TWI667929B - A performance control system for wireless access point based on thermal condition and method thereof - Google Patents

Abstract

A network traffic control system for a wireless access point based on thermal conditions, comprising: a temperature monitoring module, receiving and monitoring temperature data of a wireless access point, and calculating a first network traffic limit by temperature data; flow control The module receives the first network traffic limit; and a parameter module stores the parameters required for the operation; wherein the wireless access point is internally provided with at least one temperature sensor, and the temperature monitoring module reads at intervals The temperature data of the wireless access point measured by the temperature sensor, and calculating the first network traffic limit and notifying the flow control module; wherein the flow control module receives the first network traffic limit, according to the A network traffic limit calculates a first maximum network traffic of the wireless access point and sets a first maximum network traffic limit.

Description

Network condition control system for wireless access point based on thermal condition and method thereof

The invention relates to a network processing system and a processing method, in particular to a control system for monitoring and controlling network traffic of a wireless access point based on thermal conditions such as temperature and voltage, and a processing method thereof.

In the prior art, most wireless access point modes of operation can be divided into a bridge mode (Bridge Mode) and a router mode (Router Mode). Among them, the bridge mode works by bridging all the wired network interfaces (Wired Interfaces) and the wireless network interfaces (Wireless Interfaces) into one or more bridges, which are bridged in the bridge interface. It is a Bridge Port. When a bridge receives a packet, the packet enters the bridge to which the bridge belongs; the bridge mechanism determines which one or more bridges the packet should be forwarded through the Learning Mechanism (Mac Learning).

In addition to the bridging mechanism, the router mode basically has one or more WAN interfaces, and the packets entering the bridge through the routing mechanism, if the destination address is not in the bridge, but in the wide area network, After the packet is passed through Network Address Translation (NAT), it will be forwarded to one of the WAN interfaces, and the packet entering from the WAN interface will be translated by Network Address Translation (NAT). It is forwarded to the bridge for processing, and finally reaches a certain bridge. However, whether it is bridge mode or router mode, basically the wireless access point is dealing with various data packets and network protocols, so when the network traffic is processed, the load of the whole system is higher, when the load is higher. When it is high, it will cause the temperature of the wireless access point to rise.

In detail, most electronic products, including computers, laptops, mobile phones, wired routers, and wireless access points, basically generate certain thermal energy when performing various data processing, data conversion, audio and video data processing, etc. . When the computer system generates too much heat and cannot be cooled immediately, the internal temperature of the computer will continue to rise, even exceeding the temperature that individual components or systems can withstand. This may cause serious consequences such as system instability and crashing of components or components. In response to this problem, the traditional heat dissipation mechanism includes the use of large-area heat sinks and large fans to help dissipate heat. For embedded network products such as wireless access points and routers, the size of the product itself is small and the current trend is common. It is in the form of a fanless (Fan-less), so it can only rely on the heat sink for heat dissipation. However, the area of the heat sink that can be used due to its small size is also limited. Especially for the in-wall wireless access point (In-Wall AP), based on user safety, plastic materials can only be used as panels, because the heat sink can be used in a small area and the surface is made of plastic material. As a result, the heat dissipation capability is also poor. Therefore, when a large number of data packets and network protocols are continuously processed for bridging and routing, more heat is generated and the system is overheated or unstable. In addition, with the generalization of 5GHz high-bandwidth technologies such as 802.11ac, wireless access points face more severe challenges in the dual-band (Dual Band and Dual concurrent) high-bandwidth requirements.

Currently, wireless access points commonly used in the market generally use AC power supply or Power over Ethernet (PoE). Whether it is AC or PoE power supply, there will be a corresponding power supply module in the wireless access point. Each power supply module has its own stable operating temperature and maximum output wattage capacity limit. When the temperature of the system continues to rise, it may cause its power conversion efficiency to decrease, and its output voltage is insufficient or unstable. On the other hand, due to the limitation of the maximum output wattage, the wireless access point will also face an unsustainable and stable output voltage while continuously processing large-volume data packets and complex network protocol operations, which will also cause the system. Unstable or down.

