KR101154336B1 - Mobile terminal for performing vertical handover in heterogeneous networks and handover method using the same - Google Patents

Abstract

The mobile terminal receives the signal-to-noise ratio from the base station, extracts the current data rate from the strength of the signal-to-noise ratio, divides the current data rate by the maximum data rate, and calculates the normalized data rate. A load normalization unit that calculates the current network load, divides the current network load from the total network load, and calculates the normalized network load, and adds the total network cost to the value of the current network cost according to the network type. The network cost normalizer and the normalized data rate, the normalized data load, the normalized network load, and the cost of the normalized network are calculated by adding different weights to each network.Selecting a network having a value and comprising a network selection to perform the handover.

Description

Mobile Terminal for Performing Vertical Handover in Heterogeneous Networks and Handover Method Using The Same {Mobile Terminal for Performing Vertical Handover In Heterogeneous Networks and Handover Method Using the Same}

The present invention is a handover method for performing a vertical handover, and in particular, a vertical handover in a heterogeneous network performing a handover of a heterogeneous network in consideration of the data rate extracted from the strength of the signal-to-noise ratio, the network cost, and the network load The present invention relates to a mobile terminal and a handover method using the same.

Recent mobile technology is growing rapidly, and with the launch of smartphones and tablet PCs, it has become a hot topic in the industry.

This has created new markets, such as Apple's App Store and Google's Android Market.

On the other hand, the development of the mobile Internet has recently increased the demand for data traffic.

Mobile service providers are considering an early transition to 4th Generation (4G) to dissipate the surging data traffic and increasing the Wi-Fi zone. In addition, the WiMAX network, which is emerging as the next generation network, is also important.

Efficient vertical handover to other networks is required in a situation where three networks, namely, Wideband Code Division Multiple Access (WCDMA), WiMAX, and Wi-Fi, are mixed.

Vertical handover must consider various factors in an environment where various heterogeneous networks coexist.

However, considering too many factors, it does not bring the effect of improved performance compared to the increased amount of computation.

In order to solve this problem, an object of the present invention is to perform a handover by selecting an enhanced network by applying different weights to data rates, network costs, and network loads extracted from signal-to-noise ratio strengths. .

According to an aspect of the present invention, a mobile terminal receives a signal-to-noise ratio from a base station, extracts a current data rate from the strength of the signal-to-noise ratio, and divides the current data rate by a maximum data rate to normalize the same. A data normalization unit for calculating a data rate; A load normalization unit configured to receive a network usage from the base station, calculate a current network load, and divide the current network load by the total network load to calculate a normalized network load; A network cost normalization unit calculating a cost of a normalized network by dividing a value of a current network cost according to a network type by a sum of total network costs; And calculating the sum of the normalized data rate, the load of the normalized network, and the cost of the normalized network by applying different weights to each network, and selecting a network having the largest value to perform a handover. And a network selection unit.

In the handover method for performing vertical handover between heterogeneous networks in a mobile station according to an aspect of the present invention, the mobile station receives a signal-to-noise ratio from a base station and extracts a current data rate from the strength of the signal-to-noise ratio. Calculating a normalized data rate by dividing the current data rate by the maximum data rate; Receiving a usage amount of a network from the base station, calculating a current network load and dividing the current network load by a total network load to calculate a normalized network load; Calculating a cost of a normalized network by dividing a value of a current network cost according to a network type by a sum of total network costs; And calculating the sum of the normalized data rate, the load of the normalized network, and the cost of the normalized network by applying different weights to each network, and selecting a network having the largest value to perform a handover. It includes a step.

According to the above-described configuration, the present invention applies different weights to the data rate extracted from the signal-to-noise ratio, the cost of the network, and the network load, respectively, to determine the selection ratio of the most beneficial Wi-Fi network in terms of cost per data and data rate. It has the effect of increasing and decreasing the relative disadvantage of WiMAX and WCDMA network selection.

1 is a diagram schematically illustrating a configuration of a handover system for performing a vertical handover operating between heterogeneous networks according to an embodiment of the present invention.
2 is a block diagram briefly illustrating an internal configuration of a mobile terminal according to an embodiment of the present invention.
FIG. 3A is a diagram illustrating a network selection ratio when the weight for each case is not considered according to an embodiment of the present invention. FIG.
3B is a diagram illustrating a network selection ratio in the case of considering weight for each case according to an embodiment of the present invention.
4A is a diagram illustrating the cost of an entire network according to an embodiment of the present invention.
Figure 4b is a view showing a Wi-Fi selection rate for each case according to an embodiment of the present invention.
5 is a diagram illustrating a handover method for performing a vertical handover operating between heterogeneous networks in a mobile terminal according to an embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

1 is a diagram schematically illustrating a configuration of a handover system for performing a vertical handover operating between heterogeneous networks according to an embodiment of the present invention.

