CN111865342B

CN111865342B - Detection device and intelligent wearable equipment

Info

Publication number: CN111865342B
Application number: CN202010648649.XA
Authority: CN
Inventors: 李晶; 王洪军; 周磊; 杜军红; 汤肖迅
Original assignee: Shanghai Longcheer Technology Co Ltd
Current assignee: Shanghai Longcheer Technology Co Ltd
Priority date: 2020-07-07
Filing date: 2020-07-07
Publication date: 2021-11-02
Anticipated expiration: 2040-07-07
Also published as: CN111865342A

Abstract

The invention provides a detection device and intelligent wearable equipment, comprising: the biological health data signal detection device is applied to biological health data signal detection of intelligent wearable equipment and comprises a plurality of signal transmitting units and signal receiving units; the signal transmitting unit is in discrete encapsulation; the signal receiving unit is in discrete encapsulation; the signal transmitting unit and the signal receiving unit are separated; wherein the number of each signal transmitting unit is 1 or more than 1; wherein the number of each signal receiving unit is 1 or more than 1. The detection device adopts a signal source separation type design, and the freedom degree of model selection of a receiving device is larger; the degree of freedom in the selection of the type of the emitting device is greater.

Description

Detection device and intelligent wearable equipment

Technical Field

The invention relates to the field of electronic products, in particular to a biological health data signal detection device applied to intelligent wearable equipment and the intelligent wearable equipment comprising the biological health data signal detection device.

Background

The development of the era, the progress of science and technology and the acceleration of life rhythm lead more and more people to pay attention to the real-time monitoring of self health data, and an intelligent health data detection system in wearable equipment is born at the mercy. Health data such as heart rate, blood oxygen, respiration, sleep, movement and the like are separated from the limits of medical institutions, and portable, real-time and noninvasive continuous monitoring is realized.

PhotoPlethysmoGraphy, PhotoPlethysmography (PPG) for short, is a noninvasive detection method for detecting blood volume change in living tissues by means of photoelectricity. When a light beam with a certain wavelength is irradiated on the skin surface, the light beam is transmitted to the photoelectric receiver in a transmission mode (figure 1) or a reflection mode (figure 2), in the process, the light intensity detected by the detector is attenuated due to the absorption of the skin, muscle and blood at the detection end. The green light skin has good absorptivity, is suitable for testing the blood flow of the skin, and generally uses a green light source as an input signal emission unit for heart rate testing; reduced hemoglobin (Hb) and oxygen and hemoglobin (SpO2) have opposite absorption properties for specific wavelengths of red light (around 660 nm) and infrared light (around 940 nm), and are generally used as input signal emitting units for blood oxygen tests. The test algorithms of other health data are evolved from the specific algorithms of the specific detection scenes of the two heart rate and blood oxygen data according to different detection items.

The arrangement of the detection units of the intelligent health detection equipment which is popular in the market is mostly divided into the following two forms:

as shown in fig. 3, the signal transmitting unit and the signal receiving unit are integrally packaged;

as shown in fig. 4, the signal transmitting unit and the signal receiving unit are separately packaged, and the signal transmitting unit is integrally packaged.

The signal transmitting and receiving units are integrally packaged, the related functions and appearance design freedom degree of the product is low, the individualized requirements of different products cannot be met, and the product gradually fades out of the market;

the signal transmitting and receiving units are integrally packaged, so that the requirement for difference of spatial distances between different signals and the signal receiving units cannot be met, or the degree of freedom of difference design of the spatial distances between different signal transmitting units and different signal receiving units is limited;

although the degree of freedom of design of the unit in which the signal transmitting unit and the signal receiving unit are separately packaged and the unit in which the signal transmitting unit is integrally packaged is higher than that of the former unit, the spatial arrangement forms of the signal transmitting unit and the signal receiving unit are more various; however, the signal transmitting units are still integrally packaged, and although miniaturization and integration are completed to a great extent, the signal transmitting units are mutually constrained, so that the maximum service performance, distribution freedom, stability and the like of a single body packaged independently cannot be achieved, and the disadvantages of poor disassembling and replacing performance and the like exist.

