CN111107619A - Power control method of communication system, communication system and storage medium - Google Patents

Abstract

The invention relates to the technical field of communication, and discloses a control method of a communication system, the communication system and a storage medium, wherein the method comprises the following steps: obtaining power distribution information of each subsystem according to a first mapping relation configured in advance; the first mapping relation is used for indicating power distribution information corresponding to the subsystem; the power distribution information comprises a power distribution parameter and a first weighting coefficient; after the power output of each subsystem is correspondingly controlled according to the power distribution information of each subsystem, the total power of all the subsystems is calculated; when the total power of all the subsystems is not in the preset first power range, the power output of each subsystem is correspondingly adjusted according to the first weighting coefficient of each subsystem, so that the total power of all the subsystems is in the first power range. The invention realizes reasonable power distribution to all subsystems and achieves the optimized utilization of the whole power of the communication system.

Description

Power control method of communication system, communication system and storage medium

Technical Field

The present invention relates to the field of communications technologies, and in particular, to a power control method for a communication system, and a storage medium.

Background

Communication systems are a general term for technical systems for carrying out information transmission processes, and modern communication systems mainly implement information transmission by means of transmission mechanisms of electromagnetic waves in free space or in a guide medium. With the development of communication technology and information processing technology, people have higher and higher requirements on system capacity; therefore, how to increase the system capacity is a key problem to be solved by the communication system, and improving the power allocation strategy of the communication system is a main measure for solving the problem.

Currently, existing communication systems are generally directed to power management of individual subsystems. However, in the process of implementing the present invention, the present inventors found that the prior art has at least the following technical problems: since the existing communication system generally has a plurality of subsystems, when power management is performed by individually controlling each subsystem, it is impossible to reasonably perform power allocation.

Disclosure of Invention

The invention aims to provide a power control method, a communication system and a storage medium of a communication system, which can reasonably distribute power to all subsystems and achieve the optimal utilization of the whole power of the system.

In order to solve the above technical problem, the present invention provides a power control method for a communication system, including:

obtaining power distribution information of each subsystem according to a first mapping relation configured in advance; wherein the first mapping relation is used for indicating power allocation information corresponding to the subsystem; the power distribution information comprises a power distribution parameter and a first weighting coefficient;

after the power output of each subsystem is correspondingly controlled according to the power distribution information of each subsystem, the total power of all the subsystems is calculated;

when the total power of all the subsystems is not in a preset first power range, correspondingly adjusting the power output of each subsystem according to the first weighting coefficient of each subsystem so as to enable the total power of all the subsystems to be in the first power range

Preferably, the power control method of the communication system further includes:

respectively detecting the power and the throughput of each subsystem;

according to the power and the throughput of each subsystem, calculating an initial weighting coefficient of each subsystem correspondingly;

calculating the total power of all the subsystems after correspondingly controlling the power output of each subsystem according to the power of each subsystem and the initial weighting coefficient;

when the total power of all the subsystems is in a preset second power range, taking the initial weighting coefficient of the subsystem as a first weighting coefficient of the subsystem;

and establishing the first mapping relation according to the power of each subsystem and the first weighting coefficient.

Preferably, the power control method of the communication system further includes:

when the total power of all the subsystems is not in the second power range, adjusting the initial weighting coefficient of each subsystem until the total power of all the subsystems is in the second power range;

and taking the adjusted initial weighting coefficient of the subsystem as a first weighting coefficient of the subsystem.

Preferably, the power control method of the communication system further includes:

acquiring the highest temperature and the lowest temperature of each subsystem;

configuring the maximum value and the minimum value of the weighting coefficient of each subsystem according to the maximum temperature and the minimum temperature of each subsystem;

when the first weighting coefficient of any subsystem is smaller than the minimum value of the weighting coefficient, replacing the first weighting coefficient of the subsystem with the minimum value of the weighting coefficient;

and when the first weighting coefficient of any subsystem is larger than the maximum value of the weighting coefficient, replacing the first weighting coefficient of the subsystem with the maximum value of the weighting coefficient.

