CN110167049B - Network connection control method, system, intelligent terminal and computer readable storage medium - Google Patents

Abstract

The invention provides a network connection control method, a system, an intelligent terminal and a computer readable storage medium, wherein the network connection control method comprises the following steps: establishing a first communication connection and a second communication connection; presetting a terminal parameter threshold, a network delay threshold and a transmission time threshold; detecting current terminal parameters; detecting a first network delay and a second network delay when any one or more of a current terminal temperature, a current chip utilization rate, and a current power consumption exceeds a terminal temperature threshold, is lower than a chip utilization rate threshold, and exceeds a power consumption threshold; calculating a first transmission time and a second transmission time when the first network delay and the second network delay are less than or equal to a network delay threshold; selectively closing the first communication connection or the second communication connection when the first transmission time and the second transmission time are less than the transmission time threshold. After the technical scheme is adopted, the use requirements of users on the intelligent terminal are met, and the overall balance of power consumption and temperature performance is realized.

Description

Network connection control method, system, intelligent terminal and computer readable storage medium

Technical Field

The present invention relates to the field of intelligent control, and in particular, to a network connection control method, system, intelligent terminal, and computer-readable storage medium.

Background

With the increasing popularization of intelligent terminals, the requirements of people on the use experience brought by the intelligent terminals in use are higher and higher. For example, many users who have deep use of game type, video type, and live type applications installed on the smart terminal want to enjoy smooth and fast game and entertainment experience when using the smart terminal. The basic requirement of the experience is that the network connection of the intelligent terminal cannot be subjected to the situations of current interruption, current limitation and even network disconnection during the experience.

In order to ensure that the network is always stable and smooth, the intelligent terminal can be internally provided with a plurality of network interfaces, and the intelligent terminal can access an external network to receive and transmit data through each network interface. However, the simultaneous use of multiple network interfaces in the same time period can cause problems of high power consumption, serious heating and the like of the intelligent terminal. For example, taking a smart phone as an example, a wifi network and a mobile network are used at the same time, where the wifi network is a default data network, and an application program in the smart terminal frequently uses the mobile network to receive and transmit small data while using the wifi network to perform service data exchange, so as to monitor the network quality, and as a result, the two network interfaces of the wifi network and the mobile network are always operated, which causes the problems of high power consumption and serious heating. And many application programs can automatically perform exception handling under the condition of poor network use, such as a large amount of occupied system resources, multiplexing other network interfaces and the like, and the problems of blockage of an operating system of the intelligent terminal and the like are caused.

Based on the above situation, a scheme of selecting a network channel only according to the received signal strength has been proposed in the prior art, such as the patent application disclosed as WO2017/166572a 1. In this kind of scheme, can't be suitable for the strong but poor network of time ductility of signal, and only rely on signal strength to judge, too one side under some circumstances, the simplification has closed behind a certain network access, experiences to cause the influence to the user uses intelligent terminal's use.

Therefore, a new network connection control method and system are needed to save power consumption when multiple network interfaces are used simultaneously under the condition of ensuring that network connection is not interrupted.

Disclosure of Invention

In order to overcome the technical defects, the invention aims to provide a network connection control method, a network connection control system, an intelligent terminal and a computer readable storage medium, which not only meet the use requirements of users on the intelligent terminal, but also realize the overall balance of power consumption and temperature performance.

The invention discloses a network connection control method, which comprises the following steps:

the intelligent terminal establishes a first communication connection based on a wireless network and a second communication connection based on a cellular network;

a terminal parameter threshold, a network delay threshold and a transmission time threshold are preset in the intelligent terminal, wherein the terminal parameter threshold comprises a terminal temperature threshold, a chip utilization rate threshold and a power consumption threshold, and the transmission time threshold is configured to be defined by the time required for transmitting data of a preset data volume;

detecting current terminal parameters of the intelligent terminal, wherein the current terminal parameters comprise current terminal temperature, current chip utilization rate and current power consumption;

detecting a first network delay of the first communication connection and a second network delay of the second communication connection when any one or more of a current terminal temperature, a current chip utilization rate, and a current power consumption respectively exceeds a terminal temperature threshold, is lower than a chip utilization rate threshold, and exceeds a power consumption threshold;

calculating a first transmission time and a second transmission time required for the first communication connection and the second communication connection to transmit a preset data volume when the first network delay and the second network delay are less than or equal to a network delay threshold;

selectively closing the first communication connection or the second communication connection when the first transmission time and the second transmission time are less than the transmission time threshold.

