CN113324673A - Temperature monitoring method, device, equipment and storage medium - Google Patents

Abstract

The application discloses a temperature monitoring method, a device, equipment and a storage medium, wherein the method comprises the following steps: acquiring a basic temperature value of a sleep environment; acquiring a real-time temperature value of a sleep environment; comparing the basic temperature value with the real-time temperature value; if the real-time temperature value is smaller than the basic temperature value, determining whether a delay value of the real-time temperature value which is continuously smaller than the basic temperature value exceeds a preset reminding time threshold value or not; and if the delay value exceeds the reminding time threshold value, outputting a reminding signal. That is, in this application, whether the temperature continues to descend is judged through the time delay numerical value that real-time temperature value lasts to be less than basic temperature value, avoids appearing the change of temperature fluctuation in the short time and leads to judging the mistake to reach temperature monitoring's accuracy, when the process time that the temperature descends surpassed and reminds the time threshold value, the prompt facility of reminding is realized again to the prompt facility that consequently, on the basis of accurate monitoring.

Description

Temperature monitoring method, device, equipment and storage medium

Technical Field

The present application relates to the field of intelligent devices, and in particular, to a temperature monitoring method, apparatus, device, and storage medium.

Background

Along with the development of science and technology, more and more intelligent products enter our lives, the quality of our lives is improved, and especially under the condition that people have high requirements for sleep, the corresponding intelligent sleep monitoring products are more and more popular.

The infant is in the growth and development period, the metabolism is vigorous, the body temperature is raised when the infant sleeps at night in winter, the infant often turns over and easily kicks off the quilt, after the quilt falls, the infant cannot cover the quilt by himself, the body is exposed outside, and the infant easily catches a cold, so that the infant needs to wake up from time to observe the condition that the infant quilt covers when an adult sleeps, the sleeping quality of the adult is easily affected, and sometimes the infant cannot cover the quilt in time when the adult sleeps deeply.

The existing method is to know the sleeping environment of an infant and remind a father and a mother to cover a quilt basically through a camera image analysis method, and has the defects that firstly, the image of the sleeping environment of the infant is captured through the camera, the risk that others peep the privacy of the infant is increased, and a certain privacy crisis exists, and secondly, the principle of camera monitoring is through infrared monitoring, but infrared rays can be influenced by light, so that the monitoring is inaccurate; some monitor the condition that the infant sleeps at night and covers the quilt through some special monitoring mechanisms, if install the control, parents independently look over whether the infant covers the quilt through long-range, and this kind of mode belongs to the camera image and is discerned one, has above-mentioned shortcoming equally, in addition, still has to look over in time, increases parents and looks over the shortcoming of frequency, and is impractical.

That is, the existing sleep temperature monitoring devices have low accuracy and slow reaction efficiency.

Disclosure of Invention

The application mainly aims to provide a temperature monitoring method, and aims to solve the technical problem of how to improve the accuracy of temperature monitoring.

In order to achieve the above object, the present application provides a temperature monitoring method, including:

acquiring a basic temperature value of a sleep environment;

acquiring a real-time temperature value of a sleep environment;

comparing the basic temperature value with the real-time temperature value;

when the real-time temperature value is smaller than the basic temperature value, determining whether a delay value of the real-time temperature value continuously smaller than the basic temperature value exceeds a preset reminding time threshold value or not;

and if the delay value exceeds the reminding time threshold value, outputting a reminding signal.

Further, the step of determining whether the delay value of the real-time temperature value continuously smaller than the basic temperature value exceeds a preset reminding time threshold value if the real-time temperature value is smaller than the basic temperature value includes:

judging the orientation of the front face of the intelligent wearable device, wherein a first shielding sensor is installed on the front face;

when the front face faces downwards, judging whether a second shielding sensor is shielded or not, wherein the second shielding sensor is installed on the side face of the intelligent wearable device;

and when the second shielding sensor is not shielded, determining that the reminding time threshold is the first reminding time threshold.

Further, the reminding time threshold further includes a second reminding time threshold, and when the front face faces downward, after the step of judging whether the second shielding sensor is shielded, the method includes:

and when the second shielding sensor is shielded, determining the reminding time threshold value as the second reminding time threshold value.

Further, after the step of determining the orientation of the front surface of the smart wearable device, the method includes:

and when the front side faces upwards, determining that the reminding time threshold is the first reminding time threshold.

Further, the step of obtaining a basic temperature value of the sleep environment includes:

and acquiring a temperature value of the intelligent wearable device when the intelligent wearable device is placed in a quilt, and taking the temperature value as the basic temperature value.

Further, after the step of comparing the basic temperature value with the real-time temperature value, the method includes:

and if the real-time temperature value is greater than or equal to the basic temperature value, executing the step of acquiring the real-time temperature value of the sleep environment.

