KR100336033B1 - Method for controlling access of a mobile communication mobile station - Google Patents

Abstract

When a mobile communication terminal sends an access probe to access a network, the base station adds the number of times that other terminals have attempted to access the network to the access channel messages and informs the base station and transmits a persistent delay of the access parameter message. The present invention relates to a method for controlling access of a mobile communication terminal to control access attempts of other terminals in a cell by reflecting the persistent delay value. The base station calculates a PSIST value and transmits the PSIST value in an access parameter message to a terminal. Making a step; Receiving an access parameter message transmitted from the base station, and calculating a probability (P) value at which the terminal can access the base station using the PSIST value in the received message; Calculating a pseudo delay value according to the calculated P value; Transmitting the NUM_ACC ESS_ATTEMPT value to the base station according to the calculated pseudo delay value in an access message; The PSIST value is recalculated using the NUM_ACCESS_ATTEMPT value transmitted from the terminal, the PSIST value is changed, and then the access parameter message is transmitted to the terminal to control the access of the terminal.

Description

Method for controlling access of a mobile communication mobile station

The present invention relates to a mobile communication system. In particular, when a mobile communication terminal sends an access probe to access a network, the base station is added to the access channel messages by adding the number of times that other terminals attempt to access the network. The present invention relates to a method for controlling access of a mobile communication terminal to control access attempts of other terminals in a cell by informing the request and reflecting the same in a persistent delay value of an access parameter message.

In general, the process of establishing a call by the terminal in the mobile communication system is as shown in FIG. 1, the power-up (S101), terminal initialization state (S102), and terminal idle state (Sdle) of the terminal (S103). , The system access state (S104), the call state (S105) in that order. 1 is a diagram schematically illustrating a flow of a call processing process of a terminal in a general mobile communication system.

In the initial state of the terminal (S102), the base station is selected using pilot information provided from the base station, and the terminal is switched to the idle state (S103) by synchronizing time information with the base station using sync information.

Based on this, in the idle state (S103), the base station monitors the information provided by the base station to the paging channel to access the system, receives a paging message requiring a response, or connects to the system when an initial call request is required. It is switched to the state (S104). At this time, in the system access state (S104), the terminal attempts to access the system based on random access (Random Access), and receives an acknowledgment (Acknowledge) from the system to enter the call connection state (S105).

That is, when the terminal attempts to access the base station system in the coverage area, the originating message is transmitted by using the access channel. In this case, one access channel slot is transmitted for one outgoing message transmission. Will be used. The outgoing message includes terminal self information (terminal number, mode indicating whether the terminal is in CDMA dedicated mode or dual mode, class indicating whether it is PCS or cellular phone, etc.) and called number. To the system (base station) within a certain period of time for the outgoing message sent by the terminal through the access channel (determined by the sum of the Acc_Tmo (Acknowledgement Timeout) and the probe backoff in the access parameter message sent from the base station to the mobile station). Upon receipt of an acknowledgment from the system, the system connection attempt is terminated successfully.

However, if the terminal does not receive an acknowledgment from the base station within a certain time, it retransmits the outgoing message and waits for the acknowledgment. If it does not receive an acknowledgment again, it retries again. The number of retransmissions is defined (determined by Num_Step (the number of step) and MAX_Req_Seq (Maximum Number of Access Probe Sequence) in the access parameter message sent from the base station to the terminal). If the system fails to receive an acknowledgment from the system, the connection attempt of the system is terminated.

FIG. 2A illustrates a structure of an access template in a general mobile communication system, FIG. 2B illustrates a detailed structure of an access sub-template shown in FIG. 2A, and FIG. 2C illustrates details of an access probe sequence illustrated in FIG. 2B. FIG. 2D is a diagram illustrating a detailed structure of the access probe shown in FIG. 2C, and FIG. 3 is a diagram illustrating access parameter message information transmitted from a base station to a terminal in a general mobile communication system.

The terminal attempts to transmit to the access channel through a random access procedure using information on an access parameter message provided from the base station. The process of sending a message and receiving an acknowledgment of the message is called an Access Attempt, and an Access Template consists of one or more Access Sub-Attempts. It is shown in detail in 2a, 2b and 2c.

Each transmission in the access sub template is called an access probe. Each access probe is composed of an access channel preamble and an access channel massage capsule. Here, one access channel preamble and one access channel message capsule are referred to as one access channel slot. In this case, the access channel preamp is a 94 continuous zero signal used by the base station to acquire a terminal, and the access channel message capsule includes information necessary for access.

Since the access preamble of the terminal is composed of 94 zeros, the branch station checks the number of incoming zeros to find the access channel preamble. The verification method correlates the signals input to the base station in the branch station searcher with the Walsh Symbol Index 'O' to check whether a preamble composed of '0' is received.