The integrated packaging and arrangement mode of the signal transmitting units limits the freedom degree of arrangement design of different signal transmitting units on the spatial position of the signal receiver;

as described above, the integrated packaging and arrangement manner of the signal transmitting units limits the degree of freedom in spatial position arrangement between each signal transmitting unit and the signal receiving unit, and cannot give consideration to spatial position arrangement with accurate relative output values required by the heart rate and blood oxygen algorithms under different structural environments, thereby affecting the accuracy of the heart rate and blood oxygen algorithms, further affecting the accuracy of health data of wearable equipment, further affecting user experience, and further affecting brand credibility;

as the signal transmitting unit is integrally packaged and arranged, the selectable unit models are relatively few due to high integration level and miniaturization degree;

as the signal transmitting unit is integrally packaged and arranged, due to the high integration level and miniaturization degree, the advanced processing and packaging technology is adopted, but the yield is not high, and then the price of the unit monomer is relatively high.

Disclosure of Invention

The technical problem to be solved by the invention is to provide a detection device, which can enable the freedom degree of the type selection of a transmitting device and a receiving device to be larger; the freedom degree of the distance design between the signal source and the receiver is larger; the algorithm accuracy of personalized equipment with different mechanisms, different performances, different appearances and the like is facilitated; the design of different individualized structure requirements, functional requirements and appearance requirements of different products is facilitated.

In order to solve the technical problems, the invention provides a detection device which is applied to biological health data signal detection of intelligent wearable equipment and comprises a plurality of signal transmitting units and signal receiving units; the signal transmitting unit is in discrete encapsulation; the signal receiving unit is in discrete encapsulation; the signal transmitting unit and the signal receiving unit are separated; wherein the number of each signal transmitting unit is 1 or more than 1; wherein the number of each signal receiving unit is 1 or more than 1.

The detection device has the beneficial effects that: by adopting the design of separating a signal source, the freedom degree of the type selection of a receiving device is larger; the freedom of the type selection of the emitting device is larger; the freedom degree of the distance design between the signal source and the receiver is larger; the freedom degree of distance design between the signal source and the receiver is larger, and the algorithm accuracy of personalized equipment with different mechanisms, different energy, different appearances and the like is facilitated; the design of different individualized structure requirements, functional requirements and appearance requirements of different products is facilitated.

Preferably, the number of the signal transmitting units is more than two packaging structures in a separated form; the signal transmitting units are of an integrated appearance packaging structure, different signal transmitting units are packaged independently, and the spatial arrangement distance size is larger than the minimum packaging size of the smallest single body; the number of the signal transmitting units is multiple, and the models of the signal transmitting units are the same or different; the number of the signal receiving units is multiple, and the models of the signal receiving units are the same or different.

Preferably, in order to ensure the diversity of the types and the possibility of the same or similar spatial arrangement among different signal sources, the possibility that any part of the signal emission sources arranged in a separated form can be packaged together by more than or equal to 2 signal sources is not excluded; the number of the signal sources is more than or equal to 3. Preferably, the receiving units of different signals are the same unit which can sense different signals, and the sensing sensitivity can be the same or different; and/or, wherein the receiving units of different signals are different units only sensing specific signals; and/or, wherein the receiving unit of different signals is a different unit which only senses the specific signal, and other signals are cut off; and/or the receiving units of different signals are different units only sensing specific signals, other signals are sensed in a differentiated mode, and effective signals with different health vital sign data are extracted according to different algorithms of different health data and different filtering modes.

Preferably, the outer surface of the package of each signal transmitting unit and/or signal receiving unit can be added with a unit capable of modulating the angle, intensity, phase and transmission time of the signal, and the unit comprises various optical lenses including a curved surface, an aspheric surface, a free-form surface, a paraboloid, a tread and a grating surface;

the outer surface of the package of each signal transmitting unit and/or signal receiving unit is added with a device with optical transmission property, which has the functions of signal transmission, human skin protection, package sealing and beauty.