Further, after the step of obtaining the basic temperature value of the sleep environment, the method includes:

judging whether the third shielding sensor is shielded or not;

and when the third shielding sensor is shielded, executing the step of acquiring the real-time temperature value of the sleep environment.

The present application further provides a temperature monitoring device, which is characterized in that the temperature monitoring device comprises:

the first acquisition module is used for acquiring a basic temperature value of the sleep environment;

the second acquisition module is used for acquiring a real-time temperature value of the sleep environment;

the data comparison module is used for comparing the basic temperature value with the real-time temperature value;

the determining module is used for determining whether the delay value of the real-time temperature value which is continuously smaller than the basic temperature value exceeds a preset reminding time threshold value or not when the real-time temperature value is smaller than the basic temperature value;

and the output reminding module is used for outputting a reminding signal when the delay value exceeds the reminding time threshold.

This application still provides an intelligence wearing equipment, intelligence wearing equipment includes: a memory, a processor, and a program stored on the memory for implementing the temperature monitoring method;

the memory is used for storing a program for realizing the temperature monitoring method;

the processor is configured to execute a program for implementing the temperature monitoring method, and the program for implementing the temperature monitoring method, when executed by the processor, may implement the steps of the temperature monitoring method as described above.

The present application also provides a storage medium having stored thereon a program for implementing a temperature monitoring method, the program implementing the temperature monitoring method implementing the steps of the temperature monitoring method as described above when executed by a processor.

Compared with the prior art, the quilt kicking phenomenon of the infant in sleep is monitored by a camera image analysis method, so that the accuracy is low and the response is slow. The method comprises the steps of obtaining a basic temperature value of a sleep environment; acquiring a real-time temperature value of a sleep environment; comparing the basic temperature value with the real-time temperature value; if the real-time temperature value is smaller than the basic temperature value, determining whether a delay value of the real-time temperature value which is continuously smaller than the basic temperature value exceeds a preset reminding time threshold value or not; and if the delay value exceeds the reminding time threshold value, outputting a reminding signal. That is, in this application, through the real-time temperature value of monitoring sleep environment, compare it with basic temperature value, be less than basic temperature value based on real-time temperature value, be less than through real-time temperature value the time delay numerical value of basic temperature value judges whether the temperature lasts the decline, avoids appearing the change of temperature fluctuation in the short time and leads to the judgement mistake to reach temperature monitoring's accuracy, when the process time of temperature decline surpassed warning time threshold value, the prompt signal is exported in the fast reaction, consequently, on the basis of accurate monitoring, the promptness of reminding is realized again.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present application and together with the description, serve to explain the principles of the application.

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, and it is obvious for those skilled in the art to obtain other drawings without inventive exercise.

FIG. 1 is a schematic flow chart of a first embodiment of a temperature monitoring method according to the present application;

FIG. 2 is a flowchart illustrating a detailed step of step S40 in the first embodiment of the temperature monitoring method of the present application;

FIG. 3 is a detailed flowchart of one embodiment of step S41 in the first embodiment of the temperature monitoring method according to the present application;

fig. 4 is a schematic view of a front structure of a dial plate of the smart watch in the first embodiment of the temperature monitoring method of the present application;

fig. 5 is a schematic side view of a watch dial of the smart watch according to the first embodiment of the temperature monitoring method of the present application;

FIG. 6 is a schematic flow chart of a second embodiment of the temperature monitoring method of the present application;

FIG. 7 is a functional block diagram of a preferred embodiment of the temperature monitoring device of the present application;

fig. 8 is a schematic device structure diagram of a hardware operating environment according to an embodiment of the present application.

The objectives, features, and advantages of the present application will be further described with reference to the accompanying drawings.

Detailed Description

It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

The embodiment of the application provides a temperature monitoring method and device.

Referring to fig. 1, fig. 1 is a general operation diagram of a temperature monitoring method, which is used for assisting the following description of various embodiments, showing an implementation flow of the present invention based on the temperature monitoring method (herein, it refers to detecting the phenomenon of kicking quilt by baby, if other fields use the method or device, other types of situations requiring temperature monitoring should be included in the protection scope) when the phenomenon of kicking quilt by baby in sleep needs to be monitored

In a first embodiment of the temperature monitoring method, applied to the smart wearable device, with reference to fig. 1, the temperature monitoring method includes:

step S10, acquiring a basic temperature value of the sleep environment;

step S20, acquiring a real-time temperature value of the sleep environment;

step S30, comparing the basic temperature value with the real-time temperature value;

step S40, when the real-time temperature value is smaller than the basic temperature value, determining whether the delay value of the real-time temperature value continuously smaller than the basic temperature value exceeds a preset reminding time threshold value;

and step S50, if the delay value exceeds the reminding time threshold, outputting a reminding signal.

