KR100575502B1 - Hard handoff method between frequency in the mobile communication system - Google Patents

Abstract

According to the present invention, a wireless network is designed so that the cell size is different by varying the pilot strength for each frequency in a CDMA-based mobile communication system. Thus, a hard handoff between different frequencies can be achieved by simple modification of software without adding a separate hardware device. The present invention relates to a method of hard handoff between frequencies in a mobile communication system that can be safely performed. When designing a wireless network for a cell using a common frequency and an extended frequency, the cell size of the extended frequency is set to be smaller than the cell size of the common frequency. After designing the wireless network, if the terminal for the extended frequency passes the handoff region, the point of dropping the channel of the extended frequency is regarded as the point of occurrence of hard handoff between frequencies, and the base station between the extended frequency and the common frequency Perform an intra-hard handoff, In this case, a soft handoff between common frequencies is performed between neighboring base stations. Thus, a cell size is set differently for each frequency without additionally installing a conventional hardware device such as a common pilot device and a dummy pilot device. Securely perform hard handoff between different frequencies through post-intra-hard handoff and soft handoff, which not only saves the base station cost for handoff operation, but also makes it easy to cross-frequency hard hand with a simple modification of the software. There is an advantage to being able to implement off.

Description

Hard handoff method between frequencies in a mobile communication system

1 is a diagram illustrating a wireless network to which an inter-frequency hard handoff method according to the present invention is applied;

2 is a flowchart illustrating an inter-frequency hard handoff method of a mobile communication system according to the present invention.

<Description of the symbols for the main parts of the drawings>

10,20,30: 1st, 2nd, 3rd 1FA cell

40,50: 1st, 2nd 2FA cell

The present invention is a handoff method of a mobile communication system using a code division multiple access (CDMA) method, by designing a wireless network to vary the cell size by varying the pilot strength for each frequency to separate hardware (Hardware) The present invention relates to a method for hard handoff between frequencies in a mobile communication system, which enables a hard handoff between different frequencies to be safely performed by simply modifying software without adding a device.

In general, the channel resources of both cells are differently set at the boundary points of the urban area and the outer area due to the difference in subscriber density.

In other words, in the urban area with high subscriber density, most of the areas where frequency allocation is greater than 2FA (Frequency Assignment), and in the outer area where the subscriber density is low, mainly 1FA can be sufficiently serviced.

Accordingly, when a terminal in an urban area using an extended frequency, which is an additional frequency resource rather than a common frequency, moves to an outlying area, a handoff, that is, a hard handoff between different frequencies, occurs in the handoff region. .

However, since there is no extended frequency in the outlying region, the terminal using the extended frequency cannot make a pilot measurement, so it is ambiguous to determine the start time of the handoff, which causes frequent disconnection during actual service.

In order to solve the above problem, conventionally, a hardware device is additionally installed in an outer region to generate a pilot for an extended frequency so that the terminal can also measure a pilot in the outer region.

Therefore, the pilot measurement report message can be used to know the clear handoff time in the terminal, and the handoff operation can be performed more safely.

That is, in case of performing the hard handoff between different frequencies in the conventional mobile communication system, many problems occur due to the uncertainty of the handoff point in actual service, so that the handoff between different frequencies is enabled by the software implementation described in the specification. Also, there was a problem such as a call truncation phenomenon, and accordingly, a pilot for extended frequency was generated through separate hardware devices such as a common pilot unit and a dummy pilot unit to generate a hard handoff. Soft handoff was performed simultaneously.

However, when additional hardware devices are additionally installed as described above, a disadvantage is that a separate cost is consumed, such as a high base station cost, which in turn lowers the price competitiveness compared to other companies.

In addition, if any particular cell has a high subscriber density and inevitably needs to increase the frequency resource, there is a problem in that a hardware device needs to be additionally installed to increase the number of frequency resources around all the base stations surrounding the base station.

The present invention has been made to solve the above problems, and its object is to design a wireless network to vary the cell size by varying the pilot strength for each frequency in a mobile communication system employing a CDMA scheme, and to have a small cell area. Intra-hard handoff at the boundary of the system, then soft handoff to enable secure handoff between different frequencies without the need for additional hardware devices. The present invention provides a method of hard handoff between frequencies of a system.