Preferably, the signal transmission areas of the units of the wearable device distributed in the signal transmission unit separation mode are completely or incompletely blocked, or no blocking structures are arranged; wherein the thicknesses of the signal transmission areas of the units of the wearable equipment distributed in the signal transmission unit separation mode are the same or different; the wearable equipment applied to the signal transmitting unit separation mode distribution has a surface in the shape of a part contacting with the body surface, or various forms of curved surfaces for realizing accurate signal transmission and extraction; the thickness of the signal transmission area of each unit of the wearable device distributed in the signal transmission unit separation mode is 0 mm, or the thickness of accurate testing and engineering process realization is realized.

Preferably, the passing area of the transmitting signal or the receiving signal is a special structure with the intensity, direction or phase of the modulation signal; the signal passing area for transmitting signals or receiving signals is a structure capable of influencing the appearance or the function; the typical structure of the modulation signal intensity, direction, phase and appearance, which has special modulation function to the distribution of the transmitting and receiving signals, is the Fresnel lines of various design forms and appearance forms, or the structure with the same function; wherein the transmitting signal transmission area and the receiving signal transmission area of the wearable device distributed in the signal transmitting unit separation mode are made of the same or different materials; wherein the material of the transmitting signal transmission area and the material of the receiving signal transmission area of the wearable device distributed in a separation mode of the signal transmitting unit are all materials which can effectively and selectively pass through or pass through completely; wherein, the materials applied to each transmitting signal transmission area of the wearable device distributed in the signal transmitting unit separation mode can be all materials which are processed and used in an engineering way; the materials of the transmission areas of the received signals of the wearable equipment distributed in the signal transmitting unit separation mode are all engineering processed and used materials which ensure that the data signals carrying various biological health sign information selectively pass or completely pass.

Preferably, the safe distance between the signal transmitting unit and the signal receiving unit and the signal transmission unit, between the signal transmitting unit and the signal receiving unit and between the signal receiving unit and the signal transmitting unit and between the signal transmitting unit and the signal receiving unit and between the signal transmitting unit and between the signal receiving unit and the signal transmitting unit; the wearing distance between the wearable device and the body surface of the living being is 0 mm or the distance for realizing reliable testing of health data.

Preferably, any spatial arrangement of the wearable device is suitable for multiple structural forms; the arbitrary spatial arrangement of the wearable device is suitable for various supporting structures, various fixing structures, various light blocking structures, and various functional or appearance units; the random spatial arrangement of the wearable equipment is suitable for a data processing method, an algorithm, an effective data extraction method and an effective data filtering method of various health data.

The invention also provides intelligent wearable equipment comprising the detection device.

The intelligent wearable equipment has the beneficial effects that: by adopting the design of separating a signal source, the freedom degree of the type selection of a receiving device is larger; the freedom of the type selection of the emitting device is larger; the freedom degree of the distance design between the signal source and the receiver is larger; the freedom degree of distance design between the signal source and the receiver is larger, and the algorithm accuracy of personalized equipment with different mechanisms, different energy, different appearances and the like is facilitated; the design of different individualized structure requirements, functional requirements and appearance requirements of different products is facilitated.

Drawings

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

FIG. 1 is a schematic diagram of a transmission mode of a conventional photoplethysmography method;

FIG. 2 is a diagram of a reflection method of conventional photoplethysmography;

FIG. 3 is a schematic diagram of a conventional signal transmitting unit and a signal receiving unit packaged together;

FIG. 4 is a schematic diagram of a conventional signal transmitting unit and a signal receiving unit separately packaged and a signal transmitting unit integrally packaged;

FIG. 5 is a schematic view of the detecting device of the present invention.

