CN116520971B - Self-adaptive power consumption adjusting method and system for wearable device and readable storage medium - Google Patents

Abstract

The invention discloses a self-adaptive power consumption adjusting method, a self-adaptive power consumption adjusting system and a readable storage medium of a wearable device, wherein the method comprises the following steps: acquiring monitoring data of a wearable device, wherein the monitoring data comprises external event data and internal power consumption data; real-time adjusting constituent modules of the wearable device based on the monitoring data, wherein a gravity sensor module and a heart rate monitoring module in the constituent modules are adjusted based on the external event data; and adjusting a power amplifier module, a transmission module and a display module in the composition module based on the internal power consumption data. The invention can ensure the high-performance operation of the wearable equipment, and makes a real-time adjustment scheme for the high-power-consumption modules of the system while the user operates smoothly, thereby realizing the optimal solution of power consumption and further improving the endurance time of the wearable equipment.

Description

Self-adaptive power consumption adjusting method and system for wearable device and readable storage medium

Technical Field

The invention relates to the technical field of wearable equipment, in particular to a method and a system for adjusting self-adaptive power consumption of the wearable equipment and a readable storage medium.

Background

With the continuous development of science and technology, various scientific and technological products enter the daily life of people, for example, intelligent wearing equipment is a necessary product for the daily life of people along with the development of times, wherein the intelligent wearing equipment is specifically a general name for applying wearing technology to carry out intelligent design on daily wearing and developing wearable equipment, and products such as intelligent watches, intelligent bracelets, intelligent glasses, intelligent clothes and the like.

However, when the intelligent wearable device is used, many problems still exist, for example, the standing standby time is long, but the performance is bad and pleasant in the scene of real use of the user, the powerful endurance time cannot be provided, and the use experience of the user is seriously affected.

Disclosure of Invention

The invention aims to provide a self-adaptive power consumption adjusting method, a self-adaptive power consumption adjusting system and a self-adaptive power consumption adjusting system for a wearable device, and a readable storage medium, so that the high-performance operation of the wearable device can be ensured, and a real-time adjusting scheme is made for a high-power consumption module of a system while a user operates smoothly, so that the optimal solution of power consumption is achieved, and the endurance time of the wearable device is improved.

The first aspect of the invention provides a self-adaptive power consumption adjusting method of a wearable device, comprising the following steps:

acquiring monitoring data of a wearable device, wherein the monitoring data comprises external event data and internal power consumption data;

adjusting the constituent modules of the wearable device in real time based on the monitoring data, wherein,

adjusting a gravity sensor module and a heart rate monitoring module in the composition module based on the external event data; and

and adjusting a power amplification module, a transmission module and a display module in the composition module based on the internal power consumption data.

In this scheme, acquire the monitoring data of wearing equipment, specifically include:

waking up the wearable device, identifying an operating parameter of the wearable device for monitoring, wherein,

based on the gravity sensor module and the heart rate monitoring module on the wearable equipment, monitoring to obtain the external event data;

identifying a power consumption factor based on internal operation data of the wearable device, and extracting the internal power consumption data based on the power consumption factor.

In this scheme, wake up wearing equipment, discernment wearing equipment's operating parameter is in order to monitor, specifically includes:

acquiring a wake-up response value for waking up the wearable device;

identifying an operating parameter of the wearable device based on the wake-up response value, wherein,

if the operation parameter is a preset value, monitoring the external event data and the internal power consumption data;

and if the operation parameter is not the preset value, not monitoring the external event data and the internal power consumption data.

In this scheme, if the operation parameter is not the preset value, data analysis is performed based on the operation parameter to identify wake-up failure data, and output is performed based on the wake-up failure data.

In this scheme, based on external event data adjusts gravity sensor module and heart rate monitoring module, specifically include:

identifying a gravity sensing value based on the gravity sensor module, wherein if the gravity sensing value exceeds a preset sensing value, the heart rate monitoring module is adjusted to be started in real time;

and if the gravity sensing value does not exceed the preset sensing value, periodically starting the heart rate monitoring module based on a heart rate monitoring period.

In this scheme, based on internal power consumption data adjusts power amplifier module, transmission module and display module, specifically include:

identifying the power amplifier module, the transmission module and the power consumption sequencing of the display module based on the internal power consumption data;

and obtaining an adjusting priority based on the power consumption sorting, and carrying out grading opening of each module based on the adjusting priority, wherein the simultaneous opening quantity of the power amplification module, the transmission module and the display module is not more than three.

