KR100474889B1 - Method for transmitting overhead message - Google Patents

Abstract

The present invention relates to overhead message transmission, and more particularly, to an overhead message transmission method in which mobile stations in a slotted mode can efficiently receive an overhead message. In the overhead message transmission method as described above, when a plurality of overhead messages are transmitted from a base station to a mobile station using a plurality of slots at a predetermined time period, the plurality of overhead messages are distributed and transmitted at predetermined intervals in the plurality of slots. And a second step of distributing the next plurality of overhead messages to the next slot of each of the plurality of slots used in the first step if the set time period is repeated after the first step.

Description

Method for transmitting overhead message

TECHNICAL FIELD The present invention relates to an overhead message transmission method, and more particularly, to an overhead message transmission method in which mobile stations in a slotted mode are suitable for efficiently receiving an overhead message.

Code Division Multiple Access (CDMA) systems include mobile stations (MSs), base stations (BTSs), base station controllers (BSCs) and switching stations (or mobile switching centers) ( MSC: Mobile Switching Center) is a digital mobile communication technology that is being used.

Here, the mobile station responds to a call request and an incoming call, performs a call setup procedure in association with a base station, the base station allocates a channel necessary for call setup, performs call setup / release related control, and the base station controller performs voice A vocoder / selector that handles traffic such as / data, and interworking with the base station and the switching station, performs call setup / release control of the base station control station, and the mobile switching station registers / retrieves the mobile station, generates a paging message, Perform call establishment / release control.

In the CDMA scheme operated according to the IS-95 and J-STD-008 standards, the channel scheme between the base station and the mobile station has a different channel structure on the forward link from the base station to the mobile station and on the reverse link from the mobile station to the base station.

The forward link consists of a pilot channel, a synchronous channel, a paging channel, and a forward traffic channel. The reverse link consists of an access channel and a reverse traffic channel.

The pilot channel is a channel for finding the nearest base station and the adjacent base station by allowing the mobile station to select and synchronize the pilot signal having the greatest intensity among the pilot signals generated by each base station of the mobile communication network when accessing the mobile communication network. Since the mobile station has no information about the system, there is no data, and the mobile station synchronizes by transmitting only the short code of the base station spread to Walsh 0. At this time, since all base stations use the same short code, in order to distinguish each base station from each other, each base station varies a start time of a PN code, and the mobile station can distinguish base stations with this time difference.

The synchronization channel is a channel for transmitting various parameter information of each base station to a mobile station and includes a system identifier (ID), a network identifier (ID), and a pilot channel pseudo noise offset (PN offset) number.

The paging channel transmits a paging message for the terminating mobile station, transmits all control messages to be sent to the mobile station before the traffic channel is established, and delivers additional information, paging for a specific mobile station, channel assignment, etc. to the mobile station in the service area. .

The forward traffic channel is then used to convey voice or data and signal information from the base station to the mobile station.

The access channel is used to transmit all control messages that the mobile station will send to the base station before the traffic channel is established, such as outgoing and incoming response messages, and the mobile station attempts to talk to the base station or respond to messages received on the paging channel.

The reverse traffic channel is then used to transmit signal information including traffic frames and control messages such as voice or data from the mobile station to the base station.

Among them, the paging channel is a continuous channel, and its transmission rate is 4800bps and 9600bps, and the mobile stations are operated at one ratio designated by the base station.

Types of overhead messages include a system parameters message, an access parameters message, a code division multiple access channel list message, and a neighbor base station list message (band). pass 0 only: For Digital Cellular Network (DCN)), Extended Neighbor List Message (band pass 1 only: For Personal Cellular Communication (PCS)), Extended System Parameter Message ), There are Global Service Redirection Messages.

Hereinafter, a conventional overhead message transmission method will be described with reference to the accompanying drawings.

1 is a diagram illustrating a conventional overhead message transmission method.

