CN113760048A

CN113760048A - Electronic equipment and control method

Info

Publication number: CN113760048A
Application number: CN202111054595.5A
Authority: CN
Inventors: 袁立; 蔡树会; 陈金山
Original assignee: Lenovo Beijing Ltd
Current assignee: Lenovo Beijing Ltd
Priority date: 2021-09-09
Filing date: 2021-09-09
Publication date: 2021-12-07
Anticipated expiration: 2041-09-09
Also published as: CN113760048B

Abstract

In an electronic device provided by the present application, including: the main machine at least comprises a first body and a second body which are connected in a rotating way; the display screen is rotatably connected with the host through the first body or the second body and can display contents to be output and output by the host; the first body or the second body rotates relative to the other body, so that different included angles are formed between the first body or the second body and the display screen. In the scheme, the first body and the second body rotate relatively to enable the space between the first body and the second body to change, heat dissipation is facilitated, frequency reduction operation is directly performed on the CPU, system performance of the electronic equipment is protected, and user experience is improved.

Description

Electronic equipment and control method

Technical Field

The present disclosure relates to the field of electronic device control, and more particularly, to an electronic device and a control method.

Background

An AIO (all-in-one) is an electronic device that integrates a lightweight profile and a powerful processing capability.

The AIO equipment comprises a display screen and a system part, and the air outlet of the system part is arranged on one side close to the display screen, so that the heat dissipation of the AIO equipment is easily shielded by the display screen, and the temperature value of the system is too high.

In the prior art, when the temperature value of the AIO device is too high, the CPU is down-converted from high frequency to low frequency, but direct down-conversion and the like may cause a user to jam and the like during using a machine, which affects the performance of a system part and user experience.

Disclosure of Invention

In view of the above, the present application provides an electronic device, comprising:

an electronic device, comprising:

the main machine at least comprises a first body and a second body which are connected in a rotating way;

the display screen is rotatably connected with the host through the first body or the second body and can display contents to be output and output by the host;

the first body or the second body rotates relative to the other body, so that different included angles are formed between the first body or the second body and the display screen.

Optionally, in the electronic device, the host includes:

a heat generating component disposed on the first body or the second body;

the heat dissipation module is arranged close to the heating component and used for dissipating heat of the heating component;

and the controller connected with the heat dissipation module can control the heat dissipation parameters of the heat dissipation module and/or control the performance parameters of the electronic equipment according to the included angle.

Optionally, in the electronic device, the electronic device further includes a detection element disposed on the display screen and/or the host, and the detection element is configured to detect an included angle between the first body or the second body and the display screen; and/or the presence of a gas in the atmosphere,

the host computer still including set up in the air intake of first body or the second body, the air intake set up in first body or the second body is towards the first surface of display screen.

A method of controlling an electronic device as claimed in any preceding claim, comprising:

determining an included angle between a display screen of the electronic equipment and a host, wherein the included angle comprises an included angle between a first body or a second body of the electronic equipment and the display screen;

and controlling heat dissipation parameters and/or performance parameters of the electronic equipment at least based on the included angle.

Optionally, in the method, the controlling the heat dissipation parameter and/or the performance parameter of the electronic device based on at least the included angle includes:

determining the angle range of the included angle;

if the included angle is in the first angle range, controlling the performance parameters of the electronic equipment at least based on the included angle; and/or the presence of a gas in the atmosphere,

if the included angle is in a second angle range, controlling the heat dissipation parameter of the electronic equipment or controlling the heat dissipation parameter and the performance parameter of the electronic equipment at least based on the included angle;

the electronic equipment has the maximum air intake or the minimum air intake in the first angle range, and the air intake of the electronic equipment in the second angle range is between the minimum air intake and the maximum air intake.

obtaining a first operating parameter and/or a first temperature value of a heat generating component of the electronic equipment, and controlling a heat dissipation parameter of a heat dissipation module of the electronic equipment and/or controlling a second operating parameter of the electronic equipment based on the first operating parameter and/or the first temperature value and the included angle; or the like, or, alternatively,

obtaining operation information of the electronic equipment, and controlling a heat dissipation parameter of a heat dissipation module of the electronic equipment and/or controlling a second operation parameter of the electronic equipment based on the operation information and the included angle; or the like, or, alternatively,

obtaining power supply information of the electronic equipment, and controlling a heat dissipation parameter of a heat dissipation module of the electronic equipment and/or controlling a second operation parameter of the electronic equipment based on the power supply information and the included angle; or the like, or, alternatively,

the method comprises the steps of obtaining a supporting form of a display screen of the electronic equipment supported by the first body or the second body, and controlling a heat dissipation parameter of a heat dissipation module of the electronic equipment and/or controlling a second operation parameter of the electronic equipment based on the supporting form and the included angle.