The second aspect of the present invention also provides a wearable device adaptive power consumption adjustment system, including a memory and a processor, where the memory includes a wearable device adaptive power consumption adjustment method program, and the wearable device adaptive power consumption adjustment method program when executed by the processor implements the following steps:

acquiring monitoring data of a wearable device, wherein the monitoring data comprises external event data and internal power consumption data;

adjusting the constituent modules of the wearable device in real time based on the monitoring data, wherein,

adjusting a gravity sensor module and a heart rate monitoring module in the composition module based on the external event data; and

and adjusting a power amplification module, a transmission module and a display module in the composition module based on the internal power consumption data.

In this scheme, acquire the monitoring data of wearing equipment, specifically include:

waking up the wearable device, identifying an operating parameter of the wearable device for monitoring, wherein,

based on the gravity sensor module and the heart rate monitoring module on the wearable equipment, monitoring to obtain the external event data;

identifying a power consumption factor based on internal operation data of the wearable device, and extracting the internal power consumption data based on the power consumption factor.

In this scheme, wake up wearing equipment, discernment wearing equipment's operating parameter is in order to monitor, specifically includes:

acquiring a wake-up response value for waking up the wearable device;

identifying an operating parameter of the wearable device based on the wake-up response value, wherein,

if the operation parameter is a preset value, monitoring the external event data and the internal power consumption data;

and if the operation parameter is not the preset value, not monitoring the external event data and the internal power consumption data.

In this scheme, if the operation parameter is not the preset value, data analysis is performed based on the operation parameter to identify wake-up failure data, and output is performed based on the wake-up failure data.

In this scheme, based on external event data adjusts gravity sensor module and heart rate monitoring module, specifically include:

identifying a gravity sensing value based on the gravity sensor module, wherein if the gravity sensing value exceeds a preset sensing value, the heart rate monitoring module is adjusted to be started in real time;

and if the gravity sensing value does not exceed the preset sensing value, periodically starting the heart rate monitoring module based on a heart rate monitoring period.

In this scheme, based on internal power consumption data adjusts power amplifier module, transmission module and display module, specifically include:

identifying the power amplifier module, the transmission module and the power consumption sequencing of the display module based on the internal power consumption data;

and obtaining an adjusting priority based on the power consumption sorting, and carrying out grading opening of each module based on the adjusting priority, wherein the simultaneous opening quantity of the power amplification module, the transmission module and the display module is not more than three.

A third aspect of the present invention provides a computer readable storage medium, including therein a wearable device adaptive power consumption adjustment method program of a machine, which when executed by a processor, implements the steps of a wearable device adaptive power consumption adjustment method according to any one of the above.

According to the self-adaptive power consumption adjusting method, system and readable storage medium for the wearable equipment, high-performance operation of the wearable equipment can be guaranteed, a user can smoothly operate and experience, and meanwhile, a real-time adjusting scheme is made for high-power consumption modules of the system, so that optimal solution of power consumption is achieved, and the endurance time of the wearable equipment is prolonged.

Drawings

FIG. 1 shows a flow chart of a method for adaptive power consumption adjustment of a wearable device of the present invention;

fig. 2 shows a block diagram of a wearable device adaptive power consumption regulation system of the present invention.

Detailed Description

In order that the above-recited objects, features and advantages of the present invention will be more clearly understood, a more particular description of the invention will be rendered by reference to the appended drawings and appended detailed description. It should be noted that, in the case of no conflict, the embodiments of the present application and the features in the embodiments may be combined with each other.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced in other ways than those described herein, and therefore the scope of the present invention is not limited to the specific embodiments disclosed below.

Fig. 1 shows a flowchart of a method for adjusting adaptive power consumption of a wearable device.

As shown in fig. 1, the application discloses a method for adjusting adaptive power consumption of a wearable device, which includes the following steps:

s102, acquiring monitoring data of a wearable device, wherein the monitoring data comprise external event data and internal power consumption data;

s104, real-time adjustment is carried out on the constituent modules of the wearable equipment based on the monitoring data;

s106, adjusting a gravity sensor module and a heart rate monitoring module in the composition module based on the external event data;

s108, adjusting a power amplifier module, a transmission module and a display module in the composition module based on the internal power consumption data.