Referring to fig. 1, a first embodiment of a temperature monitoring method includes the following specific steps:

step S10, acquiring a basic temperature value of the sleep environment;

in this embodiment, it should be noted that the intelligent wearable device refers to a device that has a bluetooth transmission function and can access the internet or a personal area network, such as a smart watch, a bracelet, and the following detailed analysis is performed by taking the smart watch as an example, and the specific implementation of other intelligent wearable devices is basically the same and is not described herein again.

In this embodiment, the smart watch is placed in the quilt, and the obtained temperature value is the basic temperature value.

Specifically, be provided with temperature sensor B on the intelligent wrist-watch, use temperature sensor B to monitor the temperature value of each flow, the infant wears the intelligent wrist-watch on the wrist, when the infant has covered the quilt, the hand is put into the quilt, at this moment, through the ambient temperature around the intelligent wrist-watch of temperature sensor B monitoring, with the extension of time, the ambient temperature around the intelligent wrist-watch slowly rises, the temperature keeps the small amplitude change in certain extent thereafter, namely the temperature in the quilt when the infant has covered the quilt sleep, the temperature at this moment is basic temperature value.

Step S20, acquiring a real-time temperature value of the sleep environment;

after the basic temperature value is obtained, the basic temperature value is stored in a memory of the intelligent watch, the temperature sensor B works continuously, and the temperature value of the surrounding environment of the intelligent watch at every moment is monitored, namely the real-time temperature value.

Step S30, comparing the basic temperature value with the real-time temperature value;

the data processor in the intelligent watch is combined with the basic temperature value and the real-time temperature value data to compare the basic temperature value with the real-time temperature value, and whether the real-time temperature value is smaller than the basic temperature value is judged, if the real-time temperature is smaller than the basic temperature value, the temperature monitoring time is indicated, the temperature around the intelligent watch is reduced, because the temperature around the intelligent watch is reduced probably because the watch is exposed outside and also probably because the body temperature of the infant is changed at different time stages in the normal sleeping process, the real-time temperature monitored by the intelligent watch is changed, therefore, the reduction of the temperature around the intelligent watch cannot be directly indicated by the fact that the quilt is kicked off, the situation that the intelligent watch is outside the quilt and the quilt is kicked off by the infant can exist, and the phenomenon that the quilt is not kicked off can also exist, therefore, on the basis that the real-time temperature value is compared with the basic temperature value reduced, and whether the quilt is kicked or not needs to be further accurately judged.

Further, after the step of comparing the basic temperature value with the real-time temperature value, the method includes:

step a, if the real-time temperature value is larger than or equal to the basic temperature value, executing the step of acquiring the real-time temperature value of the sleep environment.

After the real-time temperature value is compared with the basic temperature value, the real-time temperature value is obtained to be larger than or equal to the basic temperature value, the temperature of the detection time is not reduced, the process of keeping the real-time temperature value constant with the basic temperature value is achieved, the intelligent watch is still placed in the quilt at the moment, namely, the quilt is in a state of not being kicked away, the follow-up steps are not required to be executed, and the real-time temperature around the watch can be continuously monitored. It can be understood that the information of whether the temperature is reduced is obtained by comparing the real-time temperature with the basic temperature, and the step of monitoring the real-time temperature is continuously executed under the condition that the temperature is not reduced, so that the continuity and the circulation of temperature monitoring are realized.

Step S40, when the real-time temperature value is smaller than the basic temperature value, determining whether the delay value of the real-time temperature value continuously smaller than the basic temperature value exceeds a preset reminding time threshold value;

the real-time temperature value represents the instantaneous temperature at a certain moment, whether the temperature is reduced or not is determined by comparing the real-time temperature value around the intelligent watch with the basic temperature value, the temperature is reduced at a certain transient moment possibly, and the temperature starts to rise again after the transient reduction, so that after the real-time temperature value is determined to be smaller than the basic temperature value, the time of the temperature reduction process is also determined to be a delay value, and whether the delay value exceeds a preset reminding time threshold or not is determined, so that whether the temperature around the intelligent watch is continuously reduced or not is accurately determined;

it should be noted that the preset reminding time threshold is selected according to different states of the smart watch and is divided into a first time threshold and a second time threshold, for example, the first time threshold may be set to be 5 minutes, and the second time threshold may be set to be 10 minutes.