Optionally, the method, wherein controlling a second operating parameter of the electronic device includes:

controlling operating parameters of heat generating components of the electronic device and/or controlling operating application information of the electronic device.

if the electronic equipment is connected with base equipment, obtaining a third operating parameter of the base equipment, and controlling a heat dissipation parameter of a heat dissipation module of the electronic equipment and/or controlling a second operating parameter of the electronic equipment based on the third operating parameter and the included angle; or the like, or, alternatively,

and if the electronic equipment is connected with base equipment, controlling the heat dissipation parameter of the heat dissipation module of the electronic equipment and/or controlling the second operation parameter of the electronic equipment and controlling the third operation parameter of the base equipment based on the included angle.

Optionally, the method, wherein controlling a third operating parameter of the base device includes:

and controlling the operating parameters of the heating part of the base equipment and the heat dissipation parameters of the heat dissipation module based on the included angle, the heat dissipation parameters of the heat dissipation module of the electronic equipment and/or the second operating parameters so as to cooperate with the electronic equipment to execute a preset task.

Optionally, the method further includes:

outputting prompt information for adjusting the included angle and/or the supporting form of the display screen supported by the first body or the second body; and/or the presence of a gas in the atmosphere,

adjusting the included angle and/or the support form of the display screen supported by the first body or the second body based on at least heat dissipation parameters and/or performance parameters of the electronic equipment.

A readable storage medium having stored thereon a computer program for being invoked and executed by a processor for carrying out the steps of the control method according to any one of the preceding claims.

As can be seen from the above technical solutions, an electronic device provided in the present application includes: the main machine at least comprises a first body and a second body which are connected in a rotating way; the display screen is rotatably connected with the host through the first body or the second body and can display contents to be output and output by the host; the first body or the second body rotates relative to the other body, so that different included angles are formed between the first body or the second body and the display screen. In the scheme, the first body and the second body rotate relatively to enable the space between the first body and the second body to change, heat dissipation is facilitated, frequency reduction operation is directly performed on the CPU, system performance of the electronic equipment is protected, and user experience is improved.

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 introduced below, it is obvious that the drawings in the following description are only embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

Fig. 1 is a schematic structural diagram of an electronic device embodiment 1 provided in the present application;

fig. 2 is a schematic view of an electronic device in embodiment 1 of the electronic device provided in the present application;

fig. 3 is a schematic structural diagram of a host in embodiment 1 of an electronic device provided in the present application;

fig. 4 is another schematic structural diagram of a host in embodiment 1 of an electronic device provided in the present application;

fig. 5 is a schematic structural diagram of a host in embodiment 1 of an electronic device provided in the present application;

fig. 6 is a schematic structural diagram of an electronic device in embodiment 1 of the electronic device provided in this application;

fig. 7 is a schematic diagram of an electronic device in embodiment 1 of the electronic device provided in the present application;

fig. 8 is a flowchart of embodiment 1 of a control method provided in the present application;

fig. 9 is a flowchart of embodiment 2 of a control method provided in the present application;

fig. 10 is a flowchart of embodiment 3 of a control method provided in the present application;

fig. 11 is a flowchart of embodiment 4 of a control method provided in the present application;

fig. 12 is a schematic diagram of an electronic device in embodiment 4 of a control method provided in the present application;

fig. 13 is a flowchart of embodiment 5 of a control method provided in the present application;

FIG. 14 is a flow chart of embodiment 6 of a control method provided by the present application;

fig. 15 is a flowchart of a control method according to embodiment 7 of the present application.

Detailed Description

The technical solutions in 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 only a part of the embodiments of the present application, 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 application.

Fig. 1 is a schematic structural diagram of an embodiment 1 of an electronic device provided in the present application, where the electronic device includes the following structures: a host 101 and a display screen 102;

the host 101 at least comprises a first body 1011 and a second body 1012 which are rotatably connected;

the display screen 102 is rotatably connected to the host through the first body or the second body, and can display content to be output, which is output by the host;

In the structure shown in fig. 1, the display screen is actively connected to the host through the first body.

When the display screen is connected with the first body/the second body and the host, the first body/the second body is parallel to the display screen, and the other part of the second body or the first body in the host forms different included angles with the display screen.

Fig. 2 is a schematic view of the electronic device in this embodiment, in which a host 201 of the electronic device is connected to a display screen 202, and in fig. 2, angles α between the display screen of the electronic device and a second body 2011 are 0 °, 20 °, 40 °, 60 °, and the like, respectively.

Fig. 3 is a schematic structural diagram of a host in an electronic device provided in the present application, where the host includes: a heat generating component 301, a heat dissipating module 302, and a controller 303;

wherein the heat generating component 301 is disposed on the first body or the second body;

the heat dissipation module 302 is disposed adjacent to the heat generating component 301, and configured to dissipate heat of the heat generating component;

the controller 303 is connected to the heat dissipation module 302, and can control heat dissipation parameters of the heat dissipation module according to the included angle, and/or control performance parameters of the electronic device.

