CN113706847B - Data processing method and device, storage medium and wearable device - Google Patents

Abstract

The invention discloses a data sending method, a data sending device, a storage medium and wearable equipment, wherein the data sending method comprises the following steps: detecting the data occupancy rate of the storage space; sending the data at least when the data occupancy rate of the storage space exceeds a first preset threshold; and after the data transmission is finished, emptying the storage space. The method ensures that the data cannot overflow and be lost, thereby improving the accuracy of the transmitted data, avoiding unnecessary power consumption caused by frequent transmission, saving energy and further prolonging the standby time of the equipment.

Description

Data processing method and device, storage medium and wearable device

Technical Field

The invention relates to the field of data transmission, in particular to a data processing method and device, a storage medium and wearable equipment.

Background

With the development and fusion of 5G technology and IoT technology, it is no longer a long-distance dream to achieve internet of everything. Among them, the smart wearable device, as an input interface of IoT, is beginning to play an increasingly important role in the fields of data acquisition, calculation, and data and even voice communication. However, wearable devices are low power consumption products themselves, which are very sensitive to the standby time of the device. The use of NB-IoT, eSIM, and even SIM in wearable devices can pose a significant challenge to the standby time of the device, and even more, these techniques can interfere with the device data acquisition quality and data communication quality when the device is started, and further, can have a significant negative impact on the data computation accuracy of the device and the user experience when the device is used. For example, when the device starts NB-IoT to transmit the acquired data to the cloud, the working current of the device may increase instantaneously, which may further lower the working voltage of the device, and in addition, the strong radio frequency interference of the NB itself may degrade the physiological data being acquired by the device, such as PPG data.

Unfortunately, most of the existing devices adopting NB-IoT transmission technology consider the limitation of storage space, and at present, the most common way is to start data transmission at regular intervals, such as an hour, transmit the stored data to the corresponding cloud for storage, and then clear the memory of the device for the subsequent storage of new data.

The method may cause that data transmission is not timely performed, so that the data volume exceeds the upper limit of the storage space, data storage overflow is caused and loss is caused, and frequent data transmission may also be performed under the condition of less data storage volume, so that the power consumption of the device is improved.

Disclosure of Invention

Objects of the invention

The invention aims to provide a data processing method, a data processing device, a storage medium and wearable equipment to solve the problem of power consumption improvement caused by data storage overflow loss and frequent data transmission.

(II) technical scheme

To solve the above problem, a first aspect of the present invention provides a data processing method, including: detecting the data occupancy rate of the storage space; sending the data at least when the data occupancy rate of the storage space exceeds a first preset threshold value; and after the data transmission is finished, emptying the storage space.

The first preset threshold further includes: detecting motion information of a user; when the data occupancy rate of the storage space at least based on the storage space exceeds a first preset threshold, the sending the data further comprises: and when the user is in a motion state and the data occupancy rate of the storage space exceeds a second preset threshold value, sending the data, wherein the second preset threshold value is smaller than the first preset threshold value.

Further, the sending the data at least based on the storage space data occupancy rate exceeding a first preset threshold further comprises: and when the user is in a static state and the data occupancy rate of the storage space exceeds a third preset threshold value, sending the data, wherein the third preset threshold value is smaller than the second preset threshold value.

Further, the method also comprises the following steps: when the physiological data of the user is not acquired or the charging state data is acquired, stopping physiological data acquisition and physiological parameter calculation; when the occupancy rate of the data based on at least the storage space exceeds a first preset threshold, the sending the data comprises: and when the data occupancy rate of the storage space exceeds a third preset threshold value, sending the data.

Further, the sending the data based on at least the storage space data occupancy exceeding a first preset threshold further comprises: and when the abnormal physiological parameters of the user are acquired, the data are immediately sent.

Further, one of the following is also included: reducing the confidence of the acquired physiological data when the data is transmitted; suspending the calculation of the physiological parameter while transmitting the data; or suspend physiological data acquisition while transmitting the data.

According to another aspect of the present invention, there is provided a data processing apparatus comprising: the memory detection module is used for detecting the data occupancy rate of the storage space; the comparison module is used for comparing the data occupancy rate of the storage space with a first preset threshold value; a sending module, configured to send the data; when the comparison result of the comparison module is that the data occupancy rate of the storage space is greater than the preset threshold value, the sending module sends the data; and the memory cleaning module is used for emptying the storage space after the data transmission is finished.

