KR100517981B1 - Access probe apparatus using location and method thereof - Google Patents

Abstract

The present invention relates to an apparatus and method for access probes using distance information. In the case of determining a communication power with a base station through an access probe (AP), when attempting to connect with a base station using a fixed initial AP power and failing, Since the proper communication power is determined by repeating the step of attempting to reconnect with the base station using the AP power increased by the predetermined staff power, the longer the distance between the base station and the terminal, the longer the base station access time and the more power is wasted. An APM receiver for receiving an access parameter message (APM) from the base station; An APM processing unit for acquiring an initial access probe (AP) power, a step size, and the number of access probes (APs) from the APM received from the APM receiving unit; A GPS unit for obtaining location information of the terminal location; An SCM receiving unit for obtaining location information of a base station from a synchronization channel message (SCM); A distance calculator configured to obtain a distance between a base station and a terminal from the position information acquired by the GPS unit and the SCM receiver; An AP power determiner for re-determining the initial AP power, the step size, and the number of APs based on the results of the distance calculator and the APM processor; By providing an access probe device and a method using the distance information including the AP transmitter for transmitting the AP at the power selected by the output of the AP power determination unit to reduce the time to attempt to access the base station when the distance between the base station and the terminal is far Therefore, there is an effect to reduce the wasted power.

Description

Access probe apparatus and method using distance information {ACCESS PROBE APPARATUS USING LOCATION AND METHOD THEREOF}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus and method for access probes using distance information, and more particularly, to an access probe based on distance information between a mobile terminal and a base station in a mobile terminal having a built-in Global Positioning System (GPS) function. The present invention relates to an access probe apparatus and method using distance information, which determines an initial power of an AP), and is suitable for reducing connection time and power consumption between a mobile terminal and a base station.

The portable terminal communicates with the base station and registers itself with the base station. In this case, a process of determining an appropriate signal strength for communicating with the base station is called an AP process.

In the case of a code division multiple access (CDMA) portable terminal, when the power for communicating with the base station is large, it interferes with signals of other adjacent portable terminals, thereby increasing the noise level in the adjacent terminals. Therefore, the CDMA portable terminal is adapted to communicate with the base station at an appropriate signal strength. This also serves to prevent excessive power consumption of the terminal.

When the mobile terminal and the base station are adjacent to each other, even if a small power is used, smooth communication is possible, but as the distance from the base station increases, the communication must be performed using a relatively high power.

Therefore, when a mobile terminal attempts to connect with a base station, the mobile terminal should attempt to connect using low power, and if it fails, use a larger power to gradually increase power and attempt to connect.

That is, when the distance between the base station and the terminal is far, the access time increases and the power consumption for determining the appropriate power increases.

1 illustrates a configuration of a conventional AP device and illustrates components of a terminal side.

As shown, power is obtained using an access parameter message (APM) receiving unit 10 for receiving message power from a base station and a power value set in a message obtained from the APM receiving unit 10. The APM processing unit 20 for determining a, and the AP transmission unit 30 for transmitting a message at a corresponding power in accordance with the power value determined by the APM processing unit 20.

The APM receiving unit 10 receives an APM transmitted from a base station. The APM includes information such as initial AP power, power step size for increasing power, and the total number of steps.

The APM processing unit 20 defines an initial AP power value, a power size to be increased when an access attempt fails, and the maximum number of APs that can be transmitted from the received APM.

The AP transmitter 30 substantially transmits the AP to the base station using the determined parameter values of the AP.

FIG. 2 is a graph listing AP power changes in chronological order when using a conventional AP process and successfully accessing a base station at maximum AP power.

For example, if the number of APs from the initial power to the maximum power is 9, the conventional method attempts to access the base station using a fixed initial AP power regardless of the position of the base station, and if the attempt fails, the illustrated method is shown. As described above, an attempt is made to access a base station with a new AP power increased by a predetermined staff power. After repeating this method nine times, it is possible to connect with the base station at maximum AP power.

In this case, the total consumption time is the time of repeating the AP ten times, resulting in wasting power performed up to nine times.

Accordingly, there is a need for an AP system and method for determining power to communicate with a base station at a faster time and reducing unnecessary waste of power.

As described above, the determination of the communication power with the base station through the conventional access probe (AP) attempts to access the base station using a fixed initial AP power, and in case of failure, uses the AP power increased by a predetermined staff power. Since the proper communication power is determined by repeating the step of attempting to reconnect with the base station, the longer the distance between the base station and the terminal, the longer the delay time and the wasted power increases.

In view of the above-described problems, the present invention uses a GPS for obtaining location information of a mobile terminal and an SCM receiving unit for obtaining base station location information included in a sync channel message (hereinafter referred to as SCM). It is an object of the present invention to provide an access probe apparatus and method using distance information that calculates distance and determines initial AP power by using the same, thereby reducing time for connecting with a base station and reducing wasted power.

