CN112199013A - Display switching method of smart watch - Google Patents

Abstract

The invention relates to a display switching method of a smart watch, which is characterized in that a scheme of gradually lighting a screen is set, when a user only needs to know who sends a message and does not need to know the content, the summary of the content only needs to be displayed on a first partition with the smallest lighting area, and the switching is carried out by adopting third interaction. When the user browses the message needing to be read, the lighted screen is enlarged by utilizing the second interaction, the user can conveniently read the message, and when the second partition is not large enough, the user can also set a third partition so that the content is displayed on the whole screen. Therefore, the screen is gradually lightened, the energy consumption of the screen can be greatly reduced, and the cruising ability of the watch is stronger.

Description

Display switching method of smart watch

Technical Field

The invention relates to a control method of a smart watch, in particular to a display switching method of the smart watch.

Background

The smart watch can synchronize the pushed content of the mobile phone through wireless connection, and also has the content presented after data processing, and under any condition, the watch interacts with a user, so that various contents can be seen from the screen of the watch. CN2017108632732 discloses a method for touch control without screen of a watch, in which a touch-controllable area of the watch is divided into different areas by a mobile phone, so as to implement control in areas. However, the current smart watches are more and more mobile, and the screen becomes an indispensable component of the smart watch, so that the reduction of the power consumption of the screen becomes a problem to be considered in each large-brand smart watch.

Disclosure of Invention

In view of the above, the present invention provides a display switching method for a smart watch, by which a screen display range of the watch is continuously expanded along with a user's manipulation, thereby giving consideration to both visibility and power consumption, and by which a user completely frees the other hand.

The specific technical scheme of the invention is as follows:

a display switching method of a smart watch, the method comprising:

presetting screen partitions, wherein the screen partitions at least comprise a first partition;

in the screen-off state, the watch obtains first content, carries out first prompt and pre-draws the content in the first partition;

implementing a first interaction, wherein the first partition is lightened, the first content is displayed in the first partition, and the first content is pre-drawn in a second partition with the area larger than that of the first partition;

implementing a second interaction, wherein if a second partition comprises a first partition, the first content displayed by the first partition disappears, the rest of the second partition is lightened, and the first content is displayed in the second partition; and if the second partition does not comprise the first partition, the first partition is turned off, the second partition is turned on, and the first content is displayed in the second partition.

A display switching method of a smart watch, the method comprising:

presetting screen partitions, wherein the screen partitions at least comprise a first partition;

in the screen-off state, the watch obtains first content, carries out first prompt and pre-draws the content in the first partition;

the watch obtains second content and continuously carries out the first prompt;

implementing a first interaction, wherein the first partition is bright-screened, the first content is displayed in the first partition, and the first content is pre-drawn in a second partition comprising the first partition;

judging whether a third interaction is implemented, if so, pre-drawing the second content in a first partition and displaying the second content in the first partition, and pre-drawing the second content in a second partition; if not, whether second interaction is implemented or not is judged, if yes, the second subarea is lightened, and the content currently displayed by the first subarea is displayed in the second subarea.

Further, the first interaction and the second interaction are different interactions.

Further, the third interaction is an interaction different from both the first interaction and the second interaction.

Further, the first interaction, the second interaction and the third interaction are three different preset gestures.

Further, the watch further comprises a third partition, the third partition is a partition comprising a second partition, when the first content or the second content is displayed in the second partition, whether second interaction is implemented or not is judged, if yes, the content displayed in the second partition is pre-drawn in the third partition, and the third partition is bright-screened, so that the content currently displayed in the second partition is displayed in the third partition.

Further, the first content obtained by the watch is push content of the mobile terminal bound with the watch or content triggered by the watch.

Further, the first prompt is one time of vibration and/or a prompt lamp flickers.