The heat generating component of the electronic device is a component that generates heat during operation, and may specifically be a functional chip such as a CPU (central Processing Unit) or a GPU (Graphics Processing Unit).

In specific implementation, the Controller may adopt an EC (embedded Controller)

In the structure shown in fig. 3, the heat generating component, the heat dissipating module and the controller are disposed on the second body. In an implementation, the heat generating component, the heat dissipating module and the controller may be disposed in the first body, or disposed in the first body and the second body respectively.

Specifically, due to different included angles, the size of the space between the display screen and the second body or the first body is different.

As shown in fig. 2, when the display screen and the second body are at 20 °, the space therebetween is smaller than when they are at 40 ° and 60 °.

The space between the display screen and the second body or the first body is different in size, so that the heat dissipation capacity of the area is different, the larger the space is, the ventilation is facilitated, and the stronger the heat dissipation capacity is; conversely, the smaller the space, the less the air circulation is facilitated, and the heat dissipation capability is weaker.

Therefore, the heat dissipation parameters of the heat dissipation module can be controlled based on the included angle, and if the included angle is large, the heat dissipation parameters of the heat dissipation module can be reduced; if the angle is small, the heat dissipation parameters of the heat dissipation module can be improved, so as to ensure the heat dissipation of the heating component.

Therefore, the performance parameters of the electronic equipment can be controlled based on the included angle, and the higher the performance parameters of the electronic equipment are, the larger the heat productivity of the electronic equipment is, and the larger the heat dissipation requirement is. Therefore, the angle of the included angle is large, and the performance parameters of the electronic equipment can be improved; the included angle is small, so that the performance parameters of the electronic equipment can be reduced, and the heat dissipation of the heating component is ensured.

Fig. 4 is another schematic structural diagram of a host in an electronic device according to the present application, where the host includes: a heat generating component 401, a heat dissipating module 402, a controller 403, and a detecting component 404;

the heat generating component 401, the heat dissipating module 402, and the controller 403 refer to the above explanations.

The detection piece is arranged on the display screen and/or the host, and is used for detecting an included angle between the first body or the second body and the display screen.

In the structure shown in fig. 4, the detecting member is disposed on the second body of the host.

Specifically, the detecting piece detects an included angle between the second body where the detecting piece is located and the display screen.

In specific implementation, the detecting element can be an angle sensor or a distance sensor.

The angle sensor is used for detecting an included angle between the second body where the angle sensor is located and the display screen;

the distance sensor is used for detecting the vertical distance between the setting position of the distance sensor and the display screen, and calculating to obtain the included angle between the second body and the display screen.

The detecting piece can be arranged in the display screen and used for detecting an included angle between the detecting piece and the first body or the second body.

Fig. 5 is a schematic structural diagram of a host of an electronic device provided by the present application, where the schematic structural diagram is an outer surface of the host, and the surface is a side facing a display screen, and the host 501 is provided with an air inlet 502.

The air inlet is formed in the first body or the second body, and the air inlet is formed in the first body or the second body and faces the first surface of the display screen.

In the structure shown in fig. 5, the air inlet is disposed on the second body of the host.

The heat dissipation module is matched with the air inlet, and the air inlet is used for dissipating heat of the heating component.

Therefore, the air intake sets up the first surface of second body orientation display screen in the main part, and this air intake is in this contained angle region promptly, dispels the heat through contained angle space region between this display screen and the second body, and the contained angle is big more, and the space is big more, does benefit to the circulation of air more, and the heat-sinking capability is stronger more.

Fig. 6 is a schematic structural diagram of an electronic device provided in the present application, where the electronic device includes the following structure: host 601, display screen 602, and base 603.

The host computer is arranged on the base to support the host computer and the display screen.

Wherein, this base includes bottom plate 6031 and connector 6032, and the connector slope sets up in the top of bottom plate, and connection structure sets up in connector 6032 to make the connector physical stamina support the host computer with display screen, and/or, to the host computer with display screen provides communication connection.

The bottom plate is a part for contacting with a supporting surface (such as a table top, a floor, etc.), and the contact area between the bottom plate and the supporting surface is large, so that a display screen of the electronic device and a host can be stably supported on the base.

Specifically, the base is provided with an electronic device, and the body is detachably connected with the base through a mechanical connection structure and is electrically connected with the electronic device through an electrical connection part while being mechanically connected.

The connector and the body can be only used for realizing the mechanical connection between the host and the base, namely, the base is only provided with the slot without an electric connection part, and the electric connection and the communication connection of the electronic devices in the body and the base can be realized in a wireless connection mode, namely, wireless charging and/or wireless communication can be carried out. Specifically, the electronic device arranged on the base comprises one or more of an image acquisition module, a containing groove and a function adjusting key.