The access subitem refers to access probe portions until an access probe handoff occurs or an acknowledgment for a message is received, as shown in FIG. 2B. The access subitems are divided into access probe sequences as shown in FIG. 2C. Each access probe sequence consists of 1 + NUM_ STEP access probes, which are units transmitted on the same access channel.

There are two types of messages transmitted through the access channel. First, they are divided into response massage and request massage. Both types of messages have an irregular backoff delay between 0 and 1 + BKOFF (Backoff), represented by RS for every access probe sequence. In the case of the request access probe sequence, an additional delay expressed as a PD (Persistent Delay) should be applied, which is an access template, an access overload class, and a pseudorandom test by ACCOLC. Determined by

In the above, ACCOLC represents the class of the terminal, which refers to the Arabic numerals indicated on the right side of the PSIST shown in FIG. 3, and if the Arabic numerals are 0-9, a commercial terminal, a 10, a test terminal, and 11 are emergency The terminal and the rest of the Arabic numerals are reserved.

The base station transmits the durability value for the overload class of the terminal as the PSIST value of the access parameter message, and the terminal performs the shadow random test in the access procedure access sequence using the terminal.

In order to perform the shadow random test, the terminal first generates a random number RP, 0 <RP <1. If the value is smaller than the value P generated using PSIST, the test passes and the transmission is performed in the access channel slot. If the test fails, the access probe sequence must delay transmission to at least the next slot.

The P value calculated using the PSIST has the same meaning as the probability that the terminal accesses the base station and may have a flow control function. That is, if the P value is '0', the terminal cannot connect to the base station. If the value is '1', the terminal can access the base station regardless of the calculated RP.

The PSIST value, which is a parameter that determines the P value that may affect the terminal connection attempt, may have a value between PSIST (0-9 grade) DLS RUDDN 0-63 for commercial terminals to refer to. The operator decides at random. At present, there is no guidance to change this value, and it is determined by the operator's experience. In this case, experienced operators change this value based on their own know-how, but in most cases, it is very rare to change the value initially set. Despite this, there is a problem that cannot be reflected. In addition, even when the operator changes this value according to the state of the network, there is another problem that the state of the network cannot be accurately reflected because it is determined by the operator's supervision.

Therefore, even though the user cannot connect, the user continuously tries to connect, causing another problem in which unnecessary power consumption of the terminal is consumed.

Therefore, the present invention has been made to solve the above-mentioned problems according to the prior art, the object of the present invention is that other terminals to the network when the mobile communication terminal sends an access probe (Access Probe) to connect to the network The mobile communication terminal controls the access attempts of other terminals in the cell by adding the number of attempts for access to the access channel messages to inform the base station and reflecting this in the persistent delay value of the access parameter message. It is to provide a connection control method of the.

A feature of the access control method of a mobile communication terminal according to the present invention for achieving the above object is a terminal access control method in a mobile communication system including a base station, wherein the base station calculates the PSIST value in the access parameter message Including and transmitting to the terminal; Receiving an access parameter message transmitted from the base station, and calculating a probability (P) value at which the terminal can access the base station using the PSIST value in the received message; Calculating a pseudo delay value according to the calculated P value; Transmitting a NUM_ACCESS_ATTEMPT value in an access message to a base station according to the calculated pseudo delay value; The PSIST value is recalculated using the NUM_ACCESS_ATTEMPT value transmitted from the terminal, the PSIST value is changed, and the access control message is transmitted to the terminal through an access parameter message.

1 is a view schematically illustrating a flow of a call processing process of a terminal in a general mobile communication system;

FIG. 2A illustrates a structure of an access template in a general mobile communication system, FIG. 2B illustrates a detailed structure of an access sub-template shown in FIG. 2A, and FIG. 2C illustrates details of an access probe sequence illustrated in FIG. 2B. Figure 2d is a view showing the structure, Figure 2d shows a detailed structure for the access probe shown in Figure 2c,

3 is a diagram illustrating access parameter message information transmitted from a base station to a terminal in a general mobile communication system;

4 is a flowchart illustrating an operation of a method for controlling access of a mobile communication terminal in a mobile communication system according to the present invention.

Hereinafter, a method for controlling access of a mobile communication terminal according to the present invention will be described in detail with reference to the accompanying drawings.

First, as shown in Figs. 2a to 2d, the terminal attempts an access template to request an initial call from the base station. This access item is composed of an access sub-item, which in turn is composed of access probe sequences.