It should be noted that, in this embodiment, when a user wears the wearable device, based on the wearable device, corresponding monitoring data may be obtained, and accordingly, the monitoring data includes the external event data and the internal power consumption data, so that real-time adjustment may be performed on constituent modules of the wearable device based on the monitoring data, where the constituent modules include a gravity sensor module, a heart rate monitoring module, a power amplifier module, a transmission module and a display module, specifically, based on the external event data, the gravity sensor module and the heart rate monitoring module in the constituent modules are adjusted, and based on the internal power consumption data, the power amplifier module, the transmission module and the display module in the constituent modules are adjusted, so as to ensure high-performance operation of the wearable device, and make a real-time adjustment scheme for the high-power consumption modules while the user operates smoothly, so as to improve the endurance time of the wearable device.

According to an embodiment of the present invention, the acquiring monitoring data of the wearable device specifically includes:

waking up the wearable device, identifying an operating parameter of the wearable device for monitoring, wherein,

based on the gravity sensor module and the heart rate monitoring module on the wearable equipment, monitoring to obtain the external event data;

identifying a power consumption factor based on internal operation data of the wearable device, and extracting the internal power consumption data based on the power consumption factor.

It should be noted that, in this embodiment, when the monitoring data of the wearable device is obtained, the wearable device needs to be awakened first, and then the monitoring is performed based on the operation parameters of the wearable device, specifically, based on the monitoring of the gravity sensor module and the heart rate monitoring module on the wearable device, the external event data is obtained through the corresponding module, then the corresponding gravity sensor module and the heart rate monitoring module are adjusted in a reaction manner, and based on the internal operation data of the wearable device, the power consumption factor is identified, and based on the power consumption factor, the internal power consumption data is extracted, and accordingly, because the wearable device is provided with the core processor, the corresponding power consumption factor can be identified based on the internal operation data of the wearable device, so that the internal power consumption data is extracted based on the power consumption factor.

According to an embodiment of the present invention, the waking up the wearable device, and identifying an operation parameter of the wearable device for monitoring specifically includes:

acquiring a wake-up response value for waking up the wearable device;

identifying an operating parameter of the wearable device based on the wake-up response value, wherein,

if the operation parameter is a preset value, monitoring the external event data and the internal power consumption data;

and if the operation parameter is not the preset value, not monitoring the external event data and the internal power consumption data.

It should be noted that, in the above embodiment, when the monitoring data of the wearable device is obtained, it is required to wake up the wearable device first, because the monitoring is also required to consume energy, so that device wake up is required to be performed first before the monitoring, where in this embodiment, a wake-up response value for waking up the wearable device is obtained, and an operation parameter of the current wearable device is identified based on the wake-up response value, where the operation parameter includes a gravity sensor module and a heart rate monitoring module, and whether the internal operation data of the wearable device can be identified is determined, if the gravity sensor module is available, the corresponding parameter is "1", and similarly the heart rate monitoring module is available, the corresponding parameter is also "1", the internal operation data of the wearable device can be identified, and the corresponding parameter is also "1", that is, the preset value is "111", and specifically, if the operation parameter obtained is the operation parameter is "111" is obtained, the external event data and the internal power consumption data are monitored; if the operation parameter is not the preset value, that is, the obtained operation parameter is not '111', the external event data and the internal power consumption data are not monitored.

According to the embodiment of the invention, if the operation parameter is not the preset value, data analysis is performed based on the operation parameter to identify wake-up failure data, and output is performed based on the wake-up failure data.

It should be noted that, in this embodiment, since the operation parameter is "111", and the operation parameter includes the gravity sensor module and the heart rate monitoring module, and whether the internal operation data of the wearable device can be identified is determined, the order of the corresponding parameters is "the gravity sensor module parameter-the heart rate monitoring module parameter-whether the internal operation data of the wearable device can be identified", so when the operation parameter is not "111", that is, the operation parameter is not the preset value, the data analysis is performed based on the operation parameter, specifically, the annular failure parameter is identified through the sequential analysis, for example, in this embodiment, the operation parameter is "100", which indicates that the heart rate monitoring module is awakened to fail and the internal operation data of the wearable device is identified to fail; if the operation parameter is "001", it indicates that the gravity sensor module wake-up identification and the heart rate monitoring module wake-up fail, and correspondingly, for a scenario with the operation parameter of "100", the output wake-up failure data is that the heart rate monitoring module wake-up fails and the internal operation data of the wearable device is identified as failed, and for a scenario with the operation parameter of "001", the output wake-up failure data is that the gravity sensor module wake-up identification and the heart rate monitoring module wake-up fails.

According to an embodiment of the present invention, the adjusting the gravity sensor module and the heart rate monitoring module based on the external event data specifically includes:

identifying a gravity sensing value based on the gravity sensor module, wherein if the gravity sensing value exceeds a preset sensing value, the heart rate monitoring module is adjusted to be started in real time;

and if the gravity sensing value does not exceed the preset sensing value, periodically starting the heart rate monitoring module based on a heart rate monitoring period.

