CN109660469B - Method and terminal for synchronously changing network signals and device with storage function - Google Patents

Abstract

The application relates to the technical field of terminals, and discloses a method for synchronously changing network signals, a terminal and a device with a storage function. The method comprises the steps that a network signal synchronous change control circuit detects a regional network signal, a regional network signal change track is obtained, a terminal network signal change track corresponding to the regional network signal change track is determined, the terminal network signal change track is sent to a processing circuit, the processing circuit sends a generated synchronous change instruction to the network signal synchronous change control circuit, and the network signal synchronous change control circuit responds to the synchronous change instruction and synchronously changes the terminal network signal. By the mode, the network signal synchronous change control circuit can be used for detecting the change of the regional network signals in real time and synchronously changing the terminal network signals in time, so that the network delay is reduced.

Description

Method and terminal for synchronously changing network signals and device with storage function

Technical Field

The present application relates to the field of terminals, and in particular, to a method for synchronously changing network signals, a terminal, and a device having a storage function.

Background

When the area network changes, the terminal often cannot change synchronously in time along with the change of the area network, and the problem of network delay always exists.

Network latency refers to the fact that network signals are not always transmitted, but are converted, stored, processed, and then retransmitted at many network nodes. When busy, the network signal may be queued for a short period of time after storage before being processed. In a short period of time in the queue, network delay is presented to the user, which may be manifested as a network outage of a certain second or a slow time for opening a page, causing inconvenience to the user.

Disclosure of Invention

The technical problem mainly solved by the application is to provide a method for synchronously changing network signals, a terminal and a device with a storage function, and the method and the terminal can solve the problem that when regional network signals change, the terminal network signals are delayed, so that the terminal network signals and the regional network signals cannot change simultaneously.

In order to solve the technical problem, the application adopts a technical scheme that: a method of synchronously varying network signals is provided, comprising: the network signal synchronous change control circuit detects a regional network signal, acquires a regional network signal change track, determines a terminal network signal change track corresponding to the regional network signal change track, and sends the terminal network signal change track to the processing circuit, the processing circuit sends a generated synchronous change instruction to the network signal synchronous change control circuit, and the network signal synchronous change control circuit responds to the synchronous change instruction and synchronously changes the terminal network signal.

In order to solve the above technical problem, another technical solution adopted by the present application is: there is provided a terminal, including: communication circuitry and processing circuitry coupled to each other for implementing a method as described above.

In order to solve the above technical problem, the present application adopts another technical solution: provided is a device having a storage function, including: program data is stored which can be executed to implement the methods as described above.

The beneficial effect of this application does: different from the prior art, the method and the device have the advantages that the area network signals are detected through the network signal synchronous change control circuit, the area network signal change track is obtained, the terminal network signal change track corresponding to the area network signal change track is determined, the terminal network signal change track is sent to the processing circuit, the processing circuit sends the generated synchronous change instruction to the network signal synchronous change control circuit, the network signal synchronous change control circuit responds to the synchronous change instruction to synchronously change the terminal network signals, accordingly, the network signal synchronous change control circuit can be used for detecting the area network signal change in real time, the terminal network signals are synchronously changed in time, and network delay is further reduced.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic flow chart diagram of a first embodiment of a method for synchronously changing network signals according to the present application;

FIG. 2 is a schematic flow chart of a second embodiment of the method for synchronously changing network signals according to the present application;

FIG. 3 is a schematic flow chart of a third embodiment of the method for synchronously changing network signals according to the present application;

FIG. 4 is a schematic flow chart of a fourth embodiment of the method for synchronously changing network signals according to the present application;

FIG. 5 is a schematic flow chart of a fifth embodiment of the method for synchronously changing network signals according to the present application;

FIG. 6 is a schematic structural diagram of an embodiment of a terminal of the present application;

FIG. 7 is a schematic structural diagram of an embodiment of the apparatus with storage function of the present application.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments obtained by a person of ordinary skill in the art without any inventive work based on the embodiments in the present application are within the scope of protection of the present application.

As shown in fig. 1, a first embodiment of the method for synchronously changing network signals of the present application includes:

s1: the network signal synchronous change control circuit detects the regional network signal and obtains the change track of the regional network signal.

