a plurality of subcells having different service radii around the base station based on the location information of the base station and the radius information of the service area; And identifying a subcell to which the cell belongs, based on the location information of the subcell. The method of claim 9, The step of setting the transmission power of the access probe for the connection with the base station according to the calculated distance to the base station, And setting an initial transmit power of the access probe according to the subcell to which the cell belongs. The method of claim 9, Dividing the service area into a plurality of subcells having different service radii around the base station based on location information of the base station and radius information of the service area, Receiving an access parameter message including an initial access parameter power (INIT_PWR), a power step size (PWR_STEP) for power increase, and a total number of steps (NUM_STEP) transmitted by the base station; And dividing the service area into a number of subcells corresponding to the total number of steps (NUM_STEP). The method of claim 11, The step of setting the transmission power of the access probe for the connection with the base station according to the calculated distance to the base station, And sequentially setting the initial transmit power in each subcell by sequentially increasing the initial transmit power of the access probe based on the power step size PWR_STEP included in the access parameter message. A method of controlling access probe transmission power in a communication system. The method of claim 12, When a response to the access probe transmitted according to the initial transmission power is not received, the transmission power of the access probe is sequentially increased based on the power step size PWR_STEP to increase the number of steps of the access probe. Performing an access sequence for repeated transmission by NUM_STEP); And if a response is not received from the base station for the access sequence, repeating the access sequence. Receiving, by a mobile communication terminal, location information of the base station and radius information of the service area from a base station in a service area; Receiving an access parameter message including an initial access parameter power (INIT_PWR), a power step size (PWR_STEP) for power increase, and a total number of steps (NUM_STEP) from the base station; Dividing the service area into a plurality of subcells having different service radii around the base station by using the location information of the base station and radius information of the service area by the mobile communication terminal; Sequentially setting the initial transmit power of each of the subcells by sequentially increasing the initial transmit power of the access probe based on the power step size (PWR_STEP) included in the access parameter message; Determining, by the mobile communication terminal, its location information to determine a sub-cell to which it belongs; Setting an initial transmission power of an access probe for accessing the base station according to an initial transmission power of the access probe set to the subcell to which the cell belongs; Control method. The method of claim 14, The mobile terminal checks its location information and determines the sub-cell to which it belongs, And checking the location information of the mobile communication system through a global positioning system (GPS) device embedded in the mobile communication terminal. The method of claim 14, When a response to the access probe transmitted according to the initial transmission power is not received, the transmission power of the access probe is sequentially increased based on the power step size PWR_STEP to increase the number of steps of the access probe. Performing an access sequence for repeated transmission by NUM_STEP); And if a response is not received from the base station for the access sequence, repeating the access sequence.

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