In order to achieve the above object, an inter-frequency hard handoff method of a mobile communication system of the present invention provides a cell size of an extended frequency smaller than a cell size of a common frequency when designing a wireless network for a cell using a common frequency and an extended frequency. After designing the wireless network, if the terminal for the extended frequency passes through the handoff region, the point of dropping the channel of the extended frequency is regarded as the point of occurrence of hard handoff between frequencies, and the base station and the common frequency of the extended base station are recognized. Intra-hard handoff is performed between the base stations, and then soft handoff between common frequencies is performed between neighboring base stations to safely perform hard handoff between different frequencies.

Hereinafter, a method for hard handoff between frequencies of a mobile communication system according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram illustrating a wireless network to which an inter-frequency hard handoff method is applied, wherein the first to third 1FA cells 10 to 30 using a common frequency of FA0 and a common frequency of FA0 are shown. The first 2FA cell 40 and the second 2FA cell 50 are configured by using the extended frequency of FA1, and the cell size b of the extended frequency is set smaller than the cell size a of the common frequency.

First, in order to install a mobile communication system, it is necessary to design a wireless network. At this time, it is important to set a location of the system, to set a cell radius for a good call, and to determine a base station output.

Normally, when setting the cell radius, the forward and reverse links should be the same, and in the case of multi-FA, the links should be aligned between FAs.

However, in the present invention, if the FA-to-FA links are the same, handoff operation between different FAs cannot be performed. As shown in FIG. 1, a cell size of an extended frequency that does not exist in a neighboring cell in a region where FAs are imbalanced with each other is shown. (b) is set smaller than the cell size (a) of the common frequency.

Here, when the common frequency is referred to as FA0 and the extended frequency as FA1, the first to third 1FA cells 10 to 30 use the common frequency of FA0, and the first 2FA cell 40 and the second 2FA. The cell 50 uses the common frequency of FA0 and the extended frequency (hatched region) of FA1.

The cell size is mainly determined by the pilot strength and the terminal reception power. In the present invention, the pilot strength related to the handoff will be referred to.

In addition, the difference in cell size between FA0 and FA1 should be defined. In this case, the pilot strength may be affected by various factors, but is inversely related to the distance factor with the base station.

The handoff region formed according to the handoff threshold should be formed to be as long as the time to perform the handoff.

Accordingly, in the present invention, a sufficient handoff region for handoff between the neighboring first 2FA cell 40 and the second 2FA cell 50 is formed as c, and the extended frequency of FA1 is the common frequency of FA0. The cell size (b) of the extended frequency in the first and second 2FA cells (40, 50) is smaller than the cell size (a) of the common frequency to form a region capable of soft handoff after changing to Set it.

In this case, since the cell size (b) of the extended frequency may vary according to each cell environment and the handoff threshold, a specific value is determined through experimentation and verification.

The hard-to-frequency hard handoff method of the mobile communication system according to the present invention will be described in detail with reference to the operation flowchart of FIG. 2.

First, to design a wireless network (S1).

That is, the cell design of FA0 is performed like the first to third 1FA cells 10 to 30 and the first and second 2FA cells 40 and 50 shown in FIG. 1, wherein the first and second 2FA cells are shown. The cell size of FA0 at (40, 50) is a.

Subsequently, the cell design of FA1 is performed, and the wireless network design of FA1 is performed so that the first and second 2FA cells 40 and 50 have a smaller size b than the cell size a of FA0.

Since the handoff threshold uses the same value for both FA0 and FA1, even if the cell of FA1 is designed to be small, the cell boundary region pilot strength of FA0 and the cell boundary region pilot strength of FA1 are the same.

At this time, in order to make the cell boundary region pilot strength of FA0 equal to the cell boundary region pilot strength of FA1, the output of FA1 pilot strength is adjusted low by the base station.