For the aforementioned problems of heat dissipation and power consumption, there are enhancements to the design of hardware, mechanism, and heat dissipation in the prior art. However, there are limitations, so software functions are generally used to assist. Common software features include the ability to use the component's Power Save Mode to reduce power consumption and heat generation. However, when the wireless access point continues to maintain high network traffic, the power saving function does not bring much effect.

For the above reasons, if a new type of network flow control system and processing method based on temperature and voltage monitoring can be provided, when the system temperature continues to rise and reaches a certain temperature or when the system voltage is insufficient or unstable, the dynamic and Instantly adjusting the maximum network traffic limit, reducing system load, and avoiding system overheating or voltage instability will allow wireless access points to continue to provide services consistently and steadily.

To achieve the foregoing objective, the present invention provides a network traffic control system for a wireless access point based on a thermal condition, comprising: a temperature monitoring module that receives and monitors temperature data of a wireless access point, and uses temperature data. Calculating a first network traffic limit; a flow control module receiving the first network traffic limit; and a parameter module, storing the temperature monitoring module and parameters required for operation of the flow control module; wherein, the wireless connection At least one temperature sensor is disposed inside the in-point, and the temperature monitoring module reads the temperature data of the wireless access point measured by the temperature sensor every interval, and calculates the first network traffic limit and notifies the traffic. a control module, wherein after receiving the first network traffic limit, the flow control module calculates a first maximum network traffic of the wireless access point according to the first network traffic limit and sets a first maximum network traffic. limit.

Furthermore, the network flow control system of the wireless condition-based wireless access point of the present invention further includes a voltage monitoring module, and the voltage monitoring module receives and monitors the voltage data of the wireless access point, and calculates the voltage data by using the voltage data. a second network traffic limitation, wherein the wireless access point is internally provided with at least one voltage sensor, and the voltage monitoring module calculates the first time when the voltage data of the wireless access point is changed by the voltage sensor The second network traffic limits and notifies the flow control module, and the parameter module stores parameters required for the operation of the voltage monitoring module, wherein the flow control module receives the second network traffic limit and is based on the second network traffic. Limiting the calculation of a second maximum network traffic of the wireless access point and setting a second maximum network traffic limit.

Preferably, the temperature sensing module further comprises at least one virtual temperature sensor, the virtual temperature sensor is generated based on the at least one temperature sensor, and the temperature monitoring module further reads the virtual temperature sensing every interval of time. The measured temperature data of the wireless access point, and calculates the first network traffic limit and notifies the flow control module.

In another aspect, the present invention also provides a network traffic control method for a wireless access point based on a thermal condition, comprising the following steps: a temperature monitoring module obtains a state parameter of a wireless access point from a parameter module; The monitoring module reads at least one temperature data of the wireless access point measured by the at least one temperature sensor inside the wireless access point, and calculates a first network traffic limit by using the temperature data; And after receiving the first network traffic limit, the traffic control module calculates a first maximum network traffic of the wireless access point and sets a first maximum network traffic limit, wherein the parameter module stores temperature monitoring The parameters required for the module and flow control module calculations.

Preferably, the temperature monitoring module further comprises at least one virtual temperature sensor, the virtual temperature sensor is generated based on the at least one temperature sensor, and the temperature monitoring module further reads the virtual temperature sensor every interval of time. The measured temperature data of the wireless access point is calculated and the first network traffic limit is calculated and notified to the flow control module.

Preferably, after the temperature monitoring module receives the temperature data, the temperature monitoring module compares the temperature data and the state parameters of the wireless access point, and calculates the first network traffic limit.

Preferably, if the temperature data is less than the state parameter, the temperature monitoring module calculates a first network traffic limit for the wireless access point to enter the previous state. If the temperature data is greater than the state parameter, the temperature monitoring module calculates the wireless connection. The first network traffic limit of the entry point into the next state. The previous state is to increase the network traffic limit working state, and the next state is to reduce the network traffic limit working state.

