WO2015139371A1 - 一种移动设备工作模式的控制方法及控制系统 - Google Patents
一种移动设备工作模式的控制方法及控制系统 Download PDFInfo
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- WO2015139371A1 WO2015139371A1 PCT/CN2014/078866 CN2014078866W WO2015139371A1 WO 2015139371 A1 WO2015139371 A1 WO 2015139371A1 CN 2014078866 W CN2014078866 W CN 2014078866W WO 2015139371 A1 WO2015139371 A1 WO 2015139371A1
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
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- G06F3/011—Arrangements for interaction with the human body, e.g. for user immersion in virtual reality
- G06F3/015—Input arrangements based on nervous system activity detection, e.g. brain waves [EEG] detection, electromyograms [EMG] detection, electrodermal response detection
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- G06F1/1633—Constructional details or arrangements of portable computers not specific to the type of enclosures covered by groups G06F1/1615 - G06F1/1626
- G06F1/1684—Constructional details or arrangements related to integrated I/O peripherals not covered by groups G06F1/1635 - G06F1/1675
- G06F1/1694—Constructional details or arrangements related to integrated I/O peripherals not covered by groups G06F1/1635 - G06F1/1675 the I/O peripheral being a single or a set of motion sensors for pointer control or gesture input obtained by sensing movements of the portable computer
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- G06F1/3203—Power management, i.e. event-based initiation of a power-saving mode
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- G06F3/017—Gesture based interaction, e.g. based on a set of recognized hand gestures
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- A61B5/11—Measuring movement of the entire body or parts thereof, e.g. head or hand tremor, mobility of a limb
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- A—HUMAN NECESSITIES
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- A63B2220/80—Special sensors, transducers or devices therefor
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- H04M1/72403—User interfaces specially adapted for cordless or mobile telephones with means for local support of applications that increase the functionality
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02D—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN INFORMATION AND COMMUNICATION TECHNOLOGIES [ICT], I.E. INFORMATION AND COMMUNICATION TECHNOLOGIES AIMING AT THE REDUCTION OF THEIR OWN ENERGY USE
- Y02D10/00—Energy efficient computing, e.g. low power processors, power management or thermal management
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02D—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN INFORMATION AND COMMUNICATION TECHNOLOGIES [ICT], I.E. INFORMATION AND COMMUNICATION TECHNOLOGIES AIMING AT THE REDUCTION OF THEIR OWN ENERGY USE
- Y02D30/00—Reducing energy consumption in communication networks
- Y02D30/70—Reducing energy consumption in communication networks in wireless communication networks
Definitions
- the present invention relates to the field of wearable smart devices and mobile terminals, and more particularly to a method and a control system for controlling a working mode of a mobile device.
- smartphone users on the market often adjust the mobile phone working mode according to the environment in which the user is located, such as selecting a conference mode during a meeting, selecting a silent mode during a break, or selecting an outdoor mode during exercise; or
- a gravity sensor, an accelerometer, a gyroscope or a heartbeat sensor is set on the smart phone to detect the current state of the user, thereby intelligently adjusting the working mode of the mobile phone, but there is no technology for controlling the working mode of the smart terminal through other devices.
- the present invention aims to provide a control method and a control system for a mobile device working mode, which fills in the prior art, that the mobile device working mode switching mode can only be manually switched, or according to the mobile device. Insufficient stateful switching.
- a method for controlling a working mode of a mobile device comprising the steps of:
- the wearable device acquires the current vital sign data of the user, and sends the current vital sign data to the mobile device;
- the mobile device receives the physical sign data, and determines a current motion state of the user according to the physical sign data;
- the mobile device acquires a working mode corresponding to the current motion state of the user according to the current motion state of the user, and switches the current working mode of the mobile device to the corresponding working mode.
- the method for controlling a working mode of the mobile device wherein before the step A, the method further includes:
- the mobile device receives an operation instruction of the user, and sets an operation mode of the mobile device corresponding to the multiple motion states of the user.
- step A specifically includes:
- the wearable device receives an operation instruction of the user, and establishes a connection with the mobile device.
- the wearable device acquires current physical vitality data of the user through a sensor disposed therein;
- the wearable device receives an operation instruction of the user, and sends the vital sign data to the mobile device.