It is assumed that vertical handover operating between heterogeneous networks is performed based on a common radio resource manager (CRRM) 100.

The CRRM 100 effectively and equally manages available resources of various radio access technologies in a nested radio network so that a user can efficiently manage radio resources such as one radio resource pool.

The CRRM 100 collects network-related information from local radio resource managers (RRMs) 200, 210, and 220 that manage and manage each network, and establishes policy information on traffic redistribution of the network. Here, the local RRM may be variously formed, such as the WCDMA RRM 200, the Wi-Fi RRM 210, and the WiMAX RRM 220.

The CRRM 100 may provide the established policy information to the mobile terminal 400 belonging to the multi-radio network to instruct the mobile terminal 400 to determine a network to access.

The CRRM 100 manages the lower RRMs 200, 210, and 220 according to the state of the network through the information transmitted from the plurality of RRMs 200, 210, and 220.

The CRRM 100 manages radio resources of various radio access technologies. Accordingly, the CRRM 100 can efficiently support a terminal supporting various radio accesses, and it is possible to divide and use respective interfaces for various services.

The CRRM 100 controls the vertical handover operating between heterogeneous networks to be performed in the mobile terminal 400.

2 is a block diagram briefly illustrating an internal configuration of a mobile terminal according to an embodiment of the present invention.

An embodiment of the present invention is a data rate extracted from the strength of the signal to noise ratio (SINR) that has the greatest impact on vertical handover to heterogeneous networks, the cost according to the type of network, and the currently used load of the network. We will look at the performance of the vertical handover reflecting the figure.

The mobile terminal 400 according to an embodiment of the present invention includes a data rate normalization unit 410, a load normalization unit 420, a network cost normalization unit 430, and a network selection unit 440.

The data rate normalization unit 410 receives the SINR from the base station 300, extracts the current data rate from the strength of the SINR, and divides the current data rate by the maximum data rate for normalization to calculate the normalized data rate (N _data ). do.

Where DR _i is Data rate of the network, DR _max represents the maximum data rate of the network.

Table 1 below shows the data rates actually reflected according to SINR for each network.

For example, if the SINR value is 14 dB in the Wi-Fi network, the data rate is 24 Mbps. If the SINR value is 17 dB in the WCDMA network, the data rate is 3.27 Mbps.

The load normalization unit 420 receives the usage of the network from the base station 300, calculates the current network load, and subtracts the value divided by the total network load from the current network load from 1 to normalize the network load (N). Calculate _Load ).

Here, Load _used is the bandwidth currently being _used , and Load _max represents the maximum bandwidth of the network.

The higher the load, the less it will be subtracted from 1. Therefore, if there is a large load, it will have a value close to zero.

The network cost normalization unit 430 divides the current network cost C _i by C _max , which is the sum of total network costs, and subtracts the value from 1 to calculate the N _cost of the normalized network.

The higher the cost of the network to be handed over, the less likely it is to be selected as the target network for vertical handover.

Thus, the aforementioned normalized cost, normalized network load, and normalized data rate may have a value between 0 and 1.

The network selector 440 performs a handover by selecting the network having the largest value by calculating the sum of each weighted value by applying different weights to the normalized data rate, the normalized network load, and the normalized cost. do.

This is shown in Equation 4 below.

는 각 3가지 정규화 요소 간에 사용된 가중치를 나타낸다.Where j is the selected target network,

Denotes the weights used between each of the three normalization elements.

가 모두 1의 값이 된다.If the vertical handover without weighting

Are all 1s.

The network selector 440 may calculate various graphs to be described below by applying the simulator parameters of Table 2 below and the factors considered for each case of Table 3 to the network selection algorithm. Here, the network selection algorithm includes a range of cells, a network cost, a maximum data rate, a terminal speed, a terminal mobility model, a radio channel model, a simulator parameter including an antenna type, a cost of a normalized network, a load of a normalized network, and normalized data. The mobile station 400 selects a network for handover by applying one or more values of the rates.

