CN108235536B - Intelligent lamp and somatosensory monitoring system - Google Patents

Abstract

The invention provides an intelligent lamp and a somatosensory monitoring system. The intelligent lamp includes: the system comprises a power supply unit, a light source unit, a processor, a somatosensory monitoring sensor and a communication unit; the processor is respectively connected with the light source unit, the somatosensory monitoring sensor, the communication unit and the power supply unit; the motion sensing monitoring sensor is used for acquiring motion sensing data in a preset monitoring range and transmitting the motion sensing data to the processor; the processor is used for judging whether the somatosensory data is normal somatosensory data or not, and if not, the somatosensory data and the danger signal are sent to the server through the communication unit. The intelligent lamp provided by the invention can timely find that the physical condition of a person under guardianship in a monitoring range is abnormal, and timely feed a dangerous signal of the abnormal condition back to a guardian or a medical worker through the communication unit so as to remind the relevant worker to take emergency measures, thereby striving for more time for rescue.

Description

Intelligent lamp and somatosensory monitoring system

Technical Field

The invention relates to the field of illumination, in particular to an intelligent lamp and a motion sensing monitoring system.

Background

With the aging of the social population, the number of the aged people in China is increased, and the occupied population proportion is also increased. Due to the special physical condition of the old, the old can be very dangerous if accidents happen when the old lives alone or the children go to work, especially for the old with diseases or chronic diseases.

Although the old people have mobile phones at present, the connection is convenient, but once some sudden diseases such as heart disease, stroke, cerebral infarction and the like occur, the old people cannot make a call at all, and at the moment, if the old people cannot carry out emergency treatment in time, the old people are very dangerous. Along with the development of science and technology, numerous wearing equipment for old man's special design also arises at the same time, for example, intelligent walking stick, intelligent bracelet and intelligent clothing etc..

However, many elderly people cannot use electronic products skillfully, and in addition, due to the visual deterioration of the elderly people, the elderly people are not always in time to contact with a mobile phone in many emergency situations, and if wearing the device, the elderly people may have inconvenience in their activities.

Disclosure of Invention

The invention provides an intelligent lamp and a somatosensory monitoring system, which are used for solving the problem that the old cannot be quickly and efficiently contacted with the outside under an emergency condition.

In a first aspect, the present invention provides a smart lamp comprising: the system comprises a power supply unit, a light source unit, a processor, a somatosensory monitoring sensor and a communication unit;

the processor is respectively connected with the light source unit, the somatosensory monitoring sensor, the communication unit and the power supply unit

The motion sensing monitoring sensor unit is used for acquiring motion sensing data in a preset monitoring range and transmitting the motion sensing data to the processor;

the processor is used for judging whether the somatosensory data is normal somatosensory data or not, and if not, the somatosensory data and the danger signal are sent to the server through the communication unit.

In one possible design, the smart lamp further comprises: the voice unit is connected with the processor;

the voice unit is used for acquiring a first audio signal in a preset pickup range and transmitting the first audio signal to the processor;

the processor is used for compressing the first audio signal to obtain first compressed audio data;

the communication unit is configured to send the first compressed audio data to the server.

In one possible design, when the processor judges that the somatosensory data is abnormal somatosensory data, the processor is further configured to control the voice unit to start working, record a first working duration of the voice unit, and control the voice unit to stop working when the first working duration is greater than or equal to a preset audio duration;

the voice unit is used for acquiring a first audio signal within a preset pickup range within the first duration, and transmitting the first audio signal to the processor.

In one possible design, the smart lamp further comprises: a speaker coupled to the processor;

the communication unit is further used for receiving second compressed audio data sent by the server and transmitting the second compressed audio data to the processor; the second compressed audio data is uploaded to the server by the terminal;

the processor is further configured to decompress second compressed audio data to obtain a second audio signal, and transmit the second audio signal to the speaker unit;

the loudspeaker is used for sounding according to the second audio signal.

In a possible design, when the processor judges that the somatosensory data is abnormal somatosensory data, the processor is further used for starting the loudspeaker, and the loudspeaker is closed according to the fact that the second audio signal is sounded after the end of sounding.

In one possible design, the somatosensory monitoring sensor unit is a microwave sensor, and the somatosensory data includes at least one of a respiration frequency value and a heartbeat frequency value.