The various reference numbers in the figures:

100. the device comprises a device shell 101, a signal transmitting unit 102, a signal receiving unit 103 and an integrated packaging shell.

Detailed Description

The first embodiment,

The invention relates to a detection device, the concrete structure is shown in figure 5, comprising: the detection device is applied to biological health data signal detection of the intelligent wearable equipment and comprises a plurality of signal transmitting units and signal receiving units; the signal transmitting unit is in discrete encapsulation; the signal receiving unit is in discrete encapsulation; the signal transmitting unit and the signal receiving unit are separated; wherein the number of each signal transmitting unit is 1 or more than 1; wherein the number of each signal receiving unit is 1 or more than 1.

The number of the signal transmitting units is more than two packaging structures in a separated form; the signal transmitting units are of an integrated appearance packaging structure, different signal transmitting units are packaged independently, and the spatial arrangement distance size is larger than the minimum packaging size of the smallest single body; the number of the signal transmitting units is multiple, and the models of the signal transmitting units are the same or different; the number of the signal receiving units is multiple, and the models of the signal receiving units are the same or different.

In order to ensure the diversity of the type selection and the possibility of the same or similar spatial arrangement among different signal sources, the possibility that any part of the signal emission sources arranged in a separated form can be packaged together by more than or equal to 2 signal sources is not excluded; the number of the signal sources is more than or equal to 3. Any part of the signal transmitting units arranged in a separation mode is packaged together by more than or equal to 2 signal transmitting units; the number of the signal transmitting units is more than or equal to 3.

The receiving units of different signals are the same unit which can sense different signals, and the sensing sensitivity can be the same or different; and/or, wherein the receiving units of different signals are different units only sensing specific signals; and/or, wherein the receiving unit of different signals is a different unit which only senses the specific signal, and other signals are cut off; and/or the receiving units of different signals are different units only sensing specific signals, other signals are sensed in a differentiated mode, and effective signals with different health vital sign data are extracted according to different algorithms of different health data and different filtering modes.

The outer surface of the package of each signal transmitting unit and/or signal receiving unit can be added with a unit capable of modulating signal angle, intensity, phase and transmission time, and the unit comprises various optical lenses with curved surfaces, aspheric surfaces, free-form surfaces, paraboloids, tire treads and grating surfaces;

Wherein the signal transmission area of each unit of the wearable device distributed in the signal transmission unit separation mode is completely or incompletely blocked, or has no blocking structure; wherein the thicknesses of the signal transmission areas of the units of the wearable equipment distributed in the signal transmission unit separation mode are the same or different; the wearable equipment applied to the signal transmitting unit separation mode distribution has a surface in the shape of a part contacting with the body surface, or various forms of curved surfaces for realizing accurate signal transmission and extraction; the thickness of the signal transmission area of each unit of the wearable device distributed in the signal transmission unit separation mode is 0 mm, or the thickness of accurate testing and engineering process realization is realized.

The passing area of the transmitting signal or the receiving signal is a special structure with the intensity, the direction or the phase of the modulation signal; the signal passing area for transmitting signals or receiving signals is a structure capable of influencing the appearance or the function; the typical structure of the modulation signal intensity, direction, phase and appearance, which has special modulation function to the distribution of the transmitting and receiving signals, is the Fresnel lines of various design forms and appearance forms, or the structure with the same function; wherein the transmitting signal transmission area and the receiving signal transmission area of the wearable device distributed in the signal transmitting unit separation mode are made of the same or different materials; wherein the material of the transmitting signal transmission area and the material of the receiving signal transmission area of the wearable device distributed in a separation mode of the signal transmitting unit are all materials which can effectively and selectively pass through or pass through completely; wherein, the materials applied to each transmitting signal transmission area of the wearable device distributed in the signal transmitting unit separation mode can be all materials which are processed and used in an engineering way; all materials engineered and used for various purposes to ensure that the transmitted signal data is effectively distributed in the biological tissue; the materials of the transmission areas of the received signals of the wearable equipment distributed in the signal transmitting unit separation mode are all engineering processed and used materials which ensure that the data signals carrying various biological health sign information selectively pass or completely pass.