- the control method of the mobile device working mode wherein the working mode of the mobile device includes a power saving mode, a silent mode, and a normal mode.
- the method for controlling a working mode of a mobile device wherein the wearable device establishes a connection with the mobile device by using any one of Bluetooth, infrared, wifi, and NFC.
- the method for controlling a working mode of a mobile device wherein the wearable device is a smart watch, a smart bracelet, smart glasses, smart shoes, or smart clothes.
- a control system for a working mode of a mobile device comprising:
- a monitoring and sending module configured to acquire the current vital sign data of the user by the wearable device, and send the current vital sign data to the mobile device;
- a receiving and determining module configured to receive the physical sign data by the mobile device, and determine a current motion state of the user according to the physical sign data
- the mode switching module is configured to acquire, according to the current motion state of the user, a working mode corresponding to the current motion state of the user, and switch the current working mode of the mobile device to the corresponding working mode.
- control system of the working mode of the mobile device further comprising:
- a setting module configured to receive, by the mobile device, an operation instruction of the user, and set an operation mode of the mobile device corresponding to the plurality of motion states of the user respectively.
- the control system of the mobile device working mode wherein the monitoring and sending module specifically includes:
- a connecting unit configured to receive, by the wearable device, an operation instruction of the user, and establish a connection with the mobile device
- a state obtaining unit configured to acquire, by the wearable device, a current vital sign data of the user by using a sensor disposed therein;
- a sending unit configured to receive, by the wearable device, an operation instruction of the user, and send the vital sign data to the mobile device.
- the control system of the mobile device working mode wherein the wearable device is a smart watch, a smart bracelet, smart glasses, smart shoes, or smart clothes.
- the present invention provides a method and a control system for controlling a working mode of a mobile device, the method comprising: the wearable device acquiring current vital sign data of the user, and transmitting the current vital sign data to the mobile device; The physical data is described, and the current motion state of the user is determined according to the physical data; the mobile device acquires a working mode corresponding to the current motion state of the user according to the current motion state of the user, and switches the current working mode of the mobile device to the corresponding working mode. Since the wearable device or the accessory device intelligently determines the state of the user and controls the smart terminal to enter the corresponding working mode, the wearable device realizes the function of intelligently controlling the working mode switching like the remote control, so that the user is more convenient to use the device. .
- FIG. 1 is a flow chart of a preferred embodiment of a method for controlling a working mode of a mobile device according to the present invention.
- FIG. 2 is a structural block diagram of a preferred embodiment of a control system for a mobile device operating mode according to the present invention.
- the present invention provides a method and a control system for controlling the operation mode of the mobile device.
- the present invention will be further described in detail below with reference to the accompanying drawings and embodiments. It is understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.
- FIG. 1 is a flowchart of a preferred embodiment of a method for controlling a working mode of a mobile device according to the present invention. As shown in FIG. 1 , the method for controlling a working mode of a mobile device includes the following steps:
- Step S100 The wearable device acquires current vital sign data of the user, and sends the current vital sign data to the mobile device.
- the user's vital sign data is collected in real time by various sensors provided in the wearable device.
- the vital sign data in the present invention is not the data of various organs of the human body collected by the medical device in the medical field in a strict sense, but various data of the human body collected by various sensors in a broader sense, for example, in motion.
- the user's activity time and rest time, exercise intensity, number of steps, walking distance, and calories burned are recognized and recorded in various states to identify and record the delicate movements of the wrist in the state of shallow sleep and deep sleep. , record the time required to fall asleep, the balance between shallow sleep and deep sleep, the time spent lying in bed, and the number of wake-ups at night.
- the wearable device obtains the user's vital sign data
- the acquired vital sign data is transmitted to the mobile device.
- Step S200 The mobile device receives the vital sign data, and determines a current motion state of the user according to the vital sign data.
- the mobile device After the mobile device receives the vital sign data in step S200, the changes in the user behavior are detected in conjunction with the sensors in the mobile device. After the mobile device receives the physical activity data of the user sent by the wearable device, the current motion state of the user is determined according to the data in the human body vitality parameter database stored in the mobile device.
- Step S300 The mobile device acquires an operation mode corresponding to the current motion state of the user according to the current motion state of the user, and switches the current working mode of the mobile device to the corresponding working mode.