Further, the first interaction is implemented as a hand-raising interaction, comprising:

firstly, a three-axis acceleration sensor of the watch acquires three-axis acceleration data of the intelligent watch and transmits the three-axis acceleration data to the processor;

step two, a processor of the watch carries out filtering processing on the collected triaxial acceleration data to obtain processed triaxial acceleration data;

step three, storing a first acceleration threshold value in the processor, if the acceleration data of at least one axis in the acceleration data of the three axes reaches the first acceleration threshold value, judging that the human body is in a violent motion state by the processor, and simultaneously entering step four; if not, the processor judges that the human body is in a non-violent movement state and simultaneously enters the fifth step;

step four, the processor stores the sampling frequency F and the first time threshold value T₁A first amplitude threshold value, where T₁Is an integer, T₁<F, and the processor counts the time and amplitude of the acceleration data of each of the three axes rising or falling continuously: if the time of the acceleration data of any one of the three axes continuously rising or falling reaches the first time threshold T stored by the processor₁If the acceleration data of the shaft continuously rises or falls to reach the first amplitude threshold value stored by the processor, the processor judges that the hand-lifting mark appears, and the step IV is carried out; if not, repeating the step four;

step four, the processor stores a second time threshold T₂A first acceleration interval and a first number threshold, at said second time threshold T₂in/F, wherein T₂Is an integer, T₂<F, sampling T for each axis₂Counting the number of the acceleration data of each axis falling into the first acceleration interval, if the number of each axis reaches the first number threshold, judging that the hand is lifted, and entering a sixth step; if the numerical value of any axis does not reach the first numerical threshold, repeating the step four;

step five, the processor stores the sampling frequency F and a third time threshold value T₃A second amplitude threshold value, where T₃Is an integer, T₃<F, the processor counts the time and the amplitude of the continuous rising or falling of the acceleration data of the X axis and the Y axis in the three axes: if the acceleration data of the X axis and the Y axis continuously rise or fallAll reach said third time threshold T₃If the continuous rising or falling amplitudes of the acceleration data of the X axis and the acceleration data of the Y axis reach a second amplitude threshold value stored by the processor, the processor judges that a hand raising mark appears, and the fifth step is executed; if not, repeating the fifth step;

step five, the processor stores a second acceleration interval and a second number threshold, and the second time threshold T is₂within/F, sample T for each axis₂Counting the number of acceleration data of each axis falling into the second acceleration interval, if the number of each axis reaches the second number threshold, judging that the hand is lifted, and entering a sixth step; if the numerical value of any axis does not reach the second numerical threshold, repeating the step five;

and step six, the processor controls the first subarea to light.

Further, the second interaction is implemented as a wrist-turning interaction, comprising the steps of:

acquiring data of triaxial acceleration of the intelligent watch by a triaxial acceleration sensor of the intelligent watch, and transmitting the data of the triaxial acceleration to the processor;

step two, a processor of the smart watch performs filtering processing on the collected triaxial acceleration data to obtain processed triaxial acceleration data;

step three, the processor stores the sampling frequency F and the first time threshold value T₁/F and the first amplitude threshold value W0, where T₁Is an integer, T₁<F; the processor counts the time T and the amplitude W of the continuous rising or falling of the acceleration data of each axis in the three axes; if the acceleration data of the X-axis and the Z-axis in the three axes or the acceleration data of the Y-axis and the Z-axis in the three axes continuously rise or fall, the time reaches a first time threshold T stored by the processor₁If the continuously ascending or descending amplitudes of the acceleration data of the X-axis and Z-axis or the acceleration data of the Y-axis and Z-axis reach the amplitude threshold value W0 stored by the processor, the processor judges that the wrist-turning mark appears, and the step IV is carried out; if not, repeating the third step(ii) a The plane determined by the X axis and the Y axis is a plane parallel to the display screen of the bracelet, and the Z axis is an axis vertical to the plane;

step four, the processor stores a second time threshold T₂/F, acceleration interval [ A1, B1]]And a number threshold N0, where T₂Is an integer, T₂<F; at the second time threshold T₂within/F, sample T for each axis₂The acceleration data of each axis is counted to fall into the acceleration interval [ A1, B1]]If the number value N of each axis reaches the number threshold value N0, judging that the wrist is turned, and entering a fifth step; if the number value N of any axis does not reach the number threshold value N0, repeating the step three;

and fifthly, controlling the second subarea to light.

Further, the third interaction is implemented as a translation interaction, comprising the steps of:

acquiring data of triaxial acceleration of the intelligent watch by a triaxial acceleration sensor of the intelligent watch, and transmitting the data of the triaxial acceleration to the processor;

step two, a processor of the smart watch performs filtering processing on the collected triaxial acceleration data to obtain processed triaxial acceleration data;