In one possible design, if the somatosensory data is the breathing frequency value, the processor is configured to determine whether the breathing frequency value is within a preset normal breathing frequency value range, and if not, the processor sends the breathing frequency value and the danger signal to the monitoring device through the communication unit;

if the somatosensory data is the heartbeat frequency value, the processor is used for judging whether the heartbeat frequency value is within a preset normal heartbeat frequency value range, and if not, the processor sends the heartbeat frequency value and the danger signal to the monitoring equipment through the communication unit.

In a possible design, if the somatosensory data is the breathing frequency value and the heartbeat frequency value, the processor is specifically configured to determine whether the breathing frequency value is within a preset normal breathing frequency value range, and whether the heartbeat frequency value is within a preset normal heartbeat frequency value range, and if at least one of the determination results is negative, the processor sends the breathing frequency value, the heartbeat frequency value, and the risk signal to the monitoring device through the communication unit.

In one possible design, the light source unit is an LED light source and the communication unit is a wireless communication unit.

In a second aspect, the present invention further provides a motion sensing monitoring system, including any one of the possible smart lamps according to the first aspect, a server in bidirectional communication with the smart lamp, and a terminal in bidirectional communication with the server.

In one possible design, the terminal includes: the system comprises a terminal processor, a memory, a receiving module, a downloading module, a sound production module and a display module;

the receiving module is used for receiving the danger signal sent by the server;

the downloading module is used for downloading the somatosensory data and the first compressed audio data from the server;

the memory is used for storing the somatosensory data and the first compressed audio data;

the terminal processor is used for decompressing the first compressed audio data and indicating the sound production module to produce sound according to the audio data decompressed by the first compressed audio data;

the terminal processor is further used for indicating the display module to display the somatosensory data.

According to the intelligent lamp, the somatosensory data of a person under guardianship in a preset monitoring range is acquired through the somatosensory monitoring sensor in the intelligent lamp, the processor is used for judging whether the acquired somatosensory data is normal somatosensory data or not, and if not, the processor sends the somatosensory data and danger signals to the server through the communication unit. The intelligent lamp provided by the embodiment can timely find that the physical condition of a person under guardianship in the monitoring range is abnormal, and timely feed back the dangerous signal of the abnormal condition to guardians or medical personnel through the communication unit so as to remind relevant personnel to take emergency measures, thereby striving for more time for rescue.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a diagram of an application scenario of the intelligent lamp provided by the present invention;

FIG. 2 is a schematic diagram of a smart light configuration in accordance with an exemplary embodiment of the present invention;

FIG. 3 is a schematic diagram of a smart light configuration according to another exemplary embodiment of the present invention;

FIG. 4 is a schematic diagram of a smart light configuration according to yet another exemplary embodiment of the present invention;

FIG. 5 is a schematic diagram of a somatosensory monitoring system according to an exemplary embodiment of the invention;

fig. 6 is a schematic structural diagram of the terminal in the embodiment shown in fig. 5.

Description of reference numerals:

101: a power supply unit;

102: a processor;

103: a light source unit;

104: a communication unit;

105: a somatosensory monitoring sensor;

106: a voice unit;

107: a speaker;

201: a terminal processor;

202: a memory;

203: a receiving module;

204: a downloading module;

205: a sound producing module;

206: and a display module.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the 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.

The terms "first," "second," "third," "fourth," and the like in the description and in the claims, as well as in the drawings, if any, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the invention described herein are, for example, capable of operation in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

The technical solution of the present invention will be described in detail below with specific examples. The following several specific embodiments may be combined with each other, and details of the same or similar concepts or processes may not be repeated in some embodiments.

Fig. 1 is a view of an application scenario of the intelligent lamp provided by the present invention. As shown in fig. 1, the smart lamp provided by the present invention can be installed on the ceiling of a bedroom, and the smart lamp is connected with a gateway in the home to network the smart lamp. The intelligent lamp can acquire the body sensing data of the indoor personnel through the body sensing monitoring sensor, and then monitor the physical condition of the indoor personnel according to the acquired body sensing data, and once the physical condition of the indoor personnel is found to be abnormal, the intelligent lamp can send danger signals and the body sensing data to the server through the gateway so as to remind the user bound by the intelligent lamp.

