WO2018072453A1 - Smart wearable device and energy-saving operation method thereof - Google Patents

Abstract

A smart wearable device (100) and an energy-saving operation method thereof are provided. The energy-saving operation method comprises: a master chip (110) of a smart wearable device (100) entering a sleep mode; an auxiliary chip (120) of the smart wearable device (100) acquiring a real-time altitude data value via an altimeter (140) (S100); if the auxiliary chip (120) determines that the altitude data value is greater than a preset altitude threshold, the auxiliary chip (120) waking up the master chip (110) (S200); a heart rate sensor (130) acquiring a real-time heart rate data value and transmitting the value to the master chip (110) (S300); and the master chip (110) updating heart rate data to a display screen (160) of the smart wearable device (100) (S400).

Description

Intelligent wearable device and energy-saving operation method thereof Technical field

The present application relates to a smart wearable device, and in particular to a technical problem of energy saving and consumption reduction of a wearable device.

Background technique

With the development of computer technology and wearable devices, the field of smart watches is showing a trend of prosperity. It is foreseeable that wearable devices represented by smart watches will greatly change people's lives in the future. The exchange of personal information represented by personal information exchange is becoming more and more common in daily life. We can consider combining smart watches and personal information exchange to achieve better human-computer interaction.

Watches are indispensable carry-on items in people's daily lives. A watch, or watch, refers to an instrument that is worn on the wrist to time or display time. The watch usually uses a strap to bring the "head" of the display time to the wrist. With the development of technology, the current watch industry has shown a trend of integration with smart phones. The so-called smart watch integrates the calling function of the smart phone into the watch, so that the smart watch can make calls and display time, and has other application functions, such as taking pictures, instant communication, sending and receiving mail, and the like.

Because smart watches are very portable, smart watches are often used to record the exercise in the user's daily life. However, when users exercise in their daily life, they often face a safe range when their heart rate exceeds their exercise heart rate. When the heart is unable to load, it is very likely to cause syncope or sudden death during exercise. Danger, or the heart rate does not reach a certain level during exercise, resulting in the inability to achieve effective exercise. If the smart watch is only the user to record the exercise data, this does not enable the user to effectively avoid the above situation for reasonable exercise, resulting in poor user motion.

Chinese Patent Application No. CN201410442818.9, which discloses an energy-saving motion recognition-based controller, and relates to a starting device and a control device for household appliances, lighting, toys, wearable devices, alarm products, etc. A vibration sensor that wakes up the sleepy microprocessor under vibration and, after being woken up, the microprocessor continues to collect the vibration sensor. The signal completes the motion recognition and gives a control command; and enters the energy-saving standby state after determining that there is no action.

The Chinese patent application No. CN201410268216.6, the present invention discloses an energy-saving wearable device, a mobile terminal, a triggering method and a device for supporting a one-button triggering, and a one-key triggering method for the wearable device of the present invention, comprising the steps of: Collecting button information of the wearable device that is derived from the same function button; and generating an instruction corresponding to the button information according to the mode of the button and/or the button time in the button information; instruction. The invention reduces unnecessary functions, redundant buttons and useless states, reduces the power consumption of the Bluetooth module, reduces the total power consumption of the wearable device, and prolongs the battery life.

Existing smart watches, and smart watches for sports design, the most demanding, namely smart sports watches, sports, including walking, running, hiking, off-road and so on. For these sports, smart sports watches are required to complete data recording, including motion parameters, body state information, and trajectory records. The acquisition of these data is done by collecting the data on various sensors controlled by the sensor hub connected to the main chip, including acceleration sensors, heart rate sensors, position sensors, air pressure sensors, gyro sensors, etc. These sensors are required to be in motion. In the open mode, the data is always output for the wearer to refer to, and the purpose of constantly adjusting the state of motion is achieved.

Because the heart rate value of the human body can reflect the intensity of exercise and the metabolic level of the body during exercise, it is necessary to continuously obtain this parameter and display the value for the wearer for reference. At present, the heart rate sensor is always turned on after the smart sports watch is turned on. No matter what kind of motion state the wearer is, the standby time of the smart sports watch sports mode is reduced due to the large current consumption value of the heart rate sensor.

