KR20120124119A - Method for network interface according to conversion between different network interfaces - Google Patents

Abstract

PURPOSE: A network interface method is provided to minimize energy which is necessary to maintain network connectivity by converting the network interface into a heterogeneous network interface. CONSTITUTION: A control unit connects a first network interface to a network(S220). When the control unit senses the traffic conversion of the network, the control unit connects a second network interface to the network. The control unit disconnects connection between the first network interface and the network(S240). The second network interface uses smaller energy than the first network interface. [Reference numerals] (AA) Start; (BB) End; (S210) Inputting service execution command?; (S220) A control unit connects a first network interface to a network; (S230) Selecting optimal network interface; (S240) Canceling the connection between the non-selected network interface and internet; (S250) Converting into the simple connecting state; (S260) Setting the communication connection between the minimum electrical power network interface and internet; (S270) Converting the service from the optimal network interface into the minimum electrical power network interface; (S280) Canceling the communication connection between the optimal network interface and internet

Description

Method for network interface according to conversion between different network interfaces}

The present invention relates to a network interface method, and more particularly, to a network interface for communicatively connecting to a network such as the Internet for providing a service to a user.

The decline in network component prices and the diversification of the types of networks that respond to the services required have increased the number of network interfaces in a single device. An example is a laptop computer equipped with a wired / wireless LAN module as a standard, a laptop computer equipped with Bluetooth and WiBro as a standard, a mobile communication module as a standard, and a smartphone equipped with an additional WiFi and Bluetooth. As such, there will be more devices equipped with various types of network interfaces, and the types of network interfaces to be mounted will also be diversified.

In a device equipped with several types of network interfaces, a network and communication connection are established with all network interfaces, and one network interface is selected according to a priority set by a user, and packet transmission and reception are performed.

For example, a device equipped with a wired LAN module and a wireless LAN module and having a higher priority of the wired LAN, accesses the network using both network interfaces, but then transmits and receives all packets only through the wired LAN module. Will be done.

Therefore, as long as the wired LAN is not disconnected, the wireless LAN module connected to the network is not only useless but also serves as a factor of generating unnecessary energy consumption.

The present invention has been made to solve the above problems, an object of the present invention, network interface method through heterogeneous network interface switching that can minimize the energy consumption required to maintain network connectivity, while maintaining network connectivity at all times In providing.

According to an aspect of the present invention, a network interface method includes: a first connection step of connecting to a network through a first network interface; A second connection step of connecting to the network through a second network interface if there is a change in traffic with the network; And releasing a network connection by the first network interface.

And, if the traffic with the network is reduced to the first reference value or more, the second connection step is connected to the network by the second network interface, the second network interface, energy consumption than the first network interface May be a small network interface.

In addition, the second network interface may be a network interface having less bandwidth than the first network interface.

In the case where the traffic with the network is reduced by more than a first reference value, it is preferable that the packet is transmitted and received only for maintaining the connection between the first network interface and the network. .

The network interface method may further include: a third connection step of connecting to the network through the first network interface when there is a change in traffic with the network while the second network interface is connected to the network; And releasing the network connection by the second network interface.

In the third connecting step, when the traffic with the network increases above a second reference value, the third network interface is connected to the network through the first network interface, and the second network interface has a bandwidth greater than that of the first network interface. Less network interfaces can be.

In addition, when the traffic with the network increases above the second reference value, it is preferable that the packet transmission / reception for providing a service is performed between the second network interface and the network.

On the other hand, according to the present invention, the electronic device comprises: a first network interface connectable to the network; A second network interface connectable to the network; And a controller for connecting to the network through the second network interface and releasing the network connection by the first network interface when there is a change in traffic with the network while being connected to the network through the first network interface. It includes;

As described above, according to the present invention, it is possible to minimize the power consumed by the network interface while maintaining the connection of the network service. In particular, it is possible to minimize the power consumption at the network interface when only a simple connection is maintained, which is more effective in reducing energy consumption wasted at night or weekends when the system is not used.

In addition, since only one of the plurality of network interfaces connectable to the network can be connected to the network to provide a service to the user, redundant energy consumption due to the plurality of network interfaces can be prevented.

In addition, it is possible to prevent electronic devices from consuming more energy and occupying more bandwidth than necessary to maintain a simple connection, thereby maintaining optimal network conditions.

1 is a block diagram of a notebook computer to which the present invention is applicable;
2 is a flow chart provided in the description of the process of automatically switching the network interface to the lowest power network interface, and
3 is a flowchart provided to explain the process of automatically reducing from the lowest power network interface to the appropriate network interface.