Preferably, the network connection control method further includes:

setting the first communication connection or the second communication connection as a priority connection channel.

Preferably, the step of selectively closing the first communication connection or the second communication connection when the first transmission time and the second transmission time are less than the transmission time threshold comprises:

assigning a weighted value to a first transmission time and a second transmission time of a first communication connection or a second communication connection which is not used as a priority connection channel;

when the first communication connection is a priority connection channel and the first transmission time and the second transmission time are smaller than the transmission time threshold value, comparing the product of the weighted value and the second transmission time with the first transmission time, and closing the first communication connection when the product of the weighted value and the second transmission time is smaller than the first transmission time;

and when the second communication connection is a priority connection channel and the first transmission time and the second transmission time are smaller than the transmission time threshold value, comparing the product of the weighted value and the first transmission time with the second transmission time, and closing the second communication connection when the product of the weighted value and the first transmission time is smaller than the second transmission time.

Preferably, the network connection control method further includes:

presetting a first hysteresis cycle in the intelligent terminal;

when the first communication connection or the second communication connection as the priority connection channel is closed, the first communication connection or the second communication connection is enabled again after a first hysteresis period from the time of closing the starting point of the first communication connection or the second communication connection.

Preferably, the network connection control method further includes:

presetting a second hysteresis cycle in the intelligent terminal;

when the first communication connection or the second communication connection which is not used as a priority connection channel is closed, detecting a first network delay of the enabled first communication connection or the enabled second communication connection and a second network delay of the enabled second communication connection after a second hysteresis period from the starting point of closing the first communication connection or the second communication connection;

the first communication connection or the second communication connection is re-enabled when the first network delay or the second network delay is greater than the network delay threshold.

The invention also discloses a network connection control system, a first communication connection module for establishing wireless network connection, a second communication connection module for establishing cellular network connection, and a processing module,

a terminal parameter threshold, a network delay threshold and a transmission time threshold are preset in the processing module, wherein the terminal parameter threshold comprises a terminal temperature threshold, a chip utilization rate threshold and a power consumption threshold, and the transmission time threshold is configured to be defined by the time required for transmitting data of a preset data volume;

the processing module detects current terminal parameters of the intelligent terminal, wherein the current terminal parameters comprise current terminal temperature, current chip utilization rate and current power consumption;

the processing module compares the current terminal parameter with a preset terminal parameter threshold, and detects a first network delay of a first communication connection and a second network delay of a second communication connection when any one or more of the current terminal temperature, the current chip utilization rate and the current power consumption respectively exceeds the terminal temperature threshold, is lower than the chip utilization rate threshold and exceeds the power consumption threshold;

when the first network delay and the second network delay are smaller than or equal to a network delay threshold value, the processing module calculates a first transmission time and a second transmission time required by the first communication connection and the second communication connection for transmitting a preset data volume;

and when the first transmission time and the second transmission time are smaller than the transmission time threshold value, the processing module selectively closes the first communication connection or the second communication connection.

Preferably, the processing module sets the first communication connection or the second communication connection as a priority connection channel;

the processing module endows a weighted value to the first transmission time and the second transmission time of the first communication connection or the second communication connection which is not used as a priority connection channel;

when the first communication connection is a priority connection channel and the first transmission time and the second transmission time are smaller than the transmission time threshold, the processing module compares the product of the weighted value and the second transmission time with the first transmission time, and when the product of the weighted value and the second transmission time is smaller than the first transmission time, the processing module closes the first communication connection;

when the second communication connection is a priority connection channel and the first transmission time and the second transmission time are smaller than the transmission time threshold, the processing module compares the product of the weighted value and the first transmission time with the second transmission time, and when the product of the weighted value and the first transmission time is smaller than the second transmission time, the processing module closes the second communication connection.