- the mobile terminal After obtaining the current motion state of the user, the mobile terminal issues an instruction to switch the current working mode of the mobile device. For example, if the wearable device collects the number of heartbeats of the user at this time is 75 times, the data is transmitted to the mobile device, and the corresponding table of the current state of the user and the working mode of the device is set in the mobile device, and the data in the table is compared. It is known that the working mode of the mobile device corresponding to the heartbeat data is the normal mode, and the mobile device switches to the normal mode; when the wearable device collects the number of heartbeats of the user at this time is 60 times, the mobile device switches to the silent mode.
- the wearable device acquires the current state of the user, and the mobile device receives and dynamically switches the working mode according to the data. Even if the mobile device has a certain distance from the user, the working mode of the mobile device can be remotely switched, which brings great convenience to the user.
- the method before the connection between the wearable device and the mobile device is established in step S100, the method further includes:
- Step S10 The mobile device receives an operation instruction of the user, and sets an operation mode of the mobile device corresponding to each of the plurality of motion states of the user.
- the working mode of the mobile device corresponding to the multiple motion states of the user in step S10 may be set by the manufacturer before leaving the factory, or may be customized by the user according to the physical parameters.
- the working mode of the mobile device includes a power saving mode, a silent mode, and a normal mode.
- more modes can be set to meet the actual use requirements of mobile device users, such as setting a conference mode, a sport mode, and the like.
- step S100 the specific steps of establishing the connection between the wearable device and the mobile device include:
- Step S101 The wearable device receives an operation instruction of the user, and establishes a connection with the mobile device.
- the wearable device establishes a connection with the mobile device by any one of Bluetooth, infrared, wifi, and NFC. After the wearable device establishes a connection with the mobile device, the wearable device and the mobile device can perform real-time data interaction.
- Step S102 The wearable device acquires current vital sign data of the user by using a sensor disposed therein; wherein the current state of the user includes an awake state, a shallow sleep state, and a deep sleep state; determining the current state of the user is based on the setting Various sensors in the device, such as an acceleration sensor, a heartbeat sensor, a gyroscope and a gravity sensor, collect parameters such as the user's current motion state, heartbeat number, pulse rate, etc., and then comprehensively determine the current state of the user according to the above parameters.
- a sensor disposed therein wherein the current state of the user includes an awake state, a shallow sleep state, and a deep sleep state
- determining the current state of the user is based on the setting
- Various sensors in the device such as an acceleration sensor, a heartbeat sensor, a gyroscope and a gravity sensor, collect parameters such as the user's current motion state, heartbeat number, pulse rate, etc., and then comprehensively determine the current state of the
- Step S103 The wearable device receives an operation instruction of the user, and sends the vital sign data to the mobile device.
- step S100 when the wearable device transmits data to the mobile device, the data is sent periodically or irregularly, that is, the wearable device automatically sends the current state data of the user to the mobile device at a fixed time, or the wearable device is not timed.
- the user is required to send a data command, and manually send the current vitality data of the user to the mobile device.
- the wearable device is a smart watch, a smart bracelet, smart glasses, smart shoes, or smart clothes.
- a smart watch or a smart wristband is preferred, because the above two smart wearable devices can be worn all day, even if the user does not need to take off when sleeping, which is beneficial for real-time collection of smart wearable devices.
- the physical parameter of the user, the mobile device determines which operating mode to switch based on the data collected by the smart wearable device. The switching of the working mode of the mobile device can not only meet the requirements of the user for the ringtone size, but also meet the requirements for the power saving level.
- Application example 1 The user enters the rest state or wakes up from the rest state
- the 101 smart watch receives the user's connection establishment instruction before the user rests, and establishes a wireless connection with the smart phone;
- the 102 smart watch acquires the physical parameters of the user during the rest period by using various sensors disposed therein;
- the smart phone determines whether the user is currently in a sleep state according to the received user's physical parameter and the physical parameter corresponding to the user's current state correspondence table stored in the smart phone;
- the smartphone mode is adjusted to the silent mode, and at the same time, some applications and functions are restricted;
- the smartphone mode is adjusted to the normal mode, and at the same time, the restrictions on the above-mentioned partial applications and functions are released.
- the data exchange between the smart wearable device and the mobile device controls the switching of the working mode of the mobile device, which is more convenient for the user's daily life requirements, and allows the user to use and control the device more conveniently.
