TW201532467A - Manufacaturing method of controlling wireless network device for network connectivity - Google Patents

Abstract

This invention provides a manufacturing method of a controlling wireless network device for network connectivity. The method includes the following steps, receiving a control signal from a mobile communication device; receiving multiple connection signals emitted by multiple base stations; measuring the signal strength of the connection signals emitted by the base stations to judge which is the communications signal having the maximum signal strength; connecting to the base station emitted the communications signal having the maximum signal strength; applying the mobile communication device to connecting to the controlling wireless network device through the base station emitted the communications signal having the maximum signal strength.

Description

Method for controlling wireless network device to perform network connection

The invention relates to a method for controlling a wireless network device to perform network connection, and in particular to a method for improving the receiving quality of a mobile communication device.

When using the mobile communication device, the user can perform a wireless transmission through the base station, for example, through the 3G signal transmitted by the mobile phone base station. Generally speaking, the strength of the communication signal of the mobile communication device base station is often affected by the external environment (for example, decoration, equipment, walls, etc.), and the signal strength of the user when using the mobile communication device may be due to the ground. different. Even when the boundary of the wireless network space covered by the base station is located, the wireless network signal received by the mobile communication device from the base station will be weaker.

Therefore, when the user uses the mobile communication device in the mobile state, the mobile communication device changes the communication strength of the received base station according to the location. In order to enhance the wireless network signals received by the mobile communication device, the user usually needs to move the location of the mobile communication device by himself, away from the shelter, or manually adjust the angle of the mobile communication device. Under this circumstance, it is difficult for the user to grasp the better location of the reception.

In addition, as the mobile communication device moves to a different location, the built-in antenna of the mobile communication device will re-search for nearby base station signals and connect with the connectable base station as the mobile device moves. In this situation, the power consumption of mobile communication devices is relatively rapid.

Embodiments of the present invention provide a method for controlling a wireless network device to perform network connection, which can improve signal quality of a mobile communication device.

Embodiments of the present invention provide a method for controlling a wireless network device to perform network connection. The method for controlling a wireless network device to perform network connection includes receiving a control signal from a mobile communication device. Receiving a plurality of communication signals transmitted by a plurality of base stations. The signal strength of the communication signals transmitted by the base stations is measured to determine the communication signal having the highest signal strength value. Connect to the base station that transmits the communication signal with the highest signal strength value. The mobile communication device is provided for connection through the base station of the communication signal having the highest intensity value.

In summary, the embodiments of the present invention provide a method for a wireless network device to perform network connection. The mobile communication device is connected to a wireless network device through a control signal, and the first antenna receives the communication signal transmitted by the at least one base station, and the processing unit determines the communication signal having the maximum signal intensity value and generates the driving signal to the antenna steering control. The unit, the antenna steering control unit receives the driving signal to drive the first antenna to switch to the base station that transmits the communication signal with the maximum signal strength value. That is to say, by controlling the rotation angle of the first antenna, the first antenna is connected to the base station with the best communication signal. Then, the best communication signal is transmitted to the mobile communication device through the second antenna, thereby improving the quality of the communication signal received by the mobile communication device.

Accordingly, the method for performing network connection by the wireless network device provided by the present invention can replace the function of the antenna search base station signal built in the mobile communication device as compared with the conventional method for network connection. Therefore, when the user uses the mobile communication device in the mobile state, the built-in antenna of the mobile communication device does not need to search for a better base station signal with different locations, and the mobile communication device is automatically upgraded. Efficacy and saving power for mobile communication devices.

In order to further understand the technology, method and effect of the present invention in order to achieve the intended purpose, reference should be made to the detailed description and drawings of the present invention. Understand, of course The drawings and the annexed drawings are only for the purpose of illustration and description, and are not intended to limit the invention.

100‧‧‧Wireless network device

110‧‧‧first antenna

120‧‧‧second antenna

130‧‧‧Processing unit

140‧‧‧ storage unit

150‧‧‧Antenna Steering Control Unit

200‧‧‧Mobile communication equipment

300‧‧‧Base station

S101~S106‧‧‧Step procedure

1 is a functional block diagram of a wireless network device according to a first embodiment of the present invention.

2 is a flow chart showing the steps of the wireless network device of the first embodiment of the present invention.

3 is a schematic diagram showing the operation of the wireless network device of the first embodiment of the present invention.