Further, the method also comprises the following steps: the motion state detection module is used for detecting motion information of a user; the comparison module is also used for comparing the data occupancy rate of the storage space with a second preset threshold value; when the motion state detection module detects that the user is in a motion state and the comparison module compares that the data occupancy rate of the storage space exceeds a second preset threshold value, the sending module sends the data, wherein the second preset threshold value is smaller than the first preset threshold value.

Further, the comparing module is further configured to send the data by the sending module when the occupancy rate of the storage space data exceeds a third preset threshold value, the motion state detecting module detects that the user is in a stationary state, and the comparing module compares that the occupancy rate of the storage space data exceeds the third preset threshold value, where the third preset threshold value is smaller than the second preset threshold value.

Further, still include: the physiological data acquisition module is used for acquiring the physiological data of the user and/or the charging state acquisition module is used for acquiring the charging state data of the device; stopping physiological data acquisition and physiological parameter calculation when the physiological data acquisition module does not acquire the user physiological data or the charging state acquisition module acquires data in a charging state; and when the comparison module compares that the data occupancy rate of the storage space exceeds a third preset threshold value, the sending module sends the data.

Further, still include: the physiological parameter acquisition module is used for acquiring the physiological parameters of the user; and when the physiological parameter acquisition module acquires abnormal physiological parameters of the user, the sending module immediately sends the data.

Further, one of the following is also included:

the confidence coefficient adjusting module is used for reducing the confidence coefficient of the acquired physiological data;

the physiological parameter calculation module is used for suspending the calculation of the physiological parameters of the user;

and the physiological parameter acquisition stopping module is used for suspending acquisition of the physiological parameters of the user.

According to a further aspect of the present invention there is provided a storage medium having a program stored thereon, which when executed by a processor implements the steps of the method of any one of the above aspects.

According to yet another aspect of the present invention, there is provided a wearable device comprising a memory, a display, a processor and a program stored on the memory and executable on the processor, the processor implementing the steps of the method of any of the above aspects when executing the program.

(III) advantageous effects

The technical scheme of the invention has the following beneficial technical effects:

the data is guaranteed not to overflow and lose, so that the accuracy of transmitted data is improved, unnecessary power consumption caused by frequent transmission is avoided, energy is saved, and the standby time of the equipment is prolonged.

Drawings

FIG. 1 is a flow chart of a data processing method according to a first embodiment of the present invention;

FIG. 2 is a schematic diagram of data storage space management according to an alternative embodiment of the present invention;

fig. 3 is a diagram of adaptive data transmission logic in accordance with an alternative embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail with reference to the accompanying drawings in combination with the embodiments. It should be understood that the description is intended to be exemplary only, and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

It is to be understood that the embodiments described are only a few embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In addition, the technical features involved in the different embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other.

As shown in fig. 1, in a first aspect of the embodiments of the present invention, there is provided a data processing method, including:

s1: detecting the data occupancy rate of the storage space;

s2: sending data at least when the data occupancy rate of the storage space exceeds a first preset threshold value;

s3: and after the data transmission is finished, emptying the storage space.

Before starting data transmission, the data occupancy rate of the storage space is checked, if the stored data is found to exceed the set storage capacity, the data transmission unit is directly started, the data is transmitted to the cloud so as to clear the memory of the equipment in time, and the data loss caused by overflow of the acquired data is prevented.

Optionally, when at least the occupancy rate of the storage space data exceeds the first preset threshold, the sending data includes: and when the data occupancy rate of the storage space exceeds a first preset threshold value, sending data.

Optionally, the method further includes: detecting motion information of a user; when the occupancy rate of the storage space data exceeds a first preset threshold, the data transmission further includes: and when the user is in a motion state and the data occupancy rate of the storage space exceeds a second preset threshold value, sending data, wherein the second preset threshold value is smaller than the preset threshold value.

Optionally, when at least based on the storage space data occupancy rate exceeding the first preset threshold, sending the data further includes: and when the user is in a static state and the data occupancy rate of the storage space exceeds a third preset threshold value, sending data, wherein the third preset threshold value is smaller than a second preset threshold value.

The above embodiments take into account that the physiological parameter changes more dramatically during exercise than during rest, such as the heart rate, which generally changes more during exercise, and is more stable during rest. In the case of detecting that the human body is quiet, the stored data is transmitted with priority, and the data lost during data transmission can be estimated by using the previous data; in the case of sports, the request to initiate data transmission is made only when the data store reaches the alert threshold, while in the case of quiet, the system may initiate a request to initiate data transmission when the data store reaches the safe threshold. Generally, the alarm threshold value is higher than the safety threshold value, and the main consideration of the setting is that in the motion state, data needs to be acquired as much as possible to obtain the physiological parameters as complete as possible, and under the condition that the physiological parameters are not available, the acquisition of the physiological data is not interrupted.