Summary of the invention

The method of the invention is based on the data acquired by the plurality of sensors in the sensor hub, adopts data fusion technology, adaptively adjusts the heart rate sensor monitoring frequency, solves the power consumption problem caused by the heart rate sensor, and prolongs the standby time of the smart sports watch in the sport mode. The invention is achieved by the following technical solutions:

An energy-saving operation method for an intelligent wearable device, the method steps comprising:

The heart rate sensor obtains an average of normal exercise heart rate;

The master chip and the heart rate sensor of the smart wearable device enter a sleep mode;

The auxiliary control chip of the smart wearable device collects real-time altitude data values through sensors;

When the auxiliary control chip determines that the altitude data value is greater than a preset altitude threshold, the auxiliary control chip wakes up the main control chip and the heart rate sensor;

The heart rate sensor collects real-time heart rate data values and transmits them to the main control chip;

The master chip updates heart rate data to a display screen of the smart wearable device.

Further, in the energy-saving operation method, the altitude data value is acquired by an altimeter or calculated by sensing data of a position sensor and a barometric pressure sensor.

Further, in the energy saving operation method, the method steps include:

The master chip of the smart wearable device enters a sleep mode;

The heart rate sensor collects a resting heart rate value and transmits it to a memory for the auxiliary control chip to call;

The heart rate sensor collects a heart rate value and transmits the value to the auxiliary control chip;

When the auxiliary control chip determines that the exercise heart rate value is greater than a first preset multiple of the resting heart rate value (eg, 2.5 times), the auxiliary control chip wakes up the main control chip;

The heart rate sensor collects real-time heart rate data values and transmits them to the main control chip;

The master chip updates heart rate data to a display screen of the smart wearable device.

Further, in the energy saving operation method, the method steps include:

The speed sensor collects the motion speed value and transmits it to the memory for the auxiliary control chip to call;

When the auxiliary control chip determines that the exercise heart rate value is between a second predetermined multiple (eg, 2 times) of the resting heart rate value to a first preset multiple (eg, 2.5 times), the speed sensor is again Collecting a motion speed value; wherein, the value of the second preset multiple is smaller than the value of the first preset multiple;

The auxiliary control chip wakes up the main control chip when the auxiliary control chip determines that the motion speed value is greater than a preset motion speed value twice before and after;

The heart rate sensor collects real-time heart rate data values and transmits them to the main control chip;

The master chip updates heart rate data to a display screen of the smart wearable device.

The preset motion speed value is divided into a reference value 1 and a reference value 2. When the heart rate values are different, that is, greater than 2 times the resting heart rate or less than 2 times the resting heart rate, different motion speed determination criteria are adopted.

Further, in the energy-saving operation method, the motion speed value is directly acquired by the speedometer acquisition, or is obtained through calculation by the acceleration sensor and the sensing data of the positioning sensor.

Further, in the energy-saving operation method, the memory of the smart wearable device is previously stored in the height, weight, age, gender, or resting heart rate of the user of the smart wearable device.

Further, in the energy-saving operation method, the auxiliary control chip of the smart wearable device is a sensor hub chip, and after the smart wearable device enters a motion mode, the sensor hub chip collects: speed data through each of the sensors. , acceleration data, heart rate data, barometric pressure data, latitude and longitude data, altitude data, parallel displacement data, or moving direction data.

The invention also provides an intelligent wearable device:

An intelligent wearable device comprising a main control chip, an auxiliary control chip, a heart rate sensor, an altitude altimeter, a speed meter, a display screen, and a power module.

The heart rate sensor is configured to collect a heart rate data value of a user of the smart wearable device;

The altitude meter is configured to collect an altitude value of a location of the smart wearable device;

The speedometer is configured to collect a motion speed value of a user of the smart wearable device;

The auxiliary control chip is configured to acquire a data value collected by the heart rate sensor, an altitude meter, or a speedometer, and issue a wake-up instruction to the main control chip according to the calculation result of the data value;

The master chip is configured to transmit the updated (heart rate) data value to the display screen after being awake by the auxiliary control chip;

The display screen is configured to display the updated data value;

The power module is configured to provide a normal working voltage only to the auxiliary control chip, the heart rate sensor, the altitude meter, and the speedometer when the main control chip enters a sleep mode. Provide low-power, energy-saving voltages to the master chip and display.