step three, the processor stores the sampling frequency F and the first time threshold value T₁/F and the first amplitude threshold value W0, where T₁Is an integer, T₁<F; the processor counts the time T and the amplitude W of the continuous rising or falling of the acceleration data of each axis in the three axes; if the acceleration data of the X-axis and the Y-axis of the three axes continuously rise or fall, the acceleration data reach a first time threshold T stored by the processor₁If the rising or falling amplitude of the acceleration data of the two axes of the X axis and the Y axis reaches the amplitude threshold value W0 stored by the processor, the processor judges that a translation mark appears, and the step IV is executed; if not, repeating the third step; the plane determined by the X axis and the Y axis is a plane parallel to the display screen of the bracelet;

step four, the processor stores a second time threshold T₂/F, acceleration interval [ A1, B1]]And a number threshold N0, where T₂Is an integer, T₂<F; at the second time threshold T₂within/F, sample T for each axis₂The acceleration data of each axis is counted to fall into the acceleration interval [ A1, B1]]If the number value N of each axis reaches the number threshold value N0, judging that the wrist is turned, and entering a fifth step; if the number value N of any axis does not reach the number threshold value N0, repeating the step three;

and step five, the processor pre-draws the second content in a first partition and displays the second content in the first partition, and pre-draws the second content in a second partition comprising the first partition.

Through the technical scheme, the user can gradually lighten the screen, so that the energy consumption of the screen is greatly reduced.

Detailed Description

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

The terminology used in the embodiments of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used in the examples of the present invention and the appended claims, the singular forms "a", "an", and "the" are intended to include the plural forms as well, and "a" and "an" generally include at least two, but do not exclude at least one, unless the context clearly dictates otherwise.

It should be understood that the term "and/or" as used herein is merely one type of association that describes an associated object, meaning that three relationships may exist, e.g., a and/or B may mean: a exists alone, A and B exist simultaneously, and B exists alone. In addition, the character "/" herein generally indicates that the former and latter related objects are in an "or" relationship.

It should be understood that although the terms first, second, third, etc. may be used to describe … … in embodiments of the present invention, these … … should not be limited to these terms. These terms are used only to distinguish … …. For example, the first … … can also be referred to as the second … … and similarly the second … … can also be referred to as the first … … without departing from the scope of embodiments of the present invention.

The words "if", as used herein, may be interpreted as "at … …" or "at … …" or "in response to a determination" or "in response to a detection", depending on the context. Similarly, the phrases "if determined" or "if detected (a stated condition or event)" may be interpreted as "when determined" or "in response to a determination" or "when detected (a stated condition or event)" or "in response to a detection (a stated condition or event)", depending on the context.

It is also noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a good or system that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such good or system. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a commodity or system that includes the element.

The screen of an electronic product is always a power-consuming household, how to effectively increase the endurance is a problem which needs to be considered by various watch manufacturers, energy consumption is reduced mainly from the aspects of hardware, software and combination of software and hardware, and the prior art for increasing the endurance is rarely solved from the aspect of operation.

The smart watch includes a processor and a screen. The applicant has made systematic studies in previous patents on the basic algorithms of smart watches, proposing some algorithms related to raising hands, turning wrist and lighting up the screen, such as CN2016106151269, CN 2016106150853. Hand lifting, wrist turning and the like are gesture judgment, so that corresponding functions are realized. This application combines the hardware of wrist-watch, distinguishes and the gesture aspect from the hardware of wrist-watch, proposes a method that shows to switch to reduce the power consumption of screen.

The screen of the current intelligent watch is circular or square, and on a software level, the screen is partitioned and at least comprises a smaller first partition. Preferably the first section may be any shape section located over the centre of the screen, more preferably a circular or rectangular section; or a partition in the second quadrant of the screen.

The screen further comprises a second partition, wherein the second partition is larger than the first partition, and the first partition preferably spans a third quadrant and a fourth quadrant of the screen; the second preference may be a section comprising the first section, e.g. moving the center point of the first section to the center of the screen and scaling up said first section such that the enlarged second section comprises the first section. Of course, other forms of second partition may be provided, the purpose of which is to enable larger fonts and/or more content to be displayed. Preferably, the screen further comprises a third partition, which may be the entire screen display area.

The watch comprises a processor and an acceleration sensor, wherein the processor can store gestures preset by a user and can also directly judge the gestures of the user.

The processor can make judgment on hand lifting, wrist turning and translation, and the ways of hand lifting, wrist turning and translation judgment are respectively described below.