As a preferred scheme, the correspondingly calculating an initial weighting coefficient of each subsystem according to the power and throughput of each subsystem specifically includes:

establishing a second mapping relation according to the power and the throughput of each subsystem; wherein the second mapping is used to indicate a relationship between power and throughput of the subsystem;

calculating the throughput of each subsystem on unit power according to the second mapping relation;

and correspondingly determining the initial weighting coefficient of each subsystem according to the throughput of each subsystem on unit power.

Preferably, the power control method of the communication system further includes:

converting the detected power of each subsystem into binary data; then the process of the first step is carried out,

establishing the first mapping relation according to the power of each subsystem and the first weighting coefficient, specifically:

binary data corresponding to the power of the subsystem is used as a power distribution parameter of the subsystem;

and establishing the first mapping relation according to the power distribution parameter of each subsystem and the first weighting coefficient.

As a preferred scheme, the converting the detected power of each subsystem into binary data specifically includes:

converting the detected power equivalence ratio of each subsystem into a voltage value;

normalizing the voltage value of each subsystem;

obtaining binary data of each subsystem according to the normalized voltage value of each subsystem and a preset functional relation; wherein the functional relationship is used to indicate binary data corresponding to the normalized voltage value.

Preferably, the power control method of the communication system further includes:

when the fact that any subsystem releases power is detected, the power released by the subsystem is distributed to the rest subsystems according to the first weighting coefficients of the rest subsystems.

In order to solve the same technical problem, accordingly, an embodiment of the present invention further provides a communication system, including a main system and a plurality of subsystems, wherein the main system is configured to execute the power control method of the communication system.

In order to solve the same technical problem, an embodiment of the present invention further provides a computer-readable storage medium, where the storage medium stores a program, and when the program runs, the method for controlling power of the communication system is implemented.

Compared with the prior art, the invention provides a control method of a communication system, the communication system and a storage medium, wherein the total power of all subsystems is calculated after the power output of each subsystem is correspondingly controlled according to the power distribution information of each subsystem, and when the total power of all subsystems is not in a preset first power range, the power output of each subsystem is correspondingly adjusted according to the first weighting coefficient of each subsystem, so that the total power of all subsystems is in the first power range, reasonable power distribution of all subsystems is realized, and the optimal utilization of the whole power of the communication system is achieved.

Drawings

Fig. 1 is a flowchart illustrating a power control method of a communication system according to an embodiment of the present invention;

fig. 2 is a flowchart illustrating a power control method of another communication system according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a communication system according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Fig. 1 is a schematic flow chart of a power control method of a communication system according to an embodiment of the present invention.

In an embodiment of the present invention, a communication system includes a main system and a sub-system; the host system may be a Central Processing Unit (CPU) system, which is not limited in the present invention.

The power control method of the communication system provided by the embodiment of the present invention can be executed by the main system, and the embodiment of the present invention is described with the main system as an execution subject.

In the embodiment of the present invention, the power control method of the communication system includes the following steps S101 to S103:

s101, obtaining power distribution information of each subsystem according to a first mapping relation configured in advance; wherein the first mapping relation is used for indicating power allocation information corresponding to the subsystem; the power allocation information includes a power allocation parameter and a first weighting coefficient.

As can be understood, the main system is pre-configured with a first mapping relationship for indicating power allocation information corresponding to each subsystem; and when the main system receives a control instruction for performing power distribution on the subsystems, the main system obtains the power distribution information of each subsystem according to the first mapping relation.

The main system may obtain the power distribution parameter and the first weighting coefficient of each of the subsystems through training, and use the obtained power distribution parameter and the first weighting coefficient as the power distribution information of the subsystems, thereby configuring the first mapping relationship. The power distribution parameters are specifically: a parameter indicative of power allocated to the subsystem.