Further, in the smart wearable device, the display screen enters a low power standby mode when the main control chip enters a sleep mode;

The display enters a highlight standby mode after the main control chip is woken up.

Further, the smart wearable device further includes: a positioning sensor, a pressure sensor, and an acceleration sensor.

The positioning sensor is configured to collect a location data value of a location of the smart wearable device;

The air pressure sensor is configured to collect a pressure data value of a location of the smart wearable device;

The acceleration sensor is configured to collect acceleration motion data values of a user of the smart wearable device;

Further, the smart wearable device further includes: a memory, configured to store the data value collected by each sensor and a height, a weight, an age, a gender of a user of the smart wearable device, or Resting heart rate.

Further, the smart wearable device further includes: a communication module, wherein the communication module is configured to perform the data value or information interaction with the outside world by the smart wearable device

The smart wearable device implements the communication mode of the communication module, but is not limited to: a Bluetooth mode, a wifi mode, a lifi mode, and an end-to-end direct communication mode, and the smart wearable device can be inserted into a mobile phone SIM card chip, and used. 2G, 3G, 4G or 5G mobile communication.

Further, the short-range wireless communication sub-module in the (wireless) communication module includes but is not limited to near field communication (NFC), Bluetooth, wireless local area network (wifi), visible light local area network (lifi), infrared data transmission ( IrDA), ZigBee, Ultra WideBand, WiMedia, GPS, DECT, wireless 1394 and other proprietary wireless system modules.

Further, the smart wearable device further includes a gyroscope or a level meter, and the gyroscope or level is used to issue the help information when the unbalanced working state is felt. The help information can be rescued from the surrounding people through the speaker. The help information can also be sent directly to the mobile intelligent terminal of the family through the communication module, or the help information can be sent to the 120 emergency center through the communication module.

Further, the smart wearable device is: a smart watch, a smart bracelet, a smart running shoe, a smart necklace, a smart belt or a smart ring.

The present invention has at least one of the following beneficial effects:

1. The invention overcomes the technical problem that the original smart wearable device has large energy consumption and short practical use time.

2. The invention gives the smart wearable device the ability to save energy by itself and enters an energy-saving and low-power operation mode.

3. The invention greatly facilitates the use of the smart wearable device, and uses the battery for a long time, thereby reducing the number of times of charging.

4. The invention can automatically, efficiently and conveniently complete the help information when the user encounters the situation, and because the smart wearable device has the SIM card embedded therein, the external device can be connected to the outside world without binding the mobile phone. Send a communication link and react at the shortest speed to save the user the most.

5. The energy-saving operation method based on the smart wearable device provided by the invention has high reliability, high execution efficiency and wide application range.

DRAWINGS

The present invention will be further described in detail below with reference to the accompanying drawings and specific embodiments.

1 is a schematic flow chart of a first embodiment of the present invention;

2 is a schematic block diagram of a first embodiment of the present invention;

3 is a schematic diagram of a module according to a second embodiment of the present invention;

4 is a schematic diagram of a module according to a fourth embodiment of the present invention;

FIG. 5 is a schematic flow chart of a fourth embodiment of the present invention.

Description of the reference numerals

100-Intelligent wearable device; 110-master (control) chip; 120-assisted control chip/sensor center; 130-heart rate sensor; 140-altitude altimeter; 150-speed meter; 160-display/screen; 170-power module 180-memory; 190-communication module.

detailed description

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the prior art description will be briefly described below. Obviously, the following description The drawings and the drawings are illustrative of the invention and should not be construed as limiting the invention. The following description sets forth numerous specific details to facilitate the understanding of the invention. However, in some instances, well-known or conventional details have not been described in order to satisfy the brevity of the specification.

In a typical computing hardware configuration of the present application, the client/mobile smart terminal, network device, and trusted party each include one or more processors (CPUs), input/output interfaces, network interfaces, and memory.

The client, mobile terminal or network device in the present invention comprises a processor, including a single core processor or a multi-core processor. A processor may also be called one or more microprocessors, central processing units (CPUs), and the like. More specifically, the processor can be a complex instruction set computing (CISC) microprocessor, a reduced instruction set computing (RISC) microprocessor, a very long instruction word (VLIW) microprocessor, a processor implementing other instruction sets, Or a processor that implements a combination of instruction sets. The processor can also be one or more dedicated processors, such as an application specific integrated circuit (ASIC), field programmable gate array (FPGA), digital signal processor (DSP), network processor, graphics processor, network processor, A communications processor, cryptographic processor, coprocessor, embedded processor, or any other type of logical component capable of processing instructions. The instructions are used by the processor to perform the operations and steps discussed herein.