Optionally, referring to fig. 2, when the real-time temperature value is smaller than the basic temperature value, the step of determining whether a delay value of the real-time temperature value that is continuously smaller than the basic temperature value exceeds a preset reminding time threshold includes:

it should be noted that, referring to fig. 4 and 5, a light-sensing proximity sensor a is disposed on the surface of the smart watch, the optical sensor a can detect whether a shielding object is around the smart watch, specifically, a transmitter in the light-sensing proximity sensor a sends a signal to detect whether a shielding object is in front of the smart watch, the sent signal is an optical detection signal, a receiver used in cooperation with the transmitter is disposed in the light-sensing proximity sensor a, the receiver receives an optical feedback signal returned by the optical detection signal, and whether a shielding object is around the smart watch can be further determined by the optical feedback signal;

specifically, the optical sensor a has a preset optical threshold, where the preset optical threshold is a middle value between a maximum signal value and a minimum signal value received by a receiver in the optical sensor a, when there is no object around the smart watch, a signal received by the receiver in the optical sensor a is taken as the minimum signal value, when there is an object around the smart watch, a signal received by the receiver in the optical sensor a is taken as the maximum signal value, when there is an object around the smart watch, a magnitude comparison between the optical feedback signal and the preset optical threshold is used to determine whether there is a blocking object around the smart watch, the closer the distance between the blocking object and the smart watch is, the larger the optical feedback signal is, and therefore, if the optical feedback signal is greater than the preset optical threshold, it is determined that there is a blocking object around the smart watch, if the optical feedback signal is smaller than the preset optical threshold value, it is indicated that the smart watch has no shielding object in a preset range, or the distance between the shielding object and the smart watch is far beyond a monitoring range.

Further, when the real-time temperature value is smaller than the basic temperature value, determining whether a delay value of the real-time temperature value continuously smaller than the basic temperature value exceeds a preset reminding time threshold, including:

step S41, judging the orientation of the front face of the intelligent wearable device, wherein a first shielding sensor is installed on the front face;

in this embodiment, first sensor of sheltering from can be sensing gyroscope E, sensing gyroscope E set up in on the front of intelligent wrist-watch, sensing gyroscope E judges the front of intelligent wrist-watch is up or down, obtains the positive orientation signal of intelligent wrist-watch, need explain that, the intelligent wrist-watch includes front, reverse side and side, and the reverse side is the surface of laminating the wrist when the wrist is worn to the intelligent wrist-watch, and the front is relative with the reverse side, and the front generally is the surface at display screen place.

In this embodiment, there are two cases of the orientation of the front of the smartwatch:

the first condition is as follows:

step S42, when the front face faces downwards, judging whether a second shielding sensor is shielded, wherein the second shielding sensor is installed on the side face of the intelligent watch;

the smart watch comprises a front surface, a back surface and side surfaces, wherein the back surface is a surface which is attached to the wrist when the smart watch is worn on the wrist, the front surface is opposite to the back surface, the front surface is generally the surface where the display screen is located, and the side surfaces are two sides of the display screen.

Further, when the front face faces downward, the step of determining whether the second shielding sensor is shielded includes:

step b, acquiring an ultrasonic ranging signal;

when the front of the intelligent watch faces downwards, the intelligent watch is tightly attached to a quilt, a bed or a body of an infant, the optical feedback signal of the optical sensor A at the moment is larger than a preset optical threshold value, namely, the optical sensor A is shielded, the second shielding sensor can be an ultrasonic distance measuring sensor, C, D two ultrasonic distance measuring sensors are arranged on the side face of the dial plate of the intelligent watch, the ultrasonic distance measuring sensors have the self-transmitting and self-receiving functions and can measure the distance between a shielding object on the side face of the intelligent watch and the intelligent watch, and whether the second shielding sensor is shielded or not can be judged according to the distance, namely, whether the quilt is kicked or not.

Step c, comparing the ultrasonic ranging signal with a preset ranging threshold;

a specific distance range between the shielding object and the ultrasonic ranging sensor C, D is a preset distance, a value fed back by the shielding object at the preset distance to a signal sent by the ultrasonic ranging sensor C, D serves as the preset ranging threshold, and it should be noted that the specific distance range between the shielding object and the ultrasonic ranging sensor C, D is a distance between a quilt and the smart watch when the quilt is not kicked away, that is, a distance between the shielding object and the ultrasonic ranging sensor C, D, and the distance can be specifically preset;

therefore, when the ultrasonic ranging signal is greater than the preset ranging threshold value, it indicates that the shielding object is on the far side of the normal distance of the smart watch, that is, the ultrasonic ranging sensor is not shielded by a quilt, and a quilt may be kicked away;

d, when the ultrasonic ranging signal is larger than the preset ranging threshold value, determining that the second shielding sensor is not shielded;

the ultrasonic distance measuring sensors C, D are respectively arranged on two sides of the intelligent watch, the ultrasonic distance measuring sensor C and the ultrasonic distance measuring sensor D need to be compared with the preset distance measuring threshold respectively, when the ultrasonic distance measuring signal of one of the ultrasonic distance measuring sensors is greater than the preset distance measuring threshold, it is indicated that one side of the intelligent watch is exposed outside the quilt, or the distance between one side of the intelligent watch and the quilt is greater than the normal distance, and the situation that the quilt is not covered due to wind leakage or a part of the quilt is kicked away is caused, at this moment, it can be determined that the quilt of the infant is kicked away, and the intelligent watch needs to send a notification to remind parents of covering the quilt for the infant.