Preferably, if the temperature data is greater than the parameter of the next state, the parameter temperature monitoring module further calculates a first network traffic limit for the wireless access point to enter the next state. Repeatedly check that the current temperature data is less than the new state parameter. In this way, the first network traffic limit can be adjusted to a safe value in time in response to rapid changes in temperature. On the other hand, when the system temperature drops rapidly (such as when the network traffic drops and the room temperature also drops rapidly), it still maintains only the last state, avoiding the sudden drop of network traffic within a short period of time. After the surge, the system temperature increased rapidly due to the increase in network traffic.

Preferably, after the traffic control module calculates the first maximum network traffic of the wireless access point and sets the first maximum network traffic limit, the traffic control module encapsulates all incoming and outgoing packets of the wireless access point. Re-import into a virtual network interface for two-way total flow control.

Furthermore, the network traffic control method of the wireless condition-based wireless access point of the present invention further includes the following steps: a voltage monitoring module obtains a state parameter of the wireless access point from the parameter module; and the voltage monitoring module reads The voltage data of the wireless access point measured by at least one voltage sensor inside the wireless access point, and calculating a second network traffic limit by the voltage data; the flow control module receives the second network traffic After the restriction, a second maximum network traffic of the wireless access point is calculated and a second maximum network traffic limit is set, wherein the parameter module stores parameters required for the voltage monitoring module and the flow control module to operate.

Preferably, when the voltage data is higher or lower than a set voltage condition, the voltage sensor notifies the voltage monitoring module in a system interruption manner.

The embodiments of the present invention will be described in more detail below with reference to the drawings and the <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt;

1 is a schematic diagram showing the structure of a network flow control system for a wireless access point based on a thermal condition according to an embodiment of the present invention. Referring to FIG. 1 , in an embodiment of the present invention, a network access control system 1 for a wireless access point based on a thermal condition includes a temperature monitoring module 10 , a flow control module 12 , and a parameter module 14 . The network condition control system 1 of the wireless access point based on the thermal condition can monitor the temperature state of a wireless access point 2, and can control the maximum flow limit of the wireless access point 2 according to the temperature of the wireless access point 2. In addition, the wireless access point 2 can include a wide area network interface 20 (WAN Interface), a regional network interface 22 (LAN Interface), a 2.4 GHz WIFI module 24, and a 5 GHz WIFI module 26, and the wireless access point. The working mode of 2 can be bridge mode or router mode.

In detail, the temperature monitoring module 10 receives and monitors the temperature data of a wireless access point 2, and calculates a first network traffic limit by using the temperature data. The flow control module 12 is configured to receive the first network traffic limit. The parameter module 14 is used to store the parameters required for the temperature monitoring module 10 and the flow control module 12 to operate. For example, the parameters required for the operation are, for example, the state name of the wireless access point 2, the temperature threshold, Current numerical information such as maximum traffic. The wireless access point 2 is internally provided with at least one temperature sensor 120, and at least one temperature sensor 120 can be disposed adjacent to an important component inside the wireless access point 2 to monitor important components inside the wireless access point 2. temperature. The temperature monitoring module 10 reads the temperature data of the wireless access point 2 measured by the temperature sensor 120 every time interval, and calculates the first network traffic limit by using the temperature data, and further informs The flow control module 12, after receiving the first network traffic limit, the flow control module 12 calculates a first maximum network traffic of the wireless access point 2 according to the first network traffic limit and sets a The first maximum network traffic limit allows the wireless access point 2 to operate in accordance with the first maximum network traffic limit without causing excessive load and causing thermal downtime or unstable operation.

