KR20100127379A - Wireless network system and connecting method thereof - Google Patents

Abstract

PURPOSE: A wireless network system and a method for connecting the network are provided to realize the rapid correspondence according to the change of the network state without pause of the data stream during moving a wireless terminal. CONSTITUTION: A Doppler frequency calculator(10) calculates a Doppler frequency value about an AP available for access within network if the wireless terminal is accessed to the network. An IP management unit(40) manages IP resources within the network. The IP management unit generates a tree about the IP resources within the network. A network connection controller(50) controls the network connection about a wireless terminal.

Description

Wireless network system and connecting method thereof

The present invention relates to a wireless network system and a network connection method, and more particularly, when a wireless terminal accesses a network, by selecting an IP resource having a good state with respect to an IP resource in the network, the wireless network system can be connected. The present invention relates to a wireless network system and a network connection method capable of efficiently managing an IP resource while ensuring mobility of a wireless terminal.

Today, the spread of Internet services is becoming more common due to the accelerated infrastructure construction of the high-speed Internet network and the low Internet usage rates.The continuous development of the Code Division Multiple Access (CDMA) mobile communication technology and the provision of wireless Internet services using the same In addition, anytime, anywhere Internet access is possible using wireless terminals. Users who want to use the Internet in an environment where a wireless local area network is established can use a high-speed Internet service at home, school, or office using a wireless terminal.

A wireless local area network (WLAN) may use a high speed internet service through a mobile terminal within a certain distance centering on an access point (AP). Therefore, the wireless local area network overcomes the space limitations of the existing wired Internet access environment and provides a communication environment that can use the Internet anytime and anywhere wirelessly.

Compared with the wired Internet and the wireless Internet, the wired network is 2 Mbps in terms of transmission speed, while the wireless network is 64 Kbps, so the wireless network is slower than the wired network. The content for wired Internet access is standardized globally as Hyper Text Markup Language (HTML) using TCP / IP (Transmission Control Protocol / Internet Protocol), but WML, using TCP / IP and WAP (Wireless Application Protocol) in wireless Internet, It is not standardized with m-HTML and c-HTML. In addition, in terms of portability, while the wireless Internet guarantees free mobility, the wired Internet is extremely limited in mobility, and in terms of data storage, many restrictions are imposed due to the capacity and processing speed of the mobile terminal. Is superior in terms of storage capacity and speed.

Meanwhile, in order to guarantee the mobility of the wireless terminal, when the wireless terminal moves in a network, a smooth connection to an access point existing in the network should be ensured. To this end, adjacent access points are handed off sequentially to a moving wireless terminal, thereby ensuring a continuous network connection of the wireless terminal.

However, such a method of connecting to a wireless network may cause a temporary blockage of a connection at the moment when the handoff is performed from an access point close to the wireless terminal to the next access point. In particular, when receiving a data stream from a server using a wireless terminal, there is a problem that reception of the data stream is temporarily stopped at the time of handoff.

In addition, since the conventional wireless network connection method does not consider fading or transmission loss of a signal in a free space that is a transmission path of radio waves, reception sensitivity is decreased due to a change in transmission status or an obstacle blocking the flow of radio waves. In this case, there is a problem that a quick response is difficult.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and a wireless network system and a method for connecting a network to enable a quick response process according to a change in network state without interrupting a data stream while the wireless terminal is moving. It aims to provide.

A first embodiment of a wireless network system according to the present invention for achieving the above object is to calculate a Doppler frequency value for each AP (access point) accessible in the network when the wireless terminal accesses the network. Doppler frequency calculator; An IP manager configured to manage an Internet Protocol (IP) resource in the network and to generate a tree for the IP resource in the network based on a value calculated by the Doppler frequency calculator; And a network connection control unit for controlling a network connection to the wireless terminal based on the tree generated by the IP management unit.

The wireless network system may further include a gain calculator configured to calculate a gain value for compensating an irregular signal level to a certain level for each accessible AP in the network.

The wireless network system may further include a signal detector for detecting the strength of a network signal between the wireless terminal and each AP based on the calculated Doppler frequency value and the gain value.

In this case, the IP manager preferably groups the IP resources in the network based on the strength of the signal detected by the signal detector, and generates a tree for the grouped IP resources.

Preferably, the network connection controller controls the network to be connected using the IP resource in the tree generated by the IP management unit.

A second embodiment of a wireless network system according to the present invention for achieving the above object is a gain calculation unit for calculating a gain value for compensating the level of the irregular signal to a constant level for each accessible AP in the network; An IP management unit which manages IP resources in the network and generates a tree for the IP resources in the network based on the value calculated by the gain calculator; And a network connection control unit for controlling a network connection to the wireless terminal based on the tree generated by the IP management unit.