S102, after the power output of each subsystem is correspondingly controlled according to the power distribution information of each subsystem, the total power of all the subsystems is calculated.

Wherein, the power output of each subsystem is correspondingly controlled according to the power distribution information of each subsystem, which is specifically represented as: and the main system weights the power distribution parameters of the subsystem according to the first weighting coefficient of the subsystem and sends the weighted power distribution parameters to the subsystem so that the subsystem adjusts the power output of the subsystem according to the weighted power distribution parameters. Of course, the main system may also directly send the power distribution parameter of the subsystem and the first weighting coefficient to the subsystem, so that the subsystem weights the power distribution parameter of the subsystem according to the first weighting coefficient, and adjusts the power output of the subsystem according to the weighted power distribution parameter.

After the main system controls the power output of the subsystems, the main system detects the current power of each subsystem and calculates the total power of all the subsystems according to the current power of each subsystem; wherein the total power of all the subsystems is specifically the sum of the powers of all the subsystems in the communication system.

In addition, it should be noted that, in this embodiment, the weighting coefficient matrix may also be formed by the first weighting coefficient of each subsystem; therefore, when controlling the power output of the sub-subsystem, the main system may call the weighting coefficient of the sub-system in the weighting matrix to control the power output of the sub-system according to the power of the sub-system.

S103, when the total power of all the subsystems is not in a preset first power range, correspondingly adjusting the power output of each subsystem according to the first weighting coefficient of each subsystem so as to enable the total power of all the subsystems to be in the first power range.

In practical implementation, when the total power of all the subsystems is not in the preset first power range, it indicates that the power distribution to the subsystems does not meet the distribution expectation at this time, so the power output of the subsystem is adjusted accordingly according to the first weighting coefficient of the subsystem, and each subsystem is adjusted in such a way that the total power of all the subsystems is in the first power range, so that the power distribution of the subsystems meets the distribution expectation. Wherein the first power range can be set according to actual use conditions.

Specifically, when the total power of all the subsystems is not within a preset first power range, the correspondingly adjusting the power output of each subsystem according to the first weighting coefficient of each subsystem so that the total power of all the subsystems is within the first power range specifically includes:

when the total power of all the subsystems is larger than the upper limit value of the first power range, calculating a first difference value between the total power of all the subsystems and the upper limit value of the first power range;

correspondingly adjusting the power output of each subsystem according to the first difference and the first weighting coefficient of each subsystem, so that the total power of all the subsystems is greater than or equal to the upper limit value of the first power range and less than or equal to the upper limit value of the first power range;

when the total power of all the subsystems is smaller than the lower limit value of the first power range, calculating a second difference value between the total power of all the subsystems and the lower limit value of the first power range;

and correspondingly adjusting the power output of each subsystem according to the second difference and the first weighting coefficient of each subsystem, so that the total power of all the subsystems is greater than or equal to the lower limit value of the first power range and less than or equal to the upper limit value of the first power range.

It can be understood that, when the total power of all the subsystems is greater than the upper limit value of the first power range, the power value to be reduced of each subsystem may be calculated according to the first difference and the first weighting coefficient of each subsystem, and then the power output of each subsystem is correspondingly adjusted according to the power value to be reduced of each subsystem, so that the total power of all the subsystems is within the first power range. In addition, when the total power of all the subsystems is smaller than the lower limit value of the first power range, the power value to be increased of each subsystem can be calculated according to the second difference and the first weighting coefficient of each subsystem, and then the power output of each subsystem is correspondingly adjusted according to the power value to be increased of each subsystem, so that the total power of all the subsystems is in the first power range.

In addition, it should be noted that when the total power of all the subsystems is within the preset first power range, it indicates that the power distribution to the subsystems at this time meets the distribution expectation, and therefore, the power output of each subsystem does not need to be readjusted, that is, the main system keeps controlling the power output of the subsystem according to the power distribution parameter and the first weighting factor of the subsystem.

