KR100602022B1 - Method for transmitting parameter use handoff to synchronous cell site from asynchronous cell site in a mobile communication system - Google Patents

Abstract

In the mobile communication system according to the present invention, a parameter transmission method for handoff between a synchronous base station and an asynchronous base station depends on time when the asynchronous base station knows the time information of the synchronous base station using an external reference time, that is, a GPS or an auxiliary receiver. Long state information may be transmitted using an existing physical channel (AICH) of the asynchronous base station. Therefore, since the long code state information can be known without demodulating the synchronization channel of the synchronization base station, the handoff time can be minimized. Also, when a new physical channel is established without using the existing channel, it is different from other channels of the asynchronous base station. Since the same modulation and demodulation method can be used, long code state information necessary for handoff can be obtained without a large addition of hardware.

Description

Parameter transmission method for handoff between synchronous base station and asynchronous base station in mobile communication system {Method for transmitting parameter use handoff to synchronous cell site from asynchronous cell site in a mobile communication system}             

1 illustrates a cell configuration of a synchronous base station and an asynchronous base station in a mobile communication system;

2 is a diagram illustrating a compressed mode transmission method when performing a handoff from an asynchronous base station to another system (synchronous base station, GSM);

3 is a diagram illustrating a pilot offset of a forward sync channel in a synchronous base station;

4 is a diagram showing the structure of an AICH applied to a parameter transmission method required for handoff between a synchronous base station and an asynchronous base station in a mobile communication system according to the present invention;

5 is a diagram illustrating a method for transmitting a long code state using the AICH structure shown in FIG. 4;

FIG. 6 illustrates a structure of a channel newly set for transmitting the long code state shown in FIG. 5; FIG.

7 is a flowchart illustrating a method for transmitting a parameter required for handoff between a synchronous base station and an asynchronous base station in a mobile communication system according to the present invention.

<Explanation of symbols for main parts of drawing>

10: synchronous base station cell

11: synchronous base station

20, 30, 40, 50, 60: Asynchronous base station cell

21, 31, 41, 51, 61: Asynchronous base station

70: mobile station

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a base station handoff method in a mobile communication system, and more particularly, to perform handoff from a 3rd generation asynchronous wideband-code division multiple access (W-CDMA) base station to a synchronous scheme (IS-95, IS-2000) base station. Parameter Transmission Method for Handoff between Synchronous Base Station and Asynchronous Base Station in Mobile Communication System for Transmitting Synchronous Base Station Information (Long Code State) Needed to the Mobile Station through Asynchronous Channel Using External Time It is about.

In general, a mobile communication system is classified into a synchronous mobile communication system and an asynchronous mobile communication system, among which a synchronous mobile communication system interfaces data according to IS standards (IS-95, IS-41, IS-634), and is asynchronous. The mobile communication system interfaces with data according to the Universal Mobile Telecommunication System (UTRA) standard. Here, the synchronous mobile communication system refers to a second generation synchronous system currently being serviced or a third generation synchronous system (synchronous IMT-2000) to be commercialized in the future, and the asynchronous mobile communication system is a third generation asynchronous W-CDMA system (asynchronous IMT-2000). ).

If the third generation asynchronous W-CDMA system starts service in the synchronous system that is currently being serviced or the third generation synchronous system to be commercialized in the future, the handoff from the asynchronous system to the synchronous system may be performed to increase efficiency. ) Is required. Here, handoff refers to handoff when a mobile station moves to another cell during a call and is allocated a new call channel from the moved base station. In this method, a hard handoff method and a soft handoff method are used. There is a soft handoff method. Hard handoff is a break and make method that first disconnects the base station's call channel and connects to the base station's call channel of the mobile cell. The handoff method is a make and break method in which a communication channel is connected to a previously connected base station and a base station and a communication channel of a mobile cell are disconnected first and then disconnected from the base station.

1 is a diagram illustrating a cell configuration of a synchronous base station and an asynchronous base station when a synchronous system and an asynchronous system are serviced in the same region.

 As shown in FIG. 1, since the third generation asynchronous system cannot initially service in all regions, the third generation asynchronous system is adjacent to or included in a synchronous system such as IS-95, which is currently being serviced. That is, the asynchronous base stations 21, 31, 41, 51, 61 having predetermined cells 20, 30, 40, 50, and 60 are located in the cell 10 of the synchronous base station 11.