Fig. 2 is a schematic structural diagram of a smart lamp according to an exemplary embodiment of the present invention. As shown in fig. 2, the intelligent lamp provided by the present embodiment includes: power supply unit 101, light source unit 103, processor 102, somatosensory monitoring sensor 105, and communication unit 104.

The processor 102 is connected to the light source unit 103, the somatosensory monitoring sensor 105, and the communication unit 104, and the power supply unit 101 is connected to the processor 102. The power supply unit 101 is connected to an external power supply, and is configured to supply power to the light source unit 103, the processor 102, the motion sensing monitoring sensor 105, and the communication unit 104 in the smart lamp during operation. The light source unit 103 is used for lighting after being energized. The motion sensing monitoring sensor 105 is used for acquiring motion sensing data in a preset monitoring range and transmitting the acquired motion sensing data to the processor 102, after the processor 102 receives the motion sensing data sent by the motion sensing monitoring sensor 105, the processor 102 judges whether the motion sensing data is normal motion sensing data, and if not, the motion sensing data and danger signals are sent to the server through the communication unit 104.

After receiving the somatosensory data and the danger signal sent by the intelligent lamp, the server can send the somatosensory data and the danger signal to the terminal of the guardian bound with the intelligent lamp so as to remind the guardian that the somatosensory data of the person under guardianship in the monitoring range of the intelligent lamp is abnormal and danger exists possibly. In addition, after the server receives the somatosensory data and the danger signal, the server can also directly transmit the danger signal to a hospital near the position where the intelligent lamp is located, so that medical personnel can arrive at the site at the first time to rescue the person under guardianship. In this embodiment, the behavior of the server after receiving the somatosensory data and the dangerous signal is not specifically limited, and only the somatosensory data and the dangerous signal are required to be transmitted to corresponding personnel to remind relevant personnel to take measures for first aid, so that more time can be strived for rescue.

Alternatively, the light source unit 103 in the smart lamp may be an LED light source, and the communication unit 104 may be a wireless communication unit.

In this implementation, the somatosensory data of the personnel in the preset monitoring range is acquired through the somatosensory monitoring sensor in the intelligent lamp, the processor is used for judging whether the acquired somatosensory data are normal somatosensory data or not, and if not, the processor sends the somatosensory data and the danger signal to the server through the communication unit. The intelligent lamp provided by the embodiment can timely find that the physical condition of a person under guardianship in a monitoring range is abnormal, and timely feed back the dangerous signal of the abnormal condition to related personnel through the communication unit so as to remind the related personnel to take emergency measures, thereby striving for more time for rescue.

On the basis of the embodiment shown in fig. 2, fig. 3 is a schematic structural diagram of an intelligent lamp according to another exemplary embodiment of the present invention. As shown in fig. 3, the present embodiment provides an intelligent lamp including: power supply unit 101, light source unit 103, processor 102, body sensing monitoring sensor 105, communication unit 104, and voice unit 106.

The processor 102 is connected to the light source unit 103, the somatosensory monitoring sensor 105, the communication unit 104, and the voice unit 106, and the power supply unit 101 is connected to the processor 102. The power supply unit 101 is connected to an external power supply, and is configured to supply power to the light source unit 103, the processor 102, the motion sensing monitoring sensor 105, the communication unit 104, and the voice unit 106 in the smart lamp during operation. The light source unit 103 is used for lighting after being energized. The motion sensing monitoring sensor 105 is used for acquiring motion sensing data in a preset monitoring range and transmitting the acquired motion sensing data to the processor 102, after the processor 102 receives the motion sensing data sent by the motion sensing monitoring sensor 105, the processor 102 judges whether the motion sensing data is normal motion sensing data, and if not, the motion sensing data and danger signals are sent to the server through the communication unit 104.

The voice unit 106 is configured to acquire a first audio signal within a preset pickup range, transmit the acquired first audio signal to the processor 102, and in order to facilitate subsequent fast transmission, the processor 102 compresses the first audio signal to obtain first compressed audio data, and then sends the first compressed audio data to the server through the communication unit 104.