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

1 is a block diagram of a notebook computer to which the present invention is applicable. As illustrated in FIG. 1, the notebook computer 100 includes a storage unit 110, a monitor 120, a controller 130, an input unit 140, and a network interface 150.

The storage unit 110 is a space in which programs and data performed by the controller 130 are stored, and the monitor 120 is a display which displays the computing result by the controller 130 and provides the result to the user, and the input unit 140. Is a user input means for receiving a user command and transferring it to the controller 130.

The network interface 150 is communicatively connected to the Internet I and has a plurality of heterogeneous network interfaces 151, 152, 153 and 154. Specifically, as illustrated in FIG. 1, the network interface 150 includes an Ethernet interface 151, a WLAN interface 152, a Bluetooth interface 153, and a Zigbee interface 154.

1) Ethernet interface 151 is connected to communicate with the Internet (I) in accordance with the Ethernet (Ethernet) communication standards,

2) The WLAN interface 152 is connected to communicate with the Internet (I) according to the Wireless Local Area Network (WLAN) communication standard,

3) The Bluetooth interface 153 is connected to communicate with the Internet (I) in accordance with Bluetooth (Bluetooth) communication standards,

4) The Zigbee interface 154 is connected to communicate with the Internet (I) according to the Zigbee communication standard.

The network interfaces 151, 152, 153, and 154 not only have different communication standards, but also show differences in bandwidth and energy consumption.

Specifically, the bandwidth is "Ethernet interface 151> ii) WLAN interface 152> Bluetooth interface 153> Zigbee interface 154. The energy consumption is also "Ethernet interface 151> ii) WLAN interface 152> Bluetooth interface 153> Zigbee interface 154. Therefore, energy consumption may be said to be proportional to the bandwidth.

All or some of the network interfaces 151, 152, 153 and 154 can be connected to the Internet I, which is under the control of the controller 130 and will be described in detail below.

FIG. 2 is a diagram provided to explain a process of automatically switching a network interface to a lowest power network interface by the control unit shown in FIG. 1.

As shown in FIG. 2, first, when a service execution command is input from a user through the input unit 140 (S210-Y), the controller 130 may control all network interfaces 151 and 152 provided in the network interface 150. 153 and 154 establish a connection with the Internet (I) (S220).

It is assumed that the service (application) to be executed in step S210 is a service that requires a constant connection such as P2P, social network, VoIP service, and the like. This service requires that the control unit 130 maintains the connection with the Internet I through the network interface, even if the user is currently using the service, but not for a short time or for a relatively long time. Service.

Thereafter, the controller 130 selects an appropriate network interface in consideration of traffic by the running service (S230).

When the network interface is selected in step S230, power consumption may be further considered in addition to the bandwidth of the network interface. For example, when the interfaces having a bandwidth capable of handling traffic by a service are the Ethernet interface 151 and the WLAN interface 152, the WLAN interface 152 with low power consumption is selected.

However, other criteria (e.g., priority, etc.) other than power consumption may be considered, and of course, it is possible to implement which criteria are selected by the user.

The controller 130 releases the communication connection between the network interfaces not selected in step S230 and the Internet I (S240). Accordingly, only the appropriate network interface selected in step S230 among the network interfaces 151, 152, 153, and 154 that establishes a connection with the Internet I in step S220 maintains connection with the Internet I.

Thereafter, the controller 130 determines whether the connection state between the appropriate network interface selected in step S230 and the Internet I is switched to a simple connection state (S240).

The 'simple connection state' is a state in which packet transmission and reception for providing a service is not performed between an appropriate network interface and the Internet I, and only packet transmission and reception for simple connection maintenance is performed. For example, the VoIP service refers to a state in which a VoIP gateway device periodically sends a packet to the notebook computer 100 and receives a response to determine whether the VoIP service is present even while the actual call service is not performed.

In a simple connection state, the traffic between the appropriate network interface and the Internet I is severely reduced than the traffic state in the service provision state.

Therefore, the determination as to whether or not the connection state between the appropriate network interface and the Internet I has switched to the simple connection state is based on whether there has been a change in the traffic between the appropriate network interface and the Internet I, and specifically, When the traffic decreases above a predetermined threshold, it may be determined that the traffic has changed to a simple connection state.

If it is determined in step S250 that the connection state between the appropriate network interface and the Internet (I) is a simple connection state (S250-Y), the controller 130 establishes a communication connection between the lowest power network interface and the Internet (I) (S260). In operation S270, the interface for providing the service is switched from the appropriate network interface to the lowest power network interface.