In the embodiment of the invention, after the power output of each subsystem is correspondingly controlled according to the power distribution information of each subsystem, the total power of all the subsystems is calculated, and when the total power of all the subsystems is not in a preset first power range, the power output of each subsystem is correspondingly adjusted according to the first weighting coefficient of each subsystem, so that the total power of all the subsystems is in the first power range, the reasonable power distribution of all the subsystems is realized, and the optimal utilization of the whole power of the communication system is achieved.

In a preferred embodiment, as shown in fig. 2, in order to implement configuring the first mapping relationship in the main system, the power control method of the communication system of this embodiment further includes the following steps S1-S5:

s1, respectively detecting the power and the throughput of each subsystem;

s2, calculating an initial weighting coefficient of each subsystem according to the power and the throughput of each subsystem;

s3, calculating the total power of all subsystems after correspondingly controlling the power output of each subsystem according to the power of each subsystem and the initial weighting coefficient;

s4, when the total power of all the subsystems is in a preset second power range, taking the initial weighting coefficient of the subsystem as a first weighting coefficient of the subsystem;

s5, establishing the first mapping relation according to the power of each subsystem and the first weighting coefficient.

In a preferred embodiment, in order to facilitate data storage and computation by the communication system, the power control method of the communication system according to this embodiment further includes:

converting the detected power of each subsystem into binary data; then the process of the first step is carried out,

in step S2, the main system may calculate an initial weighting factor for each of the subsystems according to binary data corresponding to the power of the subsystem and the throughput of the subsystem.

In step S3, after the power output of each subsystem is controlled according to the power of each subsystem and the initial weighting coefficient, the total power of all subsystems is calculated, which is specifically represented as: and after the power output of each subsystem is correspondingly controlled according to the binary data corresponding to the power of each subsystem and the initial weighting coefficient, calculating the total power of all the subsystems according to the binary data corresponding to the current power of each subsystem. Specifically, the main system weights the binary data corresponding to the power of the subsystem according to the initial weighting coefficient of the subsystem to obtain the binary data weighted by the subsystem, and sends the binary data weighted by the subsystem to the subsystem, so that the subsystem converts the binary data weighted by the subsystem into a power value, and adjusts the power output of the subsystem according to the power value. Of course, the main system may also directly send the binary data corresponding to the power of the subsystem and the first weighting coefficient to the subsystem, so that the subsystem weights the binary data corresponding to the power of the subsystem according to the first weighting coefficient, converts the weighted binary data into a power value, and adjusts its power output according to the power value.

After the main system controls the power output of the subsystem, the subsystem converts the current power into binary data and feeds the binary data back to the main system; and after the main system obtains the binary data fed back by each subsystem, summing the obtained binary data to obtain the total power of all the subsystems.

When step S4 is implemented, the main system is pre-configured with a binary data range corresponding to the second power range; the main system compares the sum of the binary data fed back by the subsystem with the binary data range corresponding to the second power range to obtain a comparison result; the comparison result comprises that the sum of the binary data fed back by the subsystems is in a binary data range corresponding to the second power range, namely the total power of all the subsystems is in the second power range; and the sum of the binary data fed back by the subsystems is not in the binary data range corresponding to the second power range, namely the total power of all the subsystems is not in the second power range.

In step S5, the establishing the first mapping relationship according to the power of each subsystem and the first weighting coefficient specifically includes:

binary data corresponding to the power of the subsystem is used as a power distribution parameter of the subsystem;

and establishing the first mapping relation according to the power distribution parameter of each subsystem and the first weighting coefficient.