For example, the voice unit 106 transmits the acquired first audio signal to the processor 102 once every 5 minutes, so that the processor 102 compresses the first audio signal to obtain first compressed audio data, and then sends the first compressed audio data to the server through the communication unit 104.

In addition, the voice unit 106 may also be started only when the processor 102 determines that the motion sensing data is abnormal motion sensing data, specifically, when the processor 102 determines that the motion sensing data is abnormal motion sensing data, the processor 102 may control the voice unit 106 to start working, and meanwhile, after the voice unit 106 starts working, the processor 102 may further record a first duration of the working of the voice unit 106, and when the first duration is greater than or equal to a preset audio duration, control the voice unit 106 to stop working, where the voice unit 106 is specifically configured to obtain a first audio signal within a preset pickup range within the first duration, and transmit the first audio signal to the processor 102, so that the processor 102 compresses the first audio signal to obtain first compressed audio data, and then transmits the first compressed audio data to the server through the communication unit 104.

For the preset audio duration, for example, 1 minute may be set, when the processor 102 determines that the somatosensory data is abnormal somatosensory data, the processor 102 controls the voice unit 106 to start to operate, at this time, the voice unit 106 starts to record external audio data, and after 1 minute, the processor 102 controls the voice unit 106 to end recording, and transmits the acquired first audio signal to the processor 102, so that the processor 102 compresses the first audio signal to obtain first compressed audio data, and then transmits the first compressed audio data to the server through the communication unit 104. And the server forwards the acquired first compressed audio data to a terminal of the user bound by the intelligent lamp or a hospital nearby the position of the intelligent lamp. When the body sensing data of the person under guardianship is abnormal, the person under guardianship is likely to send out a distress sound in a short time, and the distress sound in the time period is recorded through the voice unit 106, so that the judgment of relevant medical personnel and guardians on the actual condition of the current patient is facilitated, and a more effective rescue scheme is conveniently formulated.

In order to enable medical staff and guardians to know actual conditions on site, when the processor 102 judges that the somatosensory data is abnormal somatosensory data, the processor 102 may further start the voice unit 106 every 1 minute. It should be noted that, in this embodiment, the first duration of the starting of the voice unit 106 and the manner and the number of times of the starting are not specifically limited, and it is only required to ensure that the voice unit 106 can record the relevant audio signal within the sound pickup range after being started.

Considering that the somatosensory data acquired by the somatosensory monitoring sensor 105 can be effectively used for judging the physical condition of the monitored person, a microwave sensor can be selected as the somatosensory monitoring sensor 105, and at this time, the acquired somatosensory data is at least one value of a breathing frequency value and a heartbeat frequency value. Generally, the respiratory frequency of normal people ranges from 0.1 to 0.7Hz, and the heartbeat frequency of normal people ranges from 0.7 to 3 Hz.

If the acquired somatosensory data is only a breathing frequency value, the processor 102 is specifically configured to determine whether the acquired breathing frequency value is within a preset normal breathing frequency value range, and if not, the processor 102 sends the currently acquired breathing frequency value and the danger signal to the server through the communication unit 104.

If the obtained somatosensory data is only a heartbeat frequency value, the processor 102 is specifically configured to determine whether the obtained heartbeat frequency value is within a preset normal heartbeat frequency value range, and if not, the processor 102 sends the currently obtained heartbeat frequency value and the danger signal to the server through the communication unit 104.

If the somatosensory data is a breathing frequency value and a heartbeat frequency value, the processor is specifically configured to determine whether the acquired breathing frequency value is within a preset normal breathing frequency value range and whether the acquired heartbeat frequency value is within a preset normal heartbeat frequency value range, and if at least one of the determination results is negative, the processor 102 sends the acquired breathing frequency value, heartbeat frequency value and danger signal to the server through the communication unit 104.

After the server receives the danger signal and the somatosensory data sent by the intelligent lamp, the server can also send the danger signal and the somatosensory data to a terminal of a guardian bound by the intelligent lamp, wherein the terminal can be an electronic device with data processing and displaying functions, such as an intelligent mobile phone, a tablet computer, a personal computer and the like. The guardian can see the state triggered by the prompt of the relevant application on the terminal interface, can also check the time of the occurrence of the abnormal event, the current respiratory frequency value and heartbeat frequency value of the monitored person by clicking to enter the application, and can also listen to the first compressed audio data to confirm whether the monitored person sends out a call for help or not.