Step S43, when the second occlusion sensor is not occluded, determining that the reminding time threshold is the first reminding time threshold.

In order to increase the accuracy of judging whether the quilt is kicked away, the comprehensive judgment needs to be carried out by combining the time of temperature reduction, at the moment, a first reminding time threshold value is selected for 5 minutes, namely, when the time of the real-time temperature value reduction is 5 minutes compared with the time of the basic temperature value reduction, the intelligent watch outputs a notification to remind parents of kicking away the quilt, and the parents need to cover the quilt with the quilt for the child.

Further, referring to fig. 2, after the step of comparing the ultrasonic ranging signal with a preset ranging threshold, the method includes:

step S44, when the second occlusion sensor is occluded, determining that the reminding time threshold is the second reminding time threshold;

when the ultrasonic ranging signal of the ultrasonic ranging sensor is smaller than or equal to the preset ranging threshold value, it is indicated that a shielding object is arranged around the smart watch, the ultrasonic ranging sensor is shielded, that is, it is determined that the second shielding sensor is shielded, when both the ultrasonic ranging sensors C, D are shielded, there may be a state that the smart watch is located in a quilt, and the quilt is not kicked away at this time, or there may be a state that the quilt is kicked away at this time, and the outside of the quilt and other objects on the bed shield the two ultrasonic ranging sensors C, D on the smart watch after the quilt is kicked away, so it is also necessary to determine whether the quilt is kicked away by the time when the real-time temperature value is lower than the basic temperature value, and in this case, it is determined that there is uncertainty, and therefore it is necessary to determine whether the quilt is kicked away for a long time, at this time, a second reminding time threshold value is selected for 10 minutes, that is, when the time for which the real-time temperature value is reduced compared with the basic temperature value reaches 10 minutes, the smart watch outputs a notification to remind parents of being kicked away, and the parents are required to cover the quilt with the quilt.

It can be understood that the orientation of the front of the smart watch is determined by the sensing gyroscope, and when the smart watch is facing down, acquiring an ultrasonic ranging signal through an ultrasonic ranging sensor, comparing the ultrasonic ranging signal with a preset ranging threshold value, comparing data based on the size of the ultrasonic ranging signal compared with the preset ranging threshold value, can obtain the information whether the ultrasonic ranging sensors on the two sides of the surface of the intelligent watch are shielded or not, can obtain the basic judgment of the quilt kicked away, determining a reminding time threshold value for sending out a notice to remind a parent cover, a mother cover and a child according to different watch states and ultrasonic distance measuring sensor states, when the process time of the temperature drop reaches the corresponding reminding time threshold, the intelligent watch can timely send out a notice to inform a father and a mother to cover a quilt, the accuracy of judgment of the condition of the quilt kicking is improved in the process, and the timeliness of reminding and informing is improved.

Case two (see fig. 3): after the step of determining the orientation of the front face of the smart wearable device, the method includes:

step S45, when the front face is facing upward, determining that the reminding time threshold is the first reminding time threshold.

Specifically, when the front of the smart watch faces upward, the optical feedback signal of the optical sensor a at this time is less than or equal to a preset optical threshold, that is, the front of the smart watch has no blocking object, the quilt of the infant is kicked away, it is necessary to remind parents of covering the quilt again for the infant, at this time, the first reminding time threshold is selected for 5 minutes, that is, when the time that the real-time temperature value is decreased compared with the basic temperature value reaches 5 minutes, the smart watch outputs a notification to remind the parents of being kicked away, and it is necessary for the parents to cover the quilt for the infant.

It can be understood that based on the basis that real-time temperature value descends, detect that intelligent wrist-watch openly faces up through the gyroscope, when optical sensor was not sheltered from, explain the quilt and kicked off, when real-time temperature value reached the very first time threshold value in time than the time delay numerical value in basic temperature value decline process this moment, in time sent the notice, remind father mother to cover the quilt, increased equally and played the accuracy that this condition of son was judged, improved the promptness of reminding the notice moreover.

Step S50, if the delay value exceeds the reminding time threshold, outputting a reminding signal;

the delay value is the time of the real-time temperature value in the continuous descending process compared with the basic temperature value, and is calculated from the time of starting descending of the real-time temperature value, which is the initial time value during initial descending, so that the delay value is the time difference between the real-time value at the monitoring moment and the initial time value, when the delay value reaches the preset reminding time threshold value, the quilt of the infant is kicked off, and the intelligent watch outputs a reminding signal to remind parents of covering the quilt of the infant.