The safe distance between the signal transmitting unit and the signal receiving unit and the signal transmitting unit and between the signal transmitting unit and the signal receiving unit and between the signal transmitting unit and between the signal receiving unit and the signal transmitting unit and the signal receiving unit; the wearing distance between the wearable device and the body surface of the living being is 0 mm or the distance for realizing reliable testing of health data.

Any spatial arrangement of the wearable device is suitable for various structural forms; the arbitrary spatial arrangement of the wearable device is suitable for various supporting structures, various fixing structures, various light blocking structures, and various functional or appearance units; the random spatial arrangement of the wearable equipment is suitable for a data processing method, an algorithm, an effective data extraction method and an effective data filtering method of various health data.

In order to meet the accurate measurement of health data such as heart rate, blood oxygen and the like on wearable equipment with different structural designs and appearance designs, different spatial arrangements of a signal transmitting unit and a signal receiving unit need to be met;

in order to meet the accurate measurement of health data such as heart rate, blood oxygen and the like on wearable equipment with different structural designs and appearance designs, different spatial arrangements of transmitting units and different signal receiving units of different signals need to be met;

the receiving units of different signals can be the same unit which can sense different signals, and the sensitivity of sensing can be the same or different;

the receiving units of different signals can be different units only sensing specific signals;

the receiving units of different signals can be different units only sensing specific signals, and other signals can be cut off;

the receiving units of different signals can be different units only sensing specific signals, other signals can be sensed in a differentiated mode, and effective signal data can be extracted according to different algorithms of different health data and different filtering modes;

a method for arranging heart rate blood oxygen detecting units in a novel signal emitting unit separation mode applied to wearable equipment is shown in figure 5.

The number of the signal transmitting units is more than two packaging structures in a separated form;

the signal transmitting units can be of an integrated appearance packaging structure, but different signal transmitting units are packaged independently, and the spatial arrangement distance is larger than the minimum packaging size of the smallest single body;

the number of each signal transmitting unit can be 1 or more;

the number of the signal receiving units of each signal can be 1 or more;

if the number of the signal transmitting units is more than 1, the model selection of each signal transmitting unit can be the same or different;

if there are more than 1 signal receiving units, the type selection of the signal receiving units can be the same or different;

in order to ensure the diversity of the types and the possibility of the same or similar spatial arrangement among different signal transmitting units, the possibility that any part of the signal transmitting units arranged in a separated form can be packaged together by more than or equal to 2 signal transmitting units is not excluded; the number of the signal transmitting units is more than or equal to 3;

in order to meet free space arrangement between different signals and signal receiving units, the possibility that a plurality of signal transmitting units are integrally packaged is not excluded, but effective signal transmitting units of different health data selectively transmit or are selectively used according to different space arrangement positions, so that the same use effect of free space arrangement of different signal transmitting unit units in separation packaging can be achieved;

the receiving units of different signals can be different units only sensing specific signals, other signals can be sensed in a differentiated mode, filtering modes are different according to different algorithms of different health data, and effective signals with different health vital sign data are extracted;

the outer surface of the package of each signal transmitting unit can be added with special units which can modulate signal angle, intensity, phase, transmission time and the like, such as various optical lenses containing curved surfaces, aspheric surfaces, free-form surfaces, paraboloids, tire treads and grating surfaces;

the outer surface of the package of each signal receiving unit can be added with special units which can modulate signal angle, intensity, phase transmission time and the like, such as various optical lenses containing curved surfaces, aspheric surfaces, free-form surfaces, paraboloids, tire treads and grating surfaces;

wherein the signal transmission area applied to each unit of the wearable device distributed in the signal transmission unit separation mode can be completely or incompletely blocked, or has no blocking structure;

the thicknesses of the signal transmission areas applied to the units of the wearable equipment distributed in the signal transmission unit separation mode can be the same or different;