As shown in fig. 7, which is a schematic diagram of the electronic device provided in the present application, the distance sensor detects a distance between the display screen and the first body or the second body and transmits a detected value to the EC, the ambient temperature sensor detects a temperature value of the heat generating component and transmits the temperature value to the EC, and the EC controls and adjusts the power of the fan and the operating parameters of the CPU. The EC and the CPU are connected via a PCIE (peripheral component interconnect express) interface.

In summary, an electronic device provided in this embodiment includes: the main machine at least comprises a first body and a second body which are connected in a rotating way; the display screen is rotatably connected with the host through the first body or the second body and can display contents to be output and output by the host; the first body or the second body rotates relative to the other body, so that different included angles are formed between the first body or the second body and the display screen. In the scheme, the first body and the second body rotate relatively to enable the space between the first body and the second body to change, heat dissipation is facilitated, frequency reduction operation is directly performed on the CPU, system performance of the electronic equipment is protected, and user experience is improved.

Corresponding to the embodiment of the electronic device provided by the application, the application also provides an embodiment of a control method applied to the electronic device.

As shown in fig. 8, a flowchart of embodiment 1 of a control method provided by the present application is applied to an electronic device, and the method includes the following steps:

step S801: determining an included angle between a display screen of the electronic equipment and the host;

the included angle comprises an included angle between a first body or a second body of the electronic equipment and the display screen.

The structure of the electronic device refers to the explanations and diagrams in the foregoing embodiments of the electronic device.

When the display screen is connected with the host through the first body, the included angle is the included angle between the display screen and the second body; when the display screen is connected with the host through the second body, the included angle is the included angle between the display screen and the first body.

The included angle may be detected by a detecting element disposed on the display screen and/or the host, and the detecting manner may refer to the explanation in the foregoing embodiment of the electronic device.

Step S802: and controlling heat dissipation parameters and/or performance parameters of the electronic equipment at least based on the included angle.

The included angle between the display screen of the electronic device and the host is different, the included angle between the display screen and the host is different in space, the larger the included angle is, the larger the space between the display screen and the host is, and the smaller the included angle is, the smaller the space between the display screen and the host is.

In summary, the control method provided in this embodiment includes: determining an included angle between a display screen of the electronic equipment and a host, wherein the included angle comprises an included angle between a first body or a second body of the electronic equipment and the display screen; and controlling heat dissipation parameters and/or performance parameters of the electronic equipment at least based on the included angle. In the scheme, the first body and the second body rotate relatively to enable the space between the first body and the second body to change, heat dissipation is facilitated, frequency reduction operation is directly performed on the CPU, system performance of the electronic equipment is protected, and user experience is improved.

As shown in fig. 9, a flowchart of embodiment 2 of a control method provided by the present application includes the following steps:

step S901: determining an included angle between a display screen of the electronic equipment and the host;

step S901 is the same as step S801 in embodiment 1, and details are not described in this embodiment.

Step S902: determining the angle range of the included angle;

step S903: and if the included angle is in the first angle range, controlling the performance parameters of the electronic equipment at least based on the included angle.

In a specific implementation, the included angle is at an angular limit reached by the relative rotation of the first body and the second body, such as 0 ° or 90 °.

Of course, it should be noted that the relative rotation between the first body and the second body to make the included angle between the display screen and the host reach the maximum value is not limited to 90 °, and the maximum value may be set according to the situation in specific implementation.

Wherein the electronic device has a maximum air intake or a minimum air intake in the first angle range.

The performance parameters of the control electronics include operating parameters of the heat generating components, such as power of the CPU, GPU, etc.

For example, when the included angle is the maximum angle, the electronic device has the maximum air intake amount within the first angle range, at this time, the space between the display screen and the second body or the first body is the maximum, which is beneficial to air circulation, and the heat dissipation capability is the strongest.

For example, when the included angle is the minimum angle, the electronic device has the minimum air intake amount in the first angle range, and at this time, the space between the display screen and the second body or the first body is the minimum, which is not favorable for air circulation, and the heat dissipation capability is the minimum.

In summary, in a control method provided in this embodiment, the controlling a heat dissipation parameter and/or a performance parameter of an electronic device based on at least the included angle includes: determining the angle range of the included angle; if the included angle is in a first angle range, performance parameters of the electronic equipment are controlled at least based on the included angle, and the electronic equipment has the maximum air intake or the minimum air intake in the first angle range. In this scheme, aiming at the condition that the angle between the display screen and the host reaches the limit value, the electronic device has the maximum air intake or the minimum air intake in the first angle range, the heat dissipation capability of the heat dissipation module cannot be further improved or reduced by adjusting the power of the heat dissipation module, and the temperature of the electronic device is adjusted by adjusting the performance parameters of the electronic device.