It should be noted that, in this embodiment, because the gravity sensor module and the heart rate monitoring module consume a great amount of energy to the wearable device, such as a smart watch, the gravity sensor module and the heart rate monitoring module need to be adjusted in real time based on external event data, wherein when the user wears the smart watch, the gravity sensing value is identified based on the gravity sensor module, and when the gravity sensing value exceeds a preset sensing value, the heart rate monitoring module is adjusted in real time, for example, when the user suddenly falls down or falls into a scene, the heart rate monitoring module needs to be started immediately, and if the gravity sensing value does not exceed the preset sensing value, the heart rate monitoring module is started periodically based on a heart rate monitoring period, so as to reduce the number of times of heart rate monitoring to exchange for endurance time.

According to an embodiment of the present invention, the adjusting power amplifier module, the transmitting module and the display module based on the internal power consumption data specifically includes:

identifying the power amplifier module, the transmission module and the power consumption sequencing of the display module based on the internal power consumption data;

and obtaining an adjusting priority based on the power consumption sorting, and carrying out grading opening of each module based on the adjusting priority, wherein the simultaneous opening quantity of the power amplification module, the transmission module and the display module is not more than three.

It should be noted that, in this embodiment, since the number of power amplification modules, transmission modules and display modules turned on simultaneously is not greater than three, that is, the number of modules turned on at the same time is indicated to be two, where the power consumption ranks of the power amplification modules, the transmission modules and the display modules are first identified based on the internal power consumption data, so that when the corresponding modules are turned on, the corresponding adjustment priorities are obtained based on the power consumption ranks, and the power consumption of each module is turned on in a grading manner based on the adjustment priorities, for example, the power consumption of the power amplification module is greater than the power consumption of the transmission module, then the adjustment priorities are corresponding to the priority of the display module being greater than the priority of the transmission module, that is, the power consumption ranks are inversely proportional to the adjustment priorities, when the functions of the three modules (power amplification module, transmission module and display module) are required to be turned on simultaneously, the display module and the transmission module are only turned on correspondingly, and the priority of the display module is highest, and in addition, when the power amplification module is turned on when the operation is stopped in the display module and the transmission module.

It is worth mentioning that the method further comprises:

acquiring an environmental noise value, comparing a preset noise limit value based on the environmental noise value, wherein,

if the environmental noise value is larger than the noise limit value, adjusting the voice content based on the power amplification module to be a display text;

and displaying the display text based on the display module.

In the above embodiment, the power consumption of the power amplification module is greater than that of the display module, so in this embodiment, when the environmental noise value is greater than the noise limit value, the user needs to turn up the volume to listen to the voice content of the power amplification module, and the environmental noise is mixed with the voice content to interfere and increase the power consumption, so that the environmental noise value is compared with the noise limit value, when the environmental noise value is greater than the noise limit value, the voice content based on the power amplification module is adjusted to be a display text, and the display text is displayed by using the display module, so that the power consumption loss of the power amplification module is reduced, and the display module is used for displaying the corresponding text content to replace the text content.

It is worth mentioning that the method further comprises:

screening the induction period of the gravity sensor module based on the working sleep time; wherein,

when the operation time of the wearable equipment is recognized to be within the working time, the induction period of the gravity sensor module is adjusted to be a first period;

and when the operation time of the wearable equipment is identified to be in the sleep time, adjusting the induction period of the gravity sensor module to be a second period, wherein the induction duration of the second period is shorter than that of the first period.

It should be noted that, in this embodiment, the demand of the user for the gravity sensor is different during the working period and the sleeping period when the user wears the wearable device, so that the sensing period of the gravity sensor module of the wearable device needs to be adjusted according to the working time and the sleeping time, wherein when the running time of the wearable device is recognized to be within the working time, the sensing period of the gravity sensor module is adjusted to be a first period, for example, the working time is "09:00-12:00" point and "14:00-18:00" point, during which the user is in the working time, and accordingly, the working time can be set according to the user himself, the first period in the period is "50min standby, 10min sleep", specifically, each standby "5min" is sleep "1min"; and for recognizing that the running time of the wearable device is within the sleep time, adjusting the sensing period of the gravity sensor module to be a second period, for example, the sleep time is "21:00-next day 07:00", wherein the user is in sleep time during the period, and accordingly, the sleep time can also be set according to the user, the second period in the period is" 30min standby and 30min sleep ", specifically," 1min sleep "is performed every standby" 1min ", wherein the sensing duration of the second period is shorter than the sensing duration of the first period, specifically," 50min "is performed during the sensing duration of the first period, and" 30min "is performed during the sensing duration of the second period.