That is, the base station adjusts the pilot gain, which is a parameter related to the pilot strength, and uses 20% of the current total forward power as the pilot power. However, in order to apply the present invention, the pilot power of FA1 is changed to a value smaller than the above value. Should be controlled by

Subsequently, after designing the wireless network by setting the cell size (b) of the extended frequency to be smaller than the cell size (a) of the common frequency as in step S1, the terminal using FA1 in the first 2FA cell 40 A hard handoff method according to the present invention, which occurs when N moves to the first 1FA cell 10 is described.

The terminal receives a pilot measurement report message measuring the pilot strength of FA1 from the base station while moving from the first 2FA cell 40 to the first 1FA cell 10 (S2).

From the pilot measurement report message received in step S2, if the pilot strength at the cell boundary of FA1 (e shown in FIG. 1) is less than or equal to the handoff drop threshold (S3), the terminal requests a handoff from the base station ( S4).

That is, the terminal recognizes a point in time at which the channel of the extended frequency is dropped as a point in time of hard handoff between the extended frequency and the common frequency.

Subsequently, intra-hard handoff is performed by forcibly switching from the channel of the extended frequency of FA1 to the channel of the common frequency of FA0 allocated in advance according to the handoff instruction received from the base station by the handoff request of the terminal (S5). .

After the intra-hard handoff is performed in the handoff region (d shown in FIG. 1) of the first 2FA cell 40 as in step S5, the frequency of use of the terminal is changed to the common frequency of FA0. The terminal moving to the handoff region (d shown in FIG. 1) of the first 2FA cell 40 searches for a pilot of a neighboring neighbor base station having the common frequency of FA0 to handoff the first 2FA cell 40. In the region (d shown in FIG. 1), soft handoff is performed at a common frequency of FA0 of the first 1FA cell 10 (S6).

As described above, according to the present invention, since both intra-hard handoff and soft handoff are performed in the hard handoff region between different frequencies, a good call can be made without disconnection of a call.

As described above, according to the present invention, an intra-hard handoff and a soft handoff are performed after setting different cell sizes for each frequency without separately installing a conventional hardware device such as a common pilot device and a dummy pilot device. By performing the hard handoff safely between different frequencies through the scheme, there is an economical effect of saving the cost of the base station for the handoff operation, and it is possible to implement the hard handoff between frequencies with a simple modification of the software.

Claims (4)

In the hard handoff method between different frequencies of the mobile communication system, The first step of designing a wireless network by setting the cell size differently for each frequency used in the base station, and when the terminal for the extended frequency moves to the cell region of the common frequency after performing the first step, a pilot of the extended frequency from the base station A second step of receiving a measurement report message; and a third step of requesting handoff to the base station when the pilot strength at the cell boundary of the extended frequency is less than or equal to the handoff drop threshold from the pilot measurement report message received in the second step; A fourth step of performing an intra-hard handoff by forcibly switching from a channel of an extended frequency to a channel of a pre-allocated common frequency according to the handoff instruction of the base station by the handoff request of the third step; After the step, the terminal changed to the common frequency searches for a pilot for the common frequency of the neighboring base station Hard handoff method between the frequency at which is characterized by performing the soft hand-off between frequencies tube made of an a fifth step of each other to complete the hard handoff operations between different frequencies the mobile communication system. The mobile communication system of claim 1, wherein, when designing the wireless network in the first step, the base station using the common frequency and the extended frequency sets the cell size of the extended frequency to be smaller than the cell size of the common frequency. Inter-frequency hard handoff method in. The method of claim 2, wherein, when setting the cell size of the extended frequency, the base station adjusts the pilot gain which is a parameter related to the extended frequency to lower the pilot output of the extended frequency to set the cell size of the extended frequency. A method for hard handoff between frequencies in a mobile communication system.  The method of claim 1, wherein in the third step, when the pilot strength at the cell boundary of the extended frequency is less than or equal to the handoff drop threshold, a time point at which the terminal drops a channel of the extended frequency is a hard handoff occurrence time between the extended frequency and the common frequency. A method for inter-frequency hard handoff in a mobile communication system, characterized by requesting handoff to a base station.

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