The Local Area Network signal is not limited to a signal of a specific Area, the Local Area Network may be a Local Area Network (LAN), a Wide Area Network (WAN), and a metropolitan Area Network (man), and the Local Area Network may also be a wireless Network, and the wireless Network includes a wireless Network (such as 5G, 4G, 3G, or GPRS) and a wireless Local Area Network (WiFi) implemented by a public mobile communication Network. The network signal synchronous change control circuit is a circuit for controlling the synchronous change of the local area network signals and the terminal network, and the local area network signal change track is a set of a series of local area network signal track change values and comprises at least one local area network signal track change value. The network signal synchronous change control circuit can detect the regional network signals, and if the changed regional network signals are detected, a series of regional network signal track change values are obtained.

S2: and determining a terminal network signal change track corresponding to the regional network signal change track.

The terminal network signal change track is a set of a series of terminal network signal track change values, and comprises at least one terminal network signal track change value. After the network signal synchronous change control circuit acquires the change track of the regional network signal, a series of terminal network signal track change values can be determined by using a formula or an algorithm and the like.

S3: and sending the terminal network signal change track to a processing circuit.

And after determining the terminal network signal change track, the network signal synchronous change control circuit sends the terminal network signal change track to the processing circuit for processing.

S4: and the processing circuit sends the generated synchronous change instruction to the network signal synchronous change control circuit.

The synchronous change instruction is an instruction generated by triggering the terminal network signal change track, and can be used for authorizing or informing the network signal synchronous change control circuit to synchronously change the terminal network signal according to the regional network signal change track.

Specifically, after the network signal synchronous change control circuit sends the terminal network signal change track to the processing circuit, the processing circuit generates a synchronous change instruction and sends the synchronous change instruction to the network signal synchronous change control circuit for authorization to inform the network signal synchronous change control circuit that the regional network signal and the terminal network signal can be synchronized, wherein the synchronous change instruction includes the network signal change track.

S5: the network signal synchronous change control circuit responds to the synchronous change instruction and synchronously changes the terminal network signal.

The network signal synchronous change control circuit responds to the synchronous change instruction sent by the processing circuit and synchronously changes the terminal network signals according to the terminal network signal change track.

The method comprises the steps of detecting regional network signals through a network signal synchronous change control circuit, obtaining regional network signal change tracks, determining terminal network signal change tracks corresponding to the regional network signal change tracks, sending the terminal network signal change tracks to a processing circuit, sending generated synchronous change instructions to the network signal synchronous change control circuit through the processing circuit, responding the synchronous change instructions by the network signal synchronous change control circuit, synchronously changing the terminal network signals, detecting regional network signal changes in real time by utilizing the network signal synchronous change control circuit, synchronously changing the terminal network signals in time, and further reducing network delay.

As shown in fig. 2, a second embodiment of the method for synchronously changing network signals according to the present application is based on the first embodiment, and the step S1 is further defined to include:

s11: the network signal detection sub-circuit detects the regional network signal in real time, acquires a regional network signal change track and generates a regional network signal change induction detection signal, wherein the regional network signal change induction detection signal comprises the regional network signal track.

The network signal synchronous change control circuit comprises a network signal detection sub-circuit and a synchronous change sub-circuit, wherein the network signal detection sub-circuit is used for detecting the regional network signals, and the synchronous change sub-circuit is used for synchronously changing the regional network signals and the terminal network signals. The network signal detection sub-circuit continuously detects the regional network signal within a preset time, the preset time can be set by a user, at least one regional network signal track change value is obtained, and the obtained previous regional network signal track change value and the obtained next regional network signal track change value may be different or the same. The network signal detection sub-circuit generates a local area network signal change induction detection signal after acquiring a local area network signal change track formed by a series of local area network signal change track values, wherein the signal is used for informing the synchronous change sub-circuit that the synchronous local area network signal and the terminal network signal can be operated, and the signal comprises a local area network signal change track formed by a series of local area network signal change track values.

S12: the network signal detection sub-circuit sends the local network signal change sensing detection signal to the synchronous change sub-circuit.

After the network signal detection sub-circuit generates a local network signal change induction detection signal comprising a local network signal track, the network signal detection sub-circuit sends the local network signal change track formed by a series of local network signal change track values to the synchronous change sub-circuit so as to trigger the synchronous change sub-circuit to carry out the operation of synchronizing the local network signal and the terminal network signal.

As shown in fig. 3, a third embodiment of the method for synchronously changing network signals according to the present application is based on the second embodiment, and the step S2 is further defined to include:

s21: the synchronous change sub-circuit induces a detection signal according to the received regional network signal change to obtain at least one regional network signal track change value.