Fig. 2 shows a block diagram of a wearable device adaptive power consumption regulation system of the present invention.

As shown in fig. 2, the invention discloses a self-adaptive power consumption adjusting system of a wearable device, which comprises a memory and a processor, wherein the memory comprises a self-adaptive power consumption adjusting method program of the wearable device, and the self-adaptive power consumption adjusting method program of the wearable device realizes the following steps when being executed by the processor:

acquiring monitoring data of a wearable device, wherein the monitoring data comprises external event data and internal power consumption data;

adjusting the constituent modules of the wearable device in real time based on the monitoring data, wherein,

adjusting a gravity sensor module and a heart rate monitoring module in the composition module based on the external event data; and

and adjusting a power amplification module, a transmission module and a display module in the composition module based on the internal power consumption data.

It should be noted that, in this embodiment, when a user wears the wearable device, based on the wearable device, corresponding monitoring data may be obtained, and accordingly, the monitoring data includes the external event data and the internal power consumption data, so that real-time adjustment may be performed on constituent modules of the wearable device based on the monitoring data, where the constituent modules include a gravity sensor module, a heart rate monitoring module, a power amplifier module, a transmission module and a display module, specifically, based on the external event data, the gravity sensor module and the heart rate monitoring module in the constituent modules are adjusted, and based on the internal power consumption data, the power amplifier module, the transmission module and the display module in the constituent modules are adjusted, so as to ensure high-performance operation of the wearable device, and make a real-time adjustment scheme for the high-power consumption modules while the user operates smoothly, so as to improve the endurance time of the wearable device.

According to an embodiment of the present invention, the acquiring monitoring data of the wearable device specifically includes:

waking up the wearable device, identifying an operating parameter of the wearable device for monitoring, wherein,

based on the gravity sensor module and the heart rate monitoring module on the wearable equipment, monitoring to obtain the external event data;

identifying a power consumption factor based on internal operation data of the wearable device, and extracting the internal power consumption data based on the power consumption factor.

It should be noted that, in this embodiment, when the monitoring data of the wearable device is obtained, the wearable device needs to be awakened first, and then the monitoring is performed based on the operation parameters of the wearable device, specifically, based on the monitoring of the gravity sensor module and the heart rate monitoring module on the wearable device, the external event data is obtained through the corresponding module, then the corresponding gravity sensor module and the heart rate monitoring module are adjusted in a reaction manner, and based on the internal operation data of the wearable device, the power consumption factor is identified, and based on the power consumption factor, the internal power consumption data is extracted, and accordingly, because the wearable device is provided with the core processor, the corresponding power consumption factor can be identified based on the internal operation data of the wearable device, so that the internal power consumption data is extracted based on the power consumption factor.

According to an embodiment of the present invention, the waking up the wearable device, and identifying an operation parameter of the wearable device for monitoring specifically includes:

acquiring a wake-up response value for waking up the wearable device;

identifying an operating parameter of the wearable device based on the wake-up response value, wherein,

if the operation parameter is a preset value, monitoring the external event data and the internal power consumption data;

and if the operation parameter is not the preset value, not monitoring the external event data and the internal power consumption data.

It should be noted that, in the above embodiment, when the monitoring data of the wearable device is obtained, it is required to wake up the wearable device first, because the monitoring is also required to consume energy, so that device wake up is required to be performed first before the monitoring, where in this embodiment, a wake-up response value for waking up the wearable device is obtained, and an operation parameter of the current wearable device is identified based on the wake-up response value, where the operation parameter includes a gravity sensor module and a heart rate monitoring module, and whether the internal operation data of the wearable device can be identified is determined, if the gravity sensor module is available, the corresponding parameter is "1", and similarly the heart rate monitoring module is available, the corresponding parameter is also "1", the internal operation data of the wearable device can be identified, and the corresponding parameter is also "1", that is, the preset value is "111", and specifically, if the operation parameter obtained is the operation parameter is "111" is obtained, the external event data and the internal power consumption data are monitored; if the operation parameter is not the preset value, that is, the obtained operation parameter is not '111', the external event data and the internal power consumption data are not monitored.

According to the embodiment of the invention, if the operation parameter is not the preset value, data analysis is performed based on the operation parameter to identify wake-up failure data, and output is performed based on the wake-up failure data.