The client, mobile terminal or network device in the present invention includes a memory for storing big data, and may include one or more volatile storage devices such as random access memory (RAM), dynamic RAM (DRAM), synchronous DRAM. (SDRAM), static RAM (SRAM) or other type of storage device. The memory can store information including sequences of instructions executed by the processor or any other device. For example, a variety of operating systems, device drivers, firmware (eg, input and output base systems or BIOS), and/or executable code and/or data of an application can be loaded into memory and executed by the processor.

The operating system of the client, mobile terminal or network device in the present invention may be any type of operating system, such as Microsoft's Windows, Windows Phone, Apple IOS, Google's Android, and Linux, Unix operating system or other real-time. Or an embedded operating system such as VxWorks.

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the description of the prior art will be briefly described below. Obviously, the following description and the accompanying drawings are The invention is exemplified and should not be construed as limiting the invention. The following description sets forth numerous specific details to facilitate the understanding of the invention. However, in some instances, well known or conventional The details are not stated to meet the succinct requirements of the instructions. Specific devices and methods of the present invention are described in the following examples:

First embodiment

The embodiment provides a method for the energy-saving operation of the smart wearable device. FIG. 1 is a schematic flowchart of the first embodiment of the present invention, where the method steps include:

The heart rate sensor 130 obtains the current heart rate value and is updated by the main control chip 110 to the display screen;

The master chip 110 and the heart rate sensor 130 of the smart wearable device 100 enter a sleep mode;

S100: The auxiliary control chip 120 of the smart wearable device 100 collects real-time altitude data values by using a sensor;

S200: When the auxiliary control chip 120 determines that the altitude data value is greater than a preset altitude threshold, the auxiliary control chip 120 wakes up the main control chip 110 and the heart rate sensor 130;

S300: The heart rate sensor 130 collects real-time heart rate data values and transmits them to the main control chip 110;

S400: The main control chip 110 updates the heart rate data to the display screen 160 of the smart wearable device.

Preferably, in the energy-saving operation method, the altitude data value is directly collected by the altimeter 140, or is obtained through calculation of the sensing data of the position sensor and the air pressure sensor.

Preferably, in the energy-saving operation method, the auxiliary control chip of the smart wearable device is a sensor hub chip 120. After the smart wearable device enters a motion mode, the sensor hub chip collects through each of the sensors: Speed data, acceleration data, heart rate data, barometric pressure data, latitude and longitude data, altitude data, parallel displacement data, or moving direction data.

This embodiment further provides an intelligent wearable device, as shown in FIG. 2 is a schematic diagram of a module according to a first embodiment of the present invention:

An intelligent wearable device 100 includes a main control chip 110, an auxiliary control chip 120, a heart rate sensor 130, an altitude meter 140, a speedometer 150, a display screen 160, and a power module 170.

The heart rate sensor 130 is configured to collect a heart rate of a user of the smart wearable device 100 Data value

The altitude meter 140 is configured to collect an altitude value of a location of the smart wearable device 100;

The speedometer 150 is configured to collect a motion speed value of a user of the smart wearable device 100;

The auxiliary control chip 120 is configured to acquire the data values collected by the heart rate sensor 130, the altitude altimeter 140, or the speedometer 150, and issue a wake-up instruction to the main control chip 110 according to the calculation result of the data value;

The master chip 110, after being awake by the assistant chip 120, is used to transmit the updated (heart rate) data value to the display screen 160;

The display screen 160 is configured to display the updated data value;

The power module 170 is configured to provide a normal operating voltage only to the auxiliary control chip 120, the heart rate sensor 130, the altitude altimeter 140, and the speedometer 150 when the main control chip 110 enters a sleep mode. At this time, the power module 170 provides a low power consumption voltage to the main control chip 110 and the display screen 160.

Preferably, in the smart wearable device, the display screen 160 enters a low power consumption low-light standby mode when the main control chip 110 enters a sleep mode;

The display screen 160 enters a highlight standby mode after the main control chip 110 is woken up.