An apparatus of the present invention for achieving the above object comprises an APM receiving unit for receiving an access parameter message (APM) from the base station; An APM processing unit for acquiring an initial access probe (AP) power, a step size, and the number of access probes (APs) from the APM received from the APM receiving unit; A GPS unit for obtaining location information of the terminal location; An SCM receiving unit for obtaining location information of a base station from a synchronization channel message (SCM); A distance calculator configured to obtain a distance between a base station and a terminal from the position information acquired by the GPS unit and the SCM receiver; An AP power determiner for re-determining the initial AP power, the step size, and the number of APs based on the results of the distance calculator and the APM processor; And an AP transmitter for transmitting the AP with the selected power according to the output of the AP power determination unit.

In addition, the method of the present invention comprises the steps of measuring the terminal distance using the GPS function and transmitting it to the distance calculator; Receiving an access parameter message (APM) to obtain an initial access probe (AP) power, a step size, and an access pro- cess number (AP); Receiving a synchronization channel message (SCM) to obtain a base station location and delivering it to a distance calculator; Re-determining the initial AP power, the step size, and the number of APs by comparing the distance calculator output with the values obtained by receiving the APM; Starting the AP transmission with the newly obtained initial AP power, and repeatedly attempting to connect with the base station while increasing the AP power until it is connected to the base station or does not exceed the determined number of APs.

The new initial AP power has a lower value than the required power estimated from the calculated distance.

Embodiments of the access probe apparatus and method using the present invention as described above will be described in detail with reference to the accompanying drawings.

3 is a block diagram of an embodiment of the present invention, there are newly added functional parts as shown. However, it should be noted that as the function of the portable terminal is expanded, the GPS unit 40, the synchronization channel message (SCM) receiving unit 50, and the distance calculating unit 60 are already applied functional units.

That is, the GPS unit 40, the SCM receiver 50, and the distance calculator 60 need not be newly configured to carry out the present invention, but use the functional units already used to suit the purpose of the present invention.

Therefore, it should be noted that the functional unit used only in the present invention among the illustrated components is only the AP power determination unit 70. Since this is a function that can be implemented in software, hardware additions or changes are not essential for the application of the present invention. It is a great advantage to be able to implement the advantages of the present invention with simple software additions or changes.

Now, the method of implementing the present invention through the above configuration will be described.

First, since the GPS unit 40 is used for the purpose of acquiring the position of the terminal, the position of the terminal can be known by using the GPS unit 40.

In addition, the SCM receiving unit 50 may determine the location of the base station using the base station location information (latitude / longitude) included in the SCM.

The distance calculator 60 may calculate the distance between the base station and the terminal using the output values of the GPS unit 40 and the SCM receiver 50.

As described above, the APM processing unit 20 obtains the initial AP power, the step value of the AP power to be increased when the base station access fails, and the total AP count information from the APM obtained from the APM receiving unit 10.

The AP power determination unit 70 receives the initial AP power, the step value of the AP power to increase when the base station access failure from the APM processing unit 20, the total AP number information, and receives the base station from the distance calculator 60 Receiving the distance between the terminal and the terminal determines the new initial AP power value in consideration of the distance between the base station and the terminal, thereby changing the total number of AP information.

For example, if the initial AP power is 100, the AP power step value is 10, and the total number of APs is 10, the maximum AP power is 190. However, if the distance between the base station and the terminal is far and the measured value at design time is about 180 from the current distance, the AP power determination unit sets about 170 as the initial AP power. The reason why the initial AP power value is smaller than the expected value is because the output power of the terminal should be lowered as much as possible. When the new initial AP power is determined, the total number of available APs is newly determined three times so that the maximum AP power value does not exceed 190.

If the AP is successful in connection with the base station when the power is 190, in the present invention, the access can be successful by repeating the AP four times. Therefore, the time for attempting the AP seven times from 100 to 160 and the power consumed at that time are saved. You can do it.

4 is a flowchart illustrating an embodiment of the present invention, comprising: measuring a terminal distance by using a GPS function and transmitting it to a distance calculator; Receiving an APM to obtain initial AP power, staff size, and number of APs; Receiving the SCM, obtaining a location of a base station, and transferring the received location information to a distance calculator; Determining an initial AP power, step size, and number of access probes by comparing the output of the distance calculator with the values obtained by receiving the APM; Attempting to access an AP by transmitting an AP with the newly obtained initial AP power; Terminating the AP process after the connection if the connection with the base station is successful in the step; Increasing AP power by a predetermined step size and determining whether the increased AP power exceeds a maximum value when the connection with the base station is not successful in the step; In this step, if the AP power exceeds the maximum value, the connection with the base station is considered to have failed, and if the AP power is less than or equal to the maximum value, the step of attempting to access the base station again with the corresponding power.