Firstly, judging the hand-up, and implementing the function of a preset value by the processor based on the hand-up judgment, if the first partition is lightened:

firstly, a three-axis acceleration sensor of the watch acquires three-axis acceleration data of the intelligent watch and transmits the three-axis acceleration data to the processor;

step two, a processor of the watch carries out filtering processing on the collected triaxial acceleration data to obtain processed triaxial acceleration data;

step three, storing a first acceleration threshold value in the processor, if the acceleration data of at least one axis in the acceleration data of the three axes reaches the first acceleration threshold value, judging that the human body is in a violent motion state by the processor, and simultaneously entering step four; if not, the processor judges that the human body is in a non-violent movement state and simultaneously enters the fifth step;

step four, the processor stores the sampling frequency F and the first time threshold value T₁A first amplitude threshold value, where T₁Is an integer, T₁<F, and the processor counts the time and amplitude of the acceleration data of each of the three axes rising or falling continuously: if the time of the acceleration data of any one of the three axes continuously rising or falling reaches the first time threshold T stored by the processor₁If the acceleration data of the shaft continuously rises or falls to reach the first amplitude threshold value stored by the processor, the processor judges that the hand-lifting mark appears, and the step IV is carried out; if not, repeating the step four;

step four, the processor stores a second time threshold T₂A first acceleration interval and a first number threshold, at said second time threshold T₂in/F, wherein T₂Is an integer, T₂<F, sampling T for each axis₂Counting the number of the acceleration data of each axis falling into the first acceleration interval, if the number of each axis reaches the first number threshold, judging that the hand is lifted, and entering a sixth step; if the numerical value of any axis does not reach the first numerical threshold, repeating the step four;

step five, the processor stores the sampling frequency F and a third time threshold value T₃A second amplitude threshold value, where T₃Is an integer, T₃<F, the processor counts the time and the amplitude of the continuous rising or falling of the acceleration data of the X axis and the Y axis in the three axes: if the acceleration data of the X axis and the Y axis continuously rise or fall time reaches the third time threshold valueT₃If the continuous rising or falling amplitudes of the acceleration data of the X axis and the acceleration data of the Y axis reach a second amplitude threshold value stored by the processor, the processor judges that a hand raising mark appears, and the fifth step is executed; if not, repeating the fifth step;

step five, the processor stores a second acceleration interval and a second number threshold, and the second time threshold T is₂within/F, sample T for each axis₂Counting the number of acceleration data of each axis falling into the second acceleration interval, if the number of each axis reaches the second number threshold, judging that the hand is lifted, and entering a sixth step; if the numerical value of any axis does not reach the second numerical threshold, repeating the step five;

and step six, the processor controls the first subarea to light.

And II, judging by wrist turning, wherein the processor judges to implement the function of a preset value based on wrist turning, if the second partition is lightened:

acquiring data of triaxial acceleration of the intelligent watch by a triaxial acceleration sensor of the intelligent watch, and transmitting the data of the triaxial acceleration to the processor;

step two, a processor of the smart watch performs filtering processing on the collected triaxial acceleration data to obtain processed triaxial acceleration data;

step three, the processor stores the sampling frequency F and the first time threshold value T₁/F and the first amplitude threshold value W0, where T₁Is an integer, T₁<F; the processor counts the time T and the amplitude W of the continuous rising or falling of the acceleration data of each axis in the three axes; if the acceleration data of the X-axis and the Z-axis in the three axes or the acceleration data of the Y-axis and the Z-axis in the three axes continuously rise or fall, the time reaches a first time threshold T stored by the processor₁If the continuously ascending or descending amplitudes of the acceleration data of the X-axis and Z-axis or the acceleration data of the Y-axis and Z-axis reach the amplitude threshold value W0 stored by the processor, the processor judges that the wrist-turning mark appears, and the step IV is carried out; if not, repeating the third step(ii) a The plane determined by the X axis and the Y axis is a plane parallel to the display screen of the bracelet, and the Z axis is an axis vertical to the plane;

step four, the processor stores a second time threshold T₂/F, acceleration interval [ A1, B1]]And a number threshold N0, where T₂Is an integer, T₂<F; at the second time threshold T₂within/F, sample T for each axis₂The acceleration data of each axis is counted to fall into the acceleration interval [ A1, B1]]If the number value N of each axis reaches the number threshold value N0, judging that the wrist is turned, and entering a fifth step; if the number value N of any axis does not reach the number threshold value N0, repeating the step three;

and fifthly, controlling the second subarea to light.

