CN111384584B - Antenna radiator position adjusting method, storage medium and electronic device - Google Patents

Abstract

The embodiment of the application provides an antenna radiator position adjusting method, a storage medium and an electronic device, wherein the electronic device comprises a scroll body and an antenna radiator, the scroll body comprises a rotating shaft and a rotating part, the rotating part rotates around the rotating shaft, the rotating shaft is arranged on the axis of the scroll body, the rotating part is arranged on the axis around the rotating shaft, and the antenna radiator is arranged on the rotating part; the method comprises the following steps: driving the antenna radiator to rotate and acquiring signal strength values corresponding to the antenna radiator at a plurality of positions; determining a position corresponding to the maximum signal intensity value as a target position from the signal intensity values corresponding to the positions; and rotating the antenna radiator to the target position. By adjusting the position of the antenna radiator, the quality of the antenna radiator signal is improved, and the use requirements of users are met.

Description

Antenna radiator position adjusting method, storage medium and electronic device

Technical Field

The present disclosure relates to the field of electronic technologies, and in particular, to an antenna radiator position adjustment method, a storage medium, and an electronic device.

Background

With the development of communication technology, electronic devices such as smart phones are becoming more and more popular. In the related art, the antenna radiator of the electronic device is generally fixedly arranged at a certain position of the electronic device, and when the antenna radiator is shielded or the signal of the antenna radiator at the current position is poor, the signal intensity of the antenna radiator cannot meet the user requirement.

Disclosure of Invention

The embodiment of the application provides an antenna radiator position adjusting method, a storage medium and an electronic device, which can adjust the position of an antenna radiator according to requirements, improve the quality of an antenna radiator signal and meet the use requirements of users.

In a first aspect, an embodiment of the present application provides an antenna radiator position adjustment method, which is applied to an electronic device, where the electronic device includes a reel body and an antenna radiator, the reel body includes a rotating shaft and a rotating member, the rotating member rotates around the rotating shaft, the rotating shaft is disposed on an axis of the reel body, an axis of the rotating member rotating around the rotating shaft is disposed on the axis, and the antenna radiator is disposed on the rotating member; the method comprises the following steps:

driving the antenna radiator to rotate and acquiring signal strength values corresponding to the antenna radiator at a plurality of positions;

determining a position corresponding to the maximum signal intensity value as a target position from the signal intensity values corresponding to the positions;

and rotating the antenna radiator to the target position.

In a second aspect, an embodiment of the present application further provides a storage medium, on which a computer program is stored, and when the computer program runs on a computer, the computer is caused to execute the steps of the antenna radiator position adjusting method.

In a third aspect, an embodiment of the present application further provides an electronic device, including:

the scroll comprises a scroll body and a control device, wherein the scroll body comprises a rotating shaft and a rotating part, the rotating part rotates around the rotating shaft, the rotating shaft is arranged on the axis of the scroll body, and the axis of the rotating part rotating around the rotating shaft is arranged on the axis;

an antenna radiator disposed on the rotation member;

the radio frequency module is connected with the antenna radiator and is used for acquiring the signal intensity value received by the antenna radiator;

the control module is connected with the radio frequency module and used for driving the antenna radiating body to rotate and acquiring signal strength values corresponding to the antenna radiating body at a plurality of positions through the radio frequency module; determining the position with the maximum signal intensity value as a target position from the signal intensity values corresponding to the positions; and rotating the antenna radiator to the target position.

The method for adjusting the position of the antenna radiator provided by the embodiment of the application comprises the steps of firstly driving the antenna radiator to rotate and obtaining signal strength values corresponding to the antenna radiator at a plurality of positions; then, determining the position corresponding to the maximum signal intensity value as a target position from the signal intensity values corresponding to the positions; and finally, rotating the antenna radiator to the target position. Through the adjustment to the antenna radiator position, improved the quality of antenna radiator signal, satisfied user's user demand.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings used in the description of the embodiments will be briefly introduced below. It is obvious that the drawings in the following description are only some embodiments of the application, and that for a person skilled in the art, other drawings can be derived from them without inventive effort.

Fig. 1 is a first partial assembly view of an electronic device according to an embodiment of the present disclosure.

Fig. 2 is a second partial assembly view of an electronic device according to an embodiment of the present disclosure.

Fig. 3 is a third partial assembly view of an electronic device according to an embodiment of the present disclosure.

Fig. 4 is a fourth partial assembly view of an electronic device according to an embodiment of the present application.

Fig. 5 is a fifth partial assembly view of an electronic device according to an embodiment of the present application.

Fig. 6 is a sixth partial assembly view of an electronic device provided in an embodiment of the present application.

Fig. 7 is a schematic view of an electronic device provided in an embodiment of the present application, where a flexible display screen is in an extended state.

Fig. 8 is a first flowchart of a method for adjusting a position of an antenna radiator according to an embodiment of the present disclosure.

Fig. 9 is a second flowchart of a method for adjusting a position of an antenna radiator according to an embodiment of the present disclosure.

Fig. 10 is a third flowchart of a method for adjusting a position of an antenna radiator according to an embodiment of the present application.

Fig. 11 is a fourth flowchart of a method for adjusting a position of an antenna radiator according to an embodiment of the present application.

Fig. 12 is a fifth flowchart of a method for adjusting a position of an antenna radiator according to an embodiment 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. It is to be understood that the embodiments described are only a few embodiments of the present application and not all 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.

The following is a detailed description of the analysis.

In the present embodiment, description will be made from the perspective of an electronic apparatus.

Referring to fig. 1, fig. 1 is a first partial assembly view of an electronic device according to an embodiment of the present disclosure. The electronic device 100 includes a spool body 101 and an antenna radiator 103, the spool body 101 includes a rotation shaft 1011 and a rotation member 1012, the rotation member 1012 rotates around the rotation shaft 1011, the antenna radiator 103 is disposed on the rotation member 1012, the spool body 101 includes a first end 1013 and a second end 1014 disposed at both ends, the rotation member 1012 is disposed at the first end 1013 or the second end 1014, the rotation shaft 1011 is disposed on an axis 1015 of the spool body, an axial center of the rotation member 1012 rotating around the rotation shaft 1011 is disposed on the axis 1015, and the rotation shaft 1011 may be disposed at the first end 1013 or the second end 1014 of the spool body 101. Since the antenna radiator 103 is disposed on the rotor 1012, the antenna radiator 103 may be disposed on the first end 1013 or the second end 1014 of the spool body 101.