As shown in fig. 10, a flowchart of embodiment 3 of a control method provided by the present application includes the following steps:

step S1001: determining an included angle between a display screen of the electronic equipment and the host;

step S1001 is the same as step S801 in embodiment 1, and details are not described in this embodiment.

Step S1002: determining the angle range of the included angle;

step S1003: if the included angle is in the first angle range, controlling the performance parameters of the electronic equipment at least based on the included angle;

wherein, steps S1002-1003 are the same as steps S902-903 in embodiment 2, and are explained with reference to embodiment 2 herein, and are not repeated.

Step S1004: and if the included angle is in a second angle range, controlling the heat dissipation parameter of the electronic equipment or controlling the heat dissipation parameter and the performance parameter of the electronic equipment at least based on the included angle.

The electronic device comprises a display screen, a host and a second body, wherein an included angle between the display screen and the host is in a second angle range, at the moment, a space between the display screen and the second body or the first body is smaller than a space with the largest angle, and the air circulation capacity is smaller than the largest angle but larger than the smallest angle.

When the performance parameters of the electronic equipment are not suitable for adjustment, the adjustment of the heat dissipation parameters of the electronic equipment can be controlled only; when the performance of the electronic device can be adjusted, the heat dissipation parameter and the performance parameter of the electronic device can be adjusted respectively.

For example, in the second angle range between the display screen and the second body or the first body, the space between the display screen and the second body or the first body is favorable for air circulation, and if the application running in the electronic device cannot be stopped, that is, the running power consumption of the CPU or the GPU cannot be reduced, the heat dissipation capability of the electronic device can be increased by increasing the power of the heat dissipation module.

For example, in the second angle range between the display screen and the second body or the first body, the space between the display screen and the second body or the first body is favorable for air circulation, if the application running in the electronic device can be stopped or the heat generating component can be subjected to frequency reduction, that is, the running power consumption of the CPU or the GPU can be reduced, the heat dissipation capability of the electronic device can be increased by increasing the power of the heat dissipation module, or the temperature of the heat generating component of the electronic device can be reduced by adjusting the performance parameters of the electronic device, such as reducing the power of the heat generating component (frequency reduction or application stop).

In summary, in a control method provided in this embodiment, the controlling a heat dissipation parameter and/or a performance parameter of an electronic device based on at least the included angle includes: determining the angle range of the included angle; if the included angle is in the first angle range, controlling the performance parameters of the electronic equipment at least based on the included angle; if the included angle is in a second angle range, controlling the heat dissipation parameter of the electronic equipment or controlling the heat dissipation parameter and the performance parameter of the electronic equipment at least based on the included angle; the electronic equipment has the maximum air intake or the minimum air intake in the first angle range, and the air intake of the electronic equipment in the second angle range is between the minimum air intake and the maximum air intake. In the scheme, different modes for reducing the temperature of the electronic equipment can be selected according to different angle ranges of the included angle between the display screen and the body.

As shown in fig. 11, a flowchart of embodiment 4 of a control method provided by the present application includes the following steps:

step S1101: determining an included angle between a display screen of the electronic equipment and the host;

step S1101 is the same as step S801 in embodiment 1, and details are not repeated in this embodiment.

Wherein, step S1102: and controlling heat dissipation parameters and/or performance parameters of the electronic equipment at least based on the included angle.

In step S1102, the specific implementation manners include the following four types:

the method comprises the steps of firstly, obtaining a first operation parameter and/or a first temperature value of a heat generating component of the electronic equipment, and controlling a heat dissipation parameter of a heat dissipation module of the electronic equipment and/or controlling a second operation parameter of the electronic equipment based on the first operation parameter and/or the first temperature value and the included angle.

The first temperature value is detected by a temperature sensor arranged at a position adjacent to the heat generating component; the first operating parameter is obtained from the heat-generating component by the controller through a communication interface, such as a PCIE interface, with the heat-generating component.

In the scheme, a first operation parameter of the heat generating component is obtained, and the operation condition of the heat generating component can be determined based on the first operation parameter.

Specifically, based on the first operating parameter and the included angle, it is determined that the electronic device generates operating conditions of the heating component under the included angle, such as power consumption of the CPU, power consumption of the GPU, which applications are in an operating state, and the like, where the higher the power consumption of the heating component is, the more heat is generated, the more applications are in the operating state, and the more heat is generated.

Specifically, based on the first temperature value and the included angle, it is determined that the electronic device runs under the included angle, such as the temperature of the CPU, the temperature of the GPU, and the like, and the higher the temperature value is, the higher the power consumption of the heat generating component is.