In this situation, the mobile station 70 supporting both of the asynchronous / synchronous modes receives services from the asynchronous base stations 21, 31, 41, 51, and 61, but there are no asynchronous base stations 21, 31, 41, 51, and 61. When the mobile station 70 moves to the boundary of the non-synchronous base station 11, the mobile station 70 does not have any asynchronous base stations 21, 31, 41, and 61 to be handed off. 11) handoff is required.

As described above, when the asynchronous base station 50 performs handoff to another system, that is, the synchronous base station 11 or the Global System for Mobile Communication (GSM), the asynchronous base station 50 operates in the compressed mode as shown in FIG. 2 is a diagram illustrating a compressed mode transmission method when performing a handoff from an asynchronous base station to another system (synchronous station, GSM).

As shown in FIG. 2, a maximum time for searching for a base station to be handed off in the compressed mode is 8 ms. Therefore, when the mobile station 70 serving the asynchronous base stations 21, 31, 41, 51, 61 performs handoff to the synchronous base station 11, information of the synchronous base station 11 shown in FIG. Must be earned through the Idle Period. At this time, the information of the synchronization base station 11 may be obtained by a forward sync channel, a pilot channel, a traffic channel, and the like transmitted from the synchronization base station 11.

3 illustrates the timing of the pilot channel, the synchronization channel, and the traffic channel of the synchronization base station, and illustrates the pilot offset of the forward synchronization channel in the synchronization base station.

As shown in FIG. 3, in order to perform handoff from an asynchronous base station to a synchronous base station, pilot synchronization, base station offset, super frame timing of a synchronization channel, and long code state of a traffic channel are shown. The mobile station connecting to the asynchronous base station should be able to obtain it during the compressed mode to minimize call disconnection time in performing handoff.

When the pilot channel of a synchronous base station uses a short code having a length of 2 ¹⁵ (26.667 ms) at all base stations and distinguishes the base stations by the offset, the entire period when searching for pilot synchronization in the compressed mode There is a problem that it takes a lot of time because you have to search all (26.667ms).

In addition, in order to know the offset information for identifying each base station and the state of the long code used in the traffic and paging channels, the synchronization channel must be demodulated. In FIG. Since it is 80ms, there is another problem that takes a long time to demodulate all of them. Therefore, the handoff execution time becomes very long from the asynchronous base station to the synchronous base station, which causes a problem that the handoff is impossible.

Accordingly, the present invention has been made to solve the above-described problems according to the prior art, and an object of the present invention is to provide synchronous base station information (long code state) necessary to perform a handoff from a third generation asynchronous W-CDMA base station to a synchronous base station. The present invention provides a parameter transmission method for handoff between a synchronous base station and an asynchronous base station in a mobile communication system for transmitting a long code state to an mobile station through an asynchronous channel using an external time reference.

When handoff is performed from an asynchronous base station to a synchronous base station, timing information, a pilot offset, and a long code state of a synchronous base station to be handed off to a mobile station connected to the asynchronous base station should be known during the Idle Period of the compressed mode. Therefore, in the mobile communication system according to the present invention for achieving the above object, a parameter transmission method for handoff between a synchronous base station and an asynchronous base station includes information required for handoff during an Idle period in order to obtain the information of the synchronous base station. In order to obtain the asynchronous base station may operate the asynchronous base station using an auxiliary receiver or a global positioning system (GPS) capable of receiving external reference time, that is, time information of the synchronous base station. In this case, the mobile station can acquire information necessary for handoff through the asynchronous base station, and the mobile station can easily transmit a list of neighboring base stations which do not depend on time change using a channel matched to the physical layer of the existing asynchronous base station. Can be.

Long code states, on the other hand, are time dependent and must be delivered to the mobile station at the correct time. Therefore, there is a need for a method for delivering a long code state at an accurate time, and a method for transmitting the long code state using a channel capable of knowing an accurate timing among physical channels of an asynchronous base station, or for setting and transmitting a new channel. It is.

After all, in the mobile communication system according to the present invention, the characteristic of the parameter transmission method for handoff between the synchronous base station and the asynchronous base station is dependent on time when the asynchronous base station knows the time information of the synchronous base station using the auxiliary receiver or GPS. The long code state information is transmitted to the mobile station by using the existing physical channel of the asynchronous base station so that the handoff is performed from the asynchronous base station to the synchronous base station.