Referring to fig. 2, fig. 2 is a second partial assembly view of an electronic device according to an embodiment of the present disclosure. The antenna radiator may be disposed on the rotating member 1012, the rotating member 1012 may be in a ring shape, the rotating shaft 1011 is disposed in the ring shape of the rotating member 1012, and the rotating member 1012 may rotate around the rotating shaft 1011 while driving the antenna radiator 103 to rotate, in this embodiment, the antenna radiator 103 is a first antenna radiator 1031 disposed on a rotating member 1012, and the rotating member 1012 is disposed on a first end 1013 of the spool body 101, it being understood that the rotating member 1012 may also be disposed on a second end 1014 of the spool body 101. The rotating shaft 1011 further comprises a rotating shaft support 1016 connected with the rotating shaft, the rotating shaft support 1016 can fix the rotating shaft 1011 on the axis of the reel body and fix the rotating shaft 1011 in the ring of the rotating part 1012, so that the function of rotating the rotating part 1012 around the rotating shaft 1011 can be realized, and the position of the antenna radiator can be adjusted by driving the rotating part 1012 to rotate, and the quality of the antenna radiator signal can be improved.

The electronic device 100 includes a radio frequency module 104 and a control module 105, the radio frequency module 104 is connected to the antenna radiator 103, the radio frequency module 104 is configured to obtain a signal strength value received by the antenna radiator 103, the radio frequency module 104 may be configured to receive and transmit a signal from the antenna radiator 103, convert a radio signal received by the antenna radiator 103 into a wired electrical signal, convert the wired electrical signal into a radio signal, and transmit the radio signal, and the antenna radiator 103 is connected to the radio frequency module 104 through a feeder line.

The control module 105 is connected with the radio frequency module 104, the control module 105 is configured to drive the antenna radiator 103 to rotate, acquire signal strength values corresponding to the antenna radiator 103 at multiple positions through the radio frequency module 104, and determine, from the signal strength values corresponding to the multiple positions, a position with a maximum strength value as a target position; the antenna radiator 103 is rotated to a target position, the rf module 104 and the control module 105 are disposed on a motherboard 106 of the electronic device, and the motherboard 106 may be disposed at a middle position of the reel body 101.

In some embodiments, the antenna radiator comprises at least two first antenna radiators, each of the at least two first antenna radiators being disposed at the first end or the second end, e.g., two first antenna radiators disposed at the first end, or two first antenna radiators disposed at the second end. Referring to fig. 3, fig. 3 is a third partial assembly view of the electronic device according to the embodiment of the present disclosure, in which the antenna radiator 103 includes at least two first antenna radiators 1031, the at least two first antenna radiators 1031 are uniformly disposed on the rotating member 1012, the rotating member 1012 is disposed at the first end 1013 of the spool body, and the rotating member 1012 can also be disposed at the second end 1014 of the spool body 101. Evenly set up to divide equally according to the number of first antenna radiator 1031 the number of degrees that rotates a week of rotation piece 1012, set up first antenna radiator 1031 on rotation piece 1012 according to this number of degrees interval that divides equally, for example, when first antenna radiator 1031 quantity is two, rotation piece 1012 rotates a week and is 360, the number of degrees that can obtain the interval between two first antenna radiator 1031 through the calculation is 180, when first antenna radiator 1031 quantity is three, the number of degrees that can obtain the interval between three first antenna radiator through the calculation is 120, through setting up a plurality of first antenna radiator 1031, can reduce the pivoted time of antenna radiator, improve the efficiency of antenna radiator to the signal transceiving.

In some embodiments, the antenna radiator comprises at least two first antenna radiators, at least one first antenna radiator being disposed at the first end portion and at least one first antenna radiator being disposed at the second end portion. Referring to fig. 4, fig. 4 is a fourth partial assembly view of an electronic device according to an embodiment of the disclosure. The two first antenna radiators 1031 are respectively provided on the two rotation members 1012, and the two rotation members 1012 are respectively provided at the first end 1013 and the second end 1014 of the reel body 101. The antenna radiator 103 may further include 4 first antenna radiators 1031, two first antenna radiators 1031 are uniformly disposed on one rotating member 1012, the other two first antenna radiators 1031 are uniformly disposed on the other rotating member 1012, and the two rotating members 1012 are disposed at the first end 1013 and the second end 1014 of the spool body 101, respectively. By arranging the antenna radiator at different positions of the scroll body 101, when one of the positions is blocked, the signal quality of the antenna radiator is poor, and a better signal of the antenna radiator can be obtained.

The electronic device described above includes at least two first antenna radiators, and it is understood that the electronic device may further include 3 or 4 or more first antenna radiators, the number and the positions of the antenna radiators may be set according to the structure of the electronic device and the user's requirement for signal quality, and the first antenna radiators may be antenna radiators of GSM, WCDMA, LTE, etc., so that the signal requirements of the electronic device for 2G, 3G, 4G, and 5G can be met, and the electronic device can receive and transmit antenna radiator signals of each frequency band.

In some embodiments, the antenna radiator includes at least a first antenna radiator and a second antenna radiator, please refer to fig. 5, and fig. 5 is a fifth partial assembly diagram of an electronic device according to an embodiment of the present disclosure. The antenna radiator 103 includes a first antenna radiator 1031 and a second antenna radiator 1032, the first antenna radiator 1031 is provided on the rotation member 1012, the rotation member 1012 is provided on the first end 1013 of the spool body 101, the second antenna radiator 1032 is provided on the other rotation member 1012, and the other rotation member 1012 is provided on the second end 1014 of the spool body 101.

In some embodiments, the antenna radiator may further include two first antenna radiators and two second antenna radiators, please refer to fig. 6, where fig. 6 is a sixth partial assembly diagram of an electronic device according to an embodiment of the present disclosure. The two first antenna radiators are uniformly disposed on the rotating member 1012, the rotating member 1012 is disposed at the first end 1013 of the spool body 101, the two second antenna radiators are uniformly disposed on the other rotating member 1012, and the other rotating member 1012 is disposed at the second end 1014 of the spool body 101.

Can set up the quantity and the antenna radiator position of antenna radiator according to electronic equipment's structure and user to signal quality's demand, first antenna radiator can be GSM, WCDMA, the antenna radiator of LTE sharing, can realize electronic equipment to 2G, 3G and 4G's signal demand, can realize electronic equipment to the receiving and dispatching of the radio signal of each frequency channel, second antenna radiator can be WIFI, GPS sharing antenna radiator, can realize electronic equipment to the WIFI signal, the demand of GPS signal, through setting up different antenna radiators in the different positions of spool body 101, satisfy electronic equipment to the demand of different frequency channel radio signals, can realize electronic equipment to the receiving and dispatching of the radio signal of different frequency channels.