Thirdly, judging translation, and implementing the function of a preset value based on translation judgment by the processor, such as switching display content:

acquiring data of triaxial acceleration of the intelligent watch by a triaxial acceleration sensor of the intelligent watch, and transmitting the data of the triaxial acceleration to the processor;

step two, a processor of the smart watch performs filtering processing on the collected triaxial acceleration data to obtain processed triaxial acceleration data;

step three, the processor stores the sampling frequency F and the first time threshold value T₁/F and the first amplitude threshold value W0, where T₁Is an integer, T₁<F; the processor counts the time T and the amplitude W of the continuous rising or falling of the acceleration data of each axis in the three axes; if the acceleration data of the X-axis and the Y-axis of the three axes continuously rise or fall, the acceleration data reach a first time threshold T stored by the processor₁If the rising or falling amplitude of the acceleration data of the two axes of the X axis and the Y axis reaches the amplitude threshold value W0 stored by the processor, the processor judges that a translation mark appears, and the step IV is executed; if not, repeating the third step; wherein the plane determined by the X axis and the Y axis is parallel to the display screen of the braceletA plane;

step four, the processor stores a second time threshold T₂/F, acceleration interval [ A1, B1]]And a number threshold N0, where T₂Is an integer, T₂<F; at the second time threshold T₂within/F, sample T for each axis₂The acceleration data of each axis is counted to fall into the acceleration interval [ A1, B1]]If the number value N of each axis reaches the number threshold value N0, judging that the wrist is turned, and entering a fifth step; if the number value N of any axis does not reach the number threshold value N0, repeating the step three;

and step five, the processor pre-draws the second content in a first partition and displays the second content in the first partition, and pre-draws the second content in a second partition.

When the watch is in a screen off state, after receiving push content from a mobile terminal bound with the watch or content triggered by the watch, the watch vibrates once to remind a user, and then pinhole light flickers to prompt that unread content still exists.

At this time, the processor pre-draws the pushed first content in a first partition of the screen. The pre-drawing can accelerate the processing process, and the pre-drawn content is displayed immediately when the first screen is bright.

At the moment, the processor judges the gesture, and lights a first partition of the screen when the processor monitors that the first interaction is implemented. The first content may preferably be pre-rendered in the second partition. The first interaction may be the above-described hand-up determination. Because the first partition is smaller, the first content displayed by the first partition is mainly the type and/or sender of the message, and has basic information of the first content displayed by the first partition, a user can judge whether to further check the message, when the detailed content needs to be checked continuously, the processor judges the gesture, when the processor detects that the second interaction is implemented, if the second partition comprises the first partition, the first content displayed by the first partition disappears, the rest parts of the second partition are lightened, and the first content is displayed in the second partition; and if the second partition does not comprise the first partition, the first partition is turned off, the second partition is turned on, and the first content is displayed in the second partition. The second partition displays more of the first content than the first partition displays, and the second partition displays all of the first content. Preferably, the second interaction may be the wrist-turning judgment described above.

In another embodiment, after the watch receives the first content, the first interaction is implemented, the watch receives the second content after the first content is pre-drawn in the first partition, at this time, the watch vibrates again to remind the user, and then the pinhole light continuously flashes to remind that unread content still exists.

At this time, it is determined in advance whether the user has performed the third interaction, and if the third interaction is performed, the processor displays the second content arranged after the first content in the first partition in chronological order, which indicates that the user does not want to read the first content. To save processing time, the processor pre-renders the second content in the first partition before displaying the second content in the first partition, and pre-renders the second content in the second partition after displaying the second content in the first partition. And if the third interaction is not implemented, judging whether a second interaction is implemented, if the second interaction is implemented, lightening a screen of a second partition, and displaying the content currently displayed in the first partition in the second partition. Preferably, the third interaction may be a translation judgment.

Another preferred scheme is that when the second partition cannot meet the content reading requirement of the user, a third partition larger than the second partition may be set, where the third partition is a partition including the second partition, and when the first content or the second content is displayed in the second partition, it is determined whether to implement the second interaction, if so, the content displayed in the second partition is pre-drawn in the third partition, the second partition is turned off, and then the third partition is turned on to display the content currently displayed in the second partition in the third partition. Preferably the third partition is the entire screen display area.

