CN111327770B - Terminal falling protection method and system - Google Patents

Abstract

The invention discloses a terminal fall protection method and a terminal fall protection system. The method comprises the following steps: the method comprises the steps of measuring motion state information of a terminal in real time, obtaining the appearance of a predicted impact surface in real time, predicting the falling state of the terminal according to the motion state information and the appearance of the predicted impact surface, and adjusting parameters of an air bag device according to the falling state so that the air bag device protects the terminal. The method can reduce the probability of terminal drop damage.

Description

Terminal falling protection method and system

Technical Field

The invention relates to the technical field of artificial intelligence, in particular to a method and a system for terminal fall protection.

Background

In the process of daily use of the mobile phone, the mobile phone is inevitably dropped, so that the mobile phone is damaged, for example, the screen is cracked, the body is deformed or the mobile phone cannot be started. Because the mobile phone plays an increasingly important role in daily life and study of people, the damage of the mobile phone brings much trouble to the daily life of people. Besides, when other mobile terminals are used, the problem that the terminals are dropped and damaged often exists.

The current method for protecting the terminal from being damaged when falling is to protect the terminal by using protection tools such as a protection sleeve, a hanging rope and a storage bag, but when the falling plane has a bulge, the protection method is difficult to realize that the terminal is not damaged when falling.

Disclosure of Invention

Therefore, the invention provides a terminal falling protection method and device, which aim to solve the problem that the terminal is damaged when falling due to the defects of a terminal falling protection technology in the prior art.

In order to achieve the above object, a first aspect of the present invention provides a terminal drop protection method, including:

measuring motion state information of the terminal in real time;

acquiring and predicting the appearance of an impact surface in real time;

predicting the falling state of the terminal according to the motion state information and the appearance of the predicted impact surface;

and adjusting parameters of the air bag device according to the falling state so that the air bag device protects the terminal.

Preferably, before the step of obtaining the topography of the predicted impact surface in real time, the method further comprises:

monitoring whether the terminal is in a weightlessness state according to the motion state information;

and when the terminal is in a weightlessness state, sending an activation signal to obtain the morphology of the predicted impact surface.

Preferably, before the step of sending the activation signal, the method further comprises:

judging whether the duration time of the weightless state exceeds a preset time or not;

and when the duration time of the weightless state exceeds the preset time, sending the activation signal.

Preferably, the step of adjusting parameters of the airbag device according to the falling state includes:

judging whether the terminal is still in a falling process;

and when the terminal is still in the falling process, adjusting parameters of the air bag device according to the falling state so that the air bag device protects the terminal.

Preferably, the airbag device parameter includes at least one of an airbag position and an inflation amount.

Preferably, the motion state information includes: at least one of altitude information, speed information, and attitude information.

Preferably, the fall condition comprises: at least one of a predicted travel trajectory, a predicted impact time, a predicted impact angle, and a predicted impact location.

A second aspect of the present invention provides a terminal fall protection system, which is characterized in that the system includes:

the sensing module is used for measuring the motion state information of the terminal in real time;

the image acquisition module is used for acquiring and predicting the appearance of the impact surface in real time;

the information processing module is used for predicting the falling state of the terminal according to the motion state information and the appearance of the predicted impact surface;

and the control module adjusts the parameters of the air bag device according to the falling state so that the air bag device protects the terminal.

Preferably, the system further comprises:

the air bag device is arranged at the side position of the terminal and used for protecting the terminal according to the air bag device parameters adjusted by the control module; wherein the airbag device parameters include an airbag position and an inflation amount.

Preferably, the sensing module includes at least one of a height sensor, a speed sensor, a tilt sensor, and a gravity sensor.

The invention has the following advantages:

the invention provides a terminal fall protection method, which comprises the steps of firstly, measuring motion state information of a terminal in real time and acquiring and predicting the appearance of an impact surface in real time; then, predicting the falling state of the terminal according to the motion state information and the shape of the predicted impact surface; and finally, adjusting the parameters of the air bag device according to the falling state to ensure that the air bag device protects the terminal. Therefore, the terminal can be effectively protected when falling to any shape and impact surface to be predicted at any time, and the probability of damage caused by falling of the terminal is reduced.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

Fig. 1 is a flowchart of a terminal fall protection method according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a terminal fall protection system according to an embodiment of the present invention;

fig. 3 is a flowchart of a mobile phone fall protection method according to an embodiment of the present invention.