- the present invention further provides a control system for a working mode of a mobile device, as shown in FIG. 2, including:
- the monitoring and sending module 210 is configured to acquire the current vital sign data of the user and send the current vital sign data to the mobile device; as described above.
- the receiving and determining module 220 is configured to receive the vital sign data by the mobile device, and determine a current motion state of the user according to the vital sign data; specifically, as described above.
- the mode switching module 230 is configured to acquire, according to the current motion state of the user, a working mode corresponding to the current motion state of the user, and switch the current working mode of the mobile device to the corresponding working mode; specifically, as described above.
- control system of the mobile device working mode further includes:
- the setting module 200 is configured to receive, by the mobile device, an operation instruction of the user, and set an operation mode of the mobile device corresponding to the plurality of motion states of the user respectively; specifically, as described above.
- the monitoring and sending module 210 specifically includes:
- the connecting unit is configured to receive, by the wearable device, an operation instruction of the user, and establish a connection with the mobile device; as described above.
- a state obtaining unit configured to acquire, by the wearable device, a current vital sign data of the user through a sensor disposed therein; specifically as described above.
- a sending unit configured to receive, by the wearable device, an operation instruction of the user, and send the vital sign data to the mobile device; specifically, as described above.
- the wearable device is a smart watch, a smart bracelet, smart glasses, smart shoes, or smart clothes.
- the present invention provides a method and a control system for controlling a working mode of a mobile device, the method comprising: the wearable device acquiring current vitality data of the user, and transmitting the current vital data to the mobile device