Specifically, based on the first operating parameter, the first temperature value, and the included angle, it is determined that the electronic device is operated under the included angle by the heating component, such as the temperature of the CPU, the temperature of the GPU, and the like, and the higher the temperature value is, the higher the power consumption of the heating component is, the higher the power consumption of the CPU, the power consumption of the GPU, which applications are in an operating state, and the like, and the higher the power consumption of the heating component is, the more heat is generated, the more applications in the operating state are, and the more heat is generated.

Specifically, control electronic equipment's heat dissipation module's heat dissipation parameter includes: the power of the heat dissipation module (such as a fan) is increased or decreased.

In specific implementation, a temperature control curve can be preset, the temperature control curve corresponds to different included angles, temperatures and heat dissipation parameters, then, the corresponding temperature control curve can be selected based on the included angles and the temperatures, and the rotating speed of the fan is changed based on the selected temperature control curve, so that the heat dissipation parameters of the heat dissipation module are controlled.

For example, if the current rotation speed of the fan is 2000 revolutions, the temperature control curve is searched to obtain the rotation speed of the fan corresponding to the current included angle of 30 ° and the temperature of 50 ℃ of 2500 revolutions, and the rotation speed of the fan is adjusted to 2500 revolutions.

Wherein controlling a second operating parameter of the electronic device comprises: controlling operating parameters of heat generating components of the electronic device and/or controlling operating application information of the electronic device.

The method comprises the following steps of controlling the operating parameters of a heating component, specifically realizing control by carrying out frequency reduction operation on the heating component;

the method comprises the steps of controlling running application information of the electronic equipment, and particularly realizing control by stopping application of a control part.

And secondly, obtaining operation information of the electronic equipment, and controlling a heat dissipation parameter of a heat dissipation module of the electronic equipment and/or controlling a second operation parameter of the electronic equipment based on the operation information and the included angle.

The operation information of the electronic equipment represents the overall current operation condition of the electronic equipment, and specifically comprises operation parameters of the heat dissipation module and the heating component.

The operation parameter of the heat dissipation module is the current operation condition of the heat dissipation module, such as the rotation speed of the fan. The operating parameters of the heat-generating component characterize the current operating conditions of the heat-generating component, such as high-frequency operation, low-frequency operation, or which applications are operated.

When the heat dissipation module reaches the maximum power, the power of the heat dissipation module cannot be continuously increased, and the temperature of the electronic equipment can be reduced only by controlling the second operation parameter of the electronic equipment.

When the heat dissipation module does not reach the highest power, the power of the heat dissipation module can be continuously increased, only the operating parameters of the heat dissipation module can be controlled, or the temperature of the electronic equipment can be reduced by controlling the operating parameters of the heat dissipation module and the second operating parameters of the electronic equipment.

And thirdly, obtaining power supply information of the electronic equipment, and controlling the heat dissipation parameter of the heat dissipation module of the electronic equipment and/or controlling a second operation parameter of the electronic equipment based on the power supply information and the included angle.

The power supply of the electronic equipment comprises an alternating current power supply and a direct current power supply, wherein the alternating current power supply is an external commercial power and can provide stable electric energy for the electronic equipment; the direct current power supply is a power supply provided by a battery of the electronic equipment, can provide electric energy with stable content for a period of time for the electronic equipment, and has a maintenance time shorter than commercial power.

The method comprises the following steps of controlling the operating parameters of a heating component, specifically realizing control by carrying out frequency reduction operation on the heating component; and controlling the running application information of the electronic equipment, specifically, realizing control by stopping application of a control part.

When the power supply of the electronic equipment is an alternating current power supply, the heat dissipation parameters of the heat dissipation module are preferably improved so as to ensure application and operation in the electronic equipment; when the power supply of the electronic equipment is a direct-current power supply and the electric quantity of the power supply is larger than the threshold value, the electric quantity is large, and in order to ensure the performance of the electronic equipment, the heat dissipation parameters of the heat dissipation module are preferably improved so as to ensure the application operation in the electronic equipment; when the electric quantity of the power supply is smaller than the threshold value, the electric quantity is less, in order to ensure the running time of the electronic equipment, the running application information of the electronic equipment is preferably controlled, and the application with higher power consumption can be selected to stop running so as to reduce the temperature of the electronic equipment.

And fourthly, obtaining a supporting form of the display screen of the electronic equipment supported by the first body or the second body, and controlling the heat dissipation parameter of the heat dissipation module of the electronic equipment and/or controlling the second operation parameter of the electronic equipment based on the supporting form and the included angle.

The support form comprises a transverse screen support form and a vertical screen support form.

The display screen is supported by the first body or the second body transverse screen and supported by the vertical screen, the included angle formed by the first body or the second body transverse screen and the vertical screen is different, and the relative position between the display screen and the air inlet formed in the host is also different, so that different support forms can be adopted to reduce the temperature of the electronic equipment in different control modes.

Fig. 12 is a schematic view of an electronic apparatus in which (a) the display screen is supported by the first body vertical screen, and (b) the display screen is supported by the first body horizontal screen.