Here, the IP manager preferably generates a tree so that the IP resource in the network becomes higher as the value calculated by the gain calculator decreases.

The network connection method according to the present invention for achieving the above object, in a method for supporting a network connection, when a wireless terminal accesses a network, calculating a Doppler frequency value for each accessible AP in the network step; Managing an IP resource in the network, and generating a tree for the IP resource in the network based on the calculated Doppler frequency value; And controlling a network connection to the wireless terminal based on the generated tree.

Preferably, the network connection method further includes calculating a gain value for compensating the irregular signal level to a constant level for each accessible AP in the network.

In addition, the network connection method may further include detecting the strength of a network signal between the wireless terminal and the respective AP based on the calculated Doppler frequency value and the gain value.

The network connection method may further include grouping IP resources in the network based on the detected strength of the network signal. In this case, the tree generation step generates a tree for the grouped IP resources.

Preferably, the network connection step controls the network to be connected using the IP resources of the generated tree.

As a result, the wireless network system and the method for connecting the network according to the present invention enable rapid response processing in accordance with the change of the network state without interrupting the data stream while the wireless terminal is moving.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention. However, the embodiments of the present invention described below are provided to enable those skilled in the art to more easily understand the present invention, and the scope of the present invention is not limited to the described embodiments.

1 is a diagram schematically illustrating a wireless network system according to the present invention. Referring to the drawings, the wireless network system may include a Doppler frequency calculator 10, a gain calculator 20, a signal detector 30, an IP manager 40, and a network connection controller 50.

When the wireless terminal (not shown) approaches the network, the Doppler frequency calculator 10 calculates Doppler frequency values for each accessible AP (not shown) in the network. In general, a wireless local area network environment includes a plurality of APs in a network. In this case, each AP and the wireless terminal may have different strengths of signals transmitted and received according to distances between the wireless terminal and the AP, radio wave obstacles between the wireless terminal and the AP, and whether the wireless terminal approaches or moves away from the AP. In the present invention, in order to reflect such factors, the Doppler frequency value for each accessible AP in the wireless terminal and the network is calculated and reflected in the network connection.

Here, the Doppler frequency refers to the frequency measured using the Doppler effect found by Christian Johann Doppler (1803-1853). The Doppler effect is called the change in frequency and wavelength depending on the wave source of a wave and the relative velocity of the observer.

In a wave moving through a medium, such as sound, the effect varies depending on the relative velocity of the observer and the source of the wave. However, for waves that do not require a medium, such as gravity in light or special theory of relativity, only the relative velocities of the observer and the source of wave affect the Doppler effect.

In classical physics, the observed frequency (frequency) f and the emitted frequency f ₀ are given by

Where v is the velocity in the medium of the wave and v _s is the velocity of the radio source relative to the medium. Also, v _r is the velocity of the observer relative to the medium. The two speeds, v _s and v _r, increase when the observed frequency moves toward or away from the source. Also, when they are far from each other, the frequency decreases.

Equation 1 assumes a situation in which a radio source directly approaches or moves away. As the radio source approaches the observer at a certain angle and speed, the observed frequency is initially higher than the emitted frequency and then monotonously decreases as it approaches the observer. When they approach the observer most, they become the same and decrease monotonically as they move away.

If the observer is very close to the object's path, it will change rapidly from high to low, and if it is far from the path, it will change slowly.

If the velocity of the wave is much greater than the relative velocity of the source and observer (e.g. electromagnetic or light), then the observed frequency f and the emitted frequency f ₀ are given by

Where v _{s, r} = v _s -v _r is the velocity of the source for the observer. Negative values move toward the viewer and negative values move away from the viewer. In addition, c is the velocity of the wave (for example, 3 m10 ⁸ m / s for the electromagnetic wave which proceeds with vacuum). Λ ₀ is the wavelength of the propagating radio wave at the coordinate of the emission source.

The frequency entering the transceiver is transmitted / received at a frequency slightly out of a predetermined frequency according to the transmission state in the free space, and also by the Doppler effect. In the present invention, the Doppler frequency for the frequency of the input signal is calculated by using AFC (Adaptive Frequency Control).

If a memory having a calculated Doppler frequency value is provided, information about a previous state can be obtained from the memory, and thus a state measurement of the Doppler frequency can be recorded to enable more efficient state measurement.