The synchronous change sub-circuit receives the local area network signal change induction detection signal sent by the processing circuit, namely the synchronous change sub-circuit receives a local area network signal change track, wherein the local area network signal change track comprises at least one local area network signal track change value.

S22: and determining a terminal network signal track change value corresponding to the regional network signal track change value.

After the synchronization change sub-circuit acquires the change value of the signal track of the local area network, a change value of the signal track of the terminal network corresponding to the change value of the signal track of the local area network can be calculated by a formula or an algorithm, and the like, wherein one change value of the signal track of the local area network corresponds to one change value of the signal track of the terminal network, or one change value of the signal track of the local area network corresponds to a plurality of change values of the signal track of the terminal network, or a plurality of change values of the signal track of the local area network correspond to one change value of the signal track of the terminal network, and the correspondence is not necessarily one-to-one correspondence, so that no specific limitation is made.

The specific formula or algorithm may be selected according to the requirement of synchronization precision, for example, the change value of the signal trajectory of the area network may be superimposed on a preset value to obtain a corresponding change value of the signal trajectory of the terminal network, or the change value of the signal trajectory of the area network may be mapped to the corresponding change value of the signal trajectory of the terminal network based on a preset mapping relationship, which is not specifically limited herein.

Specifically, in one embodiment, the network signal detection sub-circuit detects that a change value of a local network signal track at a certain time is a, acquires a and sends a to the synchronous change sub-circuit, and the synchronous change sub-circuit calculates a change value B of a terminal network signal track corresponding to a through a preset formula.

In this embodiment, step S3 is further defined to include:

s31: the synchronous change sub-circuit generates a terminal network signal change track and sends the terminal network signal change track to the processing circuit.

And the synchronous change sub-circuit generates a terminal network signal change track through a series of terminal network signal track change values at different determined moments, wherein the terminal network signal change track comprises a series of terminal network signal track change values at different moments, including at least one terminal network signal track change value.

As shown in fig. 4, a fourth embodiment of the method for synchronously changing network signals according to the present application is based on the third embodiment, and the step S22 is further defined to include:

s221: the synchronous change sub-circuit obtains the change values of the regional network signal tracks at a plurality of moments.

S222: and (3) calculating the change value of the terminal network signal track at the same moment by using the following formula:

|±Δ∑f(a)(n)(t1)|-|±Δ∑f(b)(n)(t1)|

≈|±Δ∑f(a)(n)(t2)|-|±Δ∑f(b)(n)(t2)|≈…

≈|±Δ∑f(a)(n)[t(n)]|-|±Δ∑f(b)(n)[t(n)]|

wherein, (a), (n) is local network signal, f (b), (n) is terminal network signal, Δ Σ f (a), (n) (t (n)) is local network signal track change value at time t (n), and Δ Σ f (b) (t (n)) is terminal network signal track change value at time t (n).

After the network signal detection sub-circuit sends the regional network signal track change values at multiple moments to the synchronous change sub-circuit, the synchronous change sub-circuit obtains the regional network signal track change values at the multiple moments. The network signal detection sub-circuit acquires a regional network signal change track value at a certain moment, and sends the regional network signal change track value at the moment to the synchronous change sub-circuit, and after the synchronous change sub-circuit acquires the regional network signal change values at different moments, the terminal network signal change value at the moment can be calculated by using the formula based on the principle that the difference between the regional network signal change value and the terminal network signal change value at the same moment is approximately constant. When the formula is used for calculation, the value which is approximately equal to the value can be treated as equal sign, and meanwhile, the terminal network signal track change value at the initial moment can be set to be 0 or other preset values, so that the terminal network signal track change value at other moments can be calculated. Of course, in other embodiments, the terminal network signal trajectory change value at other time may also be set, or estimated by other methods, which is not limited herein.

Specifically, in one embodiment, the network signal detection sub-circuit obtains a change trajectory value Δ Σ f (a) at time t1 (n) [ t1], and sends Δ Σ f (a) and (n) [ t1] to the synchronization change sub-circuit. At time t2, a local area network signal change track value Δ Σ f (a) (n) (t2) is acquired, and Δ Σ f (a) (n) (t2) is sent to the synchronous change sub-circuit. The default value of the change of the terminal network signal trajectory at time t1 is zero, i.e., Δ Σ f (b) is (n) [ t1] ═ 0. According to the following formula:

|±Δ∑f(a)(n)(t1)|-|±Δ∑f(b)(n)(t1)|

≈|±Δ∑f(a)(n)(t2)|-|±Δ∑f(b)(n)(t2)|

the terminal network signal trajectory change value Δ Σ f (b) (n) (t2) at time t2 can be calculated, and so on at other times.