Further, infant's intelligence wearing equipment can send BLE (Bluetooth Low Energy) signal or internet communication signal to parent's intelligence wearing equipment (parent's intelligence wearing equipment is the equipment or the mobile terminal that have Bluetooth transfer function, can insert internet or personal area network, such as intelligent wrist-watch, bracelet etc.), and this signal is used for reminding parents to cover the quilt for infant, and the signal can be reminded through modes such as sound, light and shadow, vibrations.

The invention relates to a method based on temperature monitoring, which comprises the following steps: acquiring a basic temperature value and a real-time temperature value of a sleep environment, comparing the real-time temperature value with the basic temperature value, when the real-time temperature value is smaller than the basic temperature value, further determining whether a delay value of the real-time temperature value continuously smaller than the basic temperature value exceeds a preset reminding time threshold value, and if the delay value exceeds the reminding time threshold value, outputting a reminding signal; after the real-time temperature is detected to be reduced compared with the basic temperature, the temperature at the detection moment is reduced, the delay value in the temperature reduction process is further compared with the preset reminding time threshold, the integral temperature is more accurately judged to be reduced, and a reminding signal is timely output when the delay value reaches the reminding time threshold, so that the accuracy and the reminding timeliness of temperature detection are improved.

Compared with the prior art: the phenomenon that an infant kicks a quilt during sleeping is monitored through a camera graphic analysis method, whether the quilt covers the infant or not is analyzed and judged through infrared rays in the camera, infrared rays are influenced by light, certain monitoring inaccuracy exists, and the risk of privacy disclosure of the infant is increased due to the use of the camera.

Further, on the basis of the first embodiment of the temperature monitoring method, a second embodiment is also provided, and with reference to fig. 6, after the step of obtaining the basic temperature value of the sleep environment, the method includes:

step S60, determining whether the third blocking sensor is blocked;

in this embodiment, the third shielding sensor may be a light-sensing proximity sensor, and the light-sensing proximity sensor a on the smart watch may detect whether a shielding object exists around the smart watch;

further, the step of judging whether the third shielding sensor is shielded comprises,

and e, sending out an optical detection signal.

The emitter in the light sensation proximity sensor A sends out a signal to detect whether a shelter exists in front, and the sent signal is an optical detection signal.

And f, acquiring an optical feedback signal corresponding to the optical detection signal.

A receiver matched with the transmitter is arranged in the light sensor A, the receiver receives an optical feedback signal returned by the optical detection signal, and whether a shelter exists around the intelligent watch can be further judged through the optical feedback signal;

step g, when the optical feedback signal is greater than the preset optical threshold, determining that the third shielding sensor is shielded;

the optical sensor A has a preset optical threshold value, where the preset optical threshold value is a middle value between a maximum signal value and a minimum signal value received by a receiver in the optical sensor A, when no object exists around the smart watch, a signal received by the receiver in the optical sensor A is taken as the minimum signal value, when an object is tightly attached around the smart watch, a signal received by the receiver in the optical sensor A is taken as the maximum signal value, whether a blocking object exists around the smart watch is judged by comparing the optical feedback signal with the preset optical threshold value, the closer the blocking object is to the smart watch, the larger the optical feedback signal is, and therefore, if the optical feedback signal is greater than the preset optical threshold value, it is determined that a blocking object exists around the smart watch, if the optical feedback signal is smaller than the preset optical threshold value, it is indicated that the smart watch has no shielding object in a preset range, or the distance between the shielding object and the smart watch is far beyond a monitoring range.

Step S70, when the third shielding sensor is shielded, executing the step of obtaining the real-time temperature value of the sleep environment;

when the third shielding sensor is shielded, it is indicated that shielding objects are also arranged around the intelligent watch, that is, the intelligent watch is located in a quilt, and the quilt of an infant is in a normal covering state, at the moment, the intelligent watch starts to monitor the sleeping environment of the infant to acquire a real-time temperature value of the sleeping environment, that is, when the quilt is completely covered on the infant, after parents leave, the intelligent watch starts to actively monitor the sleeping environment of the infant, and after the temperature is reduced due to the fact that the quilt is kicked away, the intelligent watch outputs a reminding signal to inform the parents of passively covering the infant with the quilt.

Further, the step of obtaining the optical feedback signal corresponding to the optical detection signal includes,

when the optical feedback signal is smaller than or equal to the preset optical threshold, it is determined that the third shielding sensor is not shielded, that is, the quilt of the infant is kicked away, and it is required for parents to independently cover the quilt again for the infant before the parents are not reminded to notify, and when the optical feedback signal is detected to be larger than the preset optical threshold, that the quilt is covered, the monitoring of the real-time temperature of the sleep environment can be continuously performed;

when the optical feedback signal is less than or equal to the preset optical threshold, it may also be said that the distance from the blocking object to the smart watch is far, that is, the distance from the quilt to the body of the infant or the smart watch is far, which indicates that the quilt is not completely attached to the body of the infant, and there is a case of wind leakage or uncovered, and at this time, parents are also required to independently cover the quilt again for the infant before being reminded of the notification.