1 is a functional block diagram of a wireless network device according to a first embodiment of the present invention. Referring to FIG. 1, a wireless network device 100 is shown wirelessly coupled to a base station 300, and a wireless network device 100 is coupled to the mobile communication device 200. The wireless network device 100 is configured to receive or transmit with the base station 300. The wireless network device 100 is configured to receive a control signal generated by the mobile communication device 200 and transmit or receive a data signal with the mobile communication device 200. The wireless network device 100 includes a first antenna 110, a second antenna 120, a processing unit 130, a storage unit 140, and an antenna steering control unit 150. The first antenna 110 and the second antenna 120 are coupled to the processing unit 130, respectively. The processing unit 130 is coupled to the storage unit 140. The antenna steering control unit 150 is coupled to the first antenna 110 and the processing unit 130. It is to be noted that in the embodiment of the present invention, the wireless network device 100 will be emphasized. Those skilled in the art should understand the functions of the base station 300 and the mobile communication device 200, and details are not described herein.

The wireless network device 100 is configured to provide the mobile communication device 200 for connection. More specifically, the wireless network device 100 can serve as a relay node between the mobile communication device 200 and the base station to provide the mobile communication device 200 for signal transmission. In the embodiment of the present invention, the wireless network device 100 may be a Wifi access point, a Bluetooth connection device, or other access device with a wireless transmission function, but the present invention does not As a restriction.

The first antenna 110 is configured to transmit a data signal from the mobile communication device 200 or to receive an information signal sent by the base station 300. It is worth mentioning that In the embodiment of the present invention, the first antenna 110 is a directional antenna, and those skilled in the art should understand that an antenna array, an omnidirectional antenna, or the like can also be used. The antenna is an embodiment, and the invention is not limited thereto.

The second antenna 120 is configured to receive a control signal or a data signal sent by the mobile communication device 200 or to send an information signal to the mobile communication device 200. In the embodiment of the present invention, the second antenna 120 is an omnidirectional antenna. It should be noted that the second antenna 120 may also be implemented by other antennas, and the invention is not limited thereto. In addition, in the embodiment of the present invention, the wireless network device 100 and the mobile communication device 200 can also be connected in a wired manner. For example, the mobile communication device 200 can directly connect to the wireless network device 100 through the data transmission line, and wirelessly transmit the control signal or the data signal to the base station 300 through the wireless network device 100.

The processing unit 130 is configured to provide a function of the arithmetic processing of the wireless network device 100. In detail, when the wireless network device 100 receives the control signal from the mobile communication device 200, the processing unit 130 further generates an instruction to control the antenna steering control unit 150 to adjust the direction of the first antenna 110. When the wireless network device 100 receives the data signal from the first antenna 110 or the second antenna 120, or before the wireless network device 100 transmits the data signal base station 300 or the mobile communication device 200, the processing unit 130 Further signal or code conversion.

For example, the first antenna 110 is a transmitting and receiving antenna of a 3G signal, and the second antenna 120 is a transmitting and receiving antenna of a Wifi signal. Therefore, when the wireless network device 100 receives the data signal from the base station 300, the wireless network device 100 further converts the 3G data signal into a Wifi signal for transmission. In addition, during the conversion process, the processing unit 130 may further encrypt encode the data signal (instead, decoding) to provide increased security during forwarding. Conversely, when the wireless network device 100 receives the data signal from the wireless network device 100, the data signal of the Wifi signal is further converted into a 3G signal for transmission.

It is worth mentioning that the processing unit 130 further provides whether the detection is between the first antenna 110 and the base station 300, and whether the connection between the second antenna 120 and the mobile communication device 200 is unblocked. If one of the links is interrupted, the processing unit 130 may further temporarily store the received data signal in the storage unit 140. For example, when the connection between the wireless network device 100 and the base station 300 is interrupted (for example, when the base station with strong signal is reselected for connection), the mobile communication device 200 and the wireless network at this time. The device 100 is still in a connected state, so the wireless network device 100 temporarily stores the received data signal from the mobile communication device 200 in the storage unit 140 and waits for the wireless network device 100 to reconnect with the base station 300 before transmitting. . On the other hand, if the base station 300 and the wireless network device 100 are in the connected state, and the mobile communication device 200 and the wireless network device 100 are interrupted, the wireless network device 100 temporarily stores the received data signal from the base station 300 in the storage. In the unit 140, the wireless network device 100 waits for the connection with the mobile communication device 200 to resume transmission.

The storage unit 140 is configured to store various information required by the wireless network device 100 during transmission. More specifically, the storage unit 140 can provide the wireless network device 100 to store the searched base station 300 data and the mobile communication device 200 data connected thereto. The data may be the signal strength, location information, device information, and the like of the base station 300 or the mobile communication device 200. For example, the wireless network device 100 can directly connect according to the historical base station location information stored by the storage unit 140 and according to its own location information. In addition, the storage unit 140 is configured to provide a temporary storage function during the data signal transmission process. In the embodiment of the present invention, the storage unit 140 may be implemented by a non-volatile/volatile storage unit (such as a ROM or a RAM), and the invention is not limited thereto.