In the drawings:

21: the sensing module 22: image acquisition module

23: the information processing module 24: control module

25: airbag device

Detailed Description

The following detailed description of embodiments of the invention refers to the accompanying drawings. It should be understood that the detailed description and specific examples, while indicating the present invention, are given by way of illustration and explanation only, not limitation.

The embodiment provides a terminal fall protection method, as shown in fig. 1, the method includes the following steps:

and step 101, measuring the motion state information of the terminal in real time.

In this embodiment, the motion state information of the terminal includes: at least one of altitude information, speed information, and attitude information. The height information is the distance information between the terminal and the predicted impact surface; the speed information comprises the movement speed and the movement direction of the current movement of the terminal; the attitude information is the angle of the terminal with respect to the horizontal plane, i.e., horizontal, vertical, or inclined by a certain angle.

And 102, acquiring the morphology of the predicted impact surface in real time.

Wherein the predicted impact surface is a media surface that the terminal may impact when dropped, including but not limited to a floor, a table, or a wall surface. The shape of the predicted impact surface comprises flat or convex shapes.

In one embodiment, before the morphology of the predicted impact surface is obtained in real time, whether the terminal is in the weightlessness state is monitored according to the motion state information measured in real time in step 101, for example, the acceleration of the terminal during motion is determined in real time according to the motion state information, and whether the terminal is in the weightlessness state is determined according to the acceleration. And when the terminal is in a weightlessness state, sending an activation signal to obtain the morphology of the predicted impact surface.

In another embodiment, in order to avoid the terminal resource waste caused by the terminal sending the activation signal by mistake, when the terminal is determined to be in the weightless state, whether the duration of the weightless state exceeds a preset time is determined, and the preset time may be set to 0.05 second, 0.1 second, or the like. And when the duration time of the weightless state exceeds the preset time, sending an activation signal to obtain the morphology of the predicted impact surface.

And 103, predicting the falling state of the terminal according to the motion state information and the shape of the predicted impact surface.

Wherein the falling state of the terminal comprises at least one of a predicted running track, a predicted impact time, a predicted impact angle and a predicted impact part. In one embodiment, if the terminal is rotating dropped, the predicted trajectory includes a predicted number of rotations.

And 104, adjusting the parameters of the air bag device according to the falling state so that the air bag device protects the terminal.

In the present embodiment, the airbag device parameter includes at least one of an airbag position and an inflation amount. The airbag position includes each side position of the terminal, and can be marked by using different airbag marks. The inflation quantity is used for indicating the inflation quantity in the air bag, and can be indicated by the volume of gas or percentage. When the amount of inflation is expressed as a percentage, 0% indicates that the airbag is not inflated, and 100% indicates that the airbag is filled with gas. It should be noted that, in this embodiment, when the parameters of the airbag device are adjusted according to the falling state, the appropriate parameters of the airbag device can be adjusted according to different falling states. The terminal is characterized in that the proper air bag position is adjusted to trigger the air bag device to deflate, the air bags at one or more air bag positions are inflated, and the terminal can be protected from being damaged when falling under the condition of reducing the cost; the terminal can be prevented from rebounding after falling by adjusting the proper inflation quantity, and damage caused by falling again after the terminal bounces is avoided.

In one embodiment, in order to further prevent the terminal from falling to the state of predicting the damage of the terminal after the impact surface bounces, the step of adjusting the parameters of the airbag device according to the falling state specifically comprises the following steps: and judging whether the terminal is still in the falling process, and adjusting the parameters of the air bag device according to the falling state when the terminal is still in the falling process so that the air bag device protects the terminal.

In another embodiment, when the parameters of the airbag device are adjusted according to the falling state, the parameters such as the weight and/or the gravity center position of the terminal are also required to be referred to, so that the terminal is protected from being damaged when falling in an all-around manner.

According to the terminal falling protection method provided by the embodiment, the motion state information of the terminal is measured in real time, the appearance of the predicted impact surface is obtained in real time, the falling state of the terminal is predicted according to the motion state information and the appearance of the predicted impact surface, and the parameters of the air bag device are adjusted according to the falling state, so that the air bag device protects the terminal, the terminal can be effectively protected when falling to the predicted impact surface with any appearance at any time, and the probability of damage caused by falling of the terminal is reduced.

The present embodiment provides a terminal fall protection system, as shown in fig. 2, the system includes: a sensing module 21, an image acquisition module 22, an information processing module 23, a control module 24 and an airbag device 25. The control module 24 is in signal connection with the sensing module 21, the image acquisition module 22, the information processing module 23 and the airbag device 25; there is also a signal connection between the information processing module 23 and the sensing module 21 and the image acquisition module 22.