Optionally, the method further includes: stopping physiological data acquisition and physiological parameter calculation when the physiological data of the user or the charging state data are not acquired; when the data occupancy rate of the storage space exceeds a first preset threshold value, the data sending comprises: and when the data occupancy rate of the storage space exceeds a third preset threshold value, sending the data.

The above embodiment is that when the device is detected to be unworn or poorly worn or in a charged state, the device also needs to transmit all stored data in time to empty the data space, at which time the device stops physiological data acquisition and calculation.

Optionally, when at least based on the storage space data occupancy rate exceeding the first preset threshold, sending the data further includes: and when the abnormal physiological parameters of the user are acquired, the data are immediately sent.

In the embodiment, in an emergency situation, if the algorithm detects an abnormal physiological condition, if an arrhythmia occurs, the device immediately starts to transmit data to the cloud end, so that the physiological monitoring server can know the abnormal condition at the first time.

Optionally, one of the following is also included: when data is sent, the confidence coefficient of the acquired physiological data is reduced; suspending the calculation of the physiological parameter while transmitting the data; or suspend physiological data acquisition while transmitting data.

Because the data transmission mechanism of the current NB-IoT in the practical application process only needs to start transmission when data exists in the memory space of the device, even if only a small amount of data reaches the data transmission time window, the NB emission current is large, which results in the improvement of the power consumption of the device; when an equipment system starts NB emission, the system current can be increased in a doubling manner instantly, so that the power supply is unstable during sensor data acquisition, and signals of the sensor are interfered; in addition, during NB data transmission, the electromagnetic waves of the NB antennas may also cause irreversible interference to the data being collected by the device sensors. Both types of interference will cause the data collected during the time when the NB transmission is initiated to be directly bad data. The scheme is as follows: when data is sent, the confidence coefficient of the collected data is reduced; or suspending the calculation of the physiological parameter while transmitting the data; or suspend data collection while data is being transmitted. Under the condition of ensuring that data is not overflowed and lost, the interference of data transmission on physiological data acquisition and physiological parameter calculation is avoided as much as possible, the power consumption of the equipment can be obviously reduced, the standby time is prolonged, more importantly, the accuracy of the physiological data acquisition and calculation of the equipment is ensured, and the reliability of the calculation of the equipment is improved.

In another aspect of the embodiments of the present invention, there is provided a data processing apparatus including: the memory detection module is used for detecting the data occupancy rate of the storage space; the comparison module is used for comparing the occupancy rate of the storage space data with a first preset threshold; the sending module is used for sending data; when the comparison result of the comparison module is that the data occupancy rate of the storage space is greater than a preset threshold value, the sending module sends data; and the memory cleaning module is used for emptying the storage space after the data transmission is finished.

Before the sending module starts data transmission, the comparison module counts the data occupancy rate of the storage space of the device, if the stored data is found to exceed the set storage capacity, the data transmission module is directly started to transmit the data to the cloud so as to clear the memory of the equipment in time, and the data loss caused by the overflow of the collected data is prevented.

Optionally, the comparing module is further configured to compare the occupancy rate of the storage space data with a first preset threshold; when the data occupancy rate of the storage space exceeds a first preset threshold value, the sending module sends data.

Optionally, the method further includes: the motion state detection module is used for detecting motion information of a user; the comparison module is also used for comparing the occupancy rate of the storage space data with a second preset threshold value; when the motion state detection module detects that the user is in a motion state and the comparison module compares that the data occupancy rate of the storage space exceeds a second preset threshold value, the sending module sends data, and the second preset threshold value is smaller than the preset threshold value.

Optionally, the comparison module is further configured to send the data by the sending module when the occupancy rate of the storage space data exceeds a third preset threshold, the motion state detection module detects that the user is in a stationary state, and the comparison module compares that the occupancy rate of the storage space data exceeds the third preset threshold, where the third preset threshold is smaller than the second preset threshold.

Optionally, in the apparatus, the first preset threshold corresponds to a maximum value of the storage space, the second preset threshold corresponds to an alert threshold, and the third preset threshold corresponds to a safety threshold, as shown in fig. 2.