- the mobile device receives the vital sign data, and determines the current motion state of the user according to the physical sign data; the mobile device acquires a working mode corresponding to the current motion state of the user according to the current motion state of the user, and switches the current working mode of the mobile device to the corresponding Operating mode.
- the wearable device or the accessory device intelligently determines the state of the user and controls the smart terminal to enter the corresponding working mode, the wearable device realizes the function of intelligently controlling the working mode switching like the remote control, so that the user is more convenient to use the device. .
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Abstract
本发明所提供的一种移动设备工作模式的控制方法及控制系统,所述方法包括:穿戴式设备获取用户当前的体征数据,并将所述当前的体征数据发送至移动设备;移动设备接收所述体征数据,并根据体征数据判断用户当前运动状态;移动设备根据用户当前运动状态,获取与用户当前运动状态对应的工作模式,并将移动设备当前工作模式切换至该对应的工作模式。由于通过穿戴式设备或附属设备,智能地判断用户所处状态,控制智能终端进入对应的工作模式,穿戴式设备实现了像遥控一样智能控制工作模式切换的功能,让用户使用设备的时候更方便。
Description
技术领域
本发明涉及穿戴式智能设备及移动终端领域,尤其涉及的是一种移动设备工作模式的控制方法及控制系统。
背景技术
随着智能手机的功能越来越强,应用越来越多,人们使用手机的时间也随之变长,耗电问题就成为智能手机用户需考虑的最大问题。手机厂商虽然设计了很多省电模式,但大部分厂商或开发者设计的省电模式是从软件层面上做到到更省电,而对何时开启或关闭省电模式却没有设计贴近用户使用习惯的方案。
现在市场上的智能手机用户在切换手机工作模式时,往往会根据用户自身所处的环境来手动调整,例如开会时选择会议模式、休息时选择静音模式或运动时选择户外模式等;或者是在智能手机上设置重力传感器、加速度传感器、陀螺仪或心跳传感器等来检测用户当前状态,从而智能调整手机工作模式,但没有一种通过其他设备来控制智能终端工作模式的技术出现。
因此,现有技术还有待于改进和发展。
发明内容
鉴于上述现有技术的不足,本发明的目的在于提供一种移动设备工作模式的控制方法及控制系统,填补了现有技术中移动设备工作模式切换方式只能采取手动切换,或者根据移动设备所处状态智能切换的不足。
本发明的技术方案如下:
一种移动设备工作模式的控制方法,其中,所述方法包括步骤:
A、穿戴式设备获取用户当前的体征数据,并将所述当前的体征数据发送至移动设备;
B、移动设备接收所述体征数据,并根据体征数据判断用户当前运动状态;
C、移动设备根据用户当前运动状态,获取与用户当前运动状态对应的工作模式,并将移动设备当前工作模式切换至该对应的工作模式。
所述移动设备工作模式的控制方法,其中,所述步骤A之前还包括:
S、移动设备接收用户的操作指令,设置与用户多个运动状态分别对应的移动设备的工作模式。
所述移动设备工作模式的控制方法,其中,所述步骤A具体包括:
A1、穿戴式设备接收用户的操作指令,与移动设备建立连接;
A2、穿戴式设备通过设置在其中的传感器获取用户当前的体征数据;
A3、穿戴式设备接收用户的操作指令,将所述体征数据发送至所述移动设备。
所述移动设备工作模式的控制方法,其中,所述移动设备的工作模式包括省电模式、静音模式和正常模式。
所述移动设备工作模式的控制方法,其中,所述穿戴式设备通过蓝牙、红外、wifi和NFC中任意一种与所述移动设备建立连接。
所述移动设备工作模式的控制方法,其中,所述穿戴式设备为智能手表、智能手环、智能眼镜、智能鞋、或智能衣服。