In more detail, it is as follows.

First, the terminal distance is measured using the GPS function and transmitted to the distance calculator. Since the GPS function is a function recently added to the terminal, the absolute position of the terminal may be measured using the same.

In addition, the APM processor receives the initial AP power, staff size, and the number of APs by receiving the APM. This is the same as the conventional AP process. Through this, the initial AP power, the step size, and the number of APs to be used can be obtained when the distance between the base station and the terminal is close. Even if the present invention is used, the step size does not change.

Then, the position of the base station is obtained to calculate the distance between the terminal and the base station. Since the base station position is included as an absolute position (latitude / longitude) in the sync channel message (SCM), it is extracted and used. Since the base station position can also be obtained from a functional unit (SCM receiving unit) used in a terminal including a GPS function, the present invention uses the existing function as it is.

The distance calculator estimates the distance between the base station and the terminal using the base station position through the SCM and the terminal position through the GPS.

Then, the distance between the base station and the terminal determines whether the distance between the base station and the terminal can use a fixed initial AP power value, the relationship between the distance and the AP power value is determined at design time to determine the equation or table It must be stored in the form. If the distance between the base station and the terminal is close by using the relationship between the distance and the AP power, the initial AP power specified in the APM is used as it is. If the distance between the base station and the terminal is relatively large, the effective AP power value is calculated accordingly. Reset to value Of course, it has already been mentioned that the power value lower than the expected effective AP power value can be used as the initial AP power value in order to minimize the transmitted power value.

When the initial AP power value is newly determined as described above, the number of repeatable APs is recalculated accordingly.

The AP is transmitted by the newly obtained initial AP power and attempts to access the base station. If the connection is successful, the AP process is used as communication power and the AP process is terminated.

However, if the current AP power is not connected to the base station, the AP power is increased by a predetermined step value, and it is checked whether the current AP power value exceeds the maximum value. If the value is less than the maximum value, the access point is attempted again with the increased AP power value, and the process is repeated. If the maximum value is exceeded, the communication with the base station is abandoned and the user is notified. In this case, the terminal becomes incapable of communication.

FIG. 5 is a graph listing changes in AP power in chronological order when using the present invention AP process and successfully accessing a base station at maximum AP power.

In the present invention, if it is determined that the distance between the base station and the terminal is relatively far, the initial AP power is set high, so the number of attempts to access the base station is reduced, thereby reducing the total consumption time and power consumption.

As described above, the apparatus and method for access probe using the distance information of the present invention determine the initial AP power by calculating the distance from the terminal to the base station using the terminal location from the GPS embedded in the portable terminal and the base station location information included in the SCM. By doing so, when the distance between the base station and the terminal is far, there is an effect of reducing the time to attempt to access the base station, and wasted power.

1 is a block diagram of a conventional access probe apparatus.

Figure 2 is a graph showing the power consumption over time of a conventional access probe.

Figure 3 is a block diagram of an embodiment of the present invention.

Figure 4 is a flow chart of one embodiment of the present invention.

Figure 5 is a graph showing the power consumption over time of the access probe of the present invention.

* Description of the symbols for the main parts of the drawings *

10: APM receiver 20: APM processor

30: AP transmitter 40: GPS unit

50: SCM receiver 60: distance calculator

70: AP power determination unit

Claims (3)

An APM receiving unit for receiving an access parameter message (APM) from a base station; An APM processing unit for acquiring an initial access probe (AP) power, a step size, and the number of access probes (APs) from the APM received from the APM receiving unit; A GPS unit for obtaining location information of the terminal location; An SCM receiving unit for obtaining location information of a base station from a synchronization channel message (SCM); A distance calculator configured to obtain a distance between a base station and a terminal from the position information acquired by the GPS unit and the SCM receiver; An AP power determiner for re-determining the initial AP power, the step size, and the number of APs based on the results of the distance calculator and the APM processor; And an AP transmitter for transmitting the AP with the selected power according to the output of the AP power determination unit. Measuring a terminal distance using a GPS function and transferring the terminal distance to a distance calculator; Receiving an access parameter message (APM) to obtain an initial access probe (AP) power, a step size, and an access pro- cess number (AP); Receiving a synchronization channel message (SCM) to obtain a base station location and delivering it to a distance calculator;  Re-determining the initial AP power, the step size, and the number of APs by comparing the distance calculator output with the values obtained by receiving the APM; Starting the AP transmission with the newly obtained initial AP power, and repeatedly attempting to connect with the base station while increasing the AP power until the number of times of accessing the AP or the determined number of APs is not exceeded. Access probe method using. The method of claim 2, wherein the new initial AP power has a value lower than a required power estimated from the calculated distance.