In addition, the long code state is transmitted to the mobile station by acquiring long code state information using the same modulation and demodulation method as other channels of the asynchronous base station by setting a new channel without using the physical channel of the existing asynchronous base station. It is characterized by the fact.

That is, in the mobile communication system according to the present invention, the parameter transmission method required for the handoff between the synchronous base station and the asynchronous base station is characterized in that the handoff processing method between the synchronous base station and the asynchronous base station is carried out between the asynchronous base station and the mobile station. Establishing a new physical channel; Receiving monitoring information on an adjacent asynchronous base station transmitted by the mobile station and determining whether there is an asynchronous base station to be handed off among adjacent asynchronous base stations according to the received monitoring information; As a result of the determination, when there are no asynchronous base stations to be handed off among adjacent asynchronous base stations, the mobile station transmits a handoff request signal to the synchronous base station, and the asynchronous frame timing and zero of the synchronous base station acquired through the external reference time from the asynchronous base station. Receiving an offset indicating a difference in offset timing; Receiving a compressed mode message from an asynchronous base station at the mobile station, searching for a pilot channel of an adjacent synchronous base station using offset information received from the asynchronous base station, and acquiring a corresponding synchronous base station to which the mobile station belongs; The mobile station receives the long code state information transmitted through the existing channel or the newly set physical channel matched with the physical layer of the asynchronous base station, and performs handoff to the obtained synchronous base station using the received long code state information. Consists of performing steps.

In another aspect of the present invention, the existing channel set between the mobile station and the asynchronous base station is an AICH capable of transmitting long code state information to the mobile station in accordance with the PCCPCH and the frame timing, and the AICH is a 15 access slot for 2 frames. It has a structure for transmitting long code state information to a mobile station by using a predetermined bit not used for each access slot.

In addition, according to another aspect of the present invention, the newly established physical channel between the mobile station and the asynchronous base station transmits the pilot number 1 and the long code state twice within one frame, and the long code state information is CRC coding and convolutional coding. Is transmitted to the mobile station through interleaving and interleaving, and the PCCPCH and frame timing have the same structure.

Hereinafter, a detailed description will be made of the accompanying drawings for a parameter transmission method for handoff between a synchronous base station and an asynchronous base station in a mobile communication system according to the present invention.

First, when the dual mode mobile station supporting the asynchronous / synchronous mode connected to the asynchronous base station needs to be handed off to the synchronous base station, the mobile station searches for the synchronous base station in the compressed mode. In this case, the mobile station must search for the pilot channel of the synchronous base station and demodulate the synchronous channel to obtain the information necessary for handoff.

At this time, if the asynchronous base station can know the transmission time of the synchronous base station through the GPS or the auxiliary receiver, the handoff can be efficiently performed because it is not necessary to search the entire pilot code to select the synchronous base station in the handoff.

However, the synchronization channel demodulation for obtaining the long code state takes much time (240 ms) even when the pilot channel is synchronized. Therefore, it is impossible to demodulate it in the compressed mode, and to solve this problem, the long code state may be transmitted using a channel of an asynchronous base station.

Since the long code state information is information that changes with time, it should be delivered to the mobile station at the correct time. To solve this problem, one of the channels of the asynchronous base station can be used to know the time when the mobile station transmits from the asynchronous base station. In this case, a new physical channel can be transmitted by setting a new physical channel.

That is, in case of using the channel matched with the physical layer of the existing asynchronous base station, since there is not enough space to transmit the long code state, a modulation scheme can be used to obtain a coding severe channel gain. This is advantageous in terms of resources because it does not need to be allocated.

On the other hand, when the long code state information is transmitted by setting a new physical channel, a modulation method such as coding can be used, but there is a disadvantage in terms of resources such as channel code allocation.

The two methods described above, namely, a method of transmitting long code state information using an existing physical channel configured in an asynchronous base station and a method of transmitting long code state information to a mobile station by setting a new physical channel will be described in detail. Let's look at it.

First, when using an existing physical channel, it is efficient to use a channel having a space capable of transmitting a long code state. Such a channel includes an Acquisition Indicator Channel (AICH), and the structure of the AICH is shown in FIG.