The sensing module 21 is configured to measure motion state information of the terminal in real time. The sensing module 21 includes at least one of a height sensor, a speed sensor, a tilt sensor, and a gravity sensor. The height sensor is used for measuring the height information of the terminal in real time, and the height information is the distance information between the terminal and a predicted impact surface; the speed sensor is used for measuring the speed information of the terminal in real time, and the speed information comprises the movement speed and the movement direction of the current movement of the terminal; the tilt angle sensor is used for measuring attitude information of the terminal in real time, wherein the attitude information is an angle of the terminal relative to a horizontal plane, namely a horizontal angle, a vertical angle or a certain inclined angle; the gravity sensor is used for measuring the change of the center of gravity of the terminal in real time.

And the image acquisition module 22 comprises one or more cameras and is used for acquiring and predicting the appearance of the impact surface in real time. Wherein the predicted impact surface is a medium surface predicted to be in contact with the terminal after the terminal is dropped, and the medium surface includes but is not limited to the ground, a desktop or a wall surface. The topography of the predicted impact surface may include flat or convex, etc.

And the information processing module 23 is used for predicting the falling state of the terminal according to the motion state information and the shape of the predicted impact surface. Wherein the falling state of the terminal comprises at least one of a predicted running track, a predicted impact time, a predicted impact angle and a predicted impact part. In one embodiment, if the terminal is rotating and falling, the information processing module 23 determines a predicted operation track according to the change of the center of gravity of the terminal measured by the gravity sensor in the sensing module 21, wherein the predicted operation track comprises the predicted number of rotations.

And the control module 24 is used for controlling the sensing module 21, the image acquisition module 22 and the airbag device 25 to be opened and closed. In one embodiment, the control module 24 is further configured to receive information sent by the information processing module 23. For example, before the image obtaining module 22 obtains and predicts the morphology of the impact surface in real time, the information processing module 23 monitors whether the terminal is in a weightless state according to the motion state information measured by the sensing module 21 in real time. When the terminal is in a weightless state, the information processing module 23 sends an activation signal to the control module 24, and the control module 24 controls the image acquisition module 22 to be started according to the activation signal so as to acquire the morphology of the predicted impact surface.

Preferably, in order to avoid the terminal resource waste caused by the information processing module 23 sending the activation signal by mistake, when the information processing module 23 determines that the terminal is in the weightless state, it is further determined whether the duration of the weightless state exceeds a preset time, where the preset time may be set to 0.05 second, 0.1 second, or the like. When the duration time of the weightless state exceeds the preset time, the information processing module 23 sends an activation signal to the control module 24, and the control module 24 controls the image acquisition module 22 to be started according to the activation signal so as to acquire the morphology of the predicted impact surface.

The control module 24 is further configured to adjust parameters of the airbag device according to the falling state of the terminal predicted by the information processing module 23, so that the airbag device 25 protects the terminal.

The airbag device 25 includes a gas storage module and an airbag. The gas storage module of the airbag device 25 is initially filled with a gas, which is hydrogen or helium. The airbag device 25 is built in the side position of the terminal for protecting the terminal according to the airbag device parameters adjusted by the control module 24. Specifically, the gas storage module of the airbag device 25 inflates one or more airbags according to the adjusted parameters of the airbag device, so that the airbags pop up to buffer the impact between the terminal and the predicted impact surface and protect the terminal from being damaged. It should be noted that the airbag device parameters include the airbag position and the inflation amount. The positions of the air bags comprise the positions of all side edges of the terminal, and can be marked by using different air bag marks; the inflation quantity is used for indicating the inflation quantity in the air bag, and can be indicated by the volume of gas or percentage. When the inflation amount is indicated by percentage, 0% indicates that the control module 24 controls the airbag device 25 not to inflate the airbag, and 100% indicates that the control module 24 controls the airbag device 25 to fill the airbag with gas.

It should be further noted that, in this embodiment, when the control module 24 adjusts the parameters of the airbag device according to the falling state, the control module may adjust the appropriate parameters of the airbag device according to different falling states. The control module 24 adjusts a proper airbag position to trigger the airbag device 25 to inflate the airbag at one or more airbag positions, so that the terminal can be protected from being damaged when falling under the condition of reducing the cost; the control module 24 adjusts the appropriate inflation amount to ensure that the terminal does not bounce after falling, and damage caused by falling again after the terminal bounces is avoided. It should be noted that the control module 24 can also control the air bag device 25 to deflate the air bag filled with gas.

