KR20050024002A - Handoff method - Google Patents

Abstract

PURPOSE: A hand-off method is provided to prevent that a receiving rate is degraded due to the location registration of a mobile communication terminal after performing hand-off by performing an idle hand-off without performing a high speed RAHO(ReAcquisition Hand-Off) in case that it is necessary for registering the location of the mobile communication terminal after performing the hand-off. CONSTITUTION: A mobile communication terminal operates in a slotted mode and determines whether it is necessary for performing a high speed RAHO. If it is unnecessary for performing the high speed RAHO, the mobile communication terminal continuously operates in the slotted mode. If it is necessary for performing the high speed RAHO, the mobile communication terminal judges whether it is necessary for registering the location of the mobile communication terminal. If it is necessary for registering the location of the mobile communication terminal, the mobile communication terminal performs an assigned slot-monitoring operation. If it is unnecessary for registering the location of the mobile communication terminal, the mobile communication terminal performs the high speed RAHO. If a stop slot-monitoring condition is satisfied while the assigned slot-monitoring operation is performed, the mobile communication terminal performs an idle hand-off.

Description

Handoff Method {HANDOFF METHOD}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a handoff method, and more particularly, to a handoff method capable of preventing a decrease in reception rate due to location registration after handoff.

Handoff refers to changing a call path to a moved cell when the mobile terminal moves out of one cell to another cell. Handoff may occur when the mobile terminal is in a call state or in a call waiting state. When the mobile communication terminal is handed off in a call reception state, it is called idle handoff.

Idle handoff is defined in the Wireless Mobile Communications Standard (IS-2000 2.6.2.1.4), and the active pilot strength and the neighbor pilot strength are measured in a call waiting state, i.e., idle state. In comparison, it is performed when the adjacent pilot strength is strong enough.

Since idle handoff is performed while the mobile terminal is awake, it occurs during the assigned slot in slotted mode. The mobile terminal checks if a page comes from the base station during the assigned slot. If the mobile terminal performs the handoff while checking the call, the call from the base station may be missed. Accordingly, idle handoff is performed only after a stop slot-monitering condition (IS-2000 2.6.2.1.1) is satisfied in the assigned slot, i.e., when a message from the base station is no longer called. .

The disadvantage of idle handoff is that it takes time for handoff. For example, if the signal of base station B is stronger than the signal of base station A when the mobile terminal enters a sleep state and wakes up while monitoring the channel of base station A, the mobile terminal once has a channel of base station A. After monitoring, if the stop slot monitoring condition is satisfied, handoff to base station B is performed. Therefore, a delay of handoff occurs until the stop slot monitoring condition is satisfied.

In order to solve the delay problem of the idle handoff, a fast Reacquisition Handoff (RAHO) has been proposed to perform a handoff to a base station (base station B) that sends a strong signal as soon as the mobile terminal wakes up.

In high-speed RAHO, the neighboring pilots expected to be handed off before the mobile terminal enters the dormant state are memorized, and then the strength of the neighboring pilots memorized before reacquisition of the active pilot at wakeup is measured. Since the handoff is performed immediately when the strength is strong, no delay of the handoff occurs.

The conventional mobile communication terminal performs handoff using an idle handoff algorithm in a non-slotted mode and performs handoff using a fast RAHO algorithm in a slot mode.

However, in the fast RAHO, handoff is performed immediately after the wakeup and before the allocation slot is started, so if location registration is needed after the handoff, location registration occurs during the allocation slot. It takes time to complete the location registration, so if the call comes from the base station before the location registration is completed, the call is missed.

Therefore, when the fast RAHO is performed in the cell boundary area where location registration occurs frequently, the reception rate of the mobile communication terminal is lowered.

The present invention was devised to solve the above problems, and when the position registration is required after the handoff, by performing the idle handoff without performing the fast RAHO, it is possible to prevent a decrease in the reception rate due to the position registration after the handoff. It is an object to provide a handoff method.

To this end, the handoff method according to the present invention comprises the steps of determining whether a high speed RAHO is required while the mobile communication terminal is operating in the slot mode, and continues to operate in the slot mode if the high speed RAHO is not needed, Determining whether registration is necessary; performing allocation slot monitoring if location registration is required; performing fast RAHO if location registration is not required; and performing a stop slot monitoring condition while performing allocation slot monitoring operation. Performing an idle handoff.

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

1 shows a flowchart of a handoff method according to the present invention.

The mobile terminal continuously checks whether there is a call from the base station in a call reception state. If the monitoring is continuously performed, the mobile terminal consumes too much battery and thus cannot use the mobile terminal for a long time.

In order to reduce battery consumption, the mobile station and the base station set a time zone with each other, and the base station sends a call only in a specific time zone, and the mobile communication terminal checks for a call coming in the specific time zone. Since the mobile terminal wakes up and checks the call only in a specific time zone, the mobile communication terminal may enter a dormant state except at a specific time zone, thereby reducing battery consumption. In this way, the mobile communication terminal is in a dormant state and wakes up at a specific time zone. The slot mode is called slotted mode, and the call of the base station at the specific time zone is called assigned slot monitoring.

The mobile terminal performs monitoring during the assigned slot while repeating sleep and wake-up in the slot mode. While operating in the slot mode, the mobile communication terminal determines whether a high speed RAHO is required.

If the fast RAHO is not needed, the operation continues in the slot mode without the handoff, and if the fast RAHO is required, it is determined whether the location registration is necessary.

In case of handoff to a specific base station, whether location registration is required or not is determined as follows.

1) If an overhead message of a specific base station does not have information about a system parameter message, it is determined that location registration is necessary.

2) If the overhead message of a specific base station has information about a system parameter message and is not included in any of SID_NID_LIST or ZONE_LISTs stored in the mobile communication terminal with reference to its sid / nid, location registration is necessary. To judge.

3) If the overhead message of a specific base station has information about a system parameter message and is included in both SID_NID_LIST and ZONE_LISTs stored in the mobile communication terminal with reference to the sid / nid, it is determined that location registration is not necessary. .

If it is deemed necessary to register the location by this determination method, the allocation slot monitoring is performed without performing the fast RAHO. If it is determined that location registration is not necessary, fast RAHO is performed.

The mobile communication terminal performs idle handoff when the stop slot monitoring condition is satisfied based on an idle handoff algorithm while performing an allocation slot monitoring operation.

If the location registration to the mobile base station after the handoff needs to be performed, if the idle handoff is performed without performing the fast RAHO as described above, the call of the base station is not missed. In other words, if the mobile terminal is awakened, the mobile terminal wakes up, but does not handoff to the base station with strong signal, but monitors the current base station. OFF will be performed. Therefore, no missed call occurs due to location registration after handoff, like a fast RAHO.

As described above, the present invention performs idle handoff when location registration is required, and performs fast RAHO when location registration is not required. There is an effect of improving the reception rate of the mobile communication terminal in the cell boundary region.

1 is a flowchart of a handoff method according to the present invention.

Claims (1)

Determining whether a high speed RAHO is required while the mobile terminal operates in the slot mode; If the high speed RAHO is not required, continue to operate in the slot mode, if the high speed RAHO is required to determine whether the location registration is necessary, Performing allocation slot monitoring if location registration is required, and performing fast RAHO if location registration is not required; And performing idle handoff when the stop slot monitoring condition is satisfied while performing the allocation slot monitoring operation.