Preferably, the smart wearable device further includes: a positioning sensor, a pressure sensor, an acceleration sensor,

The positioning sensor is configured to collect a location data value of a location of the smart wearable device;

The air pressure sensor is configured to collect a pressure data value of a location of the smart wearable device;

The acceleration sensor is configured to collect acceleration motion data values of a user of the smart wearable device;

Preferably, the smart wearable device is: a smart watch, a smart bracelet, a smart running shoe, a smart necklace, a smart belt or a smart ring.

Second embodiment

On the basis of the first embodiment, the embodiment further provides an energy-saving operation method, where the method steps include:

B100: The master chip of the smart wearable device enters a sleep mode;

B200: the heart rate sensor collects a resting heart rate value, and transmits the value to the memory for the auxiliary control chip to call;

B300: the heart rate sensor collects a heart rate value and transmits the value to the auxiliary control chip;

B400: The auxiliary control chip wakes up the main control chip when the auxiliary control chip determines that the exercise heart rate value is greater than a first preset multiple of the resting heart rate value (for example, 2.5 times);

B500: the heart rate sensor collects real-time heart rate data values and transmits the values to the main control chip;

B600: The master chip updates heart rate data to a display screen of the smart wearable device.

Preferably, the energy-saving operation method, the memory of the smart wearable device is pre-stored in the height, weight, age, gender or resting heart rate of the user of the smart wearable device.

On the basis of the first embodiment, the present embodiment further provides an intelligent wearable device, as shown in FIG. 3 is a schematic diagram of a module according to a second embodiment of the present invention:

Preferably, the smart wearable device 100 further includes: a memory 180, configured to store the data value collected by each sensor and the height, weight, age of the user of the smart wearable device, Gender or resting heart rate.

Preferably, the smart wearable device 100 further includes: a communication module 190, wherein the communication module is configured to perform the data value or information interaction with the outside world by the smart wearable device.

The communication mode implemented by the communication module of the smart wearable device includes, but is not limited to, a Bluetooth mode, a wifi mode, a lifi mode, and an end-to-end direct communication mode, and the smart wearable device can be inserted into a mobile phone SIM card chip. Use 2G, 3G, 4G or 5G mobile communication.

Preferably, the short-range wireless communication sub-module in the (wireless) communication module includes, but is not limited to, near field communication (NFC), Bluetooth, wireless local area network (WiFi), visible light local area network (lifi), Infrared data transmission (IrDA), ZigBee, Ultra WideBand, WiMedia, GPS, DECT, wireless 1394 and other dedicated wireless system modules.

Preferably, the smart wearable device further includes a gyroscope or a level, and the gyroscope or level is used to issue a distress message when the unbalanced working state is felt. The help information can be rescued from the surrounding people through the speaker. The help information can also be sent directly to the mobile intelligent terminal of the family through the communication module, or the help information can be sent to the 120 emergency center through the communication module.

Third embodiment

Based on the second embodiment, the embodiment preferably provides an energy-saving operation method, where the method steps include:

C100: the speed sensor collects the motion speed value and transmits it to the memory for the auxiliary control chip to call;

C200: when the auxiliary control chip determines that the exercise heart rate value is between a second preset multiple (eg, 2 times) of the resting heart rate value to a first preset multiple (eg, 2.5 times), the speed The sensor collects the motion speed value again;

C300: the auxiliary control chip wakes up the main control chip when the auxiliary control chip determines that the motion speed value is greater than a preset motion speed value twice before and after;

C400: the heart rate sensor collects real-time heart rate data values and transmits the values to the main control chip;

C500: The master chip updates heart rate data to a display screen of the smart wearable device.

The preset motion speed value is divided into a reference value 1 and a reference value 2. When the heart rate values are different, that is, greater than 2 times the resting heart rate or less than 2 times the resting heart rate, different motion speed determination criteria are adopted.

Preferably, in the energy-saving operation method, the motion speed value is directly acquired by the speedometer acquisition, or is obtained through calculation by the acceleration sensor and the sensing data of the positioning sensor.

Embodiment 4

At present, when the smart sports watch is turned on, the heart rate sensor is always in working state. Due to the problem of large power consumption, the standby time of the watch is shortened, and even the wearer's movement cannot be completed. Cheng, this is a very big problem.