the shape of the contact part of the wearable equipment applied to the signal transmitting unit separation mode distribution and the body surface can be a plane or any curved surface in various forms capable of realizing accurate signal transmission and extraction;

the thickness of a signal transmission area applied to each unit of the wearable equipment distributed in the signal transmission unit separation mode is 0 mm, or other thicknesses which can realize accurate test and engineering process;

the passing area of the transmitting signal or the receiving signal can be a special structure with the intensity, direction or phase of the modulated signal;

the signal passing area for transmitting or receiving a signal as described above may be a special structure that can affect the appearance or function;

the typical structure which can modulate the signal intensity, direction, phase and appearance and has special modulation function on the distribution of the transmitting and receiving signals is a Fresnel line with various design forms and appearance forms or other special structures with the same function;

the materials of the transmitting signal transmission area and the receiving signal transmission area of the wearable device which are applied to the signal transmitting unit separation mode distribution can be the same or different;

the material of the transmitting signal transmission area and the material of the receiving signal transmission area of the wearable device which are applied to the signal transmitting unit separation mode distribution can be all materials which can effectively and selectively pass through or pass through completely respectively;

the materials of the transmission signal transmission areas of the wearable equipment which are applied to the signal transmission unit separation mode distribution can be all materials which can ensure that the transmission signal data can be effectively distributed in the biological tissue and can be engineered and used;

the materials applied to the transmission areas of the receiving signals of the wearable equipment distributed in the signal transmitting unit separation mode are all materials which can ensure that data signals carrying various biological health sign information can selectively pass through or all pass through and can be processed and used in an engineering mode;

the safe distance between the test function unit applied to the wearable device distributed in the signal transmitting unit separation mode and other units such as the signal transmitting unit, the signal receiving unit, the mechanism shell, even the biological body surface and the like can be 0 mm, or the safe distance considering other factors such as unit tolerance, assembly tolerance, detachability factor and the like;

the wearing distance between the wearable device and the biological body surface can be 0 mm or other distances for realizing reliable test of health data;

any spatial arrangement of the wearable equipment with the signal transmitting units distributed in a separated mode can also be suitable for various structural forms;

any spatial arrangement of the wearable equipment distributed in the signal transmitting unit separation mode can also be suitable for various functional or appearance units such as various supporting structures, various fixing structures, various light blocking structures and the like;

any spatial arrangement of wearable devices distributed in different signal transmitting unit separation modes can be suitable for data processing methods, algorithms, effective data extraction methods, effective data filtering methods and the like of various health data.

Example II,

The intelligent wearable device can be various electronic products needing health data detection, such as an intelligent watch, an intelligent bracelet and the like.

The invention is not limited to the embodiments discussed above. The foregoing description of the specific embodiments is intended to describe and explain the principles of the invention. Obvious modifications or alterations based on the teachings of the present invention should also be considered as falling within the scope of the present invention. The foregoing detailed description is provided to disclose the best mode of practicing the invention, and also to enable a person skilled in the art to utilize the invention in various embodiments and with various alternatives for carrying out the invention.

Claims

1. A detection device is applied to biological health data signal detection of intelligent wearable equipment,

the device is characterized by comprising a plurality of signal transmitting units and signal receiving units;

the signal transmitting unit is in discrete encapsulation;

the signal receiving unit is in discrete encapsulation;

the signal transmitting unit and the signal receiving unit are separated;

wherein the number of each signal transmitting unit is 1 or more than 1;

wherein the number of each signal receiving unit is 1 or more than 1;

any part of the signal emission sources arranged in a separation mode is packaged together by more than or equal to 2 signal sources; the number of the signal sources is more than or equal to 3;

the receiving units of different signals are the same unit which can sense different signals, and the sensing sensitivity can be the same or different;

and/or, wherein the receiving units of different signals are different units only sensing specific signals;

and/or, wherein the receiving unit of different signals is a different unit which only senses the specific signal, and other signals are cut off;

and/or the receiving units of different signals are different units only sensing specific signals, other signals are sensed in a differentiated mode, and effective signals with different health vital sign data are extracted according to different algorithms of different health data and different filtering modes.