Through the technical scheme, the scheme of gradually lighting the screen is set, when a user only needs to know who sends a message and does not need to know the content, the summary of the content only needs to be displayed on the first partition with the smallest lighting area, and the third interaction is adopted for switching. When the user browses the message needing to be read, the lighted screen is enlarged by utilizing the second interaction, the user can conveniently read the message, and when the second partition is not large enough, the user can also set a third partition so that the content is displayed on the whole screen. Therefore, the screen is gradually lightened, the energy consumption of the screen can be greatly reduced, and the cruising ability of the watch is stronger.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (10)

1. A display switching method of a smart watch, the method comprising:

presetting screen partitions, wherein the screen partitions at least comprise a first partition;

in the screen-off state, the watch obtains first content, carries out first prompt and pre-draws the content in the first partition;

implementing a first interaction, wherein the first partition is lightened, the first content is displayed in the first partition, and the first content is pre-drawn in a second partition with the area larger than that of the first partition;

implementing a second interaction, wherein if a second partition comprises a first partition, the first content displayed by the first partition disappears, the rest of the second partition is lightened, and the first content is displayed in the second partition; and if the second partition does not comprise the first partition, the first partition is turned off, the second partition is turned on, and the first content is displayed in the second partition.

2. A display switching method of a smart watch, the method comprising:

presetting screen partitions, wherein the screen partitions at least comprise a first partition;

in the screen-off state, the watch obtains first content, carries out first prompt and pre-draws the content in the first partition;

the watch obtains second content and continuously carries out the first prompt;

implementing a first interaction, wherein the first partition is bright-screened, the first content is displayed in the first partition, and the first content is pre-drawn in a second partition comprising the first partition;

judging whether a third interaction is implemented, if so, pre-drawing the second content in a first partition and displaying the second content in the first partition, and pre-drawing the second content in a second partition; if not, whether second interaction is implemented or not is judged, if yes, the second subarea is lightened, and the content currently displayed by the first subarea is displayed in the second subarea.

3. The display switching method according to claim 1 or 2, wherein the third interaction is an interaction different from both the first interaction and the second interaction.

4. The display switching method according to claim 1 or 2, wherein the first interaction, the second interaction, and the third interaction are three different gestures that are preset.

5. The display switching method according to claim 1 or 2, wherein the watch further includes a third partition, the third partition is a partition including a second partition, when the first content or the second content is displayed in the second partition, it is determined whether to perform a second interaction, if so, the content displayed in the second partition is pre-drawn in the third partition, and the third partition is lighted up, so that the content currently displayed in the second partition is displayed in the third partition.

6. The display switching method according to claim 1 or 2, wherein the first content obtained by the watch is push content of a mobile terminal bound to the watch or content triggered by the watch itself.

7. The display switching method according to claim 1 or 2, wherein the first prompt is a vibration once and/or a prompt lamp blinking.

8. The display switching method according to claim 1 or 2, wherein the first interaction is implemented as a hand-up interaction, including:

firstly, a three-axis acceleration sensor of the watch acquires three-axis acceleration data of the intelligent watch and transmits the three-axis acceleration data to the processor;

step two, a processor of the watch carries out filtering processing on the collected triaxial acceleration data to obtain processed triaxial acceleration data;

step three, storing a first acceleration threshold value in the processor, if the acceleration data of at least one axis in the acceleration data of the three axes reaches the first acceleration threshold value, judging that the human body is in a violent motion state by the processor, and simultaneously entering step four; if not, the processor judges that the human body is in a non-violent movement state and simultaneously enters the fifth step;

step four, the processor stores a sampling frequency F, a first time threshold T1/F and a first amplitude threshold, wherein T1 is an integer, T1< F, and counts the time and amplitude of the acceleration data of each of the three axes rising or falling continuously: if the time of the acceleration data of any one of the three axes continuously rising or falling reaches a first time threshold T1/F stored by the processor, and the amplitude of the acceleration data of the axis continuously rising or falling reaches a first amplitude threshold stored by the processor, the processor judges that the hand raising mark appears, and the step enters the first step; if not, repeating the step four;

step four, the processor stores a second time threshold T2/F, a first acceleration interval and a first number threshold, in the second time threshold T2/F, wherein T2 is an integer, T2< F, samples T2 acceleration data of each axis, counts the number value of the acceleration data of each axis falling into the first acceleration interval, if the number value of each axis reaches the first number threshold, the processor judges that the hand is lifted, and the process enters step six; if the numerical value of any axis does not reach the first numerical threshold, repeating the step four;