In this embodiment, whether the quilt is kicked off is judged by judging whether the optical sensor a on the smart watch is sheltered from, when the optical sensor a is not sheltered from, it indicates that the quilt is not covered on the infant, and at this moment, it is required for the infant to be covered by the quilt by parents, and after the quilt is covered again, the optical sensor a displays to be sheltered from, so that the real-time temperature value of the sleep environment and the situation of kicking the quilt automatically in the follow-up process can be continuously monitored, and whether the actions of the quilt by the parents are finished can also be judged, thereby ensuring the circulation of the temperature monitoring process of the smart watch.

The present application further provides a temperature monitoring device, referring to fig. 7, the temperature monitoring device includes:

the first acquisition module 10 is used for acquiring a basic temperature value of a sleep environment;

the second acquiring module 20 is used for acquiring a real-time temperature value of the sleep environment;

a comparison module 30, configured to compare the basic temperature value with the real-time temperature value;

a determining module 40, configured to determine whether a delay value of the real-time temperature value that is continuously smaller than the basic temperature value exceeds a preset reminding time threshold when the real-time temperature value is smaller than the basic temperature value;

and the output module 50 is configured to output a reminding signal when the delay value exceeds the reminding time threshold.

Optionally, the determining module 40 includes:

the first judging submodule judges the orientation of the front face of the intelligent wearable device, wherein a first shielding sensor is installed on the front face;

the second judging submodule judges whether a second shielding sensor is shielded or not when the front side faces downwards, wherein the second shielding sensor is installed on the side face of the intelligent wearable device;

and the first determining submodule determines that the reminding time threshold is the first reminding time threshold when the second shielding sensor is not shielded.

Optionally, the second determining sub-module further includes:

and the second determining submodule determines that the reminding time threshold is the second reminding time threshold when the second shielding sensor is shielded.

Optionally, the first determining sub-module further includes:

and the third determining submodule determines that the reminding time threshold is the first reminding time threshold when the front side faces upwards.

Optionally, the first obtaining module 10 includes:

and the third acquisition sub-module is used for acquiring a temperature value of the intelligent wearable device when the intelligent wearable device is placed in the quilt, and the temperature value is used as the basic temperature value.

Optionally, the alignment module 30 further includes:

and the first judgment module executes the step of acquiring the real-time temperature value of the sleep environment if the real-time temperature value is greater than or equal to the basic temperature value.

Optionally, the temperature monitoring device further comprises:

the second judgment module is used for judging whether the third shielding sensor is shielded or not; and when the third shielding sensor is shielded, executing the step of acquiring the real-time temperature value of the sleep environment.

The specific implementation of the temperature monitoring device of the present application is substantially the same as that of each embodiment of the temperature monitoring method, and is not described herein again.

In addition, this application still provides a temperature monitoring equipment. Referring to fig. 8, fig. 8 is a schematic device structure diagram of a hardware operating environment according to an embodiment of the present application.

Referring to fig. 8, the temperature monitoring apparatus may include: a processor 1001, such as a CPU, a memory 1005, and a communication bus 1002. The communication bus 1002 is used for realizing connection communication between the processor 1001 and the memory 1005. The memory 1005 may be a high-speed RAM memory or a non-volatile memory (e.g., a magnetic disk memory). The memory 1005 may alternatively be a memory device separate from the processor 1001 described above.

Optionally, the temperature monitoring device may further include a rectangular user interface, a network interface, a camera, RF (Radio Frequency) circuitry, a sensor, audio circuitry, a WiFi module, and so forth. The rectangular user interface may comprise a Display screen (Display), an input sub-module such as a Keyboard (Keyboard), and the optional rectangular user interface may also comprise a standard wired interface, a wireless interface. The network interface may optionally include a standard wired interface, a wireless interface (e.g., WI-FI interface).

Those skilled in the art will appreciate that the temperature monitoring device configuration shown in fig. 8 does not constitute a limitation of the mobile terminal switching device and may include more or fewer components than shown, or some components in combination, or a different arrangement of components.

Referring to fig. 8, a memory 1005, which is a storage medium, may include an operating system, a network communication module, and a temperature monitoring program therein. The operating system is a program that manages and controls the hardware and software resources of the temperature monitoring device, supporting the operation of the temperature monitoring program as well as other software and/or programs. The network communication module is used to implement communication between the various components within the memory 1005, as well as communication with other hardware and software in the temperature monitoring system.

In the temperature monitoring apparatus in fig. 8, the processor 1001 is configured to execute a temperature monitoring program stored in the memory 1005, and implement the steps of the temperature monitoring method according to any one of the above.