In the description of the present application, it is to be understood that the terms "first", "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implying any number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more features.

Referring to fig. 7, fig. 7 is a schematic view illustrating a flexible display screen in an extended state in an electronic device according to an embodiment of the present application. In this embodiment, the electronic device 100 includes a reel body 101 and a flexible display screen 102.

The flexible display screen 102 may be a touch screen display incorporating conductive capacitive touch sensor electrode layers or other touch sensor components (e.g., resistive touch sensor components, acoustic touch sensor components, force-based touch sensor components, light-based touch sensor components, etc.), or may be a non-touch sensitive flexible display. Capacitive touch screen electrodes may be formed from an array of indium tin oxide pads or other transparent conductive structures.

The flexible display screen 102 may include an array of display pixels formed from Liquid Crystal Display (LCD) components, an electrophoretic display pixel array, a plasma display pixel array, an organic light emitting diode display pixel array, an electrowetting display pixel array, or display pixels based on other display technologies. A flexible display cover layer, such as a flexible transparent glass layer, a flexible light-transmissive plastic, a flexible sapphire, or other flexible transparent dielectric layer, may be used to protect the flexible display screen 102.

The flexible display screen 102 is wound in the scroll body 101 in a winding state, the flexible display screen 102 can be unwound from the scroll body 101 in an unwinding state, the winding state of the flexible display screen 102 can be a standby state or a screen part display state of the electronic device 100, the unwinding state of the flexible display screen 102 can be a working state of the electronic device 100, wherein the flexible display screen 102 is used for displaying images, compared with a flat display screen, the flexible display screen 102 adopts a flexible substrate to replace a rigid substrate such as a glass substrate, the flexible display screen 102 can be deformed such as curled, bent and folded, the electronic device 100 can be conveniently carried in a winding state of the flexible display screen 102, the space occupied by the flexible display screen 102 is reduced, the electronic device can have a larger size for displaying images in an unfolding state of the flexible display screen 102, and meanwhile, the requirements of users on portability of the electronic device and large-size display screens are met.

The electronic devices described above may be computing devices such as laptop computers, computer monitors containing embedded computers, tablets, cellular telephones, media players, or other handheld or portable electronic devices, smaller devices (such as wrist-watch devices, wall-mounted devices, headset or earpiece devices, devices embedded in eyeglasses, or other devices worn on the head of a user, or other wearable or miniature devices), televisions, computer displays that do not contain embedded computers, gaming devices, navigation devices, embedded systems (such as systems in which an electronic device with a display is installed in a kiosk or automobile), devices that implement the functionality of two or more of these devices, or other electronic devices. In the exemplary configuration of fig. 1, the electronic device 100 is a portable device, such as a cellular telephone, media player, tablet computer, or other portable computing device. Other configurations may be used for electronic device 100, if desired. The example of fig. 1 is merely exemplary.

An antenna radiator adjusting method applied to the electronic device provided in any of the above embodiments is provided below.

Referring to fig. 8, fig. 8 is a first flowchart of a method for adjusting a position of an antenna radiator according to an embodiment of the present application, specifically, the method includes:

and 201, driving the antenna radiator to rotate, and acquiring signal strength values corresponding to the antenna radiator at a plurality of positions.

The antenna radiator is arranged on the rotating member, the control module drives the rotating member to rotate around the rotating shaft to drive the antenna radiator to rotate around the rotating shaft, in the rotation process of the antenna radiator, the radio frequency module obtains signal strength values corresponding to the antenna radiator at multiple positions, specifically, the antenna radiator can rotate around the rotating shaft by 360 degrees, methods for obtaining the signal strength values corresponding to the antenna radiator at multiple positions are various, for example, a signal strength value corresponding to one position is recorded every 10 degrees of rotation of the antenna radiator, when the rotation of the antenna radiator is finished, signal strength values at 36 different positions are recorded, signal strength values corresponding to the antenna radiator at multiple positions can be recorded by setting a fixed time, for example, the time for rotating the antenna radiator by 360 degrees around the rotating shaft is 1s, and the signal strength values of the positions of the antenna radiator can be recorded every 20ms, when the rotation of the antenna radiator is finished, the signal strength values of 50 different positions are obtained, and it can be understood that when the signal strength values corresponding to the different positions are obtained, the position information is recorded at the same time.

And 202, determining the position corresponding to the maximum signal intensity value as a target position from the signal intensity values corresponding to the multiple positions.

After the radio frequency module obtains the strength values corresponding to the antenna radiator at the multiple positions, the control module determines the position with the maximum signal strength value as the target position from the strength values corresponding to the multiple positions, and it can be understood that the control module includes a comparison unit, and obtains the signal strength value with the maximum signal strength value by comparing the obtained strength values corresponding to the antenna radiator at the multiple positions one by one. It is understood that the position information may be angle information of the rotation member rotating to the position, for example, 10 ° of rotation of the rotation member records a signal intensity value of an antenna radiator, and the corresponding position information is 10 °, 20 °, 30 ° … … 350 °, and 360 °, and may also be time information of rotation of the rotation member to the position, for example, 20ms of rotation of the rotation member records a signal intensity value of an antenna radiator, and the rotation member rotates 20ms, 40ms, 60ms … … 980ms, and 1000ms respectively to the position according to the corresponding position information.

The position information of the antenna radiator in the rotation process may also be obtained by other methods, which are not limited herein.

And 203, rotating the antenna radiator to a target position.

The control module drives the antenna radiator to rotate to the marked target position, and it can be understood that the control module drives the rotating member to rotate, so as to drive the antenna radiator to rotate, the signal intensity value corresponding to the target position is the maximum, the position information is taken as the angle information of the rotating member rotating to the position for example, when the angle information corresponding to the target position is less than 180 degrees, the rotating member is driven to rotate clockwise by the angle corresponding to the target position, when the angle information corresponding to the target position is greater than 180 degrees, the rotating member is driven to rotate counterclockwise by the angle which is a group angle with the angle corresponding to the target position, for example, when the angle corresponding to the target position is 90 degrees, the rotating member is driven to rotate clockwise by 90 degrees, the antenna radiator is rotated to the target position, when the angle corresponding to the target position is 270 degrees, the rotating member is driven to rotate counterclockwise by 90 degrees, and 90 degrees can be obtained by subtracting 270 degrees from 360 degrees, the antenna radiator is rotated to a target position by a group angle of 90 degrees and 270 degrees. Compared with the time required for the antenna radiator to rotate to the target position only in one direction, the method for driving the antenna radiator to rotate to the target position shortens the time for the antenna radiator to rotate to the target position and improves the working efficiency of the antenna radiator.