Preferably, the processing module sets the first communication connection or the second communication connection as a priority connection channel;

a second hysteresis cycle is also preset in the processing module, wherein the first hysteresis cycle is extruded by the second hysteresis cycle;

when the first communication connection or the second communication connection as the priority connection channel is closed, starting from the starting point of closing the first communication connection or the second communication connection, and after a first hysteresis cycle, the processing module starts the first communication connection or the second communication connection again;

when the first communication connection or the second communication connection which is not used as the priority connection channel is closed, after a second hysteresis period from the starting point of closing the first communication connection or the second communication connection, the processing module detects the enabled first network delay of the first communication connection or the enabled second network delay of the second communication connection;

the processing module re-enables the first communication connection or the second communication connection when the first network delay or the second network delay is greater than the network delay threshold.

The invention also discloses an intelligent terminal which comprises the network connection control system.

The invention also discloses a computer readable storage medium on which a computer program is stored, which computer program, when executed by a processor, implements a network connection control method as described above.

After the technical scheme is adopted, compared with the prior art, the method has the following beneficial effects:

1. for the holding of the intelligent terminal by the user, the temperature of the intelligent terminal is controlled to be below the comfortable hand feeling temperature, and the satisfaction degree of the user is improved;

2. the processing chip of the intelligent terminal is realized, for example, the cpu frequency is kept in a high utilization rate range, the data processing speed is increased, and the user experience is improved;

3. the data transmission of the intelligent terminal meets the real-time requirement, and the transmission delay is within the reliability range;

4. the intelligent terminal is stable in power consumption and does not exceed the range when being used and even used deeply, and the endurance of the intelligent terminal is improved.

Drawings

FIG. 1 is a flow chart illustrating a network connection control method according to a preferred embodiment of the present invention;

FIG. 2 is a flow chart illustrating a network connection control method according to another preferred embodiment of the present invention;

FIG. 3 is a flow chart illustrating a network connection control method according to yet another preferred embodiment of the present invention;

fig. 4 is a schematic diagram of a network connection control system according to a preferred embodiment of the present invention.

Detailed Description

The advantages of the invention are further illustrated in the following description of specific embodiments in conjunction with the accompanying drawings.

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The implementations described in the exemplary embodiments below are not intended to represent all implementations consistent with the present disclosure. Rather, they are merely examples of apparatus and methods consistent with certain aspects of the present disclosure, as detailed in the appended claims.

The terminology used in the present disclosure is for the purpose of describing particular embodiments only and is not intended to be limiting of the disclosure. As used in this disclosure and the appended claims, the singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It should also be understood that the term "and/or" as used herein refers to and encompasses any and all possible combinations of one or more of the associated listed items.

It is to be understood that although the terms first, second, third, etc. may be used herein to describe various information, such information should not be limited to these terms. These terms are only used to distinguish one type of information from another. For example, first information may also be referred to as second information, and similarly, second information may also be referred to as first information, without departing from the scope of the present disclosure. The word "if" as used herein may be interpreted as "at … …" or "when … …" or "in response to a determination", depending on the context.

In the description of the present invention, it is to be understood that the terms "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention.

In the description of the present invention, unless otherwise specified and limited, it is to be noted that the terms "mounted," "connected," and "connected" are to be interpreted broadly, and may be, for example, a mechanical connection or an electrical connection, a communication between two elements, a direct connection, or an indirect connection via an intermediate medium, and specific meanings of the terms may be understood by those skilled in the art according to specific situations.

In the following description, suffixes such as "module", "component", or "unit" used to denote elements are used only for facilitating the explanation of the present invention, and have no specific meaning in themselves. Thus, "module" and "component" may be used in a mixture.

Fig. 1 is a flow chart of a network connection control method according to a preferred embodiment of the present invention. In the embodiment, based on data processing and timely response under multi-parameter and multi-dimension, dual-channel network connection control and power consumption control under various conditions are realized, and the specific steps comprise:

s100: the intelligent terminal establishes a first communication connection based on a wireless network and a second communication connection based on a cellular network.

When the intelligent terminal is used, due to the requirement of data transmission, a first communication connection based on a wireless network is established with equipment providing wireless network services, such as a router, a repeater, a base station and the like, and a second communication connection based on a cellular network is established with equipment providing the cellular network, such as the base station and the like. It is understood that the first communication connection is typically a Wifi connection and the second communication connection is typically a 3G, 4G, 5G mobile network connection. When the two communication connections are established, the intelligent terminal can transmit data through the network channel of the first communication connection and the network channel of the second communication connection at the same time.