The specific implementation of the temperature monitoring device of the present application is substantially the same as that of each embodiment of the temperature monitoring method, and is not described herein again.

The present application provides a storage medium, and the storage medium stores one or more programs, which can be further executed by one or more processors for implementing the steps of the temperature monitoring method described in any one of the above.

The specific implementation of the storage medium of the present application is substantially the same as the embodiments of the temperature monitoring method, and is not described herein again.

The present application also provides a computer program product, comprising a computer program which, when executed by a processor, performs the steps of the temperature monitoring method described above.

The specific implementation of the computer program product of the present application is substantially the same as the embodiments of the temperature monitoring method, and is not described herein again.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

The above-mentioned serial numbers of the embodiments of the present invention are merely for description and do not represent the merits of the embodiments.

Through the above description of the embodiments, those skilled in the art will clearly understand that the method of the above embodiments can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware, but in many cases, the former is a better implementation manner. Based on such understanding, the technical solutions of the present invention may be embodied in the form of a software product, which is stored in a storage medium (such as ROM/RAM, magnetic disk, optical disk) and includes instructions for enabling a terminal device (such as a mobile phone, a computer, a server, an air conditioner, or a network device) to execute the method according to the embodiments of the present invention.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. The temperature monitoring method is applied to intelligent wearable equipment and comprises the following steps:

acquiring a basic temperature value of a sleep environment;

acquiring a real-time temperature value of a sleep environment;

comparing the basic temperature value with the real-time temperature value;

when the real-time temperature value is smaller than the basic temperature value, determining whether a delay value of the real-time temperature value continuously smaller than the basic temperature value exceeds a preset reminding time threshold value or not;

and if the delay value exceeds the reminding time threshold value, outputting a reminding signal.

2. The method according to claim 1, wherein the reminding time threshold comprises a first reminding time threshold, and the step of determining whether the delay value of the real-time temperature value continuously less than the base temperature value exceeds a preset reminding time threshold if the real-time temperature value is less than the base temperature value comprises:

judging the orientation of the front face of the intelligent wearable device, wherein a first shielding sensor is installed on the front face;

when the front face faces downwards, judging whether a second shielding sensor is shielded or not, wherein the second shielding sensor is installed on the side face of the intelligent wearable device;

and when the second shielding sensor is not shielded, determining that the reminding time threshold is the first reminding time threshold.

3. The method according to claim 2, wherein the reminding time threshold further comprises a second reminding time threshold, and the step of determining whether the second shielding sensor is shielded when the front face is facing downward comprises:

and when the second shielding sensor is shielded, determining the reminding time threshold value as the second reminding time threshold value.

4. The temperature monitoring method according to claim 2, wherein the step of determining the orientation of the front face of the smart wearable device is followed by:

and when the front side faces upwards, determining that the reminding time threshold is the first reminding time threshold.

5. The temperature monitoring method of claim 1, wherein the step of obtaining a base temperature value of the sleep environment comprises:

and acquiring a temperature value of the intelligent wearable device when the intelligent wearable device is placed in a quilt, and taking the temperature value as the basic temperature value.

6. The method according to claim 1, wherein the step of comparing the base temperature value with the real-time temperature value comprises:

and if the real-time temperature value is greater than or equal to the basic temperature value, executing the step of acquiring the real-time temperature value of the sleep environment.

7. The temperature monitoring method according to any one of claims 1 to 6, wherein the step of obtaining a base temperature value of the sleep environment is followed by:

judging whether the third shielding sensor is shielded or not;

and when the third shielding sensor is shielded, executing the step of acquiring the real-time temperature value of the sleep environment.

8. A temperature monitoring device, comprising:

the first acquisition module is used for acquiring a basic temperature value of the sleep environment;

the second acquisition module is used for acquiring a real-time temperature value of the sleep environment;

the data comparison module is used for comparing the basic temperature value with the real-time temperature value;

the determining module is used for determining whether the delay value of the real-time temperature value which is continuously smaller than the basic temperature value exceeds a preset reminding time threshold value or not when the real-time temperature value is smaller than the basic temperature value;

and the output reminding module is used for outputting a reminding signal when the delay value exceeds the reminding time threshold.

9. The utility model provides an intelligence wearing equipment which characterized in that, temperature monitoring equipment includes: a memory, a processor, and a program stored on the memory for implementing the temperature monitoring method;

the memory is used for storing a program for realizing the temperature monitoring method;

the processor is configured to execute a program implementing the temperature monitoring method to implement the steps of the temperature monitoring method according to any one of claims 1 to 7.

10. A storage medium having stored thereon a program for implementing a temperature monitoring method, the program being executed by a processor to implement the steps of the temperature monitoring method according to any one of claims 1 to 7.

Images