It should be noted that, in this embodiment, since the operation parameter is "111", and the operation parameter includes the gravity sensor module and the heart rate monitoring module, and whether the internal operation data of the wearable device can be identified is determined, the order of the corresponding parameters is "the gravity sensor module parameter-the heart rate monitoring module parameter-whether the internal operation data of the wearable device can be identified", so when the operation parameter is not "111", that is, the operation parameter is not the preset value, the data analysis is performed based on the operation parameter, specifically, the annular failure parameter is identified through the sequential analysis, for example, in this embodiment, the operation parameter is "100", which indicates that the heart rate monitoring module is awakened to fail and the internal operation data of the wearable device is identified to fail; if the operation parameter is "001", it indicates that the gravity sensor module wake-up identification and the heart rate monitoring module wake-up fail, and correspondingly, for a scenario with the operation parameter of "100", the output wake-up failure data is that the heart rate monitoring module wake-up fails and the internal operation data of the wearable device is identified as failed, and for a scenario with the operation parameter of "001", the output wake-up failure data is that the gravity sensor module wake-up identification and the heart rate monitoring module wake-up fails.

According to an embodiment of the present invention, the adjusting the gravity sensor module and the heart rate monitoring module based on the external event data specifically includes:

identifying a gravity sensing value based on the gravity sensor module, wherein if the gravity sensing value exceeds a preset sensing value, the heart rate monitoring module is adjusted to be started in real time;

and if the gravity sensing value does not exceed the preset sensing value, periodically starting the heart rate monitoring module based on a heart rate monitoring period.

It should be noted that, in this embodiment, because the gravity sensor module and the heart rate monitoring module consume a great amount of energy to the wearable device, such as a smart watch, the gravity sensor module and the heart rate monitoring module need to be adjusted in real time based on external event data, wherein when the user wears the smart watch, the gravity sensing value is identified based on the gravity sensor module, and when the gravity sensing value exceeds a preset sensing value, the heart rate monitoring module is adjusted in real time, for example, when the user suddenly falls down or falls into a scene, the heart rate monitoring module needs to be started immediately, and if the gravity sensing value does not exceed the preset sensing value, the heart rate monitoring module is started periodically based on a heart rate monitoring period, so as to reduce the number of times of heart rate monitoring to exchange for endurance time.

According to an embodiment of the present invention, the adjusting power amplifier module, the transmitting module and the display module based on the internal power consumption data specifically includes:

identifying the power amplifier module, the transmission module and the power consumption sequencing of the display module based on the internal power consumption data;

and obtaining an adjusting priority based on the power consumption sorting, and carrying out grading opening of each module based on the adjusting priority, wherein the simultaneous opening quantity of the power amplification module, the transmission module and the display module is not more than three.

It should be noted that, in this embodiment, since the number of power amplification modules, transmission modules and display modules turned on simultaneously is not greater than three, that is, the number of modules turned on at the same time is indicated to be two, where the power consumption ranks of the power amplification modules, the transmission modules and the display modules are first identified based on the internal power consumption data, so that when the corresponding modules are turned on, the corresponding adjustment priorities are obtained based on the power consumption ranks, and the power consumption of each module is turned on in a grading manner based on the adjustment priorities, for example, the power consumption of the power amplification module is greater than the power consumption of the transmission module, then the adjustment priorities are corresponding to the priority of the display module being greater than the priority of the transmission module, that is, the power consumption ranks are inversely proportional to the adjustment priorities, when the functions of the three modules (power amplification module, transmission module and display module) are required to be turned on simultaneously, the display module and the transmission module are only turned on correspondingly, and the priority of the display module is highest, and in addition, when the power amplification module is turned on when the operation is stopped in the display module and the transmission module.

It is worth mentioning that the method further comprises:

acquiring an environmental noise value, comparing a preset noise limit value based on the environmental noise value, wherein,

if the environmental noise value is larger than the noise limit value, adjusting the voice content based on the power amplification module to be a display text;

and displaying the display text based on the display module.

In the above embodiment, the power consumption of the power amplification module is greater than that of the display module, so in this embodiment, when the environmental noise value is greater than the noise limit value, the user needs to turn up the volume to listen to the voice content of the power amplification module, and the environmental noise is mixed with the voice content to interfere and increase the power consumption, so that the environmental noise value is compared with the noise limit value, when the environmental noise value is greater than the noise limit value, the voice content based on the power amplification module is adjusted to be a display text, and the display text is displayed by using the display module, so that the power consumption loss of the power amplification module is reduced, and the display module is used for displaying the corresponding text content to replace the text content.