It can be understood that, in order to establish the first communication connection and the second communication connection, the intelligent terminal may be provided therein with corresponding antennas, wireless network antennas and cellular antennas, and is attached inside two sides of the intelligent terminal, so as to implement the above functions.

Taking the android system as an example, when a Wifi connection and a mobile network such as 4G and 5G are required to be used to connect a network at the same time, it is first ensured that a 4G data link is not forcibly disconnected, for example, data in frame/base/services/core/java/com/android/server/connectivity service. Other networks, such as Api Level21 and above, which represent Network cards of mobile phones, have a bindSocket () method, which can bind a single Socket to a certain Network card; or calling a getSocketFactory () method to directly produce the Socket in a factory mode;

at Api Level23 and above, a bindprocesstontwork () method of ConnectivityManager is directly called, and network requests of the whole process are bound to a certain network card and the like.

S200: presetting a terminal parameter threshold, a network delay threshold and a transmission time threshold in the intelligent terminal

In this embodiment, for the control of the dual channel network connection, the logical decision is mainly based on the following dimensions, including but not limited to: the intelligent terminal comprises a terminal parameter threshold value representing the hardware state of the intelligent terminal, a network delay threshold value representing the network quality and a transmission time threshold value, wherein the terminal parameter threshold value comprises a terminal temperature threshold value, a chip utilization rate threshold value and a power consumption threshold value. When the dual-channel network is started, the terminal temperature threshold value mainly generates heat on the intelligent terminal by the power consumption generated by the first communication connection module in charge of wifi connection and the power consumption generated by the second communication connection module in charge of cellular network connection during working, so that the intelligent terminal is heated. Therefore, for setting the terminal temperature threshold, the temperature which can be normally used by the user and does not influence the hand feeling, such as 30 ℃, 40 ℃ and the like, can be set according to the use habit and the preference of the user. The chip utilization rate indicates a self load rate occupied by a processing chip of the intelligent terminal at the current moment, for example, when a CPU performs data processing in a single-thread or multi-thread processing mode, usually, 70% or 80% of the time represents that the CPU performs high-load operation, which causes a large amount of power consumption and heat. And the power consumption threshold or the current threshold is the power consumption of the battery of the intelligent terminal when the intelligent terminal operates, such as 150mAh, 500mAh and the like. The network delay threshold represents the time required for data exchange between the intelligent terminal and the external server, and its optional value, for example, 80ms, 100ms, etc., will not cause smooth data connection such as jamming and video buffering when used by the user. The transmission time threshold is a parameter dimension that is not commonly used in the field or even recommended to be used, specifically, to form the transmission time threshold, in the intelligent terminal, a time required for transmitting network data with a data size of a preset data size, for example, a time taken for transmitting network data with a size of 1mb, 512kb, or the like, may be defined, and the transmission time threshold may be a desired time or a worst acceptable time for a user when transmitting network data with the data size, for example, a transmission time threshold for transmitting a data size of 1mb is 100ms, or 500ms, or the like. It is understood that when network data of the same size is actually transmitted, the more time is required, the worse the network quality is indicated, or the channel part of the communication connection is blocked.

S300: detecting current terminal parameters of intelligent terminal

After the parameters are preset, the connection state of the first communication connection and the second communication connection of the current connection can be evaluated by taking the parameters as a reference. Specifically, the state parameters of the intelligent terminal at the current moment, such as the current terminal temperature, the current chip utilization rate, the current power consumption and the like, which have the same dimensionality as the preset terminal parameter threshold value, are retrieved, and it can be naturally understood that the current terminal temperature corresponds to the terminal temperature threshold value and has the same units and preset and detection conditions, the current chip utilization rate corresponds to the chip utilization rate threshold value and has the same units and preset and detection conditions, and the current power consumption corresponds to the power consumption threshold value and has the same units and preset and detection conditions.