On the other hand, although a plurality of temperature sensors 120 can be disposed inside the wireless access point 2 to make temperature monitoring more complete and comprehensive, such an approach leads to an increase in cost and an increase in the wireless access point. The difficulty of PCB layout. In order to cope with such a situation, in other embodiments of the present invention, the temperature monitoring module 10 further includes at least one virtual temperature sensor (not shown) that is based on at least one temperature sensing. The device 120 is generated, that is, after the temperature data sensed by the at least one temperature sensor 120 is obtained, the temperature monitoring module 10 can be based on the temperature data of the at least one temperature sensor 120 by using a look-up table method and The algorithm such as the internal difference method simulates at least one virtual temperature sensor, and the temperature data of the plurality of main components inside the wireless access point 2 is estimated by the at least one virtual temperature sensor. In this way, the temperature monitoring module 10 further calculates the temperature data of the wireless access point 2 measured by the virtual temperature sensor, and calculates the first network traffic limit and notifies the flow control mode. Group 12.

FIG. 2 is a schematic diagram showing the structure of a network flow control system for a wireless access point based on a thermal condition according to another embodiment of the present invention. Referring to FIG. 2, in another embodiment of the present invention, the network condition control system 1 of the wireless access point based on the thermal condition further includes a voltage monitoring module 16, and the voltage monitoring module 16 can receive and monitor the wireless access. The voltage data of point 2, and a second network flow limit is calculated by the voltage data.

In detail, the wireless access point 2 is internally provided with at least one voltage sensor 160, and the voltage monitoring module 16 calculates the voltage data of the wireless access point 2 when the voltage sensor 160 detects the change. The second network traffic limits and notifies the flow control module 12, and the parameter module 14 stores parameters required for the operation of the voltage monitoring module 16. For example, the parameters required for the operation are, for example, the state of the wireless access point 2. Numerical information such as name, preset voltage data, current maximum flow rate, etc. After receiving the second network traffic limit, the traffic control module 12 calculates a second maximum network traffic of the wireless access point 2 according to the second network traffic limit and sets a second maximum network traffic. The restriction allows the wireless access point 2 to operate in accordance with the second maximum network traffic limit without the occurrence of unstable or downtime due to unstable voltage.

It should be appreciated that in other embodiments of the present invention, the network condition control system 1 of the wireless access point based on the thermal condition may include only the voltage monitoring module 16 and separately use the voltage monitoring module 16 to monitor the wireless access. Point 2 voltage stability, and further control the network traffic of the wireless access point 2 based on the voltage stability.

In addition, in the present invention, the parameter module 14 can store state parameters of various forms of wireless access points, so that the temperature monitoring module, the voltage monitoring module, and the flow control module perform operations. Therefore, the network traffic control system 1 of the wireless condition-based wireless access point of the present invention can be applied to the same series of wireless access point products, and even other Netcom products on the market. In other words, the versatility of the flow control system of the present invention is very high.

Furthermore, the network traffic control system 1 of the wireless access point based on the thermal condition can be executed by a computer device, for example, an application (APP) installed in a smart computer device, so that the user can The most convenient way to monitor the working status of the wireless access point 2.

FIG. 3 is a flow chart for explaining a network flow control method for a wireless access point based on a thermal condition according to an embodiment of the present invention. Referring to FIG. 3, the present invention also provides a network traffic control method for a wireless access point based on a thermal condition, including steps S100-S126.

Step S100 is: a temperature monitoring module obtains a state parameter of a wireless access point from a parameter module, where the state parameter is, for example, a state name of the wireless access point, a temperature threshold of each state, a current maximum flow rate, etc. Numerical information; wherein, the temperature threshold of each state may be each temperature data of the wireless access point read by the temperature monitoring module at intervals; step S102 is: the temperature monitoring module enters an initial state and Notifying the flow control module of the initial first network traffic limit; step S104 is: the temperature monitoring module reads the wireless access measured by the at least one temperature sensor inside the wireless access point every interval of time At least one temperature data of the point; step S106 is: the temperature monitoring module estimates the temperature data of the virtual temperature sensor by the table look-up method and the internal difference method by using the temperature data read in step S104; The step S106 of generating a virtual temperature sensor can be selected to implement according to actual needs.

Then, in step S108, the temperature monitoring module compares all the read temperature data with the temperature threshold stored in the upper state of the parameter module, if all the temperature data are smaller than the temperature state of the previous state. If the value is decreased by one, the process proceeds to step S110, and if not, the process proceeds to step S116.