Considering that the physiological parameters of a human body can change more dramatically in an exercise state than in a resting state, such as a heart rate, the heart rate generally changes greatly in the exercise state, and is more stable in the resting state. The device will give priority to transmitting the stored data when detecting that the human body is quiet, and the data lost during data transmission can be estimated by using earlier data; in the case of motion, the request to initiate data transmission is made only when the data store reaches the alert threshold, while in the case of silence, the system may initiate a request to initiate data transmission when the data store reaches the safe threshold.

Optionally, the method further includes: the physiological data acquisition module is used for acquiring physiological data of a user and/or the charging state acquisition module is used for acquiring charging state data of the device; stopping physiological data acquisition and physiological parameter calculation when the physiological data acquisition module does not acquire the physiological data of the user or the charging state acquisition module acquires the data in the charging state; and when the comparison module compares that the data occupancy rate of the storage space exceeds a third preset threshold value, the sending module sends the data. When the device is detected to be in an unworn or charged state, the device also needs to transmit all stored data in time so as to empty the data space, and at the moment, the device stops physiological data acquisition and calculation.

Optionally, the method further includes: the physiological parameter acquisition module is used for acquiring physiological parameters of a user; when the physiological parameter acquisition module acquires abnormal physiological parameters of the user, the sending module immediately sends data. In an emergency situation, if an abnormal physiological condition is detected, if arrhythmia occurs, the device immediately starts to transmit data to the cloud so that the physiological monitoring server can know the abnormal condition at the first time.

Optionally, one of the following is also included:

the confidence coefficient adjusting module is used for reducing the confidence coefficient of the acquired physiological data;

the physiological parameter calculation module is used for suspending the calculation of the physiological parameters of the user;

and the physiological parameter acquisition stopping module is used for suspending acquisition of the physiological parameters of the user.

The device may adjust the confidence level or suspend data acquisition and calculation during data transmission so that the algorithm reduces the confidence level of the acquired data during the time period (data being transmitted), suspends the calculation of the physiological parameter, or directly notifies the physiological data acquisition sensor to suspend data acquisition until the data transmission is completed, and then restarts the acquisition of the physiological data and the calculation of the physiological parameter.

As shown in fig. 3, in an alternative embodiment, providing an adaptive data transmission strategy includes:

the data transmission control unit checks the data occupancy rate of the storage space of the equipment before starting data transmission, and if the stored data is found to exceed the set storage capacity, the data transmission control unit directly starts the data transmission unit to transmit the data to the cloud so as to clear the memory of the equipment in time and prevent the data loss caused by overflow of the acquired data;

during data transmission, the data processing and calculating unit can be informed so that the algorithm reduces the confidence of the acquired data in the period (data is being transmitted), or the calculation of the physiological parameter is suspended, or the physiological data acquisition sensor is directly informed to suspend the data acquisition until the data transmission is finished, and then the acquisition of the physiological data and the calculation of the physiological parameter are restarted;

considering that the physiological parameters of a human body can change more dramatically in an exercise state than in a resting state, such as a heart rate, the heart rate generally changes greatly in the exercise state, and is more stable in the resting state. The device will give priority to transmitting the stored data when detecting that the human body is quiet, and the data lost during data transmission can be estimated by using earlier data; in the case of motion, the request to initiate data transmission is made only when the data store reaches the warning line, while in the case of silence, the system can initiate a request for data transmission when the data store reaches the safety line;

in an emergency situation, if the algorithm detects that an abnormal physiological condition occurs, if arrhythmia occurs, the equipment immediately starts to transmit data to the cloud so that the physiological monitoring server can know the abnormal condition at the first time;

when the device status detects that the device is not worn or charged, the device also transmits all stored data in time to empty the data space, at which time the device stops physiological data acquisition and calculation.

In a further aspect of the embodiments of the present invention, there is provided a storage medium having a program stored thereon, the program implementing the steps of any one of the above-described embodiments when executed by a processor.

In a further aspect of the embodiments of the present invention, there is provided a wearable device, including a memory, a display, a processor, and a program stored on the memory and executable on the processor, the processor implementing the steps of any one of the above-described embodiments when executing the program.

The invention aims to protect a data sending method, which comprises the following steps: detecting the data occupancy rate of the storage space; sending data at least when the data occupancy rate of the storage space exceeds a first preset threshold; and after the data transmission is finished, emptying the storage space. The method ensures that the data is not overflowed and lost, thereby improving the accuracy of the transmitted data, avoiding unnecessary power consumption caused by frequent transmission, saving energy and further prolonging the standby time of the equipment.