一种移动设备工作模式的控制系统,其中,包括:
监测及发送模块,用于穿戴式设备获取用户当前的体征数据,并将所述当前的体征数据发送至移动设备;
接收及判断模块,用于移动设备接收所述体征数据,并根据体征数据判断用户当前运动状态;
模式切换模块,用于移动设备根据用户当前运动状态,获取与用户当前运动状态对应的工作模式,并将移动设备当前工作模式切换至该对应的工作模式。
所述移动设备工作模式的控制系统,其中,还包括:
设置模块,用于移动设备接收用户的操作指令,设置与用户多个运动状态分别对应的移动设备的工作模式。
所述移动设备工作模式的控制系统,其中,所述监测及发送模块具体包括:
连接单元,用于穿戴式设备接收用户的操作指令,与移动设备建立连接;
状态获取单元,用于穿戴式设备通过设置在其中的传感器获取用户当前的体征数据;
发送单元,用于穿戴式设备接收用户的操作指令,将所述体征数据发送至所述移动设备。
所述移动设备工作模式的控制系统,其中,所述穿戴式设备为智能手表、智能手环、智能眼镜、智能鞋、或智能衣服。
本发明所提供的一种移动设备工作模式的控制方法及控制系统,所述方法包括:穿戴式设备获取用户当前的体征数据,并将所述当前的体征数据发送至移动设备;移动设备接收所述体征数据,并根据体征数据判断用户当前运动状态;移动设备根据用户当前运动状态,获取与用户当前运动状态对应的工作模式,并将移动设备当前工作模式切换至该对应的工作模式。由于通过穿戴式设备或附属设备,智能地判断用户所处状态,控制智能终端进入对应的工作模式,穿戴式设备实现了像遥控一样智能控制工作模式切换的功能,让用户使用设备的时候更方便。
附图说明
图1为本发明所述移动设备工作模式的控制方法较佳实施例的流程图。
图2为本发明所述移动设备工作模式的控制系统较佳实施例的结构框图。
具体实施方式
本发明提供一种移动设备工作模式的控制方法及控制系统,为使本发明的目的、技术方案及效果更加清楚、明确,以下参照附图并举实施例对本发明进一步详细说明。应当理解,此处所描述的具体实施例仅仅用以解释本发明,并不用于限定本发明。
请参见图1,图1是本发明所述移动设备工作模式的控制方法较佳实施例的流程图。如图1所示,所述移动设备工作模式的控制方法,包括以下步骤:
步骤S100、穿戴式设备获取用户当前的体征数据,并将所述当前的体征数据发送至移动设备;
在步骤S100中是通过设置在穿戴式设备中的各种传感器实时采集用户的体征数据。本发明中所述体征数据并不是严格意义上的在医学领域中通过医疗设备采集的人体各器官的数据,而是更广泛意义上的通过各种传感器采集的人体的各种数据,例如在运动状态下时通过各类传感器识别和记录用户的活动时间与休息时间、运动激烈程度、步数、步行距离以及消耗的热量等,在浅度睡眠及深度睡眠的状态下识别和记录手腕的细微动作,记录入睡所需要的时间、浅度睡眠与深度睡眠之间的平衡、躺在床上的时间以及夜间醒来的次数等。当穿戴式设备获取用户体征数据后,将获取的体征数据传输至移动设备。
步骤S200、移动设备接收所述体征数据,并根据体征数据判断用户当前运动状态;
在步骤S200移动设备接收所述体征数据后,结合移动设备内的传感器共同来检测用户行为的变化。当移动设备接收穿戴式设备发送的用户的体征数据后,结合移动设备中存储的人机体征参数数据库中的数据,判断用户当前的运动状态。
步骤S300、移动设备根据用户当前运动状态,获取与用户当前运动状态对应的工作模式,并将移动设备当前工作模式切换至该对应的工作模式。
移动终端获取用户的当前运动状态后,发出对移动设备当前工作模式的进行切换的指令。例如穿戴式设备采集用户此时的心跳次数为75次,则将该数据传输至移动设备,移动设备中由于对应的设置了一个用户当前状态与设备工作模式的对应表,从表中数据对比得知此时心跳数据对应的移动设备工作模式为正常模式,移动设备则切换为正常模式;当穿戴式设备采集用户此时的心跳次数为60次,则移动设备切换为静音模式。通过穿戴式设备获取用户当前的状态,移动设备接收并根据数据后智能切换工作模式,即使移动设备距离用户有一定距离,也能遥控移动设备的工作模式进行切换,给用户带来极大方便。
进一步地实施例,如图1所示,在步骤S100所述穿戴式设备和移动设备建立连接前,还包括:
步骤S10、移动设备接收用户的操作指令,设置与用户多个运动状态分别对应的移动设备的工作模式。
本发明较佳实施例步骤S10中所述用户多个运动状态分别对应的移动设备的工作模式,既可以是移动设备出厂前由厂商设置,也可以是用户根据自身体征参数自定义设置。
进一步地,所述移动设备的工作模式包括省电模式、静音模式和正常模式。除了上述三种模式外,还可以设置更多的模式以满足移动设备用户的实际使用需求,例如设置会议模式、运动模式等。
在步骤S100中,所述穿戴式设备和移动设备建立连接的具体步骤包括:
步骤S101、穿戴式设备接收用户的操作指令,与移动设备建立连接;