S400: comparing the current terminal parameter with a preset terminal parameter threshold

After the current terminal parameters are obtained, the current terminal temperature, the current chip utilization rate and the current power consumption are respectively compared with a terminal temperature threshold, a chip utilization rate threshold and a power consumption threshold, when the current terminal temperature is higher than the terminal temperature threshold, the situation that the heating of the intelligent terminal is aggravated by the use of the dual-channel network is shown, the use influence on a user is possibly caused, when the current chip utilization rate is lower than the chip utilization rate threshold, the situation that the intelligent terminal is not excessively loaded by the use of the dual-channel network is shown, on the basis, one of the network connection channels is closed, the current chip utilization rate is further reduced, when the current power consumption is higher than the power consumption threshold, the situation that the use of the internal electric quantity of the intelligent terminal is excessively increased is shown, the endurance of the intelligent terminal is reduced, and when one or more of the three situations are met, it may be considered that a change of the use of the dual channel network is triggered, whereby a first network latency of the first communication connection and a second network latency of the second communication connection are detected to determine whether one of the first communication connection or the second communication connection can satisfy the transmission requirement of the user for the network data if only one network channel is reserved. That is to say, in this embodiment of the present invention, even when it is confirmed that the dual-channel network generates heat severely and consumes too much power to the smart terminal, the network connection is determined as a priority bit.

S500: calculating a first transmission time and a second transmission time required for the first communication connection and the second communication connection to transmit a preset data volume when the first network delay and the second network delay are less than or equal to a network delay threshold value

When the first network delay of the first communication connection and the second network delay of the second communication connection are both smaller than or equal to the network delay threshold, it indicates that the first communication connection or the second communication connection under a single channel can already meet the requirement of a user for network data transmission, and therefore, one of the paths can be closed. The decisive factor for determining which network channel to close is based on the transmission time threshold. Specifically, the first transmission time and the second transmission time required for the first communication connection and the second communication connection to transmit the data with the network data size of the preset data size are calculated, that is, the same data size (the data themselves may be different, and the data size is the same) is transmitted based on the principle of the control variable method to detect whether the user requirement is met based on the condition of forming the transmission time threshold. As described above, generally, the evaluation of the network quality mainly surrounds two dimensions of the network delay and the signal strength, and the evaluation of the network quality is more accurate under detection by taking the transmission time as a reference in the present embodiment, because the dimensions of the network delay and the signal strength more embody the soft strength of the network transmission, but the dimension of the transmission time is more directly expressed in terms of the representation of the actual transmission.

S600: comparing the first and second transmission times to a transmission time threshold

When the first transmission time and the second transmission time are smaller than the transmission time threshold, which indicates that both the two network channels can meet the network data transmission requirements of the user in the current state, one of the two network channels can be closed, that is, the first communication connection or the second communication connection is selectively closed. It can be understood that, of course, the control logic may also be configured to turn off the communication connection corresponding to the first transmission time and the second transmission time, where one of the first transmission time and the second transmission time is smaller than the transmission time threshold, and the other communication connection is larger than the transmission time threshold, but the beneficial effect in step S600 is that when the network quality of one communication connection is not sufficient, it may be that the network quality under the current environment is affected, and it is very likely that the other communication connection will also be affected but is not embodied temporarily, and if one communication connection is turned off, the other communication connection may have a slow data transmission experience in the use process, which is not acceptable for the user. Therefore, in a preferred embodiment, the control logic is executed only when both the first transmission time and the second transmission time are less than the transmission time threshold.

By closing one path of the dual-channel network connection under the condition of ensuring smooth network data transmission, the current terminal temperature, the current chip utilization rate and the current power consumption can be reduced, and the heating and high power consumption conditions of the intelligent terminal are obviously improved.

In a preferred embodiment, the network connection control method further includes setting the first communication connection or the second communication connection as a priority connection channel in the intelligent terminal or a default network connection, and classifying the two channels into a high priority and a low priority. Still further, with reference to fig. 2, the control method will also be partly changed with a difference in priority for the first communication connection and the second communication connection. Specifically, when the first transmission time and the second transmission time are smaller than the transmission time threshold, the step S600 of selectively closing the first communication connection or the second communication connection includes:

s610: assigning a weight value to the first transmission time and the second transmission time of the first communication connection or the second communication connection which are not used as the priority connection channel, that is, when the first communication connection is the priority connection channel, assigning a weight value to the second transmission time of the second communication connection, wherein the weight value can be larger than 1 or smaller than 1, or vice versa;