It should be understood that the above-described embodiments of the present invention are merely illustrative of or explaining the principles of the invention and are not to be construed as limiting the invention. Therefore, any modification, equivalent replacement, improvement and the like made without departing from the spirit and scope of the present invention should be included in the protection scope of the present invention. Further, it is intended that the appended claims cover all such variations and modifications as fall within the scope and boundary of the appended claims, or the equivalents of such scope and boundary.

Claims (10)

1. A data processing method, comprising:

detecting the data occupancy rate of the storage space;

detecting motion information of a user;

sending the data at least when the data occupancy rate of the storage space exceeds a first preset threshold;

after the data is sent, emptying the storage space;

when the data occupancy rate of the storage space at least based on the storage space exceeds a first preset threshold, the sending the data further comprises:

when the user is in a motion state and the data occupancy rate of the storage space exceeds a second preset threshold value, sending the data, wherein the second preset threshold value is smaller than the first preset threshold value;

and when the user is in a static state and the data occupancy rate of the storage space exceeds a third preset threshold value, sending the data, wherein the third preset threshold value is smaller than the second preset threshold value.

2. The method of claim 1, further comprising:

and when the physiological data of the user or the charging state data are not acquired, stopping the physiological data acquisition and the calculation of the physiological parameters, and immediately transmitting the data.

3. The method of claim 1, wherein said transmitting the data based at least on the storage space data occupancy exceeding a first preset threshold further comprises:

and when the abnormal physiological parameters of the user are acquired, the data are immediately sent.

4. The method of any one of claims 1-3, further comprising one of:

reducing confidence of the collected physiological data when the data is sent;

suspending the calculation of the physiological parameter while transmitting the data; or

Suspending physiological data acquisition while transmitting the data.

5. A data processing apparatus, characterized by comprising:

the memory detection module is used for detecting the data occupancy rate of the storage space;

the motion state detection module is used for detecting motion information of a user;

the comparison module is used for comparing the data occupancy rate of the storage space with a first preset threshold value;

the sending module is used for sending the data when the data occupancy rate of the storage space is larger than the first preset threshold value at least based on the comparison result of the comparison module;

the memory cleaning module is used for emptying the storage space after the data transmission is finished;

the comparison module is also used for comparing the data occupancy rate of the storage space with a second preset threshold;

the sending module is further configured to send the data when the motion state detection module detects that the user is in a motion state and the comparison module compares that the data occupancy rate of the storage space exceeds the second preset threshold, where the second preset threshold is smaller than the first preset threshold;

the comparison module is also used for comparing the data occupancy rate of the storage space with a third preset threshold value;

the sending module is further configured to send the data when the motion state detection module detects that the user is in a stationary state and the comparison module compares that the occupancy rate of the storage space data exceeds the third preset threshold, where the third preset threshold is smaller than the second preset threshold.

6. The apparatus of claim 5, further comprising:

a physiological data acquisition module and/or a charging state acquisition module,

the physiological data acquisition module is used for acquiring the physiological data of the user,

the charging state acquisition module is used for acquiring charging state data of the device;

when the physiological data acquisition module does not acquire the physiological data of the user or the charging state data acquired by the charging state acquisition module indicates that the charging is in progress, stopping the physiological data acquisition and the calculation of physiological parameters;

the sending module is further configured to send the data immediately when the physiological data of the user is not acquired by the physiological data acquisition module or the charging state data acquired by the charging state acquisition module indicates that the charging is in progress.

7. The apparatus of claim 5, further comprising:

the physiological parameter acquisition module is used for acquiring the physiological parameters of the user;

the sending module is further configured to send the data immediately when the physiological parameter acquisition module acquires that the physiological parameter of the user is abnormal.

8. The apparatus of any of claims 5-7, further comprising one of:

the confidence coefficient adjusting module is used for reducing the confidence coefficient of the acquired physiological data when the sending module sends the data;

the physiological parameter calculation module is used for suspending the calculation of the physiological parameters of the user when the data is sent by the sending module;

and the physiological parameter acquisition module is used for suspending acquisition of the physiological parameters of the user when the data is sent by the sending module.

9. A storage medium, characterized in that the storage medium has stored thereon a program which, when being executed by a processor, carries out the steps of the method according to any one of claims 1 to 4.

10. A wearable device comprising a memory, a display, a processor, and a program stored on the memory and executable on the processor, the processor implementing the steps of the method of any of claims 1-4 when executing the program.

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