It is worth mentioning that the method further comprises:

screening the induction period of the gravity sensor module based on the working sleep time; wherein,

when the operation time of the wearable equipment is recognized to be within the working time, the induction period of the gravity sensor module is adjusted to be a first period;

and when the operation time of the wearable equipment is identified to be in the sleep time, adjusting the induction period of the gravity sensor module to be a second period, wherein the induction duration of the second period is shorter than that of the first period.

It should be noted that, in this embodiment, the demand of the user for the gravity sensor is different during the working period and the sleeping period when the user wears the wearable device, so that the sensing period of the gravity sensor module of the wearable device needs to be adjusted according to the working time and the sleeping time, wherein when the running time of the wearable device is recognized to be within the working time, the sensing period of the gravity sensor module is adjusted to be a first period, for example, the working time is "09:00-12:00" point and "14:00-18:00" point, during which the user is in the working time, and accordingly, the working time can be set according to the user himself, the first period in the period is "50min standby, 10min sleep", specifically, each standby "5min" is sleep "1min"; and for recognizing that the running time of the wearable device is within the sleep time, adjusting the sensing period of the gravity sensor module to be a second period, for example, the sleep time is "21:00-next day 07:00", wherein the user is in sleep time during the period, and accordingly, the sleep time can also be set according to the user, the second period in the period is" 30min standby and 30min sleep ", specifically," 1min sleep "is performed every standby" 1min ", wherein the sensing duration of the second period is shorter than the sensing duration of the first period, specifically," 50min "is performed during the sensing duration of the first period, and" 30min "is performed during the sensing duration of the second period.

A third aspect of the present invention provides a computer readable storage medium, including a wearable device adaptive power consumption adjustment method program, where the wearable device adaptive power consumption adjustment method program, when executed by a processor, implements the steps of a wearable device adaptive power consumption adjustment method according to any one of the above.

According to the self-adaptive power consumption adjusting method, system and readable storage medium for the wearable equipment, high-performance operation of the wearable equipment can be guaranteed, a user can smoothly operate and experience, and meanwhile, a real-time adjusting scheme is made for high-power consumption modules of the system, so that optimal solution of power consumption is achieved, and the endurance time of the wearable equipment is prolonged.

In the several embodiments provided in this application, it should be understood that the disclosed apparatus and method may be implemented in other ways. The above described device embodiments are only illustrative, e.g. the division of the units is only one logical function division, and there may be other divisions in practice, such as: multiple units or components may be combined or may be integrated into another system, or some features may be omitted, or not performed. In addition, the various components shown or discussed may be coupled or directly coupled or communicatively coupled to each other via some interface, whether indirectly coupled or communicatively coupled to devices or units, whether electrically, mechanically, or otherwise.

The units described above as separate components may or may not be physically separate, and components shown as units may or may not be physical units; can be located in one place or distributed to a plurality of network units; some or all of the units may be selected according to actual needs to achieve the purpose of the solution of this embodiment.

In addition, each functional unit in each embodiment of the present invention may be integrated in one processing unit, or each unit may be separately used as one unit, or two or more units may be integrated in one unit; the integrated units may be implemented in hardware or in hardware plus software functional units.

Those of ordinary skill in the art will appreciate that: all or part of the steps for implementing the above method embodiments may be implemented by hardware related to program instructions, and the foregoing program may be stored in a computer readable storage medium, where the program, when executed, performs steps including the above method embodiments; and the aforementioned storage medium includes: a mobile storage device, a Read-Only Memory (ROM), a random access Memory (RAM, random Access Memory), a magnetic disk or an optical disk, or the like, which can store program codes.

Alternatively, the above-described integrated units of the present invention may be stored in a computer-readable storage medium if implemented in the form of software functional modules and sold or used as separate products. Based on such understanding, the technical solutions of the embodiments of the present invention may be embodied in essence or a part contributing to the prior art in the form of a software product stored in a storage medium, including several instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to execute all or part of the methods described in the embodiments of the present invention. And the aforementioned storage medium includes: a removable storage device, ROM, RAM, magnetic or optical disk, or other medium capable of storing program code.