s620: when the first communication connection is the priority connection channel and the first transmission time and the second transmission time are smaller than the transmission time threshold, comparing the product of the weight value and the second transmission time with the first transmission time, and when the product of the weight value and the second transmission time is smaller than the first transmission time, closing the first communication connection, that is, when the priority connection channel is used, it is natural that the first communication connection is reserved first, and after the weight value is given to the second transmission time, because the weight value can be larger than 1 or smaller than 1, in the case of being larger than 1, it can be understood that the time requirement for the first transmission time is reduced (the product is larger than the original second transmission time, and the smaller the transmission time dimension is, the better), in the case of being smaller than 1, it can be understood that the time requirement for the first transmission time is increased (the reason is as above). Therefore, the user can adjust the weighted value according to the requirement of the user to change the control logic for closing which communication connection;

s630: on the other hand, when the second communication connection is the priority connection channel and the first transmission time and the second transmission time are smaller than the transmission time threshold, the product of the weighted value and the first transmission time is compared with the second transmission time, and when the product of the weighted value and the first transmission time is smaller than the second transmission time, the second communication connection is closed.

Preferably or optionally, referring to fig. 3, the network connection control method further includes:

s700: a first hysteresis cycle is preset in the intelligent terminal, and the first hysteresis cycle takes time as a unit;

s800: when the first communication connection or the second communication connection as the priority connection channel is closed, the first communication connection or the second communication connection is enabled again after a first hysteresis period from the time of closing the starting point of the first communication connection or the second communication connection. That is, for the closing of the dual-channel network, the control logic is not controlled once, but the control logic is always repeated in the use process of the intelligent terminal, and the last control result is kept in the first hysteresis cycle, that is, the first communication connection or the second communication connection is kept closed; when the communication connection as the priority connection channel is closed, which is equivalent to the one established and applied in the first hysteresis period and always has the lower priority, this control logic is more against the general user requirement, so that after the duration of the first hysteresis period elapses, the first communication connection or the second communication connection that has been closed and is preset as the priority connection channel will be enabled again.

Preferably or optionally, the network connection control method may further include:

s900: presetting a second hysteresis cycle in the intelligent terminal;

s1000: when the first communication connection or the second communication connection which is not used as the priority connection channel is closed, after a second hysteresis period from the starting point of closing the first communication connection or the second communication connection, a first network delay of the first communication connection or the second communication connection and a second network delay of the second communication connection which are enabled are detected. That is, when the first communication connection or the second communication connection reserved as the priority connection channel is used, the re-enabling necessity of the other auxiliary connection is relatively low, and the network quality of the currently started first communication connection or second communication connection can be detected, that is, the first network delay or the second network delay of the enabled first communication connection or second communication connection is detected;

s1100: when the first network delay or the second network delay is greater than the network delay threshold, it indicates that the single channel terrorist of the currently enabled first communication connection or second communication connection cannot meet the normal network data transmission requirement, and the first communication connection or the second communication connection that has been previously turned off needs to be enabled again, that is, the dual-channel network is enabled again.

Through periodic detection and regulation and control of a single-channel and double-channel network between power consumption and data transmission balance, the requirements of users on two aspects, namely low power consumption and high speed, can be met simultaneously.

Referring to fig. 4, the present invention further discloses a network connection control system, which includes a first communication connection module for establishing a wireless network connection, a second communication connection module for establishing a cellular network connection, and a processing module, wherein a terminal parameter threshold, a network delay threshold, and a transmission time threshold are preset in the processing module, the terminal parameter threshold includes a terminal temperature threshold, a chip utilization threshold, and a power consumption threshold, and the transmission time threshold is configured to be defined by a time required for transmitting data of a preset data volume; the processing module detects current terminal parameters of the intelligent terminal, wherein the current terminal parameters comprise current terminal temperature, current chip utilization rate and current power consumption; the processing module compares the current terminal parameter with a preset terminal parameter threshold, and detects a first network delay of a first communication connection and a second network delay of a second communication connection when any one or more of the current terminal temperature, the current chip utilization rate and the current power consumption respectively exceeds the terminal temperature threshold, is lower than the chip utilization rate threshold and exceeds the power consumption threshold; when the first network delay and the second network delay are smaller than or equal to a network delay threshold value, the processing module calculates a first transmission time and a second transmission time required by the first communication connection and the second communication connection for transmitting a preset data volume; and when the first transmission time and the second transmission time are smaller than the transmission time threshold value, the processing module selectively closes the first communication connection or the second communication connection.