It is understood that binary data corresponding to the power of the subsystem and the first weighting factor are used as the power distribution information, so as to establish the first mapping relationship. At this time, since the first mapping relationship is specifically used for indicating the binary data and the first weighting coefficient corresponding to each of the subsystems; therefore, when step S102 is implemented, the correspondingly controlling the power output of each subsystem according to the power distribution information of each subsystem is specifically as follows: the main system weights the binary data corresponding to the power of the subsystem according to the first weighting coefficient of the subsystem to obtain the binary data weighted by the subsystem, and sends the binary data weighted by the subsystem to the subsystem, so that the subsystem converts the binary data weighted by the subsystem into a power value after receiving the binary data weighted by the subsystem, and adjusts the power output of the subsystem according to the power value. Of course, the main system may also directly send the binary data corresponding to the power of the subsystem and the first weighting coefficient to the subsystem, so that the subsystem weights the binary data corresponding to the power of the subsystem according to the first weighting coefficient, converts the weighted binary data into a power value, and adjusts its power output according to the power value.

Further, the converting the detected power of each of the subsystems into binary data specifically includes:

converting the detected power equivalence ratio of each subsystem into a voltage value;

normalizing the voltage value of each subsystem;

obtaining binary data of each subsystem according to the normalized voltage value of each subsystem and a preset functional relation; wherein the functional relationship is used to indicate binary data corresponding to the normalized voltage value.

It should be noted that, here is only one specific implementation manner of converting the power of the subsystem into the binary data, and the embodiment of the present invention does not limit the specific manner of converting the power of the subsystem into the binary data, and those skilled in the art may also adopt other manners according to the specific situation in the practical application to convert the power of the subsystem into the binary data.

In the embodiment of the invention, the detected power of the subsystem is converted into binary data, so that the main system can store and process the data conveniently, and the control efficiency of the subsystem is improved.

In a preferred embodiment, the step S2 of calculating the initial weighting factor of each subsystem according to the power and throughput of each subsystem includes the following steps S21-S23:

s21, establishing a second mapping relation according to the power and the throughput of each subsystem; wherein the second mapping is used to indicate a relationship between power and throughput of the subsystem;

s22, calculating the throughput of each subsystem on unit power according to the second mapping relation;

and S23, according to the throughput of each subsystem on unit power, determining the initial weighting coefficient of each subsystem correspondingly.

It can be understood that, according to the detected power and throughput of the subsystem, the relationship between the power and throughput of the subsystem, that is, the second mapping relationship, can be obtained; then, calculating the throughput of the subsystem on unit power according to the relation between the power and the throughput of the subsystem; obtaining the throughput of each subsystem on unit power by the method; finally, according to the throughput of each subsystem on unit power, an initial weighting coefficient of each subsystem is determined. It should be noted that the throughput per unit power of each subsystem may be converted proportionally, so as to obtain an initial weighting coefficient for each subsystem.

In a preferred embodiment, after calculating the total power of all the subsystems in the step S3 after controlling the power output of each subsystem according to the power of each subsystem and the initial weighting factor respectively, and before establishing the first mapping relationship according to the power of each subsystem and the first weighting factor in the step S5, the power control method of the communication system further comprises the following steps S4' -S4 ":

s4', when the total power of all the subsystems is not in the second power range, adjusting the initial weighting coefficient of each subsystem until the total power of all the subsystems is in the second power range;

s4', taking the adjusted initial weighting coefficient of the subsystem as the first weighting coefficient of the subsystem.

It is understood that when the total power of all the subsystems is not in the second power range, the initial weighting coefficients of each subsystem are proportionally adjusted so that the total power of all the subsystems is in the second power range. Wherein the second power range can be set according to actual use conditions.

In a preferred embodiment, before the step S5 establishes the first mapping relationship according to the power of each subsystem and the first weighting factor, the method for controlling power of a communication system further includes the following steps:

acquiring the highest temperature and the lowest temperature of each subsystem;

configuring the maximum value and the minimum value of the weighting coefficient of each subsystem according to the maximum temperature and the minimum temperature of each subsystem;

when the first weighting coefficient of any subsystem is smaller than the minimum value of the weighting coefficient, replacing the first weighting coefficient of the subsystem with the minimum value of the weighting coefficient;

and when the first weighting coefficient of any subsystem is larger than the maximum value of the weighting coefficient, replacing the first weighting coefficient of the subsystem with the maximum value of the weighting coefficient.