가 모두 1의 값을 가지게 된다.First, case 1 considers only the normalized data rate value, case 2 considers the normalized data rate value and the cost of the normalized network, and case 3 considers the normalized data rate value and the load of the normalized network. Case 4 considers the normalized data rate value, the load of the normalized network, and the cost of the normalized network. Case 5 considers both the normalized data rate value, the load of the normalized network, and the cost of the normalized network. This is the case considering the weight between normalization factors. Case 1 through Case 4 do not consider weights

Will have all 1s.

3A is a diagram illustrating a network selection ratio when the weight for each case is not considered according to an embodiment of the present invention, and FIG. 3B is a diagram showing a network selection ratio when the weight for each case is considered according to an embodiment of the present invention. to be.

As shown in FIG. 3A, when the load of the normalized network and the cost of the normalized network are reflected, the selection ratio of Wi-Fi which is most advantageous in terms of usage cost per network and a given data rate is shown in Case 4, Case 3, Case 2, Case 1 shows the largest values.

However, as the Wi-Fi selection rate increases, the WiMAX and WCDMA network selection rates, which are relatively disadvantageous in terms of usage cost per network and given data rate, are decreasing.

Therefore, when all three factors are considered, the network selector 440 is the most correct choice when selecting the largest Wi-Fi network.

As shown in FIG. 3A, the Wi-Fi selection rate was higher in order of the load of the normalized network, the cost of the normalized network, and the normalized data rate.

For this reason, we set weights at a ratio of 6: 3: 1 for each load of a normalized network, the cost of a normalized network, and the normalized data rate, so that there is a difference between the performance of the network's selection ratio with weights and the performance without weight. Was compared.

As shown in FIG. 3B, when the weight is set, the Wi-Fi selection rate increases and WiMAX and WCDMA network selection rates decrease.

Therefore, the network selection in the case where the weight is considered is a more correct choice than the network selection in the case where the weight is not considered.

Figure 4a is a view showing the cost of the entire network according to an embodiment of the present invention, Figure 4b is a view showing a Wi-Fi selection rate for each case according to an embodiment of the present invention.

4A calculates the cost of the entire network in case 1, case 4 and case 5 after setting the same number of handovers.

4a shows that the more Wi-Fi is selected and the less WCDMA is more efficient in terms of cost, the more advantageous in terms of the cost of the entire network in the order of Case 5, Case 4, and Case 1.

As shown in Table 2, the cost of the network is calculated according to the number of handovers in FIG. 4A in which the cost of the network is 0.02 for Wi-Fi, 0.2 for WiMAX, and 0.4 for WCDMA.

As shown in Figure 4b, it can be seen that the Wi-Fi selection ratio for each case has a large value in the order of Case 5, Case 4, Case 3, Case 2, Case 1.

As a result, when considering all three factors such as the cost of a normalized network, the load of a normalized network, and the normalized data, and the weighting between the normalized factors, the most beneficial Wi-Fi in terms of cost per network and given data rate Increase the selection rate of the network and reduce the selection ratio of relatively disadvantageous WiMAX, WCDMA networks.

As a result, the method of network selection, taking into account the weighting between three factors and normalization factors, such as the cost of the normalized network, the load of the normalized network, and the normalized data, plays an important role in vertical handover between heterogeneous networks. It can be seen that.

5 is a diagram illustrating a handover method for performing a vertical handover operating between heterogeneous networks in a mobile terminal according to an embodiment of the present invention.

The data rate normalization unit 410 receives a signal-to-noise ratio from the base station 300, extracts a current data rate from the strength of the signal-to-noise ratio, and divides the current data rate by the maximum data rate to calculate a normalized data rate. (Equation 1) (S100).

The load normalization unit 420 receives the network usage from the base station 300, calculates the current network load, and divides the total network load from the current network load to calculate the normalized network load (Equation 2). (S102).

The network cost normalization unit 430 calculates the cost of the normalized network by dividing the value of the current network cost according to the network type by the sum of the total network costs (Equation 3) (S104).

The network selector 440 calculates the sum of each weighted value by applying different weights to the normalized data rate, the normalized network load, and the normalized network cost, and selects the network having the largest value. Over is performed (Equation 4) (S106).

The network selector 440 sets each weight by increasing the size ratio of each weight in the order of the load of the normalized network, the cost of the normalized network, and the normalized data rate.