When the mobile station is powered on, it is time-synchronized via a pilot channel and a synchronization channel broadcast from the base station and receives a valid paging channel message to prepare for entering a service mode or idle state. At this time, an overhead message is first received through a valid paging channel message, and information of various systems necessary for interworking with a currently connected base station is received through these overhead messages, and the mobile station enters a service mode through these information.

In the method for transmitting an overhead message in the base station, the base station uses a plurality of overhead messages O ₁ to O ₅ as shown in FIG. 1 using five slots out of 16 slots every 1.28 seconds through a paging channel. Send to the mobile station. The remaining slots are then used to transmit messages, such as incoming or short message service (SMS), to the mobile station.

According to the IS-95 and J-STD-008 standards, when transmitting overhead messages using 16 slots, it is not fixed how to distribute them to 16 slots. In other words, as shown in the figure, the overhead message is not transmitted using a specific slot among 16 slots but is randomly distributed to 16 slots along with other messages and transmitted every 1.28 seconds.

At this time, the paging channel divides the system time into small slots of 80 ms units with 2048 cycles. In order to reduce power consumption, the mobile station may use a slot mode in which a paging channel is monitored only for a specific slot and no operation is performed for the rest. .

Non Slotted mobile stations monitor all slots so they can receive all of their overhead messages no matter how distributed and transmitted within 1.28 seconds, but in idle slotted mode terminals. Monitors only one of the 16 slots. For example, only slot 7 can be monitored.

In the conventional overhead message transmission method, since the mobile station monitors only a specific slot when the mobile station is in the slotted mode, the mobile station in the slotted mode that monitors only a specific slot even when the base station transmits a new content overhead message through the paging channel is used. There was a problem that could not be monitored, especially when there are many incoming calls or other slotted messages, it is difficult for the mobile station to respond quickly to changes in the mobile communication system because these messages are more likely to prevent overhead messages from being transmitted from the base station. There was a problem.

SUMMARY OF THE INVENTION An object of the present invention has been made in view of the above-mentioned problems of the prior art, and when an overhead message is transmitted from a base station, 16 slots are regularly distributed and transmitted over a radio section, so that the slotted mode mobile station transmits the overhead message. It is an object of the present invention to provide an overhead message transmission method capable of quickly responding to a change in a mobile communication system by increasing a probability of receiving a.

According to a feature of the present invention for achieving the above object, when the base station transmits a plurality of overhead messages to the mobile station using a plurality of slots at a set time period, the plurality of overhead messages in the plurality of slots at a predetermined interval. The first step of transmitting the first message and the predetermined time period after the first step are repeated, and the overhead message distributed at the predetermined interval is distributed to the next slot of each of the plurality of slots used in the first step. This is done in a second step.

According to the present invention as described above, there is an advantage that the mobile station can quickly cope with changes in the mobile communication system.

Hereinafter, a configuration and an operation according to an exemplary embodiment of the present invention will be described with reference to the accompanying drawings.

2 is a diagram illustrating an overhead message transmission method according to the present invention.

The overhead message transmission method according to the present invention is for regularly dispersing and transmitting an overhead message transmitted randomly from a base station to a mobile station. When the mobile station is powered on, time synchronization is performed through a pilot channel and a synchronization channel broadcast from the base station. Set to enter the service mode or idle state by receiving a valid paging channel message. At this time, an overhead message is first received through a valid paging channel message, and information of various systems necessary for interworking with a currently connected base station is received through these overhead messages, and the mobile station enters a service mode through these information.

The base station regularly distributes a plurality of overhead messages O ₁ to O ₅ using five slots out of 16 slots every 1.28 seconds through the paging channel and transmits them to the mobile station.

In this case, if 1.28 seconds is divided into 16 slots, the flow of time can be expressed as an increase in the slot number, and the transmission of the overhead message has to be determined in which slot. The minimum period can be represented by MIN_SLOT_CYCLE.

When the overhead message transmission period is represented by Length, Length = MIN_SLOT_CYCLE + 1. In other words, if the overhead message is transmitted using slots 0, 3, 6, 9, and 12 in the first 1.28 seconds, the next overhead message is transmitted using slots 1, 4, 7, 10, and 13 in the next 1.28 seconds. .