It is understood that the main system may configure the minimum value of the weighting coefficients of the subsystem according to the highest temperature of the subsystem, and configure the maximum value of the weighting coefficients of the subsystem according to the lowest temperature of the subsystem, thereby implementing the configuration of two weighting coefficients at the extreme temperatures to define the range of the weighting coefficients of the subsystem; therefore, after the first weighting coefficient of the subsystem is obtained in step S4 or S4 ″, when the first weighting coefficient of the subsystem is smaller than the minimum value of the weighting coefficients of the subsystem, the minimum value of the weighting coefficients of the subsystem is used as the first weighting coefficient of the subsystem; when the first weighting coefficient of the subsystem is larger than the maximum value of the weighting coefficient of the subsystem, taking the maximum value of the weighting coefficient of the subsystem as the first weighting coefficient of the subsystem; when the first weighting coefficient of the subsystem is greater than or equal to the minimum value of the weighting coefficient of the subsystem and is less than or equal to the maximum value of the weighting coefficient of the subsystem, the first weighting coefficient of the subsystem does not need to be changed, so that the finally obtained first weighting coefficient of each subsystem is within the range of the weighting coefficient of the corresponding subsystem.

In the embodiment of the invention, the maximum value and the minimum value of the weighting coefficient of each subsystem are configured according to the maximum temperature and the minimum temperature of each subsystem, so that the first weighting coefficient of each subsystem is between the maximum value and the minimum value of the weighting coefficient, and the change of the ambient temperature is considered in the process of carrying out power distribution on the subsystems, thereby realizing dynamic compensation according to the change of the ambient temperature, further ensuring reasonable power distribution on all the subsystems, and achieving the optimal utilization of the overall power consumption of the system.

In a preferred embodiment, the power control method of the communication system further includes the following steps:

when the fact that any subsystem releases power is detected, the power released by the subsystem is distributed to the rest subsystems according to the first weighting coefficients of the rest subsystems.

It can be understood that, when the main system detects that any one of the subsystems releases power consumption, the main system may correspondingly distribute the released power consumption to the remaining subsystems according to the first weighting coefficients of the remaining subsystems except the subsystem releasing power consumption, thereby further realizing reasonable power distribution to all the subsystems.

In order to solve the same technical problem, accordingly, an embodiment of the present invention further provides a main system 101, where the main system 101 is configured to execute the power control method of the communication system. For the power control method of the communication system, reference may be made to the above description, and the detailed description of the invention is omitted here.

As shown in fig. 3, to solve the same technical problem, an embodiment of the present invention further provides a communication system 100, which includes a plurality of subsystems 102 and the above-mentioned main system 101.

In order to solve the same technical problem, an embodiment of the present invention further provides a computer-readable storage medium, where a program is stored, and when the program runs, the power control method of the communication system is implemented.

In summary, the present invention provides a control method of a communication system, a communication system and a storage medium, wherein after the power output of each subsystem is correspondingly controlled according to the power distribution information of each subsystem, the total power of all the subsystems is calculated, and when the total power of all the subsystems is not within a preset first power range, the power output of each subsystem is correspondingly adjusted according to a first weighting coefficient of each subsystem, so that the total power of all the subsystems is within the first power range, thereby implementing reasonable power distribution on all the subsystems and achieving optimal utilization of the overall power of the communication system.

The above description is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and substitutions can be made without departing from the technical principle of the present invention, and these modifications and substitutions should also be regarded as the protection scope of the present invention.