其中,所述穿戴式设备通过蓝牙、红外、wifi和NFC中任意一种与所述移动设备建立连接。所述穿戴式设备与所述移动设备建立连接后,所述穿戴式设备与所述移动设备能进行实时数据交互。
步骤S102、穿戴式设备通过设置在其中的传感器获取用户当前的体征数据;其中所述用户当前状态包括清醒状态、浅度睡眠状态及深度睡眠状态;判断用户当前所处状态,是根据设置在穿戴式设备中的各种传感器,如加速度传感器、心跳传感器、陀螺仪及重力传感器采集用户当前的运动状态、心跳次数、脉搏次数等参数,再根据上述参数综合判断用户当前状态。
步骤S103、穿戴式设备接收用户的操作指令,将所述体征数据发送至所述移动设备。
步骤S100中穿戴式设备向移动设备传输数据时,采取定时或不定时的发送,即穿戴式设备每隔一段固定时间自动将用户的当前状态的数据发送至移动设备,或是穿戴式设备不定时得接收用户的发送数据指令、手动的将用户当前的体征数据发送至移动设备。
进一步地实施例,所述穿戴式设备为智能手表、智能手环、智能眼镜、智能鞋、或智能衣服。本发明较佳实施例中选用智能手表或智能手环更佳,因为上述两种智能穿戴式设备用户可全天佩戴,即使是用户睡觉时也不用取下,这样有利于智能穿戴式设备实时采集用户的体征参数,所述移动设备根据智能穿戴式设备采集的数据来判断进行何种工作模式的切换。移动设备工作模式的切换不仅可以满足用户对铃声大小的要求,也能满足对省电级别的要求。
以下将通过具体的应用实施例对本发明做进一步说明:
应用实例1:用户进入休息状态或从休息状态转醒
101智能手表在用户休息前接收用户的建立连接指令,与智能手机建立无线连接;
102智能手表通过设置在其中的各种传感器获取用户在休息过程中的体征参数;
103智能手表将采集到的用户体征参数数据发送至智能手机;
104智能手机根据接收的用户体征参数,并结合存储在智能手机内的体征参数-用户当前状态对应表,判断用户当前是否进入睡眠状态;
105当判断用户进入睡眠状态,则智能手机模式调整为静音模式,并同时对部分应用和功能进行限制;
106当判断用户进入正常状态,则智能手机模式调整为正常模式,并同时解除对上述部分应用和功能的限制。
可见,通过智能式穿戴式设备与移动设备的数据交互,来控制移动设备工作模式的切换,是更符合用户日常生活要求,让用户使用和控制设备的时候更方便。
基于上述方法,本发明还提供了一种移动设备工作模式的控制系统,如图2所示,包括:
监测及发送模块210,用于穿戴式设备获取用户当前的体征数据,并将所述当前的体征数据发送至移动设备;具体如上所述。
接收及判断模块220,用于移动设备接收所述体征数据,并根据体征数据判断用户当前运动状态;具体如上所述。
模式切换模块230,用于移动设备根据用户当前运动状态,获取与用户当前运动状态对应的工作模式,并将移动设备当前工作模式切换至该对应的工作模式;具体如上所述。
进一步地实施例,如图2所示,所述移动设备工作模式的控制系统还包括:
设置模块200,用于移动设备接收用户的操作指令,设置与用户多个运动状态分别对应的移动设备的工作模式;具体如上所述。
进一步的实施例,所述监测及发送模块210具体包括:
连接单元,用于穿戴式设备接收用户的操作指令,与移动设备建立连接;具体如上所述。
状态获取单元,用于穿戴式设备通过设置在其中的传感器获取用户当前的体征数据;具体如上所述。
发送单元,用于穿戴式设备接收用户的操作指令,将所述体征数据发送至所述移动设备;具体如上所述。
进一步地实施例,所述穿戴式设备为智能手表、智能手环、智能眼镜、智能鞋、或智能衣服。
综上所述,本发明所提供的一种移动设备工作模式的控制方法及控制系统,所述方法包括:穿戴式设备获取用户当前的体征数据,并将所述当前的体征数据发送至移动设备;移动设备接收所述体征数据,并根据体征数据判断用户当前运动状态;移动设备根据用户当前运动状态,获取与用户当前运动状态对应的工作模式,并将移动设备当前工作模式切换至该对应的工作模式。由于通过穿戴式设备或附属设备,智能地判断用户所处状态,控制智能终端进入对应的工作模式,穿戴式设备实现了像遥控一样智能控制工作模式切换的功能,让用户使用设备的时候更方便。
应当理解的是,本发明的应用不限于上述的举例,对本领域普通技术人员来说,可以根据上述说明加以改进或变换,所有这些改进和变换都应属于本发明所附权利要求的保护范围。
Claims (17)
- 一种移动设备工作模式的控制方法,其特征在于,所述方法包括步骤:A、穿戴式设备获取用户当前的体征数据,并将所述当前的体征数据发送至移动设备;B、移动设备接收所述体征数据,并根据体征数据判断用户当前运动状态;C、移动设备根据用户当前运动状态,获取与用户当前运动状态对应的工作模式,并将移动设备当前工作模式切换至该对应的工作模式。
- 根据权利要求1所述移动设备工作模式的控制方法,其特征在于,所述步骤A之前还包括:S、移动设备接收用户的操作指令,设置与用户多个运动状态分别对应的移动设备的工作模式。