As shown in fig. 5, a fifth embodiment of the method for synchronously changing network signals according to the present application is based on the third embodiment, and before step S4, the method includes:

s41: and the data processing sub-circuit acquires a terminal network signal change track.

The processing circuit comprises a data processing sub-circuit, and before the generated synchronous change instruction is sent to the network signal synchronous change control circuit, the data processing sub-circuit can obtain a series of terminal network signal track change values from the synchronous change sub-circuit of the network signal synchronous change control circuit.

S42: and superposing the initial terminal network signal track with the terminal network signal change track to obtain the synchronous terminal network signal.

The initial terminal network signal is a terminal network signal when the area network is not changed, and the initial terminal network signal track is composed of a series of initial terminal network signal track values. The processing sub-circuit can obtain a synchronous terminal network signal corresponding to the terminal network signal change track value at the same time by superposing the initial terminal network signal track and the terminal network signal change track, wherein the synchronous terminal network signal is the changed terminal network signal.

S43: a synchronization change instruction is generated.

After the processing sub-circuit obtains the synchronous terminal network signal, a synchronous change instruction is generated, and the synchronous change instruction can be sent to the synchronous change sub-circuit so as to send the synchronous terminal network signal to the synchronous change sub-circuit and authorize the synchronous change sub-circuit to perform synchronous processing on the terminal network signal.

With continuing reference to fig. 5, the present method for synchronously changing network signals further defines step S5 comprising:

s51: the network signal synchronous change control circuit changes the terminal network signal from the initial terminal network signal to the synchronous terminal network signal in response to the synchronization instruction.

After the processing sub-circuit generates the synchronous change instruction, the synchronous change sub-circuit in the network signal synchronous change control circuit responds to the synchronous change instruction to change the terminal network signal at a certain moment from the initial terminal network signal at the moment to the synchronous terminal network signal corresponding to the same moment.

As shown in fig. 6, an embodiment of the terminal of the present application includes:

a communication circuit 10 and a processing circuit 20 connected to each other;

the communication circuit 10 is used for the control circuit to detect the regional network signal, obtain the change track of the regional network signal, determine the change track of the terminal network signal corresponding to the change track of the regional network signal, send the change track of the terminal network signal to the processing circuit, the processing circuit sends the generated synchronous change instruction to the network signal synchronous change control circuit, and the network signal synchronous change control circuit responds to the synchronous change instruction to synchronously change the terminal network signal.

The processing circuit 20 is configured to obtain the terminal network signal change trajectory through the communication circuit 10, superimpose the initial terminal network signal trajectory on the terminal network signal change trajectory to obtain a synchronous terminal network signal, and generate a synchronous change instruction, so as to implement the method provided by any one of the first to sixth embodiments of the method for synchronously changing a network signal and any non-conflicting combination of the embodiments.

The Processing circuit 20 controls the operation of the terminal, the Processing circuit 20 may also be referred to as a Central Processing Unit (CPU). The processing circuit 20 may be an integrated circuit chip having signal processing capabilities. The processing circuit 20 may also be a general purpose processor, a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), an off-the-shelf programmable gate array (FPGA) or other programmable logic device, discrete gate or transistor logic, discrete hardware components. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like.

The terminal may further comprise a memory (not shown) for storing instructions and data necessary for the operation of the processing circuit 20.

In other embodiments, the terminal may further include other components such as a display screen and a keyboard according to specific requirements, which are not specifically limited herein.

As shown in fig. 7, an embodiment of the apparatus 30 with storage function of the present application includes:

stored is program data 301, the program data 301 being executable to implement the methods provided by any one of the first to sixth embodiments of the method of synchronously varying network signals of the present application and any non-conflicting combinations. A blank memory cell, which is a memory space theoretically capable of storing a certain number of bytes, is selected in the device 30 having a storage function according to the size of the program data 301 to be stored, and a blank memory cell, which is a blank memory cell in which data is not stored. The blank storage unit is selected according to the size of the program data 301 to be stored so that the size of the storage space of the blank storage unit can store the program data 301 to be stored.

The device 30 with storage function may be a portable storage medium such as a usb disk and an optical disk, or may be a terminal, a server, or a separate component integrated in the terminal or the server, such as a chip.