Then, in step S110, the temperature monitoring module sets the deceleration count to zero and increments the up-speed count; step S112 is: if the up-speed count reaches a rising speed threshold, then proceeds to step S114, otherwise the step proceeds to step S118.

Next, in step S114, the temperature monitoring module enters the previous state, and calculates a first network traffic limit and notifies the flow control module to increase the maximum flow limit; and the flow control module receives the first network. After the traffic restriction, calculating a first maximum network traffic of the wireless access point based on the first network traffic limit and setting a first maximum network traffic limit, wherein the parameter module stores the temperature monitoring mode The group and the parameters required for the operation of the flow control module. The previous state is to increase the network traffic limit working state.

Then, in step S116, the temperature monitoring module sets the deceleration count to zero; in step S118, the temperature monitoring module compares all the read temperature data with the temperature stored in the upper state of the parameter module. If the threshold value is greater than or equal to the temperature threshold of the previous state, the process proceeds to step S120, otherwise, the process proceeds to step S126.

Next, in step S120, the temperature monitoring module sets the speed up count to zero and increments the down speed count by one; step S122 is: if the down speed count reaches a speed down threshold, then proceeds to step S124; S104.

Then, in step S124, the temperature monitoring module enters a next state and calculates a first network traffic limit and notifies the traffic control module to reduce the maximum traffic limit; the traffic control module receives the first network traffic. After the restriction, a first maximum network traffic limit is set, wherein the parameter module stores the temperature monitoring module and parameters required for the operation of the flow control module. The next state is to reduce the network traffic limit working state.

Then, in step S126, the temperature monitoring module sets the speed up count to zero; then proceeds to step S104.

In other words, in the present invention, the temperature monitoring module can compare the current working temperature and the preset working temperature of the wireless access point, and if the current working temperature is less than the preset working temperature for a period of time, the temperature monitoring module will Notifying the flow control module can increase network traffic limits. Conversely, if the current operating temperature is greater than the preset operating temperature for a period of time, the temperature monitoring module notifies the flow control module that the network traffic limit needs to be reduced to prevent the wireless access point from occurring due to network traffic exceeding the load. Hot crash. Furthermore, it can be seen from the above implementation steps that the network traffic control method of the present invention can repeatedly check that the current temperature data of the wireless access point is smaller than the parameter of the new state. In this way, the first network traffic limit can be adjusted to a safe value in time in response to rapid changes in temperature. On the other hand, when the system temperature drops rapidly (such as when the network traffic drops and the room temperature also drops rapidly), it still maintains at most only the last state, avoiding the sudden drop of network traffic within a short period of time. After the surge, the system temperature rises rapidly due to the increase in network traffic.

On the other hand, although a plurality of temperature sensors can be provided inside the wireless access point to make temperature monitoring more complete and comprehensive, such an approach leads to an increase in cost. In other embodiments of the present invention, the temperature monitoring module may further include at least one virtual temperature sensor based on at least one temperature sensing built in the wireless access point. Produced, that is, after obtaining the temperature data sensed by the at least one temperature sensor, the temperature monitoring module can be based on the temperature data of the at least one temperature sensor, by the table look-up method, the internal difference method, etc. The algorithm simulates at least one virtual temperature sensor and obtains internal temperature data of the plurality of wireless access points by the at least one virtual temperature sensor. In this way, the temperature monitoring module further reads the temperature data of the wireless access point measured by the virtual temperature sensor at intervals, and calculates the first network traffic limit and notifies the traffic. Control module.

In addition, after the flow control module calculates the first maximum network traffic of the wireless access point and sets the first maximum network traffic limit, the flow control module will use all of the wireless access points. The incoming (Ingress) and outgoing (Egress) packets are re-imported into a virtual network interface for bi-directional (Bi-Directional) total flow control.

4 is a flow chart for explaining a network flow control method for a wireless access point based on a thermal condition according to another embodiment of the present invention. Referring to FIG. 4, in another embodiment of the present invention, a method for controlling network traffic of a wireless access point based on a thermal condition further includes steps S20 to S24.