In one embodiment, in order to further prevent the terminal from falling to a state where damage to the terminal after bouncing from the impact surface is predicted, the step of adjusting the parameters of the airbag device by the control module 24 according to the falling state specifically includes: the control module 24 firstly determines whether the terminal is still in the falling process, and when the terminal is still in the falling process, the control module 24 adjusts parameters of the air bag device according to the falling state so that the air bag device protects the terminal. Preferably, when the control module 24 adjusts parameters of the airbag device according to the falling state, the parameters such as the weight and/or the center of gravity of the terminal are referred to, so that the terminal is protected from being damaged when falling in an all-round manner.

In another embodiment, the terminal fall protection system further comprises a storage module and a power module. The storage module is configured to store intermediate data generated by the sensing module 21, the image obtaining module 22, the information processing module 23, the control module 24, and the airbag device 25, where the intermediate data includes motion state information, a predicted impact surface morphology, a terminal falling state, and/or an airbag device parameter. The power module is used for providing continuous power supply for the sensing module 21, the image acquisition module 22, the information processing module 23, the control module 24, the air bag device 25 and the storage module.

The terminal fall protection system provided by this embodiment includes a sensing module 21, an image acquisition module 22, an information processing module 23, and a control module 24. Firstly, the sensing module 21 measures the motion state information of the terminal in real time, and meanwhile, the image obtaining module 22 obtains the morphology of the predicted impact surface in real time. Then, the information processing module 23 predicts the falling state of the terminal according to the motion state information and the shape of the predicted impact surface, and finally the control module 24 adjusts the parameters of the air bag device according to the falling state, so that the air bag device 25 protects the terminal, therefore, the terminal can be effectively protected when falling to the predicted impact surface with any shape at any time, and the probability of damage caused by the falling of the terminal is reduced.

The embodiment also provides a mobile phone falling protection method. Wherein, the cell-phone is installed the cell-phone and is fallen protection system, and this cell-phone falls protection system includes: the sensing module is positioned in the body or on the surface of the body; the control module, the information processing module, the storage module and the power supply module are positioned in the machine body; the front camera, the rear camera and the air bag devices arranged in the four sides of the machine body. In the mobile phone falling protection system, a control module is in signal connection with a sensing module, an information processing module, an air bag device, a front camera and a rear camera; the information processing module is in signal connection with the sensing module and the front camera and the rear camera.

As shown in fig. 3, the mobile phone fall protection method provided by this embodiment includes:

step 301, the sensing module measures the motion state information of the mobile phone in real time.

Wherein the motion state information includes at least one of altitude information, velocity information, and attitude information. The sensing module includes a sensor, such as at least one of a height sensor, a speed sensor, a tilt sensor, and a gravity sensor. In one embodiment, in order to make the height information measured by the sensing module in real time more accurate, a height sensor is arranged at each of four corners of the mobile phone.

Step 302, the sensing module sends the motion state information to the information processing module and the storage module.

Step 303, the information processing module monitors whether the mobile phone is in a weightlessness state according to the motion state information. The method for monitoring whether the mobile phone is in the weightlessness state includes but is not limited to: and determining the acceleration of the mobile phone in motion in real time according to the motion state information, and determining whether the mobile phone is in a weightlessness state or not according to the acceleration.

And step 304, when the mobile phone is in a weightless state, the information processing module sends an activation signal to the control module.

And 305, the control module receives an activation signal and starts the front camera and the rear camera according to the activation signal.

And step 306, the front camera and the rear camera acquire the predicted shape of the impact surface and send the predicted shape of the impact surface to the information processing module and the storage module.

The predicted impact surface is a medium surface which is likely to be impacted when the mobile phone falls, and the medium surface comprises but is not limited to the ground, a desktop or a wall surface. The modes of the front camera and the rear camera for acquiring the predicted impact surface appearance include but are not limited to picture taking or video recording. The shape of the predicted impact surface comprises flat or convex shapes.

And 307, the information processing module predicts the falling state of the mobile phone according to the motion state information measured by the sensing module in real time and the shape of the predicted impact surface.

The falling state of the mobile phone comprises at least one of the prediction of a running track, the prediction of impact time, the prediction of an impact angle and the prediction of an impact part. It should be noted that the falling state can indicate the result of the mobile phone falling, for example, when it is predicted that the impact part is the rear shell, the result of the mobile phone falling may be that the body is damaged; when the impact part is predicted to be the screen, the consequence of falling of the mobile phone can be screen fragmentation and the like.