The algorithm is obtained from a plurality of sensors under the periodic reading control of the sensor center, including acceleration data, heart rate data, barometric pressure data, latitude and longitude and altitude data, parallel displacement data and direction data, and then according to a predetermined method or algorithm model. Data fusion processing is performed to determine whether the heart rate sensor needs to be activated during the next data reading, thereby reducing unnecessary heart rate sensor activation, thereby saving power consumption of the smart sports watch and maximizing the use of the watch.

The task of the sensor hub is to activate the sensor under its control and complete the reading of the sensor data, and periodically update the processed data to the main chip. The hardware connection is shown in the schematic diagram of the fourth embodiment of the present invention.

Due to the large power consumption of the heart rate sensor in the working mode, selective activation is required to complete the data acquisition. The activation frequency is comprehensively judged according to the current state of the wearer, the physical state and the environment, and the method of judging is based on The speed of the sensor, the last heart rate, the barometric pressure, and the altitude are used to determine whether to activate or deactivate the heart rate sensor. This process is done at the sensor hub and does not need to be handed over to the main chip. It is the most power-saving type. The way is called sensor-based data fusion.

A typical application scenario of the present invention is described as follows:

A, the user activates the sport mode in the watch setting interface. Among them, the sport mode is a state of the whole system, and all levels can be defined as standby, sleep, exercise, and normal. At the same time, it can also be understood as a very important function of the smart watch. When entering the sport mode, the system will have actions from top to bottom. All sensors will participate in the work. The screen will update the collected data in real time, and the system consumes relatively fast power. The ability to record, display and assist the movement of the wearer.

B, the system opens the sensor hub, and the sensor hub opens the various sensors controlled by

C. The sensor hub periodically acquires data of each sensor, including acceleration data, heart rate data, barometric pressure data, latitude and longitude and altitude data, parallel displacement data, and direction data, and whether the center rate data is collected, and needs to be based on the wearer's movement speed. Once (last time) heart rate value, altitude, input model for data fusion, if collected, activate the heart rate sensor to read the wearer's heart rate value, otherwise control it to enter sleep mode

D. After the sensor hub obtains valid data, the main chip is waking up by interrupting, and the data is transmitted to the main chip. The main chip updates the data to the screen of the smart sports watch and enters the standby mode.

E, repeat C to D steps

FIG. 5 is a schematic flow chart of a fourth embodiment of the present invention, wherein the altitude is taken as the primary judgment condition, and the higher the altitude, the lower the blood oxygen saturation, and the faster the heart rate is to maintain the body, which is higher than an altitude requirement. Perform real-time monitoring. Altitude is achieved by a combination of position sensor and air pressure sensor.

The heart rate value collected before (last time/previous time) is taken as the second judgment condition, and the heart rate value is acquired by the heart rate sensor.

The current movement speed of the wearer is used as a third judgment condition, and the current movement speed is acquired by the acceleration sensor and the positioning sensor latitude and longitude information.

In addition, when the user starts to use the smart sports watch, the wearer is required to input his own height, weight, age and other information, and the wearer's resting heart rate is collected.

After all the information is obtained, it is judged according to the following flow chart whether the next data acquisition needs to activate the heart rate sensor to obtain the wearer's latest heart rate value.

The method flow can determine whether the heart rate sensor needs to be activated according to the current environment and the state of motion of the wearer, so that the heart rate sensor can be kept working under unnecessary conditions, and the watch power is quickly consumed. After verification, the standby time of the smart sports watch in sports mode can be extended by about 30%.

It is apparent to those skilled in the art that the present invention is not limited to the details of the above-described exemplary embodiments, and the present invention can be embodied in other specific forms without departing from the spirit or essential characteristics of the invention. Therefore, the present embodiments are to be considered as illustrative and not restrictive, and the scope of the invention is defined by the appended claims instead All changes in the meaning and scope of equivalent elements are included in the present invention. Any reference signs in the claims should not be construed as limiting the claim. In addition, it is to be understood that the word "comprising" does not exclude other elements or steps. A plurality of units or devices recited in the device claims may also be implemented by a unit or device by software or hardware. The first, second, etc. words are used to denote names and do not denote any particular order.