The antenna steering control unit 150 is configured to receive an instruction from the processing unit 130 such that the antenna steering control unit 150 controls the rotational direction of the directional antenna 120 according to the command. The antenna steering control unit 150 can be implemented by a motor, but the invention is not limited thereto.

2 is a flow chart showing the steps of the wireless network device of the first embodiment of the present invention. 3 is a schematic diagram showing the operation of the wireless network device of the first embodiment of the present invention. Please refer to Figure 2 and Figure 3.

Step S101 is executed to receive a control signal from the mobile communication device. In detail, when the mobile communication device 200 sends a control signal to the wireless network device 100, the wireless network device 100 receives the control signal through the first antenna 110 and transmits the control signal to the processing unit 130. After the processing unit 130 receives the control signal, an instruction to control the antenna steering control unit 150 is generated accordingly. The user can wirelessly connect the mobile communication device 200 with the wireless network device 100.

In practice, the user can use an application to enable the mobile communication device 200 to generate a control signal for controlling the wireless network device 100. It should be noted that the wireless network device 100 may be connected to only one mobile communication device 200 or may be connected to multiple mobile communication devices 200 at the same time. In addition, the mobile communication device 200 can be a mobile phone, a notebook computer, or an electronic communication device such as a multimedia tablet. However, the present invention does not limit the type of mobile communication device 200 and the manner in which control signals are output.

Step S102 is executed to receive a plurality of communication signals transmitted by the plurality of base stations 300. In detail, after the processing unit 130 receives the control signal, the processing unit 130 generates an instruction to the antenna steering control unit 150. The antenna steering control unit 150 receives an instruction from the processing unit 130 such that the antenna steering control unit 150 controls the direction of rotation of the directional antenna 120 in accordance with the instructions. The first antenna 110 rotates around the periphery and emits a detection signal. Then, the plurality of base stations 300 located in the vicinity of the wireless network device 100 transmit a plurality of communication signals after receiving the detection signal. Then, the first antenna 110 can rotate to receive a plurality of communication signals transmitted from the base stations 300.

Step S103 is executed to measure the received signal strength indication (RSSI) of the communication signals transmitted by the base stations 300 through the processing unit 130, and determine the communication signal with the highest signal strength value. With In other words, the first antenna 110 transmits different communication signals received from different base stations 300 to the processing unit 130. After receiving the communication signal, the processing unit 130 analyzes the magnitude of the signal strength value of the communication signals. The processing unit 130 determines the communication signal having the largest signal strength value according to the signal strength values of the communication signals.

Step S104 is executed to connect to the base station 300 that transmits the communication signal with the highest signal strength value. Specifically, the processing unit 130 determines how to drive the direction of rotation of the motor 150 by determining the signal strength of the communication signal having the largest signal strength value. That is to say, the processing unit 130 can determine the orientation of the base station 300 by the signal strength of the largest communication signal. Then, the processing unit 130 generates the driving signal Sd to drive the motor 150, so that the motor 150 can control the rotation direction of the first antenna 110 and perform signal connection with the base station 300 that transmits the first communication signal Sm1.

Specifically, after the wireless network device 100 is connected to the base station 300, a first communication path is formed between the wireless network device 100 and the base station 300, and the mobile communication device 200 can further pass through the wireless network device 100 and the base. The station 300 transmits the data signal. It is worth mentioning that the mobile communication device 200 converts the data signal to be transmitted into the first data signal through the wireless network device 100. For example, after the mobile communication device 200 transmits the data signal of the Wifi signal to the wireless network device 100, the wireless network device 100 further converts the data information into the first data signal of the 3G signal via the first communication path. And transmitted from the first antenna 110 to the base station 300.

In step S105, the processing unit 130 further transmits the data signal to the second antenna 120 by using the first communication path formed by the communication signal with the highest signal strength value between the wireless network device 100 and the base station 300. In detail, the first antenna 110 receives the first data signal transmitted from the base station 300, and the processing unit 130 converts the first data signal into the second data signal. The second data signal is transmitted through a second communication path formed by the wireless network device 100 and the mobile communication device 200.

It is worth noting that the first data signal is a signal transmitted by the base station 300. For example, it may be a third generation (3G) mobile communication signal, a fourth generation (4G) mobile communication signal, WiMAX or LTE, etc. Signal. The second data signal is a signal received or transmitted by the mobile communication device 200, which may be a Wi-Fi signal, a Bluetooth signal, a short-range wireless transmission signal, or the like. For example, the processing unit 130 can convert the 3G signal transmitted by the base station 300 into a Wi-Fi signal. Then, the processing unit 130 transmits the second data signal to the second antenna 120 via the second communication path. In addition, it should be noted that when the first antenna 110 is disconnected from the base station 300 that transmits the first data signal, the second data signal is temporarily stored in the storage unit 140. The storage unit 140 transmits the temporarily stored first data signal to the first antenna 110 until the connection between the first antenna 110 and the base station 300 is restored.