Preferably or optionally, the processing module sets the first communication connection or the second communication connection as a priority connection channel; the processing module endows a weighted value to the first transmission time and the second transmission time of the first communication connection or the second communication connection which is not used as a priority connection channel;

preferably or optionally, when the first communication connection is a priority connection channel and the first transmission time and the second transmission time are smaller than the transmission time threshold, the processing module compares the product of the weighted value and the second transmission time with the first transmission time, and when the product of the weighted value and the second transmission time is smaller than the first transmission time, the processing module closes the first communication connection; when the second communication connection is a priority connection channel and the first transmission time and the second transmission time are smaller than the transmission time threshold, the processing module compares the product of the weighted value and the first transmission time with the second transmission time, and when the product of the weighted value and the first transmission time is smaller than the second transmission time, the processing module closes the second communication connection.

Preferably or optionally, the processing module sets the first communication connection or the second communication connection as a priority connection channel; a second hysteresis cycle is also preset in the processing module, wherein the first hysteresis cycle is extruded by the second hysteresis cycle; when the first communication connection or the second communication connection as the priority connection channel is closed, starting from the starting point of closing the first communication connection or the second communication connection, and after a first hysteresis cycle, the processing module starts the first communication connection or the second communication connection again; when the first communication connection or the second communication connection which is not used as the priority connection channel is closed, after a second hysteresis period from the starting point of closing the first communication connection or the second communication connection, the processing module detects the enabled first network delay of the first communication connection or the enabled second network delay of the second communication connection; the processing module re-enables the first communication connection or the second communication connection when the first network delay or the second network delay is greater than the network delay threshold.

The network connection control system may also be applied to an intelligent terminal, or may be compiled into a computer readable storage medium, on which a computer program is stored, and when the computer program is executed by a processor, the network connection control method is implemented.

The smart terminal may be implemented in various forms. For example, the terminal described in the present invention may include an intelligent terminal such as a mobile phone, a smart phone, a notebook computer, a PDA (personal digital assistant), a PAD (tablet computer), a PMP (portable multimedia player), a navigation device, etc., and a fixed terminal such as a digital TV, a desktop computer, etc. In the following, it is assumed that the terminal is a smart terminal. However, it will be understood by those skilled in the art that the configuration according to the embodiment of the present invention can be applied to a fixed type terminal in addition to elements particularly used for moving purposes.

It should be noted that the embodiments of the present invention have been described in terms of preferred embodiments, and not by way of limitation, and that those skilled in the art can make modifications and variations of the embodiments described above without departing from the spirit of the invention.

Claims (10)

1. A network connection control method, comprising the steps of:

the intelligent terminal establishes a first communication connection based on a wireless network and a second communication connection based on a cellular network at the same time;

presetting a terminal parameter threshold, a network delay threshold and a transmission time threshold in the intelligent terminal, wherein the terminal parameter threshold comprises a terminal temperature threshold, a chip utilization rate threshold and a power consumption threshold, and the transmission time threshold is configured to be defined by the time required for transmitting data of a preset data volume;

detecting current terminal parameters of the intelligent terminal, wherein the current terminal parameters comprise current terminal temperature, current chip utilization rate and current power consumption;

detecting a first network delay of the first communication connection and a second network delay of the second communication connection when any one or more of a current terminal temperature, a current chip utilization rate, and a current power consumption respectively exceeds a terminal temperature threshold, is lower than a chip utilization rate threshold, and exceeds a power consumption threshold;

calculating a first transmission time and a second transmission time required for the first communication connection and the second communication connection to transmit the preset data volume when the first network delay and the second network delay are less than or equal to a network delay threshold;

selectively closing the first communication connection or the second communication connection when the first transmission time and the second transmission time are less than the transmission time threshold.

2. The network connection control method of claim 1,

the network connection control method further includes:

setting the first communication connection or the second communication connection as a priority connection channel.

3. The network connection control method of claim 2,

the step of selectively closing the first communication connection or the second communication connection when the first transmission time and the second transmission time are less than the transmission time threshold comprises:

assigning a weighted value to a first transmission time and a second transmission time of a first communication connection or a second communication connection which is not used as a priority connection channel;

when the first communication connection is a priority connection channel and the first transmission time and the second transmission time are smaller than the transmission time threshold value, comparing the product of the weighted value and the second transmission time with the first transmission time, and closing the first communication connection when the product of the weighted value and the second transmission time is smaller than the first transmission time;

and when the second communication connection is a priority connection channel and the first transmission time and the second transmission time are smaller than the transmission time threshold value, comparing the product of the weighted value and the first transmission time with the second transmission time, and closing the second communication connection when the product of the weighted value and the first transmission time is smaller than the second transmission time.