In the case of Request Attempt, the backoff delay delays the start of the access probe sequence by the delay of the RS slot and the PD of the pseudo delay. At this time, the base station transmits a PSIST value for the persistent test, and the terminal calculates the P value using this value, and uses it as a parameter of the pseudo test with a randomly generated RS value at the end of the period. Will be. In this case, the P value calculated by the terminal may control the call flow of the terminals. When the P value is 1, the P value is the same as accessing without a PD. The smaller the P value is, the higher the probability that the PD becomes. In addition, when the P value is '0', the terminal cannot access the base station. Here, the PSIST is a parameter indicating the load state of the base station. Persistent Delay is a delay represented by a PD shown in FIG. 2B and is a delay generated by the P value calculation and a random number.

In the IS-95B system, the number of access probe sequences in one access sub-template is limited to MAX_REQ_SEQ, which is a maximum value of 15.

Therefore, a 'NUM ACCESS ATTEMPT', that is, a connection attempt field, is added to a common field of access channel messages to be transmitted to an access channel message capsule, and the number of attempted access probe sequences is transmitted. At this time, the base station receiving this value calculates the PSIST value using Equation 1 below and stores the PSIST value.

PSIST = (NUM ACCESS ATTEMPTS-1) ＊ 4

In this case, the PSIST has a value between 0 and 63, and the NUN ACESS ATTEMPT is a part added to an access message and indicates a number of successive access probe sequences in an access sub-template, and 1 and 4 are values. These parameters allow the PSIST value to be between 0 and 60.

Then, the changed value is transmitted to the terminal in the next access parameter message. This PSIST value reflects the number of times that another terminal attempts to access the base station in the cell that transmits the access parameter message. The PSIST value also indicates the load state of the network.

A method for controlling access of a mobile communication terminal according to the present invention corresponding to such an operation will be described step by step with reference to FIG. 4.

4 is a flowchart illustrating an operation of a method for controlling access of a mobile communication terminal in a mobile communication system according to the present invention.

First, the base station calculates a PSIST value by using Equation 1 and includes it in an access parameter message and transmits it to the terminal (S201).

After receiving this, the terminal calculates a P value using the PSIST value transmitted from the base station (S202), and then calculates a persistent delay value according to the calculated P value (S203).

Next, the base station access is controlled by itself according to the calculated Persistent Delay value, and after calculating the Persistent Delay value, the access attempt number (NUM_ACCESS_ATTEMPT value) is included in the access message and transmitted to the base station (S204).

Accordingly, the base station recalculates the PSIST value by using Equation 1 using the NUM_ACCESS_ATTEMPT value transmitted from the terminal, that is, changes the PSIST value and transmits the PSIST value to the terminal by including it in an access parameter message. S205).

As a result, when another terminal attempts to connect several times, the PSIST value increases, and the P value calculated as the PSIST value becomes a relatively small value among the values between '0' and '1', and thus the pseudo delay of the terminal. Persistent Delay becomes longer.

In the method for controlling access of a mobile communication terminal according to the present invention as described above, when a terminal sends an access probe to access a base station, the pseudo delay value is calculated based on the number of times that other terminals attempt to access the base station. This prevents the use of the pseudo delays of the terminals in the same meaning as the random number, and calculates the pseudo delay value reflecting the state of the base station by using the P value in the same meaning as the probability that the terminal can access the base station. It is possible to prevent attempts to connect to the base station while consuming power.

In addition, since the operator does not change the PSIST value arbitrarily, it is a value calculated by the actual base station accessibility of the terminal, there is an advantage that can prevent the operator's mistake.

Claims (3)

In the terminal access control method in a mobile communication system comprising a base station, Calculating, by the base station, a value indicating a network load state (PSIST value) and including the same in an access parameter message to a terminal; Receiving an access parameter message transmitted from the base station, and calculating a probability (P) value at which a terminal can access a base station using the PSIST value in the received message; Calculating a pseudo delay value according to the calculated P value; Transmitting the number of access attempts (NUM_ACCESS_ATTEMPT value) to the base station after calculating the pseudo delay value in an access message; The base station recalculates the PSIST value by using the number of access attempts (NUM_ACCESS_ATTEMPT value) transmitted from the terminal, changes the PSIST value, and transmits to the terminal through an access parameter message to control the access of the terminal. Access control method of a mobile communication terminal characterized in that. The method of claim 1, wherein the PSIST value is calculated by multiplying 4 by subtracting 1 from the NUM_ACCESS_ATTEMPT value transmitted from the terminal. The method of claim 1, wherein the P value has a value between 0 and 1, and when the terminal accesses a lot, the PSIST value increases, and when the PSIST value increases, the P value has a value close to 0, so that the pseudo delay value is increased. Connection control method of a mobile communication terminal, characterized in that it becomes long.