The method described in the above embodiments is further illustrated in detail by way of example.

Referring to fig. 9, fig. 9 is a second flowchart of a method for adjusting a position of an antenna radiator according to an embodiment of the present application, specifically, the method includes:

301, the antenna radiation body includes two at least first antenna radiation bodies, and two at least first antenna radiation bodies evenly set up on a rotation piece, when receiving and dispatching data signal instruction, will rotate the turned angle that rotates a week and divide equally according to the quantity of first antenna radiation body, obtain a first turned angle of first antenna radiation body pivoted, the drive rotates a first turned angle. The corresponding step is skipped 303.

At least two first antenna radiators are uniformly arranged on a rotating part, the number of degrees of the rotating part rotating for a circle is uniformly divided according to the number of the first antenna radiators, the first antenna radiators are arranged on the rotating part according to the number of degrees obtained by the division, for example, when the number of the first antenna radiators is 2, the angle between the two first antenna radiators is 180 degrees, and when the number of the first antenna radiators is 3, the angle between the two first antenna radiators is 120 degrees.

The data signal receiving and sending instruction can be that a user opens a data flow switch of the electronic equipment, or can be a mechanical switch which is arranged on the scroll body and can be opened manually by the user, and the mechanical switch can trigger the data signal receiving and sending.

The rotation angle of the rotation element for one rotation is equally divided according to the number of the first antenna radiators, for example, the number of the first antenna radiators on one rotation element is 2, the rotation angle of the rotation element for one rotation is 360 °, a first rotation angle 180 ° of the rotation of one first antenna radiator is obtained, the rotation element is driven to rotate by the first rotation angle 180 °, and similarly, when the number of the first antenna radiators on one rotating member is 3, a first rotation angle of 120 degrees of rotation of one first antenna radiator is obtained, the rotating member is driven to rotate by the first rotation angle of 120 degrees, and so on, a plurality of antenna radiators can be arranged on one rotating piece according to the requirements of users and the structure of the electronic equipment, a plurality of antenna radiating bodies are arranged on one rotating part, so that the rotating angle of the rotating part is reduced, the rotating time of the antenna radiating bodies is reduced, and the working efficiency of the antenna radiating bodies is improved.

302, the antenna radiator includes at least two first antenna radiators, the number of the rotating parts is at least two, each rotating part is provided with a first antenna radiator, and when receiving a data signal receiving and sending command, each first antenna radiator is driven to rotate around the rotating shaft for a circle.

The number of the rotating members is at least two, and it is understood that one rotating member may be disposed at the first end portion of the spool body and the other rotating member may be disposed at the second end portion of the spool body, and each rotating member includes at least one first antenna radiator.

The first antenna radiators with different driving positions rotate around the rotating shafts respectively.

If the structure of the scroll body allows, three rotating parts can be further included, wherein two rotating parts are respectively arranged at the first end part and the second end part of the scroll body, and the other rotating part is arranged at the middle position of the scroll body. Through setting up the rotation piece in spool body different positions, can solve the problem that the antenna radiator is sheltered from and leads to signal quality to descend.

303, obtaining the signal intensity values received by the antenna radiator at a plurality of positions in the rotating process.

When the previous step is the step corresponding to step 302, the signal strength values received by each first antenna radiator at multiple positions in the rotation process are obtained, for example, when the number of the first antenna radiators is 2, the rotation angle of the rotating member is 180 °, it may be set that the signal strength value received by each first antenna radiator is recorded every time the rotating member rotates 10 °, and meanwhile, the position information corresponding to the signal strength value is recorded.

When the previous step is 303, the signal strength values received at multiple positions during the rotation of each first antenna radiator on each rotating member are respectively obtained, for example, when the number of the rotating members is 2, and when the number of the first antenna radiators arranged on each rotating member is 2, the rotation angle of each rotating member is 180 °. It may be provided that each of the rotary members records a signal strength value received by each of the first antenna radiators for every 10 ° of rotation, and at the same time records position information corresponding to the signal strength value.

And 304, determining the position corresponding to the maximum signal intensity value as the target position from the signal intensity values corresponding to the multiple positions.

And comparing the signal strength values of each first antenna radiator at a plurality of positions to obtain a maximum signal strength value, and marking the position corresponding to the maximum signal strength value as a target position.

The antenna radiator is rotated 305 to a target position.

And driving the rotating piece to rotate according to the marked target position, so that the antenna radiating body is rotated to the target position.

Referring to fig. 10, fig. 10 is a third flowchart of a method for adjusting a position of an antenna radiator according to an embodiment of the present application, specifically, the method includes:

401, the number of the rotating parts is at least two, the antenna radiators at least include a first antenna radiator and a second antenna radiator, the first antenna radiator is disposed on one rotating part, and the second antenna radiator is disposed on the other rotating part.

The quantity that rotates the piece is at least two, the antenna radiation body includes first antenna radiation body and second antenna radiation body at least, first antenna radiation body and second antenna radiation body are the different antenna radiation body of type, first antenna radiation body can be GSM, WCDMA, the antenna radiation body of LET etc., can realize that electronic equipment is to 2G, 3G, 4G and 5G signal demand, the second antenna radiation body can be WIFI, GPS's antenna radiation body, can realize that electronic equipment is to the WIFI signal, GPS signal's demand, first antenna radiation body sets up on a rotation piece, this rotation piece can set up the first end at the spool body, the second antenna radiation body sets up on another rotation piece, this rotation piece can set up the second end at the spool body.

402, when receiving a command of transmitting and receiving data signals, driving the first antenna radiator and the second antenna radiator to rotate around the rotating shaft for a circle.

When the number of the first antenna radiators is one, the rotating member provided with the first antenna radiators is driven to rotate around the rotating shaft for a circle, and when the number of the second antenna radiators is one, the rotating member provided with the second antenna radiators is driven to rotate around the rotating shaft for a circle. When the number of the second antenna radiators is more than two, the rotating member is driven to rotate by a first angle similarly to the method of uniformly arranging the first antenna radiators on the rotating member, which is not described herein. When receiving a data signal receiving and sending command, the first antenna radiator is driven to rotate around the rotating shaft for a circle, and the second antenna radiator is driven to rotate around the rotating shaft for a circle.

403, obtaining a first set according to the signal strength values received by the first antenna radiator at multiple positions in the rotation process, and obtaining a second set according to the signal strength values received by the second antenna radiator at multiple positions in the rotation process.