In step S106, the mobile communication device 200 receives the second data signal converted by the first data signal via the wireless network device 100 through the second antenna 120. That is, the wireless network device 100 can be wirelessly connected to the mobile communication device 200 via the second communication path. It should be noted that the second antenna 120 may be an omnidirectional antenna, and the mobile communication device 200 may wirelessly connect and transmit and receive the second data signal through the second antenna 120 of the wireless network device 100. In addition, in order to make the quality of the network connection more stable, the second antenna 120 may be a directional antenna, and the wireless network device 100 may drive the second antenna 120 through another antenna steering control unit (not shown). The direction of rotation is such that the quality of the connection between the second antenna 120 and the mobile communication device 200 is more stable.

In addition, it is worth noting that when the connection between the second antenna 120 and the mobile communication device 200 is interrupted, the information of the first data signal is temporarily stored in the storage unit 140. The storage unit 140 transmits the information of the temporarily stored first data signal to the base station 300 until the connection between the second antenna 120 and the mobile communication device 200 is restored.

In summary, the embodiments of the present invention provide a method for a wireless network device to perform network connection. The mobile communication device is connected to a wireless network device through a control signal, and the first antenna receives the communication signal transmitted by at least one base station, and the processing unit judges The antenna steering control unit receives the driving signal to drive the first antenna to the base station of the communication signal transmitting the maximum signal strength value by transmitting the driving signal to the antenna steering control unit line. That is to say, by controlling the rotation angle of the first antenna, the first antenna is connected to the base station with the best communication signal. Then, the best communication signal is transmitted to the mobile communication device through the second antenna, thereby improving the quality of the communication signal received by the mobile communication device.

Accordingly, the method for performing network connection by the wireless network device provided by the present invention can replace the function of the antenna search base station signal built in the mobile communication device as compared with the conventional method for network connection. Therefore, when the user uses the mobile communication device in the mobile state, the built-in antenna of the mobile communication device does not need to search for a better base station signal with different locations, and the mobile communication device is automatically upgraded. Efficacy and saving power for mobile communication devices.

The above is only an embodiment of the present invention, and is not intended to limit the scope of the invention. It is still within the scope of patent protection of the present invention to make any substitutions and modifications of the modifications made by those skilled in the art without departing from the spirit and scope of the invention.

100‧‧‧Wireless network device

110‧‧‧first antenna

120‧‧‧second antenna

130‧‧‧Processing unit

140‧‧‧ storage unit

150‧‧‧Antenna Steering Control Unit

200‧‧‧Mobile communication equipment

300‧‧‧Base station

Claims (10)

A method for controlling a wireless network device to perform network connection, comprising: receiving a control signal from a mobile communication device; receiving a plurality of communication signals transmitted by the plurality of base stations; measuring the transmission by the base stations The signal strength of the communication signals is used to determine the communication signal having the highest signal strength value; the base station transmitting the communication signal having the highest signal strength value; and the communication signal having the highest intensity value The base station provides the mobile communication device for connection. The method for controlling a wireless network device to perform network connection as described in claim 1, wherein the communication signals are received through a first antenna, and the signal strength of the communication signals is transmitted through a processing unit. Measure. The method for controlling a wireless network device to perform network connection according to claim 2, wherein the first antenna is a directional antenna. The method for controlling a wireless network device to perform network connection according to claim 3, wherein the step of receiving the communication signals transmitted by the base stations comprises: the processing unit controls the first antenna Steering, so that the first antenna receives the communication signals from the base stations. The method for controlling a wireless network device to perform network connection according to claim 2, wherein the step of providing the mobile communication device to connect through the base station of the communication signal having the highest intensity value comprises: The processing unit transmits a data signal to a second antenna; the mobile communication device receives, through the second antenna, the data signal transmitted by the base station that transmits the communication signal having the highest signal strength value. The method for controlling a wireless network device to perform network connection according to claim 1, wherein the mobile communication device generates and outputs the control through an application. Signal number. The method for controlling a wireless network device to perform network connection according to claim 2, wherein the first antenna forms a first communication path with the base station of the communication signal having the largest signal strength value. The method for controlling a wireless network device to perform network connection according to claim 5, wherein the second antenna forms a second communication path with the mobile communication device. The method for controlling a wireless network device to perform network connection according to claim 7, wherein when the first antenna is disconnected from the base station of the communication signal with the highest transmitted signal strength value, The second data signal sent by the mobile communication device is temporarily stored in a storage unit. The method for controlling a wireless network device to perform network connection according to claim 8 is as follows: when the second antenna and the mobile communication device are interrupted, the first data signal is temporarily stored in a storage unit.