The lowest power network interface is a network with the least power consumption, and the Zigbee interface 154 corresponds to this. ZigBee interface 154, although small in bandwidth, is sufficient to handle packets sent and received in a simple connection.

Then, the controller 130 releases the communication connection between the appropriate network interface and the Internet (I) (S280).

Accordingly, it is possible to minimize the energy consumption required to maintain Internet connectivity while maintaining Internet connectivity at all times.

Hereinafter, a description will be given in detail of the process of automatically reducing from the lowest power network interface to the appropriate network interface by the control unit shown in FIG. 1 with reference to FIG. 3.

As shown in FIG. 3, first, when the network interface is switched to the lowest power network interface (S310), the controller 130 determines whether the connection state between the lowest power network interface and the Internet I is a service providing state (S320). ).

The 'service providing state' is a state in which packet transmission and reception for providing a service is performed between the lowest power network interface and the Internet (I). In the service provision state, the traffic between the lowest power network interface and the Internet I is significantly increased than the traffic in the simple connection state.

Therefore, the determination of whether the connection state between the lowest power network interface and the Internet I has changed from a simple connection state to a service providing state is based on whether there is a change in traffic between the lowest power network interface and the Internet I. Specifically, when traffic increases above a predetermined threshold, it may be determined that the service has changed to a service providing state.

If it is determined in step S320 that the connection state between the lowest power network interface and the Internet I is a service providing state (S320-Y), the controller 130 establishes a communication connection between the appropriate network interface and the Internet I (S330). In operation S340, the interface for providing the service is switched from the 'lowest power network interface' to the 'suitable network interface'.

The appropriate network interface in step S340 refers to the network interface selected in S230 of FIG. 2.

In addition, the controller 130 releases the communication connection between the lowest power network interface and the Internet I (S350).

Meanwhile, even when the connection state between the lowest power network interface and the Internet I is switched to the service providing state, if a user command is input through the input unit 140, steps S330 to S350 may be performed. Do.

The notebook computer mentioned above is a kind of electronic device to which the technical idea of the present invention is applicable. Therefore, the present invention is applicable to other electronic devices other than notebook computers, for example, mobile devices such as tablet PCs and smartphones, as well as stationary devices such as desktop PCs and TVs.

In addition, the above-mentioned network interfaces are also exemplary only. Therefore, the technical spirit of the present invention may be applied to the case where all or part of the mentioned network interfaces are replaced with other network interfaces or other network interfaces not mentioned are added.

In addition, the above case is assumed that the communication connection to the Internet, but this is also merely an example for convenience of description, it should be noted that the technical idea of the present invention can be applied even when connecting to a network other than the Internet. do.

In addition, it is possible to implement a service switching to a "low power" network interface rather than a "low power" network interface when the simple connection state transition.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention.

100: notebook computer 110: storage unit
120: monitor 130: control unit
140: input unit 150: network interface
151: Ethernet interface 152: WLAN interface
153: Bluetooth Interface 154: Zigbee Interface
I: Internet

Claims (8)

A first connection step of connecting to a network with a first network interface;
A second connection step of connecting to the network through a second network interface if there is a change in traffic with the network; And
Releasing a network connection by the first network interface.
The method of claim 1,
The second connection step,
If the traffic with the network decreases above the first threshold, connect to the network via the second network interface,
The second network interface is a network interface method, characterized in that less energy consumption than the first network interface.
The method of claim 2,
The second network interface is a network interface method, characterized in that less bandwidth than the first network interface.
The method of claim 2,
If the traffic with the network is reduced by more than the first reference value,
The network interface method, characterized in that between the first network interface and the network, only the transmission and reception of packets to maintain the connection is performed, not the transmission and reception of packets for providing services.
The method of claim 1,
A third connection step of connecting to the network through the first network interface when there is a change in traffic with the network while being connected to the network through the second network interface; And
Releasing a network connection by the second network interface.
6. The method of claim 5,
The third connection step,
If traffic with the network increases above a second threshold, connect to the network via the first network interface,
The second network interface is a network interface method, characterized in that less bandwidth than the first network interface.
The method according to claim 6,
If the traffic with the network increased above the second threshold,
And a case where packet transmission / reception is performed between the second network interface and the network to provide a service.
A first network interface connectable to the network;
A second network interface connectable to the network; And
A control unit for connecting to the network through the second network interface and releasing the network connection by the first network interface when there is a change in traffic with the network while being connected to the network through the first network interface; Electronic device comprising a.

Images