The network selector 440 may include the normalized data rate, the sum of the normalized data rate and the cost of the normalized network, the sum of the normalized data rate and the cost of the normalized network, the normalized data rate, and the cost of the normalized network. And one case (Case) of the sum of the loads of the normalized network is calculated for each network to select the network having the largest value to perform a handover.

A handover method for performing a vertical handover operating between heterogeneous networks according to an embodiment of the present invention is described as being performed in the mobile terminal 400, but is not limited thereto. The CRRM 100 and the base station 300 may be used. The vertical handover of the mobile terminal 400 may be controlled by configuring modules of the data rate normalization unit 410, the load normalization unit 420, the network cost normalization unit 430, and the network selector 440.

The embodiments of the present invention described above are not implemented only by the apparatus and / or method, but may be implemented through a program for realizing functions corresponding to the configuration of the embodiment of the present invention, a recording medium on which the program is recorded And such an embodiment can be easily implemented by those skilled in the art from the description of the embodiments described above.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Claims (8)

A data normalization unit configured to receive a signal-to-noise ratio from a base station, extract a current data rate from the strength of the signal-to-noise ratio, and divide the current data rate by the maximum data rate to calculate a normalized data rate;
A load normalization unit configured to receive a network usage from the base station, calculate a current network load, and divide the current network load by the total network load to calculate a normalized network load;
A network cost normalization unit calculating a cost of a normalized network by dividing a value of a current network cost according to a network type by a sum of total network costs; And
Performing a handover by selecting a network having the largest value by calculating the sum of each normalized network by applying different weights to the normalized data rate, the load of the normalized network, and the cost of the normalized network. Includes network selection,
The network selecting unit may include a data rate where N _data is normalized, a _load of a network where N _Load is normalized, a _cost of a network where N _Cost is normalized, j is a selected target network,

Represents the weights used between each of the three normalization factors,

Calculate the value for each network using the equation of, select the network with the largest value and perform the handover,
Normalized data rate

Where DR _i Data rate for that network, and DR _max represents the maximum data rate for that network),
The load of the normalized network

(Where Load _used is the bandwidth currently in use and Load _max represents the maximum bandwidth for that network),
Cost of the normalized network

Wherein C _i is the current network cost and C _max represents the sum of the total network costs. The method of claim 1,
And setting the respective weights by decreasing the size ratio of each weight in the order of the load of the normalized network, the cost of the normalized network, and the normalized data rate. delete delete The method of claim 1,
The network selection unit increases the selection rate of a Wi-Fi (Wi-Fi) network, and selects a WiMAX (WideMax) network and a Wideband Code Division Multiple Access (WCDMA) network. A mobile terminal, characterized in that for reducing the ratio. In the handover method for performing a vertical handover operating between heterogeneous networks in a mobile terminal,
Receiving a signal-to-noise ratio from a base station, extracting a current data rate from the strength of the signal-to-noise ratio, and dividing the current data rate by the maximum data rate to calculate a normalized data rate;
Receiving a usage amount of a network from the base station, calculating a current network load and dividing the current network load by a total network load to calculate a normalized network load;
Calculating a cost of a normalized network by dividing a value of a current network cost according to a network type by a sum of total network costs; And
Performing a handover by selecting a network having the largest value by calculating the sum of each normalized network by applying different weights to the normalized data rate, the load of the normalized network, and the cost of the normalized network. Including steps,
N _data is normalized data rate, N _Load is normalized network load, N _Cost is normalized network cost, j is the selected target network,

Represents the weights used between each of the three normalization factors,
Performing the handover,

Calculate the value for each network using the equation of, select the network with the largest value and perform the handover,
Normalized data rate

Where DR _i Data rate for that network, and DR _max represents the maximum data rate for that network),
The load of the normalized network

Where Load _used is the bandwidth currently in use and Load _max represents the maximum bandwidth of the network.
Cost of the normalized network

(Where C _i is the current network cost and C _max represents the sum of the total network costs).
The method of claim 6,
Performing the handover,
The normalized data rate, the sum of the costs of the normalized data rate and the normalized network, the sum of the normalized data rate and the cost of the normalized network, the cost of the normalized data rate and the normalized network Performing a handover by calculating one case of each sum of the values of the normalized network and the load of the normalized network for each network, and selecting the network having the largest value.
Handover method for performing a vertical handover, comprising the. The method of claim 6,
Handover for performing the vertical handover, characterized in that for setting the respective weights by increasing the size ratio of each weight in the order of the load of the normalized network, the cost of the normalized network, the normalized data rate Way.

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