And step 308, the information processing module sends the falling state to the control module and the storage module.

And 309, receiving the falling state by the control module, and adjusting parameters of the air bag device according to the falling state so that the air bag device protects the mobile phone.

The parameters of the air bag device comprise air bag position and inflation quantity. In this embodiment, the positions of the air bags are four side positions of the mobile phone, and are marked by the first air bag, the second air bag, the third air bag and the fourth air bag. The inflation quantity is used for indicating the inflation quantity in the air bag, and can be indicated by the volume of gas or percentage. In one embodiment, the control module adjusts the positions of the air bags to the first air bag and the second air bag according to the falling state, and the inflation amount is adjusted to 100%, and then the air storage module of the air bag device rapidly inflates the first air bag and the second air bag, so that the first air bag and the second air bag pop up to protect the mobile phone. When the first air bag and the second air bag are filled with gas, the gas storage device stops inflating the first air bag and the second air bag.

According to the mobile phone falling protection method provided by the embodiment, firstly, the motion state information of the mobile phone is measured in real time through the sensing module, and secondly, the information processing module monitors whether the mobile phone is in a weightlessness state according to the motion state information, so that the mobile phone can be effectively protected when falling at any time. When the mobile phone is in a weightless state, the information processing module sends an activation signal to the control module, and the control module starts the front camera and the rear camera according to the activation signal to obtain the shape of the predicted impact surface. Then, the information processing module predicts the falling state of the mobile phone according to the motion state information measured by the sensing module in real time and the shape of the predicted impact surface, and the falling state can indicate the falling result of the mobile phone. Finally, the control module adjusts the parameters of the air bag device according to the falling state so that the air bag device protects the mobile phone, therefore, the mobile phone can be effectively protected when falling to any shape of predicted impact surface at any time, and the probability of damage caused by falling of the mobile phone is reduced.

It will be understood that the above embodiments are merely exemplary embodiments taken to illustrate the principles of the present invention, which is not limited thereto. It will be apparent to those skilled in the art that various modifications and improvements can be made without departing from the spirit and substance of the invention, and these modifications and improvements are also considered to be within the scope of the invention.

Claims (8)

1. A terminal fall protection method is characterized by comprising the following steps:

measuring motion state information of the terminal in real time;

acquiring and predicting the appearance of an impact surface in real time;

predicting the falling state of the terminal according to the motion state information and the appearance of the predicted impact surface; the fall state includes: at least one of a predicted travel trajectory, a predicted impact time, a predicted impact angle, and a predicted impact location;

adjusting parameters of an air bag device according to the falling state so that the air bag device protects the terminal; the airbag device parameter includes at least one of an airbag position and an inflation amount.

2. The method of claim 1, further comprising, prior to the step of obtaining the topography of the predicted impact surface in real time:

monitoring whether the terminal is in a weightlessness state according to the motion state information;

and when the terminal is in a weightlessness state, sending an activation signal to obtain the morphology of the predicted impact surface.

3. The method of claim 2, further comprising, prior to the step of sending an activation signal:

judging whether the duration time of the weightless state exceeds a preset time or not;

and when the duration time of the weightless state exceeds the preset time, sending the activation signal.

4. The method of claim 1, wherein the step of adjusting airbag device parameters based on the fall condition comprises:

judging whether the terminal is still in a falling process;

and when the terminal is still in the falling process, adjusting parameters of the air bag device according to the falling state so that the air bag device protects the terminal.

5. The method of claim 1, wherein the motion state information comprises: at least one of altitude information, speed information, and attitude information.

6. A terminal fall protection system, the system comprising:

the sensing module is used for measuring the motion state information of the terminal in real time;

the image acquisition module is used for acquiring and predicting the appearance of the impact surface in real time;

the information processing module is used for predicting the falling state of the terminal according to the motion state information and the appearance of the predicted impact surface; the fall state includes: at least one of a predicted travel trajectory, a predicted impact time, a predicted impact angle, and a predicted impact location;

the control module adjusts parameters of the air bag device according to the falling state so that the air bag device protects the terminal; the airbag device parameter includes at least one of an airbag position and an inflation amount.

7. The system of claim 6, further comprising:

the air bag device is arranged at the side position of the terminal and used for protecting the terminal according to the air bag device parameters adjusted by the control module; wherein the airbag device parameters include an airbag position and an inflation amount.

8. The system of claim 6, wherein the sensing module comprises at least one of a height sensor, a speed sensor, a tilt sensor, and a gravity sensor.

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