Because the first antenna radiator and the second antenna radiator are different types of antenna radiators, the signal strength values received by the first antenna radiator and the second antenna radiator at each position need to be obtained respectively, and the position information corresponding to the received signal strength values is recorded respectively. For example, the signal strength value received by the first antenna radiator at each position is a first set, the signal strength value received by the second antenna radiator at each position is a second set, the position information corresponding to the signal strength value received by the first antenna radiator is a first position information set, and the position information corresponding to the signal strength value received by the second antenna radiator is a second position information set.

404, a first target location corresponding to the maximum signal strength value is obtained from the first set, and a second target location corresponding to the maximum signal strength value is obtained from the second set.

And comparing the maximum signal intensity value received by the first antenna radiator from the first set, obtaining position information corresponding to the maximum signal intensity value from the first position information set, and obtaining a first target position according to the position information. And comparing the maximum signal intensity value received by the second antenna radiator from the second set, obtaining position information corresponding to the maximum signal intensity value from the second position information set, and obtaining a second target position according to the position information.

The first antenna radiator is turned 405 to a first target position and the second antenna radiator is turned 405 to a second target position.

Referring to fig. 11, fig. 11 is a fourth flowchart of a method for adjusting a position of an antenna radiator according to an embodiment of the present application, specifically, the method includes:

and 501, driving the antenna radiator to rotate, and acquiring signal strength values corresponding to the antenna radiator at multiple positions.

The situation corresponding to 201 may also include situations corresponding to 301, 303, and 305, the situations corresponding to 302, 304, and 305 may also include situations corresponding to 401, 402, and 403, which are already described above, and thus, description is not repeated here.

And 502, acquiring the number of positions corresponding to the maximum signal strength value.

Since the signal strength values of different positions of the antenna radiator are received by rotating the antenna radiator, there may be a case where the antenna radiator has the same maximum signal strength value at different positions, and when there is such a case, the number of positions corresponding to the maximum signal strength value is obtained, it can be understood that, for example, after one first antenna radiator rotates around the rotation shaft by one turn, the corresponding signal strength values at 90 ° rotation and 300 ° rotation are the same, and both are the maximum signal strength values. Or two first antenna radiators uniformly arranged on one rotating member, when the rotating member rotates 180 degrees, the signal intensity value corresponding to the rotation of 90 degrees of one first antenna radiator is the same as the signal intensity value corresponding to the rotation of 70 degrees of the other first antenna radiator, and the signal intensity value is the maximum signal intensity value.

And skipping 503 corresponding steps when the positions corresponding to the maximum signal strength values are at least two, and skipping 504 corresponding steps when the position corresponding to the maximum signal strength value is one.

503, when the number of the positions corresponding to the maximum signal strength values is at least two, obtaining a rotation path from the antenna radiator to the position corresponding to each maximum signal strength value, and determining the position with the minimum rotation path as the target position.

For example, after a first antenna radiator rotates around a rotation shaft for one circle, when the first antenna radiator rotates for 90 ° and rotates for 300 °, the corresponding signal strength values are the same and are the maximum signal strength values, and by calculating the size of a path from the first antenna radiator to the position, the position information of the position and the current position information of the first antenna radiator can be calculated to obtain the relative distance between the two positions.

In some embodiments, the target position may also be determined by comparing the magnitude of the angle of rotation of the rotating member. When the position angles corresponding to the multiple maximum signal strengths are all smaller than 180 °, the position with the smallest rotation angle is selected as the target position, for example, when the first antenna radiator rotates to 20 °, 30 °, and 70 °, the received signal strength value is the largest signal strength value, and the position where the antenna radiator rotates clockwise by 20 ° is set as the target position. And when the position angles corresponding to the maximum signal strength values are all larger than 180 degrees, respectively obtaining complementary angles of the position angles corresponding to the maximum signal strength values through calculation, and comparing to obtain the rotating position of the antenna radiator with the minimum complementary angle. For example, when the first antenna radiator rotates to 190 ° and 230 ° and 300 °, the received signal strength value is the maximum signal strength value, the complementary angle of 300 ° is the minimum, which is 60 ° through comparison, and the position where the antenna radiator rotates 60 ° counterclockwise is set as the target position. Similarly, when the position angles corresponding to the maximum signal strengths include both the position angles larger than 180 ° and the position angles smaller than 180 °, the first position angle with the smallest angle is selected from the position angles smaller than 180 °, the second position angle with the smallest supplementary angle is selected from the position angles larger than 180 °, the first position angle is compared with the second position angle to obtain the position angle with the smallest angle, when the position angle is the first angle, the position where the antenna radiator rotates clockwise by the first angle is set as the target position, and when the position angle is the second angle, the position where the antenna radiator rotates counterclockwise by the second angle is set as the target position.

It can be understood that, when the number of the first antenna radiators is more than one, or the number of the second antenna radiators is more than one, the target position can still be determined by determining, as the target position, the position where the rotation path of the antenna radiator to the position corresponding to the maximum signal strength value is the minimum when the positions corresponding to the maximum signal strength values are at least two according to the number of the positions corresponding to the maximum signal strength values obtained.

And 504, when the position corresponding to the maximum signal strength value is one, determining the position corresponding to the maximum signal strength value as the target position.

And 505, rotating the antenna radiator to a target position.

Referring to fig. 12, fig. 12 is a fifth flowchart of a method for adjusting a position of an antenna radiator according to an embodiment of the present application, specifically, the method includes:

601, driving the antenna radiator to rotate, and acquiring signal strength values corresponding to the antenna radiator at multiple positions.

Corresponding situations 501 may be included, and are not described herein.

And 602, obtaining a signal strength value set larger than a preset signal strength value according to the signal strength values of the antenna radiator at the plurality of positions.

The preset signal intensity value is a signal intensity value which can meet the normal work of the antenna radiator, a signal intensity value which is larger than the preset signal intensity value can be obtained by comparing the signal intensity values corresponding to the antenna radiator at a plurality of positions with the preset signal intensity value, and the signal intensity value is corresponding to position information. For example, the preset signal intensity value is-85 dbm, the signal intensity values obtained when one first antenna radiator rotates one turn are-70 dbm, -80dbm, -90dbm, -95dbm … …, and the corresponding rotation angles are 10 °, 20 °, 30 °, and 40 ° … …. The comparison results in a signal strength value set greater than the predetermined signal strength value, the signal strength value set includes-70 dbm and-80 dbm … …, it is understood that the predetermined signal strength value-85 dbm is a critical value, and when the signal strength value of the mobile phone is less than-85 dbm, the mobile phone signal is in a poor state. Of course, the preset signal strength value can be changed according to the requirement. When the signal quality requirement for the mobile phone is high, the preset signal strength value can be set to be larger than-85 dbm.

603, determining at least two first candidate positions according to the signal strength value set.