Claims (11)

1. An energy-saving operation method for an intelligent wearable device, characterized in that the method steps include:

   The master chip of the smart wearable device enters a sleep mode;

   The auxiliary control chip of the smart wearable device collects real-time altitude data values through sensors;

   When the auxiliary control chip determines that the altitude data value is greater than a preset altitude threshold, the auxiliary control chip wakes up the main control chip;

   The heart rate sensor collects real-time heart rate data values and transmits them to the main control chip;

   The master chip updates heart rate data to a display screen of the smart wearable device.
2. The energy-saving operation method according to claim 1, wherein the method steps comprise:

   The heart rate sensor collects a resting heart rate value and transmits it to a memory for the auxiliary control chip to call;

   The heart rate sensor collects a heart rate value and transmits the value to the auxiliary control chip;

   When the auxiliary control chip determines that the exercise heart rate value is greater than a first preset multiple of the resting heart rate value, the auxiliary control chip wakes up the main control chip;

   The heart rate sensor collects real-time heart rate data values and transmits them to the main control chip;

   The master chip updates heart rate data to a display screen of the smart wearable device.
3. The energy-saving operation method according to claim 2, wherein the method step comprises:

   The speed sensor collects the motion speed value and transmits it to the memory for the auxiliary control chip to call;

   When the auxiliary control chip determines that the exercise heart rate value is between the second preset multiple of the resting heart rate value to the first preset multiple, the speed sensor collects the motion speed value again; The value of the second preset multiple is smaller than the value of the first preset multiple;

   The auxiliary control chip wakes up the main control chip when the auxiliary control chip determines that the motion speed value is greater than a preset motion speed value twice before and after;

   The heart rate sensor collects real-time heart rate data values and transmits them to the main control chip;

   The master chip updates heart rate data to a display screen of the smart wearable device.
4. The energy-saving operation method according to claim 1, wherein the memory of the smart wearable device is previously stored in a height, a weight, an age, a gender, or a resting heart rate of a user of the smart wearable device.
5. The energy-saving operation method according to claim 1, wherein the auxiliary control chip of the smart wearable device is a sensor hub chip, and after the smart wearable device enters a motion mode, the sensor hub chip passes each of the Sensor, acquisition: speed data, acceleration data, heart rate data, barometric pressure data, latitude and longitude data, altitude data, parallel displacement data or moving direction data.
6. An intelligent wearable device comprising a main control chip, an auxiliary control chip, a heart rate sensor, an altitude altimeter, a speed meter, a display screen and a power module, wherein

   The heart rate sensor is configured to collect a heart rate data value of a user of the smart wearable device;

   The altitude meter is configured to collect an altitude value of a location of the smart wearable device;

   The speedometer is configured to collect a motion speed value of a user of the smart wearable device;

   The auxiliary control chip is configured to acquire a data value collected by the heart rate sensor, an altitude meter, or a speedometer, and issue a wake-up instruction to the main control chip according to the calculation result of the data value;

   The master chip is configured to transmit the updated data value to the display screen after being awake by the auxiliary control chip;

   The display screen is configured to display the updated data value;

   The power module is configured to provide a normal working voltage only to the auxiliary control chip, the heart rate sensor, the altitude meter, and the speedometer when the main control chip enters a sleep mode.
7. The smart wearable device according to claim 6, wherein the display screen enters a low-light standby mode when the main control chip enters a sleep mode;

   The display enters a highlight standby mode after the main control chip is woken up.
8. The smart wearable device according to claim 6, further comprising: a positioning sensor, a pressure sensor, an acceleration sensor,

   The positioning sensor is configured to collect a location data value of a location of the smart wearable device;

   The air pressure sensor is configured to collect a pressure data value of a location of the smart wearable device;

   The acceleration sensor is configured to collect acceleration motion data values of a user of the smart wearable device.
9. The smart wearable device according to any one of claims 6 to 7, further comprising: a memory for storing the data value collected by each sensor and the use of the smart wearable device Height, weight, age, gender or resting heart rate.
10. The smart wearable device according to claim 10, further comprising: a communication module, wherein the communication module is configured to perform the data value or information interaction with the outside world by the smart wearable device.
11. The smart wearable device according to claim 6, further comprising a gyroscope or a level, wherein the gyroscope or level is configured to issue a distress message when the unbalanced working state is sensed.

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