- 根据权利要求1所述移动设备工作模式的控制方法,其特征在于,所述步骤A具体包括:A1、穿戴式设备接收用户的操作指令,与移动设备建立连接;A2、穿戴式设备通过设置在其中的传感器获取用户当前的体征数据;A3、穿戴式设备接收用户的操作指令,将所述体征数据发送至所述移动设备。
- 根据权利要求1所述移动设备工作模式的控制方法,其特征在于,所述移动设备的工作模式包括省电模式、静音模式和正常模式。
- 根据权利要求1所述移动设备工作模式的控制方法,其特征在于,所述穿戴式设备通过蓝牙、红外、wifi和NFC中任意一种与所述移动设备建立连接。
- 根据权利要求1-5任一项所述移动设备工作模式的控制方法,其特征在于,所述穿戴式设备为智能手表、智能手环、智能眼镜、智能鞋、或智能衣服。
- 一种移动设备工作模式的控制方法,其特征在于,所述方法包括步骤:S、移动设备接收用户的操作指令,设置与用户多个运动状态分别对应的移动设备的工作模式;A、穿戴式设备获取用户当前的体征数据,并将所述当前的体征数据发送至移动设备;所述步骤A具体包括:A1、穿戴式设备接收用户的操作指令,与移动设备建立连接;A2、穿戴式设备通过设置在其中的传感器获取用户当前的体征数据;A3、穿戴式设备接收用户的操作指令,将所述体征数据发送至所述移动设备;B、移动设备接收所述体征数据,并根据体征数据判断用户当前运动状态;C、移动设备根据用户当前运动状态,获取与用户当前运动状态对应的工作模式,并将移动设备当前工作模式切换至该对应的工作模式。
- 根据权利要求7所述移动设备工作模式的控制方法,其特征在于,所述步骤A中的体征数据为通过各种传感器采集的人体的各种数据,包括:在运动状态下时通过各类传感器识别和记录用户的活动时间与休息时间、运动激烈程度、步数、步行距离以及消耗的热量数据;在浅度睡眠及深度睡眠的状态下识别和记录手腕的细微动作,记录入睡所需要的时间、浅度睡眠与深度睡眠之间的平衡、躺在床上的时间以及夜间醒来的次数数据。
- 根据权利要求7所述移动设备工作模式的控制方法,其特征在于,所述移动设备的工作模式包括省电模式、静音模式和正常模式。
- 根据权利要求7所述移动设备工作模式的控制方法,其特征在于,所述穿戴式设备通过蓝牙、红外、wifi和NFC中任意一种与所述移动设备建立连接。
- 根据权利要求7-10任一项所述移动设备工作模式的控制方法,其特征在于,所述穿戴式设备为智能手表、智能手环、智能眼镜、智能鞋、或智能衣服。
- 一种移动设备工作模式的控制方法,其特征在于,所述方法包括步骤:S、移动设备接收用户的操作指令,设置与用户多个运动状态分别对应的移动设备的工作模式;A、穿戴式设备获取用户当前的体征数据,并将所述当前的体征数据发送至移动设备;B、移动设备接收所述体征数据,并根据体征数据判断用户当前运动状态;C、移动设备根据用户当前运动状态,获取与用户当前运动状态对应的工作模式,并将移动设备当前工作模式切换至该对应的工作模式;所述步骤A中的体征数据为通过各种传感器采集的人体的各种数据,包括:在运动状态下时通过各类传感器识别和记录用户的活动时间与休息时间、运动激烈程度、步数、步行距离以及消耗的热量数据;在浅度睡眠及深度睡眠的状态下识别和记录手腕的细微动作,记录入睡所需要的时间、浅度睡眠与深度睡眠之间的平衡、躺在床上的时间以及夜间醒来的次数数据。
- 根据权利要求12所述移动设备工作模式的控制方法,其特征在于,所述步骤A具体包括:A1、穿戴式设备接收用户的操作指令,与移动设备建立连接;A2、穿戴式设备通过设置在其中的传感器获取用户当前的体征数据;A3、穿戴式设备接收用户的操作指令,将所述体征数据发送至所述移动设备。
- 一种移动设备工作模式的控制系统,其特征在于,包括:监测及发送模块,用于穿戴式设备获取用户当前的体征数据,并将所述当前的体征数据发送至移动设备;接收及判断模块,用于移动设备接收所述体征数据,并根据体征数据判断用户当前运动状态;模式切换模块,用于移动设备根据用户当前运动状态,获取与用户当前运动状态对应的工作模式,并将移动设备当前工作模式切换至该对应的工作模式。
- 根据权利要求14所述移动设备工作模式的控制系统,其特征在于,还包括:设置模块,用于移动设备接收用户的操作指令,设置与用户多个运动状态分别对应的移动设备的工作模式。
- 根据权利要求14所述移动设备工作模式的控制系统,其特征在于,所述监测及发送模块具体包括:连接单元,用于穿戴式设备接收用户的操作指令,与移动设备建立连接;状态获取单元,用于穿戴式设备通过设置在其中的传感器获取用户当前的体征数据;发送单元,用于穿戴式设备接收用户的操作指令,将所述体征数据发送至所述移动设备。
- 根据权利要求14-16任一项所述移动设备工作模式的控制系统,其特征在于,所述穿戴式设备为智能手表、智能手环、智能眼镜、智能鞋、或智能衣服。
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