Step S20 is: a voltage monitoring module obtains a state parameter of the wireless access point from the parameter module, where the state parameter is, for example, a state information of the wireless access point, a preset voltage data, a current maximum flow rate, and the like. Step S22 is: the voltage monitoring module reads voltage data of the wireless access point measured by at least one voltage sensor inside the wireless access point, and calculates a second network by using the voltage data. Step S24 is: after receiving the second network traffic limit, the traffic control module calculates a second maximum network traffic of the wireless access point and sets a second maximum network traffic limit. The parameter module stores the voltage monitoring module and parameters required for the operation of the flow control module, and the voltage monitoring module can perform voltage monitoring by using an Interrupt Service Routine (ISR).

Further, when the voltage data is higher or lower than a set voltage condition, the voltage sensor notifies the voltage monitoring module by means of an Interrupt Request (IRQ) manner, so that the voltage monitoring module knows The voltage has changed. After that, the voltage monitoring module determines whether it is necessary to change the traffic limit of the wireless access point according to the current accumulated voltage data. If the voltage monitoring module determines that the change is needed, the voltage data is calculated by the voltage data. The second network traffic limit is exceeded. Finally, after receiving the second network traffic limit, the flow control module calculates a second maximum network traffic of the wireless access point and sets a second maximum network traffic limit, so that the wireless access point Work in accordance with the new network traffic restrictions to avoid failure of the wireless access point due to voltage instability.

In summary, the present invention successfully provides a network condition control system for a wireless access point based on thermal conditions and a method thereof, which can monitor a temperature state and/or a voltage state of a wireless access point, and Dynamically adjust the network traffic of the wireless access point based on the current operating temperature and voltage state of the wireless access point. When the operating temperature of the wireless access point is too high or the voltage changes, the maximum wireless access point can be reduced. The way of network traffic reduces the workload of the wireless access point to reduce heat generation, while reducing the power consumption and stable voltage of the wireless access point, so that the service life of the wireless access point rises and remains at the most Stable working condition.

The above is only a preferred embodiment for explaining the present invention, and is not intended to limit the present invention in any way, and any modifications or alterations to the present invention made in the spirit of the same invention. All should still be included in the scope of the intention of the present invention.

1‧‧‧Network traffic control system for wireless access points based on thermal conditions

10‧‧‧ Temperature Monitoring Module

12‧‧‧Flow Control Module

14‧‧‧Parameter module

16‧‧‧Voltage monitoring module

120‧‧‧temperature sensor

160‧‧‧ voltage sensor

2‧‧‧Wireless access point

20‧‧‧ Wide Area Network Interface

22‧‧‧Regional Internet Interface

24‧‧‧2.4GHz WIFI Module

26‧‧‧5GHz WIFI Module

S100-S126‧‧‧Steps

S20-S24‧‧‧Steps

A person skilled in the art will have a better understanding of the various aspects of the present invention, as well as the specific features and advantages thereof. A schematic diagram of a network flow control system of a wireless access point based on a thermal condition according to an embodiment of the present invention; FIG. 2 is a network flow control system for a wireless access point based on a thermal condition according to another embodiment of the present invention; FIG. 3 is a flowchart illustrating a method for controlling network traffic of a wireless access point based on a thermal condition according to an embodiment of the present invention; and FIG. 4 is a diagram illustrating wireless access based on thermal conditions according to another embodiment of the present invention. Flow chart of the network traffic control method of the point.