The above description is only an embodiment of the present application, and not intended to limit the scope of the present application, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the specification and the drawings, or which are directly or indirectly applied to other related technical fields, are also included in the scope of the present application.

Claims (6)

1. A method of synchronizing a changing network signal, the method comprising:

the network signal synchronous change control circuit detects a regional network signal and acquires a regional network signal change track;

determining a terminal network signal change track corresponding to the regional network signal change track;

sending the terminal network signal change track to a processing circuit;

the processing circuit sends the generated synchronous change instruction to the network signal synchronous change control circuit;

the network signal synchronous change control circuit responds to the synchronous change instruction and synchronously changes the terminal network signal;

the network signal synchronous change control circuit comprises a network signal detection sub-circuit and a synchronous change sub-circuit;

the network signal synchronous change control circuit detects the change of the regional network signal, and the acquiring of the change track of the regional network signal comprises the following steps:

the network signal detection sub-circuit detects a regional network signal in real time, acquires a change track of the regional network signal and generates a regional network signal change induction detection signal, wherein the regional network signal change induction detection signal comprises the regional network signal track;

the network signal detection sub-circuit sends the regional network signal change induction detection signal to the synchronous change sub-circuit;

the regional network signal change track comprises at least one regional network signal change value;

the determining of the terminal network signal change trajectory corresponding to the regional network signal change trajectory includes:

the synchronous change sub-circuit obtains the change value of the at least one regional network signal track according to the received regional network signal change induction detection signal;

determining a terminal network signal track change value corresponding to the regional network signal track change value;

the sending the terminal network signal change track to a processing circuit comprises:

the synchronous change sub-circuit generates a terminal network signal change track and sends the terminal network signal change track to the processing circuit;

wherein the terminal network signal change track comprises at least one terminal network signal track change value.

2. The method of claim 1, wherein the determining a terminal network signal trajectory change value corresponding to the regional network signal trajectory change value comprises:

the synchronous change sub-circuit acquires the change values of the regional network signal tracks at a plurality of moments;

and (3) calculating the change value of the terminal network signal track at the same moment by using the following formula:

wherein, f (a), (n) is local area network signal, f (b), (n) is terminal network signal,

the change value of the regional network signal track at the moment t (n),

the terminal network signal track change value at the time t (n).

3. The method of claim 1, wherein the processing circuit comprises a data processing sub-circuit;

before the processing circuit sends the generated synchronous change instruction to the network signal synchronous change control circuit, the processing circuit further includes:

the data processing sub-circuit acquires the change track of the terminal network signal;

superposing the initial terminal network signal track on the terminal network signal change track to obtain a synchronous terminal network signal;

generating a synchronous change instruction;

wherein the synchronization change instruction comprises the synchronization terminal network signal.

4. The method of claim 3, wherein the network signal synchronous change control circuit is responsive to the synchronous change instruction to synchronously change the terminal network signal including:

and the network signal synchronous change control circuit responds to the synchronous change instruction to change the terminal network signal from the initial terminal network signal to the synchronous terminal network signal.

5. A terminal, comprising: the network signal synchronous change control circuit and the processing circuit are connected with each other;

the network signal synchronous change control circuit is used for controlling a circuit to detect a regional network signal, acquiring a regional network signal change track, determining a terminal network signal change track corresponding to the regional network signal change track, sending the terminal network signal change track to a processing circuit, and responding to a synchronous change instruction sent by the processing circuit to synchronously change the terminal network signal;

the processing circuit is used for generating a synchronous change instruction after acquiring the change track of the terminal network signal and sending the synchronous change instruction to the network signal synchronous change control circuit;

the network signal synchronous change control circuit comprises a network signal detection sub-circuit and a synchronous change sub-circuit;

the network signal detection sub-circuit is used for detecting a regional network signal in real time, acquiring a regional network signal change track, generating a regional network signal change induction detection signal and sending the regional network signal change induction detection signal to the synchronous change sub-circuit, wherein the regional network signal change induction detection signal comprises the regional network signal track;

the regional network signal track comprises at least one regional network signal track variation value;

the synchronous change sub-circuit is used for acquiring at least one regional network signal track change value according to the received regional network signal change induction detection signal and determining a terminal network signal track change value corresponding to the regional network signal track change value;

generating the terminal network signal change track, and sending the terminal network signal change track to the processing circuit; wherein the terminal network signal change track comprises at least one terminal network signal change value.

6. An apparatus having a storage function, characterized in that program data are stored, which program data can be executed to implement the method according to any one of claims 1 to 4.

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