Specifically, the display screen is supported by the first body or the second body vertical screen, and the heat dissipation efficiency of the included angle area is greater than that of the horizontal screen. Correspondingly, as a control mode, when the vertical screen is supported, the temperature of the electronic equipment can be reduced by improving the power of the heat dissipation module; when the horizontal screen is supported, the down-conversion operation can be carried out on the heat generating component or partial application can be stopped.

In this embodiment, different parameters of the electronic device, including a first operating parameter and/or a first temperature value of the heat generating component, operating information of the electronic device, power information of the electronic device, and a supporting form in which the display screen is supported by the first body or the second body, are respectively combined with an included angle between the display screen and the host, and a corresponding control manner is selected, so that the temperature of the electronic device is reduced by controlling a heat dissipation parameter of the heat dissipation module and/or a second operating parameter of the electronic device (an operating parameter of the heat generating component and/or operating application information of the electronic device).

As shown in fig. 13, a flowchart of embodiment 5 of a control method provided by the present application includes the following steps:

step S1301: determining an included angle between a display screen of the electronic equipment and the host;

step S1301 is the same as step S801 in embodiment 1, and details are not described in this embodiment.

Wherein, in step S1302: and controlling heat dissipation parameters and/or performance parameters of the electronic equipment at least based on the included angle.

Wherein, step S1302 includes:

Wherein controlling a third operating parameter of the base unit comprises:

Wherein a heat sink and/or a processor are provided in the base device.

When the electronic device is connected with a base device, a third operating parameter of the base device is obtained, and the third operating parameter represents an operating state of the base device, such as high-frequency operation or low-frequency operation of a processor, an operating application program, power consumption of the operating application program, and the like.

Specifically, based on the fact that the included angle is the maximum angle, the electronic device has the maximum air intake at the included angle, and based on the third operating parameter and the included angle, the heating component of the electronic device and the base device are controlled to realize task sharing, for example, the load of the heating component is transferred to the base device, the load of the heating component is reduced, so that the heating temperature of the heating component is reduced, and if the heat dissipation parameter of the heat dissipation module in the electronic device does not reach the maximum value, the heat dissipation parameter of the heat dissipation module can be improved.

Specifically, based on the maximum angle of the included angle, if the electronic device has the maximum air intake at the included angle, based on the third operating parameter and the included angle, if the heat dissipation parameter of the heat dissipation module in the electronic device has reached the maximum value, only the heat generating component of the electronic device and the base device are controlled to realize task sharing, for example, the load of the heat generating component is transferred to the base device, and/or the heat dissipation parameter of the heat dissipation module in the electronic device is increased.

Specifically, if the heat sink is disposed in the base device, the heat dissipation load of the heat dissipation module can be transferred to the base device, and if the heat dissipation parameter of the heat dissipation module reaches the maximum value, the heat dissipation parameter of the heat sink in the base device can be further improved.

Specifically, if only the heat sink is disposed in the base device, when the electronic device is connected to the base device, the heat dissipation load of the heat dissipation module can be transferred to the base device, such that the heat dissipation parameters of the heat sink in the base device can be increased, and the heat dissipation parameters of the heat dissipation module can be decreased, so as to dissipate heat for the electronic device.

Specifically, the operating parameters of the heating components are controlled, specifically, the control is realized by performing frequency reduction operation on the heating components; and controlling the running application information of the electronic equipment, specifically, realizing control by stopping application of a control part.

In summary, in a control method provided in this embodiment, the controlling a heat dissipation parameter and/or a performance parameter of an electronic device based on at least the included angle includes: if the electronic equipment is connected with base equipment, obtaining a third operating parameter of the base equipment, and controlling a heat dissipation parameter of a heat dissipation module of the electronic equipment and/or controlling a second operating parameter of the electronic equipment based on the third operating parameter and the included angle; or if the electronic equipment is connected with base equipment, controlling the heat dissipation parameter of the heat dissipation module of the electronic equipment and/or controlling the second operation parameter of the electronic equipment and controlling the third operation parameter of the base equipment based on the included angle. In this scheme, the load of the electronic equipment and the base equipment cooperating with the heating component and the heat dissipation load of the heat dissipation module reduce the load condition of the electronic equipment, so as to reduce the temperature of the electronic equipment.

As shown in fig. 14, a flowchart of embodiment 6 of a control method provided by the present application includes the following steps:

step S1401: determining an included angle between a display screen of the electronic equipment and the host;

step S1402: controlling heat dissipation parameters and/or performance parameters of the electronic device based at least on the included angle;

steps S1401 to 1402 are the same as steps S801 to 802 in embodiment 1, and are not described in detail in this embodiment.

Step S1403: and outputting prompt information for adjusting the included angle and/or the supporting form of the display screen supported by the first body or the second body.