Claims (9)

A network flow control system for a wireless access point based on a thermal condition, comprising: a temperature monitoring module, receiving and monitoring temperature data of a wireless access point, and calculating a first network traffic by using the temperature data a flow control module that receives the first network traffic limit; and a parameter module that stores the temperature monitoring module and parameters required for the operation of the flow control module; wherein the wireless access point is internally set Having at least one temperature sensor, the temperature monitoring module reads the temperature data of the wireless access point measured by the at least one temperature sensor at intervals, and calculates the first network traffic limit And notifying the flow control module; wherein, after receiving the first network traffic limit, the flow control module calculates a first maximum network traffic of the wireless access point according to the first network traffic limit and Setting a first maximum network traffic limit, and the traffic control module re-imports all incoming and outgoing packets of the wireless access point into a virtual network interface for bidirectional total flow Control. The network traffic control system of the wireless access point based on the thermal condition described in claim 1 further includes a voltage monitoring module, wherein the voltage monitoring module receives and monitors voltage data of the wireless access point, Calculating a second network traffic limit by using the voltage data, wherein the wireless access point is internally provided with at least one voltage sensor, and the voltage monitoring module monitors the wireless by the voltage sensor When the voltage data of the access point changes, the second network traffic limit is calculated and notified to the flow control module, and the parameter module stores parameters required for the operation of the voltage monitoring module, wherein the flow control After receiving the second network traffic limit, the module calculates a second maximum network traffic of the wireless access point according to the second network traffic limit and sets a second maximum network traffic limit. The network flow control system for a wireless condition based wireless access point according to claim 1, wherein the temperature monitoring module further comprises at least one virtual temperature sensor, the at least one virtual temperature sensor Based on the at least one temperature sensor, the temperature is generated The monitoring module further reads the temperature data of the wireless access point measured by the at least one virtual temperature sensor at intervals, calculates the first network traffic limit, and notifies the flow control module. A method for controlling network traffic of a wireless access point based on a thermal condition includes the following steps: a temperature monitoring module obtains a state parameter of a wireless access point from a parameter module; the temperature monitoring module is separated by a period of time Reading at least one temperature data of the wireless access point measured by the at least one temperature sensor inside the wireless access point, and calculating a first network traffic limit by using the temperature data; and a flow control After receiving the first network traffic limit, the module calculates a first maximum network traffic of the wireless access point and sets a first maximum network traffic limit, wherein the parameter module stores the temperature monitoring a module and a parameter required for the operation of the flow control module, wherein the flow control module calculates the first maximum network traffic of the wireless access point and sets the first maximum network traffic limit, the traffic The control module performs bidirectional total flow control by re-importing all incoming and outgoing packets of the wireless access point into a virtual network interface. The network traffic control method for a wireless condition-based wireless access point according to claim 4, wherein the at least one temperature sensor further comprises at least one virtual temperature sensor, the at least one virtual temperature sense The detector is generated based on the at least one temperature sensor, and the temperature monitoring module further reads the temperature data of the wireless access point measured by the at least one virtual temperature sensor at intervals, and calculates The first network traffic limit is issued and the flow control module is notified. The method for controlling a network traffic of a wireless access point based on a thermal condition according to claim 4, wherein, after the temperature monitoring module receives the temperature data, the temperature monitoring module compares the temperature data and The status parameter of the wireless access point, and calculating the first network traffic limit. The method for controlling a network traffic of a wireless access point based on a thermal condition according to claim 6 , wherein if the temperature data is smaller than the state parameter, the temperature monitoring module Calculating the first network traffic limit that causes the wireless access point to enter the previous state. If the temperature data is greater than the state parameter, the temperature monitoring module calculates the first one that causes the wireless access point to enter the next state. Network traffic restrictions. The method for controlling network traffic of a wireless access point based on a thermal condition according to claim 4, further comprising the step of: obtaining, by the voltage monitoring module, the state of the wireless access point from the parameter module The voltage monitoring module reads voltage data of the wireless access point measured by at least one voltage sensor inside the wireless access point, and calculates a second network traffic limit by using the voltage data. After receiving the second network traffic limit, the flow control module calculates a second maximum network traffic of the wireless access point and sets a second maximum network traffic limit, wherein the parameter module stores The voltage monitoring module and the parameters required for the operation of the flow control module are provided. The network flow control method for a wireless condition-based wireless access point according to claim 8, wherein the voltage sensor is a system when the voltage data is higher or lower than a set voltage condition The voltage monitoring module is notified by the interrupt mode.