step five, the processor stores a sampling frequency F, a third time threshold T3/F and a second amplitude threshold, wherein T3 is an integer, T3< F, and the processor counts the time and amplitude of continuous rising or falling of acceleration data of an X axis and a Y axis in three axes: if the time for the acceleration data of the X axis and the Y axis to continuously rise or fall reaches the third time threshold T3/F, and the amplitude for the acceleration data of the X axis and the Y axis to continuously rise or fall reaches the second amplitude threshold stored by the processor, the processor judges that the hand-raising mark appears, and the method enters a fifth step; if not, repeating the fifth step;

fifthly, the processor stores a second acceleration interval and a second number threshold, samples T2 acceleration data of each axis within a second time threshold T2/F, counts the number of the acceleration data of each axis falling into the second acceleration interval, judges that the hand is lifted if the number of each axis reaches the second number threshold, and enters a sixth step; if the numerical value of any axis does not reach the second numerical threshold, repeating the step five;

and step six, the processor controls the first subarea to light.

9. The display switching method according to claim 1 or 2, wherein the second interaction is implemented as a wrist-turning interaction, comprising the steps of:

acquiring data of triaxial acceleration of the intelligent watch by a triaxial acceleration sensor of the intelligent watch, and transmitting the data of the triaxial acceleration to the processor;

step two, a processor of the smart watch performs filtering processing on the collected triaxial acceleration data to obtain processed triaxial acceleration data;

step three, the processor stores a sampling frequency F, a first time threshold T1/F and the first amplitude threshold W0, wherein T1 is an integer and T1< F; the processor counts the time T and the amplitude W of the continuous rising or falling of the acceleration data of each axis in the three axes; if the time for continuously ascending or descending the acceleration data of the X-axis and the Z-axis or the two axes of the Y-axis and the Z-axis in the three axes reaches a first time threshold T1/F stored by the processor, and the amplitude for continuously ascending or descending the acceleration data of the X-axis and the Z-axis or the acceleration data of the Y-axis and the Z-axis reaches an amplitude threshold W0 stored by the processor, the processor judges that a wrist-turning mark appears, and the step IV is executed; if not, repeating the third step; the plane determined by the X axis and the Y axis is a plane parallel to the display screen of the bracelet, and the Z axis is an axis vertical to the plane;

step four, the processor stores a second time threshold T2/F, an acceleration interval [ A1, B1] and a number threshold N0, wherein T2 is an integer, and T2 is less than F; sampling T2 pieces of acceleration data for each axis within the second time threshold T2/F, counting the number N of acceleration data of each axis falling into the acceleration interval [ A1, B1], if the number N of each axis reaches the number threshold N0, judging that the wrist is switched, and entering the step five; if the number value N of any axis does not reach the number threshold value N0, repeating the step three;

and fifthly, controlling the second subarea to light.

10. The display switching method according to claim 1 or 2, wherein the third interaction is implemented as a panning interaction, comprising the steps of:

acquiring data of triaxial acceleration of the intelligent watch by a triaxial acceleration sensor of the intelligent watch, and transmitting the data of the triaxial acceleration to the processor;

step two, a processor of the smart watch performs filtering processing on the collected triaxial acceleration data to obtain processed triaxial acceleration data;

step three, the processor stores a sampling frequency F, a first time threshold T1/F and the first amplitude threshold W0, wherein T1 is an integer and T1< F; the processor counts the time T and the amplitude W of the continuous rising or falling of the acceleration data of each axis in the three axes; if the time for continuously ascending or descending the acceleration data of the two axes of the X axis and the Y axis in the three axes reaches a first time threshold T1/F stored by the processor, and the amplitude for continuously ascending or descending the acceleration data of the two axes of the X axis and the Y axis reaches an amplitude threshold W0 stored by the processor, the processor judges that a translation identifier appears, and the step IV is carried out; if not, repeating the third step; the plane determined by the X axis and the Y axis is a plane parallel to the display screen of the bracelet;

step four, the processor stores a second time threshold T2/F, an acceleration interval [ A1, B1] and a number threshold N0, wherein T2 is an integer, and T2 is less than F; sampling T2 pieces of acceleration data for each axis within the second time threshold T2/F, counting the number N of acceleration data of each axis falling into the acceleration interval [ A1, B1], if the number N of each axis reaches the number threshold N0, judging that the wrist is switched, and entering the step five; if the number value N of any axis does not reach the number threshold value N0, repeating the step three;

and step five, the processor pre-draws the second content in a first partition and displays the second content in the first partition, and pre-draws the second content in a second partition comprising the first partition.