FIG. 4 is a diagram showing the structure of an AICH applied to a parameter transmission method required for handoff between a synchronous base station and an asynchronous base station in a mobile communication system according to the present invention. FIG. 5 is a long code using the AICH structure shown in FIG. A diagram illustrating a method for transmitting a state.

The AICH can transmit the long code state at the time required by the mobile station because the frame timing coincides with the primary common control physical channel (PCCPCH).

As shown in FIG. 4, the AICH is composed of 15 access slots for 2 frames. When the SF is 256, since the AICH does not use 4 bits for each access slot, the AICH is 60 during 2 frames. Do not use bits. Accordingly, the long code state (41 bit) can be transmitted as shown in FIG. 5, and a frame quality indicator (i.e., 12 bit CRC code) is used to confirm that the long code state is correctly transmitted. You can add

Accordingly, the mobile station can demodulate the long code state information transmitted in every slot of the AICH to obtain long code state information to be used by the mobile station for 15 access slots.

FIG. 6 illustrates a structure of a channel newly set for transmitting the long code state illustrated in FIG. 5.

As illustrated in FIG. 6, when a new channel is set without using an existing AICH channel, an existing modulation and demodulation scheme such as channel coding may be used. That is, as shown in FIG. 6, when the SF is 256, the newly set channel can transmit the pilot 1 and the long code state twice within one frame, and the pilot part receives the channel and restores the long code. The state part is for reference purposes only.

As shown in FIG. 6, the long code state information of 50 bits inputted through the set new channel is transmitted at 11 Kbps, and after performing CRC coding by adding a 12-bit CRC code in the CRC coding unit, a 13.4 Kbps rate is obtained. The output is 62 bits of data.

By adding 8-bit data to the tail of the CRC-coded 62-bit data, 70-bit data is output to the convolutional encoder at 15 Kbps.

The convolutional encoder performs convolutional encoding on 70-bit long code state data, and then outputs 140 symbols of data at 30 Kbps to the block interleaver. Accordingly, the block interleaver performs interleaving to transmit interleaved long code state information at a rate of 30 Kbps. That is, the long code state part illustrated in FIG. 6 may use CRC coding, convolutional coding, and interleaver technique.

The newly set channel has the same frame timing as the PCCPCH, and the mobile station can determine when the received long code state information is used using the frame timing and the timing relationship between the asynchronous base station and the synchronous base station.

Hereinafter, a parameter transmission method required for handoff between a synchronous base station and an asynchronous base station in a mobile communication system according to the present invention will be described step by step with reference to FIG.

7 is a flowchart illustrating a method for transmitting a parameter required for handoff between a synchronous base station and an asynchronous base station in a mobile communication system according to the present invention.

First, after establishing a new physical channel between the asynchronous base station and the mobile station (S101), while connecting to the corresponding asynchronous base station where the mobile station is located (S102), the mobile station is currently accessing power monitoring information for the adjacent base station. Transmission to the asynchronous base station (S103).

Subsequently, the asynchronous base station currently connected to the mobile station receives the monitoring information transmitted from the mobile station and determines whether there is an asynchronous base station to be handed off among adjacent asynchronous base stations according to the received monitoring information (S104).

As a result, when there is an asynchronous base station to be handed off among the adjacent asynchronous base stations, the handoff is performed to the corresponding asynchronous base station (S105).

However, when there is no asynchronous base station to be handed off among adjacent asynchronous base stations in step S104, the mobile station transmits a handoff request signal to the synchronous base station (S106).

Subsequently, the mobile station receives an offset indicating the difference between the asynchronous frame timing acquired through the external reference time and the zero offset timing of the synchronous base station from the asynchronous base station (S107).

Subsequently, the mobile station receives the compressed mode message from the asynchronous base station (S108), and the mobile station measures the pilot strength of the adjacent synchronous base station using the message received from the asynchronous base station in the compressed mode, that is, offset information, and the result. Report to the connected asynchronous base station (S109).

Subsequently, the mobile station receives the long code state information transmitted through the existing channel matched with the physical layer of the asynchronous base station or the newly set physical channel (S110).