2. The detection apparatus of claim 1,

the signal transmitting units are of an appearance packaging structure in an integrated form, different signal transmitting units are packaged independently, and the spatial arrangement distance is larger than the minimum packaging size of the minimum single body;

the number of the signal transmitting units is multiple, and the models of the signal transmitting units are the same or different;

the number of the signal receiving units is multiple, and the models of the signal receiving units are the same or different.

3. The detecting device for detecting the rotation of a motor rotor according to claim 1, wherein the outer surface of the package of each signal transmitting unit and/or signal receiving unit can be added with units capable of modulating the angle, the intensity, the phase and the transmission time of signals, and the units comprise various optical lenses comprising curved surfaces, aspheric surfaces, paraboloids, treads and grating surfaces;

wherein the outer surface of the package of each signal transmitting unit and/or signal receiving unit is attached with a device with optical transmission property for signal transmission, human skin protection, package sealing, and appearance_。

4. The detecting device for detecting the rotation of a motor rotor as claimed in claim 1, wherein the signal transmission areas applied to the units of the wearable device distributed in the way of separating the signal transmitting units are completely or incompletely blocked, or have no blocking structures;

wherein the thicknesses of the signal transmission areas of the units of the wearable equipment distributed in the signal transmission unit separation mode are the same or different;

the wearable equipment applied to the signal transmitting unit separation mode distribution has a surface in the shape of a part contacting with the body surface, or various forms of curved surfaces for realizing accurate signal transmission and extraction;

the thickness of the signal transmission area of each unit of the wearable device distributed in the signal transmission unit separation mode is 0 mm, or the thickness of accurate testing and engineering process realization is realized.

5. The detection apparatus of claim 1,

the passing area of the transmitting signal or the receiving signal is a special structure with the intensity, direction or phase of the modulation signal;

the signal passing area of the transmitting signal or the receiving signal is a structure capable of influencing the appearance or the function;

the typical structure of the modulation signal intensity, direction, phase and appearance, which has special modulation function to the distribution of the transmitting and receiving signals, is the Fresnel lines of various design forms and appearance forms, or the structure with the same function;

wherein the transmitting signal transmission area and the receiving signal transmission area of the wearable device distributed in the signal transmitting unit separation mode are made of the same or different materials;

wherein, the material of the transmitting signal transmission area and the material of the receiving signal transmission area of the wearable device distributed in a separation mode of the signal transmitting unit are all the materials which can effectively and selectively pass through or completely pass through respectively;

the material applied to each transmitting signal transmission area of the wearable device distributed in the signal transmitting unit separation mode is all materials which can ensure that transmitting signal data are effectively distributed in the biological tissue and can be processed and used in an engineering way;

the materials of the transmission areas of the received signals of the wearable equipment distributed in the signal transmitting unit separation mode are all engineering processed and used materials which ensure that the data signals carrying various biological health sign information selectively pass or completely pass.

6. The detecting device for detecting the rotation of a motor rotor according to claim 4, wherein the safe distance between the signal transmitting unit and the signal receiving unit and the signal transmission area, the housing and the biological body surface is 0 mm or the safe distance considering unit tolerance, assembly tolerance and disassembly factor;

the wearing distance between the wearable device and the body surface of the living being is 0 mm or the distance for realizing reliable testing of health data.

7. The detection apparatus of claim 1,

any spatial arrangement of the wearable device is suitable for various structural forms;

the arbitrary spatial arrangement of the wearable device is suitable for various supporting structures, various fixing structures, various light blocking structures, and various functional or appearance units;

the random spatial arrangement of the wearable equipment is suitable for data processing methods of various health data.

8. An intelligent wearable device, characterized by comprising the detection apparatus of any one of claims 1-7.