The slot decision to send the overhead message is Modulo operation with the current slot as Length. The slot number is repeated from 0 to 15, and the transmission of the overhead message starts when this slot number is 0. To start.

Once the transmission is started and the system parameter message is transmitted, the next overhead message, the transmission slot of the access parameter, repeats 0, 1, and 2 when the modulo operation is performed on the slot number again with another overhead message (Diff_Ovhd_Msg). . In this case, if the overhead message is transmitted in slot 0 and all five overhead messages are transmitted in two slot intervals as described above, the current slot (CurSlot) can be modulated by Length. When the slot is zero, repeat the above process.

Here CurSlot refers to the current time in the current slot. And Slotnum = CurSlot% Length. In this case,% means modulo operation.

Therefore, if Slotnum is 0, the overhead message transmission starts from the system parameter message among the plurality of overhead messages, but the next overhead message is transmitted every two slots. A certain order is then determined for each of the plurality of overhead messages. For example, a system parameter-access message-CDMA channel list message, a neighbor base station list message (DCN) or a broad neighbor base station list message (PCS), and an extended system parameter message are defined in this order.

After the next extensive system parameter message has been sent, the next slotnum waits for the slot to become zero.

Accordingly, the base station transmits a plurality of overhead messages (O ₁ , 0 ₂ , 0 ₃ , 0 ₄ , 0 ₅ ) to the mobile station at a set time period using the 0,3,6,9,12th plurality of slots in the first 1.28 seconds. After the transmission, the first, fourth, seventh, tenth, and thirteenth slots are transmitted to the mobile station at the set time period in the next 1.28 seconds. That is, if the set time period is repeated, a plurality of slots (0, ₃ , ₆ , ₉ , 12th) using the next plurality of overhead messages (O ₁ , 0 ₂ , 0 ₃ , 0 ₄ , 0 ₅ ) in the first 1.28 seconds And transmit it to the next slot (1, 4, 7, 10, 13) of the following. To summarize the above description, when the transmission cycle is n, the first overhead message of each transmission cycle is (n -1) It is assigned to the result of mod 3, and the remaining overhead messages are distributed by two slots. In other words, in the first round, slot 0 begins with the first overhead message, the system parameter message, and thereafter two slots apart, i.e., the remaining overhead messages in (slot 3, slot 6, slot 9, slot 12). send. In this case, it can be seen that in the second transmission, the system parameter message is transmitted in slot 1, and in the third transmission, the system parameter message is transmitted from slot 2. Of course, in the fourth transmission, the operation is performed in the same manner as in the first transmission. An access message is transmitted to slot 2 and a CDMA channel list message to slot 5.

As described above, in the present invention, since the overhead messages are uniformly distributed in 16 slots at 1.28 seconds, the overhead transmitted by the base station is increased by increasing the probability that all slotted mode mobile stations receive the overhead messages with equal probability. There is an effect that can quickly respond to the message.

1 is a diagram illustrating a conventional overhead message transmission method.

2 is a diagram for explaining an overhead message transmission method according to the present invention.

Claims (2)

In the overhead message transmission method for transmitting a plurality of overhead messages to the mobile station in a set time period using a plurality of slots in the base station, When the transmission cycle is n, the first overhead message of each transmission cycle is assigned to the result value of (n-1) mod 3, and the remaining overhead messages are distributed in intervals of two slots. Overhead message transmission method. In the overhead message transmission method for transmitting a plurality of overhead messages to the mobile station in a set time period using a plurality of slots in the base station, A first step of distributing the plurality of overhead messages starting at the first slot and at intervals of two slots; A second step of distributing and transmitting a plurality of overhead messages in the next slot of each of the plurality of slots used in the first step; And performing a third process of repeatedly distributing a plurality of overhead messages in a next slot of each of the plurality of slots used in the second process according to a set time period.