The Doppler phenomena, where the wave source is far from the observer and the Doppler frequency is lowered and the frequency is closer, can be indirectly obtained for the distance between the wireless terminal and the AP or the moving speed of the wireless terminal. As the distance between them becomes weaker, the wireless terminal can be used as a criterion to change other nearby signals to a strong AP or to select another IP router. At this time, the probability model may be used to actively determine a state by using fading or jitter of a wireless signal input from various paths, or a distance or a network state may be determined by simply comparing a magnitude and a change state of a Doppler frequency.

The gain calculator 20 calculates a gain value for compensating the irregular signal level to a constant level for each accessible AP in the network. In order to keep the signal weakened by various factors generated in the free space at a constant quality, it is necessary to compensate for the irregular input level to a certain level, for which an AGC (Automatic Gain Control) circuit can be used. That is, in the wireless network, the magnitude of the frequency to be transmitted and received over time is not constant. In this case, the AGC module is used to maintain a constant quality of the transmitted and received signal. At this time, if the control unit of AGC is out of the threshold derived from the following equation, the number of times and the interval become larger or if the interval becomes shorter, it means that the signal from free space is far away or weakened by obstacles. In addition, the network state may be determined using the same. In this case, as in the Doppler frequency use, the network state probability model may be used, or the state level may be determined only by simple state comparison.

That is, the threshold is the average of the collected AGC change values within a certain range.

At this time, it may be assumed that the smaller the gain value for compensating the irregular input level to a constant level, the better the communication status between the corresponding AP and the wireless terminal.

The signal detector 30 is configured to generate a signal between the wireless terminal and each AP based on the Doppler frequency value and the gain value between the wireless terminal and each AP calculated by the Doppler frequency calculator 10 and the gain calculator 20. Detect the strength of the network signal. In this case, the signal detector 30 may detect the strength of the network signal in consideration of the strength of the wireless power signal between the wireless terminal and each AP.

The IP management unit 40 manages Internet Protocol (IP) resources in the network. Here, the IP resource refers to a communication resource that is connected to a wired network, receives an IP address, gives a lower IP address to a resource connected to the lower part, or transmits and receives data using its own IP address.

At this time, the IP manager 40 sorts the IP resources in the network based on the values calculated by the Doppler frequency calculator 10 and generates a tree for them. That is, the IP manager 40 classifies the IP resource according to the communication state based on the Doppler frequency value calculated by the Doppler frequency calculator 10 and generates a tree accordingly.

Alternatively, the IP manager 40 may sort the IP resources in the network based on the gain value calculated by the gain calculator 10 and generate a tree thereof. That is, in this case, the IP manager 40 may classify the IP resource according to the communication state based on the gain value calculated by the gain calculator 20 and generate a tree accordingly.

Alternatively, the IP manager 40 corrects the gain value calculated by the gain calculator 20 to the Doppler frequency value calculated by the Doppler frequency calculator 10, and accordingly, communicates with the wireless terminal to each AP. The state may be determined to generate a tree for the IP resource.

Alternatively, the IP management unit 40 may determine the Doppler frequency value between the wireless terminal calculated by the Doppler frequency calculator 10 and each AP, and the gain between the wireless terminal calculated by the gain calculator 20 and each AP. Based on the value or the strength of each network signal detected by the signal detector 30, IP resources in the network according to the communication status may be grouped and a tree for each group may be generated.

The network connection control unit 50 controls the network connection to the wireless terminal based on the tree generated by the IP management unit 40. That is, when the IP management unit 40 arranges the IP resources according to the network state between the wireless terminal and each AP and generates a tree thereof, the network connection control unit 50 is added to the tree generated by the IP management unit 40. Based on the connection between the wireless terminal and the AP. In this case, when the network status of the AP and the wireless terminal to which the current IP is assigned becomes worse, since the IP resources are generated in the IP management unit 40 in a tree structure, the network connection control unit 50 may be configured between the current AP and the wireless terminal. As network conditions worsen, data transmission and reception with a wireless terminal can be continuously performed using IP resources in the following order.

FIG. 2 is a flowchart illustrating a network connection method by the wireless network system of FIG. 1.

Referring to the drawing, when the wireless terminal approaches the network, the Doppler frequency calculator 10 calculates the Doppler frequency value for each accessible AP in the network (S101), and the gain calculator 20 is in the network. A gain value for compensating an irregular signal level to a constant level is calculated for each accessible AP (S103). In addition, the signal detector 30 may determine whether the signal detection unit 30 is connected between the wireless terminal 10 and each AP based on the Doppler frequency value calculated by the Doppler frequency calculator 10 and the gain value calculated by the gain calculator 20. The strength of the network signal is detected at step S105. At this time, the strength of the network signal detected by the signal detection unit 30 is shown in Fig. 3 as shown in FIG. The data transmitted / received between the software (Network Driver Software) can be detected using the Doppler frequency value and the gain value.