Subsequently, the mobile station performs handoff to the synchronous base station obtained after reviewing the report of the mobile station using the long code state information received from the asynchronous base station through the existing channel or the newly set physical channel (S111).

As a result, the mobile station receives the information of the synchronous base station from the asynchronous base station, thereby reducing the time for operating in the compressed mode. Thus, the effect of the compressed mode on the asynchronous base station is reduced.

When the mobile station uses the compressed mode, it is used only when searching for a synchronous base station to which it belongs. In this case, since the zero offset timing is already known, a small number of transmission gaps are required in the compressed mode. Therefore, when the mobile station handoffs from the asynchronous base station to the synchronous base station, it is possible to minimize the time for operating in the compressed mode and also to reduce the disconnection time to a minimum.

In the mobile communication system according to the present invention as described above, the parameter transmission method for handoff between the synchronous base station and the asynchronous base station is performed when the asynchronous base station knows the time information of the synchronous base station using an external reference time, that is, a GPS or an auxiliary receiver. In addition, time-dependent roll state information may be transmitted using an existing physical channel (AICH) of an asynchronous base station. Therefore, since long code state information can be known without demodulating the synchronization channel of the synchronization base station, the handoff time can be minimized.

In addition, even when a new physical channel is set up without using an existing channel, the same modulation and demodulation method can be used as other channels of an asynchronous base station. Thus, long code state information necessary for handoff can be obtained without significant hardware addition. have.

Claims (6)

A handoff processing method between a synchronous base station and an asynchronous base station in a mobile communication system, Establishing a new physical channel between the asynchronous base station and the mobile station; Receiving, by the mobile station, power monitoring information of an adjacent asynchronous base station while being connected to the asynchronous base station and transmitting the received power monitoring information to the connected asynchronous base station; Receiving monitoring information on an adjacent asynchronous base station transmitted by the mobile station from the asynchronous base station and determining whether there is an asynchronous base station to be handed off among the adjacent asynchronous base stations according to the received monitoring information; a) if there is an asynchronous base station to be handed off among adjacent asynchronous base stations, handoff to the asynchronous base station; b) If there is no asynchronous base station to be handed off, the mobile station makes a difference between the handoff request signal from the asynchronous base station to the synchronous base station, the asynchronous frame timing obtained from the asynchronous base station through an external reference time, and the zero offset timing of the synchronous base station. Receiving an offset indicating a; Receiving, by the mobile station, a compressed mode message from the asynchronous base station, searching for the pilot signal of the corresponding synchronous base station to which the mobile station belongs by using the offset information received from the asynchronous base station, and reporting it to the connected asynchronous base station; The mobile station receives the long code state information transmitted from the existing channel matched with the physical layer of the asynchronous base station or the newly set physical channel and uses the received long code state information to review the report of the mobile station and then obtains the synchronous type. A method for transmitting parameters required for handoff between a synchronous base station and an asynchronous base station in a mobile communication system, characterized in that the handoff is performed to a base station. The method of claim 1, The existing channel set between the mobile station and the asynchronous base station is an AICH capable of transmitting long code state information to the mobile station in accordance with the PCCPCH and frame timing. A parameter required for handoff between the synchronous base station and the asynchronous base station in the mobile communication system. Transmission method. The method of claim 2, The AICH consists of 15 access slots for 2 frames, and transmits long code state information to a mobile station using a predetermined bit for each access slot. Parameter transmission required for. The method of claim 1, The newly established physical channel between the mobile station and the asynchronous base station transmits one pilot information and two long code state information in one frame, and the long code state information is transmitted to the mobile station using CRC coding, convolutional coding and interleaving techniques. A parameter transmission method for handoff between a synchronous base station and an asynchronous base station in a mobile communication system characterized in that the transmission. The method according to claim 1 or 3, The newly established channel between the mobile station and the asynchronous base station is set to have the same frame timing as the PCCPCH, and the timing point at which the received long code state is used is determined using the frame timing and timing relationship between the asynchronous base station and the synchronous base station. A parameter transmission method for handoff between a synchronous base station and an asynchronous base station in a mobile communication system. The method of claim 1, The external reference time used in the asynchronous base station is a parameter transmission method for handoff between the synchronous base station and the asynchronous base station in the mobile communication system, characterized in that the time information of the synchronous base station obtained through a GPS or an auxiliary receiver.

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