In the embodiment, by arranging the voice unit, when the body of the person under guardianship is abnormal, the sent distress signal can be recorded by the voice unit and sent to the server through the communication unit, so that related medical personnel and guardians can judge the current actual condition of the person under guardianship more accurately, and a more effective rescue scheme can be formulated.

On the basis of the embodiment shown in fig. 3, fig. 4 is a schematic structural diagram of an intelligent lamp according to still another exemplary embodiment of the present invention. As shown in fig. 4, the present embodiment provides an intelligent lamp including: power supply unit 101, light source unit 103, processor 102, somatosensory monitoring sensor 105, communication unit 104, voice unit 106, and speaker 107.

The processor 102 is connected to the light source unit 103, the somatosensory monitoring sensor 105, the communication unit 104, the voice unit 106, and the speaker 107, and the power supply unit 101 is connected to the processor 102. The power supply unit 101 is connected to an external power supply, and is configured to supply power to the light source unit 103, the processor 102, the motion sensing monitoring sensor 105, the communication unit 104, the voice unit 106, and the speaker 107 in the smart lamp during operation. The light source unit 103 is used for lighting after being energized. The motion sensing monitoring sensor 105 is used for acquiring motion sensing data in a preset monitoring range and transmitting the acquired motion sensing data to the processor 102, after the processor 102 receives the motion sensing data sent by the motion sensing monitoring sensor 105, the processor 102 judges whether the motion sensing data is normal motion sensing data, and if not, the motion sensing data and danger signals are sent to the server through the communication unit 104.

The voice unit 106 is configured to acquire a first audio signal within a preset pickup range, transmit the acquired first audio signal to the processor 102, and in order to facilitate subsequent fast transmission, the processor 102 compresses the first audio signal to obtain first compressed audio data, and then sends the first compressed audio data to the server through the communication unit 104.

The communication unit 104 is further configured to receive second compressed audio data sent by the server, and transmit the second compressed audio data to the processor 102; and the second compressed audio data is uploaded to the server by the terminal. At this time, the processor 102 is further configured to decompress the second compressed audio data to obtain a second audio signal, and transmit the second audio signal to the speaker 107, so that the speaker 107 emits sound according to the second audio signal.

The speaker 107 may be in a state of being able to sound at any time, or the processor 102 may start the speaker 107 only when the processor 102 determines that the somatosensory data is abnormal somatosensory data, and turn off the speaker 107 after the speaker 107 sounds according to the second audio signal. In the actual using process, when the monitored person is in an abnormal condition, the terminal of the guardian receives first compressed audio data sent by the server, the data contains sound, particularly help seeking sound, emitted by the monitored person within a certain time, but in order to further confirm the actual situation on site or provide self-rescue guidance for the monitored person, the guardian can input a second audio signal through the terminal, the voice information can be uploaded to the server, and the server can further forward the second audio signal to the intelligent lamp, so that the loudspeaker 107 in the intelligent lamp emits sound according to the second audio signal, and the guardian can hear the inquiry or self-rescue guidance of the monitored person.

In addition, in order to improve the real-time performance of voice communication, so that a guardian and a person under guardianship can carry out real-time conversation, after the server receives the danger signal and the somatosensory data, the guardian can start a bidirectional voice channel with the intelligent lamp through the application of the terminal, and the guardian and the person under guardianship can carry out real-time conversation.

Fig. 5 is a schematic structural diagram of a somatosensory monitoring system according to an exemplary embodiment of the present invention. As shown in fig. 5, the somatosensory monitoring system provided by this embodiment includes: the intelligent lamp provided in any one of the embodiments of fig. 2-4, a server capable of two-way communication with the intelligent lamp, and a terminal capable of two-way communication with the server.