When the number of the signal strength values in the signal strength value set is 2, the positions corresponding to the signal strength values respectively are determined as first candidate positions, and the number of the first candidate positions is 2, it can be understood that when the number of the signal strength values in the signal strength value set is 5, the positions corresponding to the signal strength values respectively are determined as the first candidate positions, and the number of the first candidate positions is 5.

604, obtaining the path size of each first candidate position and the current position of the antenna radiator, and determining the first candidate position corresponding to the smallest path as the target position.

The antenna radiator is rotated 605 to the target position.

In some embodiments, after the antenna radiator is rotated to the target position, the user may change the position of holding the electronic device, which may affect the transmission and reception of signals by the antenna radiator. For example, the region where the palm of the user covers the spool body just covers the antenna radiator, so that the current signal of the antenna radiator is weakened, and the data receiving and sending of the electronic device cannot be met, therefore, a first holding position where the electronic device is held needs to be obtained, when the first holding position is at least partially overlapped with a first preset position, and the current signal intensity value of the electronic device is smaller than a preset signal intensity value, the user is prompted to change the holding position of the electronic device, the first preset position is a position on the spool body where the antenna radiator on the rotating member corresponds, when the antenna radiator rotates to a target position, the electronic device obtains the position on the spool body where the target position corresponds through calculation, the preset signal intensity value is a preset signal intensity value for comparison, and the signal intensity value may be-95 dbm, and only if the signal intensity value is greater than the signal intensity value, the electronic device can normally transmit and receive data, for example, a user holds the first end of the reel body, and the position of the antenna radiator for transmitting and receiving data is also at the first end of the reel body, because the position held by the user covers a certain radiation area of the antenna radiator, the current signal intensity value of the antenna radiator is less than-95 dbm, the receiving and sending of the antenna radiator signals are influenced to a certain extent, therefore, the electronic equipment prompts the user to change the holding position, the method for prompting the user can be that the prompt is displayed through a voice prompt, a flexible screen, a vibration prompt, a prompt sound prompt and the like, the current signal intensity value of the electronic equipment can be displayed in real time after the user is prompted to change the holding position, so that the user can conveniently find the most suitable holding position, wherein the most suitable holding position is the position with the best signal intensity of the antenna radiator.

In other embodiments, different from the above embodiments, the antenna radiator is affected by the position of the user holding the electronic device, and the signal transmission and reception of the electronic device is not affected by switching the operating antenna radiator, for example, two rotating members of the electronic device, a first rotating member and a second rotating member, the two rotating members being respectively disposed at the first end portion and the second end portion of the reel body, and each rotating member having a first antenna radiator. The electronic equipment receives and transmits signals by using the first antenna radiator on the first rotating part at present, when a user holds the position at the first end and at least partially coincides with the second preset position, the second preset position is the position corresponding to the antenna radiator on the first rotating part on the scroll body, and meanwhile, when the signal intensity value of the first antenna radiator on the first rotating part is smaller than the preset signal intensity value, the second rotating part at the second end is driven to rotate, and the signals are received and transmitted by the first antenna radiator on the second rotating part.

In some embodiments, before the antenna radiator is driven to rotate, in addition to driving the antenna radiator to rotate by receiving the transceiving signal command, the current signal strength value of the electronic device may be detected in real time, and when the current signal strength value is smaller than a preset signal strength value, the antenna radiator is driven to rotate, for example, the radio frequency module receives the signal strength value corresponding to the current position of the antenna radiator in real time; or when the space position of the electronic equipment changes, the signal intensity value corresponding to the current position of the antenna radiator is received through the radio frequency module, and the space position of the electronic equipment can be determined through the GPS positioning module and/or the Bluetooth positioning module; or presetting a detection period, and receiving the current signal intensity value of the antenna radiator through the radio frequency module when the detection period is separated. The signal intensity value corresponding to the current position signal of the antenna radiator is recorded through the control module, the signal intensity value corresponding to the current position of the antenna radiator is compared with a preset signal intensity value, the preset signal intensity value can be-95 dbm, when the signal intensity value of the mobile phone is smaller than-95 dbm, the electronic signal is in a poor state and cannot meet the normal working requirement of the electronic equipment, for example, when the signal intensity value of the current antenna radiator is-110 dbm, the requirement of the electronic equipment on the signal of the antenna radiator cannot be met, the antenna radiator is driven to rotate, and the signal intensity values corresponding to the antenna radiator in multiple positions are obtained.

In some embodiments, a plurality of corresponding preset signal strength values may be set according to a level of a requirement for updating real-time performance of the data of the electronic device, for example, a current state of the electronic device is detected, for example, the electronic device is in a video call state or a call state, and if a signal quality requirement is high, the preset signal strength value may be-85 dbm, and when the current signal strength value of the antenna radiator is less than-85 dbm, for example, when the current signal strength value of the antenna radiator is-95 dbm, the antenna radiator is driven to rotate, and the signal strength values corresponding to the antenna radiator at a plurality of positions are obtained.

When the current state of the electronic equipment is a standby state or a character browsing state and the requirement on signal quality is low, the preset signal strength value can be-100 dbm, and when the signal strength value of the antenna radiator is smaller than-100 dbm, for example, the current signal strength value of the antenna radiator is-110 dbm, the antenna radiator is driven to rotate, and the signal strength values corresponding to the antenna radiator at a plurality of positions are obtained.

When the signal strength values corresponding to the plurality of positions of the antenna radiator have the signal strength value larger than the preset signal strength value, determining the position corresponding to the maximum signal strength value as a target position from the signal strength values larger than the preset signal strength value, and rotating the antenna radiator to the target position.

And when the signal strength value which is greater than the preset signal strength value does not exist in the signal strength values corresponding to the plurality of positions of the antenna radiator, driving the antenna radiator to rotate again, and repeating the methods from 201 to 203.

When the signal strength values corresponding to the plurality of positions of the antenna radiator have the signal strength value larger than the preset signal strength value, determining the position corresponding to the maximum signal strength value as a target position from the signal strength values larger than the preset signal strength value, and rotating the antenna radiator to the target position.

And when the signal strength value which is greater than the preset signal strength value does not exist in the signal strength values corresponding to the plurality of positions of the antenna radiator, driving the antenna radiator to rotate again, and repeating the methods from 201 to 203.