Claims (5)

1. The self-adaptive power consumption adjusting method for the wearable device is characterized by comprising the following steps of:

acquiring monitoring data of a wearable device, wherein the monitoring data comprises external event data and internal power consumption data;

adjusting the constituent modules of the wearable device in real time based on the monitoring data, wherein,

adjusting a gravity sensor module and a heart rate monitoring module in the composition module based on the external event data;

adjusting a power amplifier module, a transmission module and a display module in the composition module based on the internal power consumption data;

the acquiring the monitoring data of the wearable device specifically comprises the following steps:

waking up the wearable device, identifying an operating parameter of the wearable device for monitoring, wherein,

based on the gravity sensor module and the heart rate monitoring module on the wearable equipment, monitoring to obtain the external event data;

identifying a power consumption factor based on internal operation data of the wearable device, and extracting the internal power consumption data based on the power consumption factor;

the waking up the wearable device, identifying an operation parameter of the wearable device for monitoring, specifically includes:

acquiring a wake-up response value for waking up the wearable device;

identifying an operating parameter of the wearable device based on the wake-up response value, wherein,

if the operation parameter is a preset value, monitoring the external event data and the internal power consumption data;

if the operation parameter is not the preset value, not monitoring the external event data and the internal power consumption data;

if the operation parameter is not the preset value, carrying out data analysis based on the operation parameter to identify wake-up failure data, and outputting based on the wake-up failure data;

the method further comprises the steps of:

acquiring an environmental noise value, comparing a preset noise limit value based on the environmental noise value, wherein,

if the environmental noise value is larger than the noise limit value, adjusting the voice content based on the power amplification module to be a display text;

and displaying the display text based on the display module.

2. The method for adjusting adaptive power consumption of a wearable device according to claim 1, wherein the adjusting the gravity sensor module and the heart rate monitoring module based on the external event data specifically comprises:

identifying a gravity sensing value based on the gravity sensor module, wherein if the gravity sensing value exceeds a preset sensing value, the heart rate monitoring module is adjusted to be started in real time;

and if the gravity sensing value does not exceed the preset sensing value, periodically starting the heart rate monitoring module based on a heart rate monitoring period.

3. The method for adjusting adaptive power consumption of a wearable device according to claim 1, wherein the adjusting the power amplifier module, the transmission module and the display module based on the internal power consumption data specifically comprises:

identifying the power amplifier module, the transmission module and the power consumption sequencing of the display module based on the internal power consumption data;

and obtaining an adjusting priority based on the power consumption sorting, and carrying out grading opening of each module based on the adjusting priority, wherein the simultaneous opening quantity of the power amplification module, the transmission module and the display module is not more than three.

4. The self-adaptive power consumption adjusting system of the wearable device is characterized by comprising a memory and a processor, wherein the memory comprises a self-adaptive power consumption adjusting method program of the wearable device, and the self-adaptive power consumption adjusting method program of the wearable device realizes the following steps when being executed by the processor:

acquiring monitoring data of a wearable device, wherein the monitoring data comprises external event data and internal power consumption data;

adjusting the constituent modules of the wearable device in real time based on the monitoring data, wherein,

adjusting a gravity sensor module and a heart rate monitoring module in the composition module based on the external event data;

adjusting a power amplifier module, a transmission module and a display module in the composition module based on the internal power consumption data;

the acquiring the monitoring data of the wearable device specifically comprises the following steps:

waking up the wearable device, identifying an operating parameter of the wearable device for monitoring, wherein,

based on the gravity sensor module and the heart rate monitoring module on the wearable equipment, monitoring to obtain the external event data;

identifying a power consumption factor based on internal operation data of the wearable device, and extracting the internal power consumption data based on the power consumption factor;

the waking up the wearable device, identifying an operation parameter of the wearable device for monitoring, specifically includes:

acquiring a wake-up response value for waking up the wearable device;

identifying an operating parameter of the wearable device based on the wake-up response value, wherein,

if the operation parameter is a preset value, monitoring the external event data and the internal power consumption data;

if the operation parameter is not the preset value, not monitoring the external event data and the internal power consumption data;

if the operation parameter is not the preset value, carrying out data analysis based on the operation parameter to identify wake-up failure data, and outputting based on the wake-up failure data;

the method further comprises the steps of:

acquiring an environmental noise value, comparing a preset noise limit value based on the environmental noise value, wherein,

if the environmental noise value is larger than the noise limit value, adjusting the voice content based on the power amplification module to be a display text;

and displaying the display text based on the display module.

5. A computer readable storage medium, characterized in that the computer readable storage medium comprises a wearable device adaptive power consumption adjusting method program, and the wearable device adaptive power consumption adjusting method program is executed by a processor to implement the steps of a wearable device adaptive power consumption adjusting method according to any one of claims 1 to 3.