Fig. 6 is a schematic structural diagram of the terminal in the embodiment shown in fig. 5. In one possible design, the terminal includes: a terminal processor 201, a memory 202, a receiving module 203, a downloading module 204, a sound generating module 205 and a display module 206;

a receiving module 203, configured to receive a danger signal sent by a server;

the downloading module 204 is used for downloading the somatosensory data and the first compressed audio data from the server;

a memory 202 for storing somatosensory data and first compressed audio data;

the terminal processor 201 is configured to decompress the first compressed audio data and instruct the sound generation module 205 to generate sound according to the audio data decompressed by the first compressed audio data;

and the terminal processor 201 is further configured to instruct the display module 206 to display the somatosensory data.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (9)

1. A smart lamp, comprising: the system comprises a power supply unit, a light source unit, a processor, a somatosensory monitoring sensor and a communication unit;

the processor is respectively connected with the light source unit, the somatosensory monitoring sensor, the communication unit and the power supply unit;

the motion sensing monitoring sensor is used for acquiring motion sensing data in a preset monitoring range and transmitting the motion sensing data to the processor;

the processor is used for judging whether the somatosensory data is normal somatosensory data or not, and if not, the somatosensory data and the danger signal are sent to the server through the communication unit;

the intelligent lamp further comprises: the voice unit is connected with the processor;

the voice unit is used for acquiring a first audio signal in a preset pickup range and transmitting the first audio signal to the processor;

the processor is used for compressing the first audio signal to obtain first compressed audio data;

the communication unit is used for sending the first compressed audio data to the server;

when the processor judges that the somatosensory data is abnormal somatosensory data, the processor is further used for controlling the voice unit to start working and recording a first working duration of the voice unit, and when the first working duration is greater than or equal to a preset audio duration, the voice unit is controlled to stop working;

the voice unit is used for acquiring a first audio signal within a preset pickup range within the first duration, and transmitting the first audio signal to the processor.

2. The smart lamp of claim 1, further comprising: a speaker coupled to the processor;

the communication unit is further used for receiving second compressed audio data sent by the server and transmitting the second compressed audio data to the processor; the second compressed audio data is uploaded to the server by the terminal;

the processor is further configured to decompress second compressed audio data to obtain a second audio signal, and transmit the second audio signal to the speaker;

the loudspeaker is used for sounding according to the second audio signal.

3. The smart lamp of claim 2, wherein when the processor determines that the somatosensory data is abnormal somatosensory data, the processor is further configured to start the speaker and turn off the speaker after the speaker sounds according to the second audio signal.

4. The smart lamp of any of claims 1-3, wherein the somatosensory monitoring sensor is a microwave sensor, and wherein the somatosensory data comprises at least one of a breath frequency value and a heartbeat frequency value.

5. The intelligent lamp according to claim 4, wherein if the somatosensory data is the breath frequency value, the processor is configured to determine whether the breath frequency value is within a preset normal breath frequency value range, and if not, the processor sends the breath frequency value and the danger signal to the server through the communication unit;

if the somatosensory data is the heartbeat frequency value, the processor is used for judging whether the heartbeat frequency value is within a preset normal heartbeat frequency value range, and if not, the processor sends the heartbeat frequency value and the danger signal to a server through the communication unit.

6. The smart lamp of claim 4, wherein if the somatosensory data is the breathing frequency value and the heartbeat frequency value, the processor is specifically configured to determine whether the breathing frequency value is within a preset normal breathing frequency value range and whether the heartbeat frequency value is within a preset normal heartbeat frequency value range, and if at least one of the determination results is negative, the processor sends the breathing frequency value, the heartbeat frequency value, and the risk signal to a server through the communication unit.

7. The smart lamp of claim 1, wherein the light source unit is an LED light source and the communication unit is a wireless communication unit.

8. A somatosensory monitoring system comprising the smart lamp of any one of claims 1-7, a server in bidirectional communication with the smart lamp, and a terminal in bidirectional communication with the server.

9. The somatosensory monitoring system according to claim 8, wherein the terminal comprises: the system comprises a terminal processor, a memory, a receiving module, a downloading module, a sound production module and a display module;

the receiving module is used for receiving the danger signal sent by the server;

the downloading module is used for downloading the somatosensory data and the first compressed audio data from the server;

the memory is used for storing the somatosensory data and the first compressed audio data;

the terminal processor is used for decompressing the first compressed audio data and indicating the sound production module to produce sound according to the audio data decompressed by the first compressed audio data;

the terminal processor is further used for indicating the display module to display the somatosensory data.

Images