In some embodiments, when the signal strength value of the antenna radiator is always smaller than the preset signal strength value within the preset time period, the antenna radiator is not driven to rotate for one circle, and the antenna radiator is rotated to the position where the signal strength value is maximum. For example, when the electronic device is in an environment with extremely weak signals for a long time, such as a remote mountain area or a signal dead angle, and the radio frequency module detects that the signal intensity value of the antenna radiator is always smaller than the preset signal intensity value within a preset time period, the antenna radiator is not driven to rotate for one circle, the antenna radiator is rotated to the position with the maximum signal intensity value, and when the antenna radiator intensity value detected by the radio frequency module within 5 minutes within the preset time period is always smaller than-95 dbm, the control module does not drive the antenna radiator to rotate for one circle, the antenna radiator is rotated to the position with the maximum signal intensity value, and the method 201 to 203 is repeated again only when receiving a data signal transceiving instruction again.

In some embodiments, when the number of times of the antenna radiator rotating again is greater than the preset number of times, the antenna radiator is not driven to rotate for one circle any more, and the antenna radiator is rotated to the position where the signal strength value is maximum. For example, when the obtained signal strength value does not exceed the preset signal strength value after the antenna radiator rotates a circle, the antenna radiator is driven to rotate again, at this time, the control module increases the number of times of rotation of the antenna radiator once, when the number of times of rotation of the antenna radiator is greater than the preset number of times of rotation, the antenna radiator is not driven to rotate a circle any more, the antenna radiator is rotated to the position where the signal strength value is maximum, at this time, the number of times of rotation of the antenna radiator in the control module is cleared, for example, when the control module detects that the number of times of rotation of the antenna radiator exceeds 20 times, the signal strength value of the antenna radiator obtained by the radio frequency module is always smaller than-95 dbm, the control module does not drive the antenna radiator to rotate a circle any more, the antenna radiator is rotated to the, the above-described methods 201 to 203 are repeated again only when the command to transmit and receive the data signal is received again, and by this method, the power consumption of the electronic device can be reduced.

In some embodiments, after determining that the location corresponding to the maximum signal strength value is the target location, the method further includes: calculating the direction with the strongest signal strength according to the target position, for example, calculating a spatial position corresponding to the target position according to the target position, calculating a radiation range of the antenna radiator at the target position, calculating the direction with the strongest signal strength of the antenna radiator according to the spatial position and the radiation range, displaying the direction with the strongest signal strength of the antenna radiator by a user, and displaying the direction with the strongest signal strength of the antenna radiator on a screen through an indication arrow; or by voice presentation; or displayed on a screen through a map or displayed through a coordinate axis; whether the detection electronics move or not is displayed, the movement of the electronic equipment can be detected through a gyroscope or a gravity sensor, and when the position distance of the movement of the electronic equipment reaches a first preset moving distance, the current signal intensity value of the electronic equipment is displayed in real time so that a user can find a position with stronger signal intensity conveniently.

In some embodiments, the method for adjusting the position of the antenna radiator further comprises: the method comprises the steps of displaying the current signal strength value of the electronic equipment in real time when the electronic equipment is detected to move, displaying the current signal strength value of the electronic equipment in real time when the moving distance of the electronic equipment is greater than a second preset moving distance, wherein the second preset moving distance is greater than the first preset moving distance, and different from the embodiment, the embodiment detects the moving position of the electronic equipment after the direction with the strongest signal strength is displayed to a user, so that the first preset moving range is set to be smaller, the user can conveniently adjust the position of the electronic equipment to enable the antenna radiator signal to reach the optimal state, in the embodiment, the current signal strength value of the electronic equipment is displayed in real time as long as the moving distance of the electronic equipment is detected to be greater than the second preset moving distance, so that the second preset moving range is larger, and the signal can be displayed in real time by triggering the user, and displaying the current signal intensity value of the electronic equipment in real time.

In summary, by driving the antenna radiator to rotate, and obtaining the signal strength values corresponding to the antenna radiator at a plurality of positions, determining the position corresponding to the maximum signal strength value as the target position from the signal strength values corresponding to the plurality of positions, and rotating the antenna radiator to the target position, the quality of the antenna radiator signal is improved, and the user use requirements are met.

An embodiment of the present application further provides a storage medium, where the storage medium stores a computer program, and when the computer program runs on a computer, the computer is caused to execute the working state prompting method in any one of the above embodiments, for example: obtaining a current first signal strength value of the antenna radiator; when the first signal intensity value is lower than a preset signal intensity value, driving the antenna radiator to move, and acquiring second signal intensity values corresponding to the antenna radiator at a plurality of positions; determining a position corresponding to the maximum signal intensity value as a target position from second signal intensity values corresponding to the plurality of positions; moving the antenna radiator to the target position.

It should be noted that the electronic device in the embodiment of the present application further includes a matching circuit that is matched with the antenna radiator, and the antenna radiator and the matching circuit are matched to implement transceiving of the antenna signal.

In the embodiment of the present application, the storage medium may be a magnetic disk, an optical disk, a Read Only Memory (ROM), a Random Access Memory (RAM), or the like.

In the foregoing embodiments, the descriptions of the respective embodiments have respective emphasis, and for parts that are not described in detail in a certain embodiment, reference may be made to related descriptions of other embodiments.

It should be noted that, for the method for adjusting the position of an antenna radiator in the embodiment of the present application, it can be understood by a person skilled in the art that all or part of the process for implementing the method for adjusting the position of an antenna radiator in the embodiment of the present application can be completed by controlling related hardware through a computer program, where the computer program can be stored in a computer-readable storage medium, such as a memory of an electronic device, and executed by at least one processor in the electronic device, and the execution process may include, for example, the process of the embodiment of the method for processing an optical sensor. The storage medium may be a magnetic disk, an optical disk, a read-only memory, a random access memory, etc.

In the electronic device according to the embodiment of the present application, each functional module may be integrated into one processing chip, or each module may exist alone physically, or two or more modules are integrated into one module. The integrated module can be realized in a hardware mode, and can also be realized in a software functional module mode. The integrated module, if implemented in the form of a software functional module and sold or used as a stand-alone product, may also be stored in a computer readable storage medium, such as a read-only memory, a magnetic or optical disk, or the like.

The above detailed description is provided for the method for adjusting the position of the antenna radiator, the storage medium and the electronic device according to the embodiments of the present application, and specific examples are applied in this text to explain the principle and the implementation of the present application, and the description of the above embodiments is only used to help understanding the method and the core concept of the present application; meanwhile, for those skilled in the art, according to the idea of the present application, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present application.