4. The network connection control method of claim 2,

the network connection control method further includes:

presetting a first hysteresis cycle in the intelligent terminal;

when the first communication connection or the second communication connection as the priority connection channel is closed, the first communication connection or the second communication connection is enabled again after a first hysteresis period from the time of closing the starting point of the first communication connection or the second communication connection.

5. The network connection control method of claim 2,

the network connection control method further includes:

presetting a second hysteresis cycle in the intelligent terminal;

when the first communication connection or the second communication connection which is not used as a priority connection channel is closed, detecting a first network delay of the enabled first communication connection or the enabled second communication connection and a second network delay of the enabled second communication connection after a second hysteresis period from the starting point of closing the first communication connection or the second communication connection;

the first communication connection or the second communication connection is re-enabled when the first network delay or the second network delay is greater than the network delay threshold.

6. A network connection control system, a first communication connection module for establishing wireless network connection and a second communication connection module for establishing cellular network connection at the same time, and a processing module,

a terminal parameter threshold, a network delay threshold and a transmission time threshold are preset in the processing module, wherein the terminal parameter threshold comprises a terminal temperature threshold, a chip utilization rate threshold and a power consumption threshold, and the transmission time threshold is configured to be defined by time required for transmitting data of a preset data volume;

the processing module detects current terminal parameters of the intelligent terminal, wherein the current terminal parameters comprise current terminal temperature, current chip utilization rate and current power consumption;

the processing module compares a current terminal parameter with a preset terminal parameter threshold, and detects a first network delay of a first communication connection and a second network delay of a second communication connection when any one or more of a current terminal temperature, a current chip utilization rate and a current power consumption respectively exceeds the terminal temperature threshold, is lower than the chip utilization rate threshold and exceeds the power consumption threshold;

when the first network delay and the second network delay are smaller than or equal to a network delay threshold value, the processing module calculates a first transmission time and a second transmission time required by the first communication connection and the second communication connection to transmit the preset data volume;

and when the first transmission time and the second transmission time are smaller than the transmission time threshold, the processing module selectively closes the first communication connection or the second communication connection.

7. The network connection control system of claim 6,

setting a first communication connection or a second communication connection as a priority connection channel in the processing module;

the processing module endows a weighted value to the first transmission time and the second transmission time of the first communication connection or the second communication connection which is not used as a priority connection channel;

when the first communication connection is a priority connection channel and the first transmission time and the second transmission time are smaller than the transmission time threshold value, the processing module compares the product of the weighted value and the second transmission time with the first transmission time, and when the product of the weighted value and the second transmission time is smaller than the first transmission time, the processing module closes the first communication connection;

when the second communication connection is a priority connection channel and the first transmission time and the second transmission time are smaller than the transmission time threshold, the processing module compares the product of the weighted value and the first transmission time with the second transmission time, and when the product of the weighted value and the first transmission time is smaller than the second transmission time, the processing module closes the second communication connection.

8. The network connection control system of claim 6,

setting a first communication connection or a second communication connection as a priority connection channel in the processing module;

a second hysteresis period is preset in the processing module, wherein the first hysteresis period is used for extruding the second hysteresis period;

when the first communication connection or the second communication connection as the priority connection channel is closed, starting from the starting point of closing the first communication connection or the second communication connection, and after a first hysteresis cycle, the processing module starts the first communication connection or the second communication connection again;

when the first communication connection or the second communication connection which is not used as a priority connection channel is closed, after a second hysteresis period from the starting point of closing the first communication connection or the second communication connection, the processing module detects a first network delay of the enabled first communication connection or the enabled second communication connection and a second network delay of the enabled second communication connection;

the processing module re-enables the first communication connection or the second communication connection when the first network delay or the second network delay is greater than a network delay threshold.

9. An intelligent terminal, characterized in that it comprises a network connection control system according to any one of claims 6 to 8.

10. A computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the network connection control method according to any one of claims 1 to 5.

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