The IP manager 40 sorts the IP resources in the network according to the network state calculated by the Doppler frequency calculator 10, the gain calculator 20, the signal detector 30, or a combination thereof. Each IP resource may be grouped into a group having a predetermined value or more and a group less than that, and a tree for each group may be generated (S107 and S109). In this case, as shown in FIG. 4, the IP manager 40 may form various groups for IP resources in the network by distance or by signal strength.

The network connection controller 50 controls the network connection to the wireless terminal based on the tree generated by the IP manager 40 (S111). In this case, as described above, when a tree is generated for each group having various IP resources, the network connection controller 50 may change the network state of the upper network to a good IP resource when the network state between the wireless terminal and the current AP is worsened. Among other IP resources belonging to the same group, the current data transmission and reception are continuously performed using the IP resources with good network status. When the conversion to the higher IP resource is completed, the data transmission and reception are continuously performed through the higher IP resource. Will continue.

As described above, the IP layer is used to continuously receive the image, and the current IP layer is defined as an active IP and a neighboring IP layer as a candidate is defined as a candidate IP stage. At this time, the active IP is allocated an arbitrary IP layer from the candidate IP layer to use network resources, and the candidate IP generates the IP tree as much as the amount of memory available to the system. If necessary, replace the assigned IP address with one of the candidate layers.

Although the preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the specific embodiments described above, and the present invention is not limited to the specific embodiments of the present invention without departing from the spirit of the present invention as claimed in the claims. Anyone skilled in the art can make various modifications, as well as such modifications are within the scope of the claims.

1 is a block diagram schematically illustrating a wireless network system according to the present invention.

FIG. 2 is a flowchart illustrating a network connection method by the wireless network system of FIG. 1.

3 is a diagram illustrating an example of signal detection by a signal detection unit.

4 is a diagram illustrating an example of a tree structure generated by the IP management unit.

Description of the Related Art

10: Doppler frequency calculator 20: Gain calculator

30: signal detection unit 40: IP management unit

50: network connection control unit

Claims (12)

A Doppler frequency calculator for calculating a Doppler frequency value for each accessible AP in the network when the wireless terminal approaches a network; An IP manager configured to manage an Internet Protocol (IP) resource in the network and to generate a tree for the IP resource in the network based on a value calculated by the Doppler frequency calculator; And And a network connection control unit for controlling a network connection to the wireless terminal based on the tree generated by the IP management unit. The method of claim 1, And a gain calculator configured to calculate a gain value for compensating an irregular signal level to a predetermined level for each accessible AP in the network. 3. The method of claim 2, And a signal detector for detecting the strength of a network signal between the wireless terminal device and each AP based on the calculated Doppler frequency value and the gain value. The method of claim 3, wherein The IP management unit groups the IP resources in the network based on the strength of the signal detected by the signal detection unit, and generates a tree for the grouped IP resources. The method according to claim 1 or 4, The network connection control unit is a wireless network system, characterized in that for controlling the network connection using the IP resources of the tree generated by the IP management unit. A gain calculator for calculating a gain value for compensating an irregular signal level to a constant level for each accessible AP in the network; An IP management unit which manages IP resources in the network and generates a tree for the IP resources in the network based on the value calculated by the gain calculator; And And a network connection control unit for controlling a network connection to the wireless terminal based on the generated tree. The method of claim 6, And the IP manager generates a tree with respect to IP resources in the network so as to be higher as the value calculated by the gain calculator decreases. When the wireless terminal accesses the network, in a method for supporting a network connection, Calculating a Doppler frequency value for each accessible AP in the network; Managing an IP resource in the network, and generating a tree for the IP resource in the network based on the calculated Doppler frequency value; And And controlling a network connection to the wireless terminal based on the tree generated by the IP management unit. The method of claim 8, And calculating a gain value for compensating an irregular signal level to a predetermined level for each accessible AP in the network. The method of claim 9, Detecting the strength of a network signal between the wireless terminal and the respective AP based on the calculated Doppler frequency value and the gain value. The method of claim 10, Grouping the IP resources in the network based on the detected strength of the network signal; The tree generation step is a wireless network connection method, characterized in that for generating a tree for the grouped IP resources. The method of claim 8 or 11, The network connection step is a wireless network connection method, characterized in that for controlling the network connection using the IP resources of the generated tree.

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