Claims (17)

1. A position adjustment method of an antenna radiator is applied to electronic equipment and is characterized in that the electronic equipment is columnar and comprises a scroll body, a flexible display screen and the antenna radiator, wherein the flexible display screen is wound in the scroll body in a winding state, the flexible display screen can be unfolded from the scroll body in an unfolding state, the scroll body comprises a rotating shaft and a rotating piece, the rotating piece rotates around the rotating shaft, the rotating shaft is arranged on the axis of the scroll body, the axis of the rotating piece rotating around the rotating shaft is arranged on the axis, and the antenna radiator is arranged on the rotating piece; the method comprises the following steps:

driving the antenna radiator to rotate and acquiring signal strength values corresponding to the antenna radiator at a plurality of positions;

determining a position corresponding to the maximum signal intensity value as a target position from the signal intensity values corresponding to the positions;

rotating the antenna radiator to the target position;

calculating to obtain the direction with the strongest signal strength according to the target position;

and displaying the direction with the strongest signal strength.

2. The method of claim 1, wherein the driving the antenna radiator to rotate and obtaining the signal strength values of the antenna radiator at a plurality of positions comprises:

when a data signal receiving and sending command is received, the antenna radiator is driven to rotate around the rotating shaft for a circle;

and acquiring signal strength values acquired at a plurality of positions in the rotation process of the antenna radiator.

3. The method of claim 2, wherein the antenna radiator comprises at least two first antenna radiators, and wherein the driving the antenna radiator to rotate around the rotation axis for one rotation comprises:

the at least two first antenna radiators are uniformly arranged on the rotating piece, the rotating angles of the antenna radiators rotating for one circle are equally divided according to the number of the first antenna radiators, a first rotating angle of the first antenna radiators is obtained, and the rotating piece is driven to rotate by the first rotating angle;

or

The number of the rotating pieces is at least two, each rotating piece is provided with one first antenna radiator, and each first antenna radiator is driven to rotate around the rotating shaft for a circle.

4. The method of claim 2, wherein the number of the rotating members is at least two, the antenna radiators include at least a first antenna radiator and a second antenna radiator, the first antenna radiator is disposed on one of the rotating members, the second antenna radiator is disposed on the other of the rotating members, and the driving the antenna radiators to rotate around the rotating shaft for one rotation includes:

and driving the first antenna radiating body and the second antenna radiating body to rotate for a circle around the rotating shaft.

5. The method of claim 1, wherein determining the position corresponding to the maximum signal strength value as the target position from the signal strength values corresponding to the plurality of positions comprises:

acquiring the number of positions corresponding to the maximum signal strength value;

when the number of the positions corresponding to the maximum signal strength values is at least two, obtaining a rotation path of the antenna radiator rotating to the position corresponding to each maximum signal strength value;

determining the position with the minimum rotation path as a target position;

and when the position corresponding to the maximum signal strength value is one, determining the position corresponding to the maximum signal strength value as a target position.

6. The method of claim 1, wherein the determining, from the signal strength values corresponding to the plurality of positions, the position with the largest signal strength value as the target position comprises:

obtaining a signal strength value set larger than a preset signal strength value according to the signal strength values corresponding to the antenna radiator at a plurality of positions;

determining at least two first positions to be selected according to the signal intensity value set;

and determining a target position from the at least two first positions to be selected.

7. The method of claim 6, wherein the determining the target position from the at least two first candidate positions comprises:

and obtaining the path size of each first position to be selected and the current position of the antenna radiator, and determining the first position to be selected corresponding to the minimum path as a target position.

8. The method of claim 1, wherein after the rotating the antenna radiator to the target position, the method further comprises:

acquiring a first holding position at which the electronic equipment is held;

when the first holding position is at least partially overlapped with a first preset position and the current signal intensity value of the electronic equipment is smaller than a preset signal intensity value, prompting a user to change the holding position of the electronic equipment, wherein the first preset position is a position corresponding to an antenna radiation body on the rotating piece.

9. The method of claim 1, wherein the rotating member includes a first rotating member and a second rotating member which are spaced apart from each other, and after the rotating the antenna radiator to the target position, the method further includes:

acquiring a second holding position at which the electronic equipment is held;

when the second holding position at least partially coincides with a second preset position corresponding to the antenna radiator on the first rotating member, obtaining a current signal strength value of the antenna radiator on the first rotating member;

and when the current signal intensity value of the antenna radiator on the first rotating member is smaller than the preset signal intensity value, switching to the antenna radiator on the second rotating member to receive and transmit signals.

10. The method of claim 1, wherein the driving the antenna radiator to rotate comprises:

and detecting the current signal intensity value of the electronic equipment in real time, and driving the antenna radiator to rotate when the current signal intensity value is smaller than a preset signal intensity value.

11. The method of claim 10, wherein detecting the current signal strength value of the electronic device in real time further comprises:

and setting a plurality of corresponding preset signal strength values according to the requirement level of the real-time updating of the data of the electronic equipment.

12. The method of claim 1, further comprising:

and when the electronic equipment is detected to move, displaying the current signal intensity value of the electronic equipment in real time.

13. A computer-readable storage medium, on which a computer program is stored, the program, when being executed by a processor, implementing the steps of the antenna radiator position adjustment method according to any one of claims 1 to 12.

14. An electronic device, comprising:

the scroll comprises a scroll body and a control device, wherein the scroll body comprises a rotating shaft and a rotating part, the rotating part rotates around the rotating shaft, the rotating shaft is arranged on the axis of the scroll body, and the axis of the rotating part rotating around the rotating shaft is arranged on the axis;

the flexible display screen is wound in the scroll body in a winding state, and can be unfolded from the scroll body in an unfolding state;

an antenna radiator disposed on the rotation member;

the radio frequency module is connected with the antenna radiator and is used for acquiring the signal intensity value received by the antenna radiator;

the control module is connected with the radio frequency module and used for driving the antenna radiating body to rotate and acquiring signal strength values corresponding to the antenna radiating body at a plurality of positions through the radio frequency module; determining the position with the maximum signal intensity value as a target position from the signal intensity values corresponding to the positions; rotating the antenna radiator to the target position; the control module is also used for calculating the direction with the strongest signal strength according to the target position; and displaying the direction with the strongest signal strength.

15. The electronic device according to claim 14, wherein the reel body includes a first end portion and a second end portion provided at both ends, and the rotation member is provided at the first end portion or the second end portion.

16. The electronic device of claim 15, wherein the antenna radiator comprises at least two first antenna radiators each disposed at the first end or the second end;

or

The first end portion is provided with at least one first antenna radiator, and the second end portion is provided with at least one first antenna radiator.

17. The electronic device of claim 15, wherein the antenna radiator comprises at least a first antenna radiator and a second antenna radiator, the first antenna radiator and the second antenna radiator each disposed at the first end or the second end;

or

The first antenna radiator is disposed at the first end portion, and the second antenna radiator is disposed at the second end portion.

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