Claims (10)

1. A method for power control in a communication system, comprising:

obtaining power distribution information of each subsystem according to a first mapping relation configured in advance; wherein the first mapping relation is used for indicating power allocation information corresponding to the subsystem; the power distribution information comprises a power distribution parameter and a first weighting coefficient;

after the power output of each subsystem is correspondingly controlled according to the power distribution information of each subsystem, the total power of all the subsystems is calculated;

when the total power of all the subsystems is not in a preset first power range, the power output of each subsystem is correspondingly adjusted according to the first weighting coefficient of each subsystem, so that the total power of all the subsystems is in the first power range.

2. The power control method of the communication system of claim 1, further comprising:

respectively detecting the power and the throughput of each subsystem;

according to the power and the throughput of each subsystem, calculating an initial weighting coefficient of each subsystem correspondingly;

calculating the total power of all the subsystems after correspondingly controlling the power output of each subsystem according to the power of each subsystem and the initial weighting coefficient;

when the total power of all the subsystems is in a preset second power range, taking the initial weighting coefficient of the subsystem as a first weighting coefficient of the subsystem;

and establishing the first mapping relation according to the power of each subsystem and the first weighting coefficient.

3. The power control method of the communication system of claim 2, further comprising:

when the total power of all the subsystems is not in the second power range, adjusting the initial weighting coefficient of each subsystem until the total power of all the subsystems is in the second power range;

and taking the adjusted initial weighting coefficient of the subsystem as a first weighting coefficient of the subsystem.

4. The power control method of the communication system according to claim 2 or 3, wherein the power control method of the communication system further comprises:

acquiring the highest temperature and the lowest temperature of each subsystem;

configuring the maximum value and the minimum value of the weighting coefficient of each subsystem according to the maximum temperature and the minimum temperature of each subsystem;

when the first weighting coefficient of any subsystem is smaller than the minimum value of the weighting coefficient, replacing the first weighting coefficient of the subsystem with the minimum value of the weighting coefficient;

and when the first weighting coefficient of any subsystem is larger than the maximum value of the weighting coefficient, replacing the first weighting coefficient of the subsystem with the maximum value of the weighting coefficient.

5. The method as claimed in claim 2 or 3, wherein said calculating the initial weighting factor for each of the subsystems according to the power and throughput of each of the subsystems comprises:

establishing a second mapping relation according to the power and the throughput of each subsystem; wherein the second mapping is used to indicate a relationship between power and throughput of the subsystem;

calculating the throughput of each subsystem on unit power according to the second mapping relation;

and correspondingly determining the initial weighting coefficient of each subsystem according to the throughput of each subsystem on unit power.

6. The power control method of the communication system according to claim 2 or 3, wherein the power control method of the communication system further comprises:

converting the detected power of each subsystem into binary data; then the process of the first step is carried out,

establishing the first mapping relation according to the power of each subsystem and the first weighting coefficient, specifically:

binary data corresponding to the power of the subsystem is used as a power distribution parameter of the subsystem;

and establishing the first mapping relation according to the power distribution parameter of each subsystem and the first weighting coefficient.

7. The method of claim 6, wherein said converting the detected power of each of said subsystems into binary data comprises:

converting the detected power equivalence ratio of each subsystem into a voltage value;

normalizing the voltage value of each subsystem;

obtaining binary data of each subsystem according to the normalized voltage value of each subsystem and a preset functional relation; wherein the functional relationship is used to indicate binary data corresponding to the normalized voltage value.

8. The power control method of the communication system according to any of claims 1-3, wherein the power control method of the communication system further comprises:

when the fact that any subsystem releases power is detected, the power released by the subsystem is distributed to the rest subsystems according to the first weighting coefficients of the rest subsystems.

9. A communication system comprising a main system for performing the power control method of the communication system according to any one of claims 1 to 8 and a plurality of subsystems.

10. A computer-readable storage medium, characterized in that the storage medium has stored thereon a program which, when executed, implements a power control method of a communication system according to any one of claims 1 to 8.

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