The method comprises the steps of determining whether an included angle and/or a supporting form need to be adjusted or not based on operating parameters of heating components in the electronic equipment.

As an example, it is determined that the operating parameter of the heat generating component in the electronic device represents that the heat dissipation amount is large, and heat dissipation needs to be increased, and specifically, the heat dissipation can be achieved by adjusting the included angle, or the current horizontal screen support is changed into the vertical screen support, and then prompt information can be generated to prompt a user to manually adjust the included angle or the support form.

As an example, when the support is currently a horizontal screen support and an included angle between the display screen and the first body or the second body is a maximum value, the heat dissipation can be increased only by changing the support form, and a prompt message is generated to prompt a user to manually adjust the support form.

In summary, the control method provided in this embodiment further includes: and outputting prompt information for adjusting the included angle and/or the supporting form of the display screen supported by the first body or the second body. In this scheme, can also adjust the contained angle or support the form through suggestion user to make user's manual adjustment contained angle or support the form, with the heat dissipation environment that changes electronic equipment, realize reducing electronic equipment's temperature.

As shown in fig. 15, a flowchart of embodiment 7 of a control method provided by the present application, where the method is applied to an electronic device, includes the following steps:

step S1501: determining an included angle between a display screen of the electronic equipment and the host;

step S1502: controlling heat dissipation parameters and/or performance parameters of the electronic device based at least on the included angle;

steps S1501 to 1502 are the same as steps S801 to 802 in embodiment 1, and are not described in detail in this embodiment.

Step S1503: adjusting the included angle and/or the support form of the display screen supported by the first body or the second body based on at least heat dissipation parameters and/or performance parameters of the electronic equipment.

The operation application and the high-frequency or low-frequency operation state of the heating component can be known based on the performance parameters of the heating component, and the heat dissipation requirement of the heating component at the current moment or at a certain future moment or within a certain period of time can be known based on the information.

Based on the result of controlling the heat dissipation parameter and/or the performance parameter of the electronic device in step S1502, the heat dissipation parameter of the heat dissipation module and the performance parameter of the heat generating component can be known, and based on the parameters, the heat dissipation requirement of the heat generating component and the heat dissipation capability of the heat dissipation module at the current time or in a future time or within a period of time can be determined, and if the two are not matched, the included angle or the support form needs to be further adjusted.

Specifically, the first body and the second body are controlled to rotate relatively based on heat dissipation parameters and/or performance parameters of the electronic device, so that an included angle between the display screen and the second body is adjusted.

Specifically, the first body and the display screen are controlled to rotate relatively based on heat dissipation parameters and/or performance parameters of the electronic equipment, so that the display screen is adjusted from horizontal screen support/vertical screen support to vertical screen support/horizontal screen support.

In summary, the control method provided in this embodiment further includes: adjusting the included angle and/or the support form of the display screen supported by the first body or the second body based on at least heat dissipation parameters and/or performance parameters of the electronic equipment. In this scheme, can also automatic adjustment contained angle or support the form to change electronic equipment's heat dissipation environment, realize reducing electronic equipment's temperature.

Corresponding to the embodiment of the control method provided by the application, the application also provides a readable storage medium corresponding to the control method.

Wherein the readable storage medium has stored thereon a computer program which is called and executed by a processor to implement the steps of the control method according to any one of the preceding claims.

Specifically, the computer program stored in the readable storage medium executes the control method, and reference may be made to the foregoing control method embodiments.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other. For the device provided by the embodiment, the description is relatively simple because the device corresponds to the method provided by the embodiment, and the relevant points can be referred to the method part for description.

The previous description of the provided embodiments is provided to enable any person skilled in the art to make or use the present application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the application. Thus, the present application is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features provided herein.

Claims

1. An electronic device, comprising:

2. The electronic device of claim 1, the host comprising:

a heat generating component disposed on the first body or the second body;

3. The electronic device according to claim 2, further comprising a detecting element disposed on the display screen and/or the host, wherein the detecting element is configured to detect an included angle between the first body or the second body and the display screen; and/or the presence of a gas in the atmosphere,

4. A control method of an electronic device according to any one of claims 1 to 3, comprising:

5. The method of claim 4, wherein controlling a heat dissipation parameter and/or a performance parameter of an electronic device based at least on the included angle comprises:

determining the angle range of the included angle;

6. The method of claim 4 or 5, wherein controlling a heat dissipation parameter and/or a performance parameter of an electronic device based at least on the included angle comprises:

7. The method of claim 6, wherein controlling a second operating parameter of the electronic device comprises:

8. The method of claim 4 or 5, wherein controlling a heat dissipation parameter and/or a performance parameter of an electronic device based at least on the included angle comprises:

9. The method of claim 8, wherein controlling a third operating parameter of the base unit comprises:

10. The method of claim 4, further comprising: