CN115005832A - Wearable equipment of intelligence - Google Patents

Abstract

The invention provides intelligent wearable equipment, which comprises a human body parameter detection module, a trigger detection module and a main control module, wherein the human body parameter detection module comprises a parameter processing module and an M individual sign electrode plate; one or more sign electrode plates in the M sign electrode plates form at least one trigger electrode plate group, and each trigger electrode plate group is matched with one target detection parameter; the number of target detection parameters is at least one; the main control module is respectively and electrically connected with the parameter processing module and the trigger detection module. The invention aims to improve the convenience of a user for measuring the human body parameters by using the intelligent wearable equipment.

Description

Wearable equipment of intelligence

Technical Field

The invention relates to the technical field of intelligent wearable equipment, in particular to intelligent wearable equipment.

Background

Along with the development of the intelligent electronic industry, the intelligent wearable equipment is popular among users of all ages because of powerful functions and convenience in carrying.

At present, wearable equipment has extremely strong health attribute, and the health detection function that can support is also more and more. With the increase of health functions, the operation steps of the user for detecting the health functions are more complicated, multiple operations are usually needed to enter the corresponding human health detection interface and perform corresponding human health detection through the wearable device, and the user is very complicated and inconvenient to use.

Disclosure of Invention

The invention mainly aims to provide an intelligent wearable device, aiming at improving the convenience of a user for measuring human body parameters by using the intelligent wearable device.

In order to achieve the above object, the present invention provides a smart wearable device, including:

the human body parameter detection module comprises a parameter processing module and M individual characteristic electrode plates electrically connected with the parameter processing module, and the electrode plates are used for collecting and outputting human body bioelectricity signals; wherein M is greater than or equal to 2; one or more sign electrode slices in the M sign electrode slices form at least one trigger electrode slice group, and each trigger electrode slice group is matched with one target detection parameter; the number of the target detection parameters is at least one;

the trigger detection module is used for outputting a corresponding trigger signal when detecting that any trigger electrode plate group is triggered by a user;

the main control module is respectively and electrically connected with the parameter processing module and the trigger detection module, and is used for determining the corresponding target detection parameters according to the received trigger signals and controlling the parameter processing module to output the human body parameter detection signals corresponding to the target detection parameters according to at least one human body bioelectricity signal.

Optionally, the smart wearable device further includes: the M sign electrode plates are respectively arranged on a non-contact position and a contact position on the equipment main body; the trigger detection module includes: the N pressure detection modules are respectively and electrically connected with the main control module, and are in one-to-one corresponding close arrangement with at least one sign electrode plate arranged on the non-contact position; wherein M is greater than or equal to N;

the pressure detection module is used for detecting the pressure born by the sign electrode plate correspondingly arranged and outputting a corresponding pressure detection signal;

the main control module is used for determining the corresponding target detection parameter when the pressure born by the corresponding sign electrode plate is determined to be greater than the preset pressure according to at least one pressure detection signal, controlling the parameter processing module to determine the human body parameter corresponding to the target detection parameter according to the plurality of human body bioelectricity signals, and outputting the corresponding human body parameter detection signal.

Optionally, the target detection parameter includes at least one of an electrocardiographic parameter, an EDA parameter, and a human body composition parameter.

Optionally, the main control module is further configured to determine, according to at least one of the pressure detection signals, a corresponding target detection parameter when a duration that the pressure applied to the corresponding sign electrode plate is greater than a preset pressure reaches a preset duration, control the parameter processing module to determine, according to the plurality of human body bioelectrical signals, a human body parameter corresponding to the target detection parameter, and output a corresponding human body parameter detection signal.

Optionally, a circuit board is arranged in the device main body, N pressure detection modules are arranged on the circuit board, and a silicone piece is further arranged between the pressure detection modules and the positions, corresponding to the sign electrode plates, on the non-contact positions.

Optionally, the sign electrode plates correspondingly arranged to the pressure detection module are electrically connected to the circuit board through connectors.

Optionally, the parameter processing module includes: the electrocardio parameter module is electrically connected with the main control module;

the M sign electrode plates comprise a first finger electrode plate, a first skin electrode plate and a second skin electrode plate, and the first finger electrode plate, the first skin electrode plate and the second skin electrode plate are respectively and electrically connected with the electrocardio parameter module;

the trigger detection module is used for outputting an electrocardio trigger signal when detecting that the first finger electrode piece is triggered by a user;

the main control module is used for determining the target detection parameter as an electrocardio parameter when receiving the electrocardio trigger signal, controlling the electrocardio parameter module to determine the electrocardio parameter of the user according to a plurality of human body bioelectricity signals acquired by the first finger electrode plate, the first skin electrode plate and the second skin electrode plate, and outputting a corresponding human body parameter detection signal;

and/or the presence of a gas in the gas,

the parameter processing module comprises: the EDA parameter module is electrically connected with the main control module;

the M sign electrode plates comprise a second finger electrode plate, a third skin electrode plate and a fourth skin electrode plate, and the second finger electrode plate, the third skin electrode plate and the fourth skin electrode plate are respectively and electrically connected with the EDA parameter module;

the trigger detection module is used for outputting an EDA trigger signal when detecting that the second finger electrode plate is triggered by a user;

the main control module is used for determining the target detection parameters as EDA parameters when receiving the EDA trigger signals, controlling the EDA parameter module to determine the EDA parameters of the user according to the plurality of human body bioelectricity signals collected by the third skin electrode plate and the fourth skin electrode plate, and outputting corresponding human body parameter detection signals;

and/or the presence of a gas in the gas,

the parameter processing module further comprises: the human body composition parameter module is electrically connected with the main control module;

m sign electrode slice includes: a third finger electrode pad, a fourth finger electrode pad, a fifth skin electrode pad and a sixth skin electrode pad; the human body composition parameter module is electrically connected with the third finger electrode plate, the fourth finger electrode plate, the fifth skin electrode plate and the sixth skin electrode plate respectively;

the trigger detection module is further configured to output a human body component trigger signal when detecting that the third finger electrode pad and the fourth finger electrode pad are both triggered by a user;

the main control module is further configured to determine that the target detection parameter is a human body composition parameter when the human body composition trigger signal is received, control the human body composition parameter module to determine the human body composition parameter of the user according to a plurality of human body bioelectrical signals acquired by the third finger electrode pad, the fourth finger electrode pad, the fifth skin electrode pad and the sixth skin electrode pad, and output a corresponding human body parameter detection signal.

Optionally, when the parameter processing module includes the electrocardiographic parameter module and the EDA parameter module, the first skin electrode pad and the third skin electrode pad are the same sign electrode pad, and the second skin electrode pad and the fourth skin electrode pad are the same sign electrode pad;

when the parameter processing module comprises the electrocardio parameter module and the human body composition parameter module, the third finger electrode plate and the first finger electrode plate are the same sign electrode plate; the fifth skin electrode plate and the first skin electrode plate are the same sign electrode plate; the sixth skin electrode plate and the second skin electrode plate are the same sign electrode plate.

Optionally, when the parameter processing module includes the EDA parameter module and the human body composition parameter module, the second finger electrode pad and the third finger electrode pad are the same sign electrode pad; the third skin electrode plate and the fifth skin electrode plate are the same sign electrode plate; the fourth skin electrode plate and the sixth skin electrode plate are the same sign electrode plate.

Optionally, when the parameter processing module includes the electrocardiographic parameter module, the body composition parameter module, and the EDA parameter module, the first finger electrode pad and the third finger electrode pad are the same sign electrode pad; the second finger electrode plate and the fourth finger electrode plate are the same sign electrode plate; the first skin electrode pad, the third skin electrode pad and the fifth skin electrode pad are the same sign electrode pad; the second skin electrode plate, the fourth skin electrode plate and the sixth skin electrode plate are the same sign electrode plate.

The intelligent wearable device comprises a human body parameter detection module, a trigger detection module and a main control module. The human body parameter detection module comprises a parameter processing module and M individual sign electrode plates electrically connected with the parameter processing module, and the electrode plates are used for collecting and outputting human body bioelectricity signals; one or more sign electrode plates in the M sign electrode plates form a trigger electrode plate group, and each trigger electrode plate group is matched with one target detection parameter; the number of target detection parameters is at least one; the trigger detection module is used for outputting a corresponding trigger signal when detecting that any trigger electrode plate group is triggered by a user; the main control module is used for determining corresponding target detection parameters according to the received trigger signals and controlling the parameter processing module to output human body parameter detection signals corresponding to the target detection parameters according to at least one human body bioelectricity signal. Therefore, in practical application, if a user wants to measure a certain human body parameter, the main control module can control the corresponding parameter processing module in the human body detection module to perform corresponding detection only by directly triggering the triggering electrode plate group corresponding to the target detection parameter in the human body parameter detection module, so that the current human body parameter corresponding to the target detection parameter is directly determined, the result is directly indicated to the user, the user does not need to perform complex menu operation on the intelligent wearable device to enter a corresponding detection interface, and the convenience of the user in measuring the human body parameter by using the intelligent wearable device is improved. Meanwhile, when the human body detection module detects human body parameters, the physical sign electrode plates included in the human body detection module need to be triggered by a user to collect human body bioelectricity signals of the user. Therefore, the appearance shape of the original intelligent wearable device can not be changed, a new shell does not need to be designed again, the upgrading cost of the product is reduced, and the production efficiency is improved.

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, 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 the structures shown in the drawings without creative efforts.

Fig. 1 is a schematic diagram of functional modules of an embodiment of a smart wearable device according to the invention;

fig. 2 is a schematic structural diagram of an embodiment of the smart wearable device according to the present invention;

fig. 3 is a schematic structural diagram of another embodiment of the smart wearable device according to the present invention;

fig. 4 is a schematic structural diagram of another embodiment of the smart wearable device of the present invention;

FIG. 5 is a functional block diagram of another embodiment of a smart wearable device of the present invention;

fig. 6 is a functional module diagram of another embodiment of the smart wearable device of the present invention;

fig. 7 is a functional block diagram of another embodiment of the smart wearable device according to the present invention.

The reference numbers illustrate:

the implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

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.

It should be noted that all the directional indicators (such as up, down, left, right, front, and rear … …) in the embodiment of the present invention are only used to explain the relative position relationship between the components, the movement situation, etc. in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indicator is changed accordingly.

In the present invention, unless otherwise expressly stated or limited, the terms "connected," "secured," and the like are to be construed broadly, and for example, "secured" may be a fixed connection, a removable connection, or an integral part; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In addition, the descriptions related to "first", "second", etc. in the present invention are only for descriptive purposes and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

Along with the development of the intelligent electronic industry, the intelligent wearable equipment is popular among users of all ages because of powerful functions and convenience in carrying. However, the existing smart wearable device generally can only locate the smart wearable device itself, and cannot provide additional location services, particularly cannot selectively locate a specific target.

To this end, the present invention provides a smart wearable device, and in an embodiment of the present invention, with reference to fig. 1, the smart wearable device includes:

the human body parameter detection module 10 comprises a parameter processing module 12 and M individual characteristic electrode plates 11 electrically connected with the parameter processing module 12; the physical sign electrode plate 11 is used for collecting and outputting human body bioelectricity signals; wherein M is greater than or equal to 2; one or more sign electrode plates of the M sign electrode plates 11 form at least one trigger electrode plate group, and each trigger electrode plate group is matched with one target detection parameter; the number of target detection parameters is at least one;

the trigger detection module 20, the trigger detection module 20 is configured to output a corresponding trigger signal when detecting that any trigger electrode plate set is triggered by a user;

the main control module 30, the main control module 30 is electrically connected to the parameter processing module 12 and the trigger detection module 20, respectively, and the main control module 30 is configured to determine a target detection parameter according to the received trigger signal, and control the parameter processing module 12 to output a human parameter detection signal corresponding to the target detection parameter according to at least one human bioelectricity signal.

It can be appreciated that the smart wearable device can be a smart watch, a smart bracelet, or the like. In this embodiment, the number of the parameter processing modules may be at least one, for example, "electrocardiographic parameter processing module, emotional parameter processing module, body fat parameter processing module, etc.," and the corresponding target detection parameter may also be at least one, for example, "electrocardiographic parameter, EDA parameter, body composition parameter, etc. The plurality of sign electrode slices 11 can be respectively electrically connected with the plurality of parameter modules, so that when a user wears the intelligent wearable device, each parameter processing module can acquire different human parameters of the user according to the human bioelectricity signals acquired and output by the plurality of sign electrode slices 11, for example, electrocardio, emotion, body fat, weight and the like of the human body.

In this embodiment, the material of the sign electrode sheet 11 may be a metal material, such as stainless steel, or a non-metal material may be used to implement a metal plating layer made on glass or sapphire, or a conductive ceramic material.

In this embodiment, one or more sign electrode slices 11 of the M sign electrode slices 11 constitute one trigger electrode slice group, and each trigger electrode slice group matches one target detection parameter, for example, the current sign electrode slice has a first finger electrode slice, a second finger electrode slice, a first skin electrode slice and a second skin electrode slice, the first finger electrode slice is a first trigger electrode slice group, and the corresponding target detection parameter is an ECG parameter; the second finger electrode plate is a second trigger electrode plate group, and the corresponding target detection parameter is an EDA parameter. When the user triggers the first trigger electrode plate set, i.e. triggers the first finger electrode plate, the trigger detection module 20 outputs a trigger signal corresponding to the ECG parameter to the main control module, so that the main control module confirms that the current target detection parameter is the ECG parameter.

In this embodiment, the main control module 30 may be implemented by an MCU (micro controller unit), a DSP (Digital Signal processor), an FPGA (Field Programmable Gate Array), or the like.

Alternatively, in this embodiment, the trigger detection module 20 may be implemented by a touch detection method, namely, the touch detection module is adopted to realize, the touch detection module can be electrically connected with the sign electrode plate 11 which is not in direct contact with the skin of the user in the wearable device, when a user touches any sign electrode plate 11 corresponding to any trigger electrode plate group with a body, such as a finger of a non-wearing hand, the touch detection module can output a corresponding touch detection signal, so that the main control module 30 can determine the currently touched physical sign electrode plate 11, and can determine the touched physical sign electrode plate 11 in a table look-up manner, namely the target detection parameters corresponding to the triggered trigger electrode plate group, so as to determine the target detection parameters required to be detected by the current user, and controls the corresponding parameter processing module 12 to perform corresponding detection work, and outputs a human body parameter detection signal corresponding to the target detection parameter. So, need not to change the structure of original intelligent wearable equipment, only need correspond the sign electrode slice 11's that needs carry out touch detection at intelligent wearable equipment position and be provided with the spring, just can realize the touch detection of user to the electrode slice, the structure is comparatively simple and the production efficiency of equipment has been improved.

Optionally, in another embodiment, the trigger detection module 20 may be implemented by using a pressure detection mode, that is, by using the pressure detection module 21, and the pressure detection module 21 may be disposed in close contact with the sign electrode pad 11 of the wearable device, which is not in direct contact with the skin of the user. The pressure detection module 21 detects the pressure applied to the sign electrode sheet 11 tightly attached to the pressure detection module, and outputs a corresponding pressure detection signal to the main control module 30, when a user presses on the sign electrode sheet 11 corresponding to any trigger electrode sheet group with a body, such as a finger, the main control module 30 can determine which sign electrode sheet 11 is currently pressed according to the pressure value represented by the pressure detection signal, i.e., determine which trigger electrode sheet group is currently triggered, and also can determine the target detection parameter corresponding to the triggered trigger electrode sheet group in a table look-up manner, so as to determine the target detection parameter required to be detected by the current user, and control the corresponding parameter processing module 12 to complete the same process as the above embodiment. So, through the mode that adopts pressure detection, whether the current human detection module of detection that can be more accurate is triggered by the user, has guaranteed accuracy and the reliability that intelligent wearable equipment detected.

It can be understood that, a display module may be further disposed in the intelligent wearable device, and after the main control module 30 determines the human parameter detection result after receiving the human parameter detection signal corresponding to the target detection parameter output by the parameter processing module 12, the display module may be directly controlled to display the result so that the user can directly know the current human parameter detection result to be detected after the trigger electrode plate set corresponding to the target detection parameter.

Optionally, in another embodiment, a communication module may be further disposed in the intelligent wearable device, the communication module may establish a connection with the intelligent terminal of the user through bluetooth, WIFI, a local area network, 4G/5G, and after the main control module 30 receives the human parameter detection signal corresponding to the target detection parameter and output by the human parameter detection module 10, the human parameter detection signal may be directly uploaded to the intelligent terminal of the user through the communication module, so as to display a current detection result on the intelligent terminal of the user. Therefore, in practical application, if a user wants to measure a human body parameter, the main control module 30 can control the parameter processing module 12 to perform corresponding detection only by directly triggering the trigger electrode plate group corresponding to the target detection parameter, and directly indicate the result to the user, so that the user does not need to perform complicated menu operation on the intelligent wearable device to enter a corresponding detection interface, and convenience of the user in measuring the human body parameter by using the intelligent wearable device is improved.

The intelligent wearable device comprises a human body parameter detection module 10, a trigger detection module 20 and a main control module 30. The human body parameter detection module 10 comprises a parameter processing module 12 and M individual characteristic electrode plates 11 electrically connected with the parameter processing module 12, wherein the electrode plates are used for collecting and outputting human body bioelectricity signals; one or more sign electrode plates 11 in the M sign electrode plates 11 form a trigger electrode plate group, and each trigger electrode plate group is matched with one target detection parameter; the number of target detection parameters is at least one; the trigger detection module 20 is configured to output a corresponding trigger signal when detecting that any trigger electrode plate set is triggered by a user; the main control module 30 is configured to determine a corresponding target detection parameter according to the received trigger signal, and control the parameter processing module 12 to output a human parameter detection signal corresponding to the target detection parameter according to at least one human bioelectric signal. Thus, in practical application, if a user wants to measure a certain human body parameter, the main control module 30 can control the corresponding parameter processing module 12 in the human body detection module to perform corresponding detection only by directly triggering the triggering electrode plate group corresponding to the target detection parameter in the human body parameter detection module 10, so as to directly determine the current human body parameter corresponding to the target detection parameter, and directly indicate the result to the user, and the user does not need to perform complicated menu operation on the intelligent wearable device to enter a corresponding detection interface, thereby improving the convenience of the user in measuring the human body parameter by using the intelligent wearable device. Meanwhile, when the human body detection module detects human body parameters, the physical sign electrode plates 11 included in the human body detection module need to be triggered by a user to acquire human body bioelectrical signals of the user. Therefore, the appearance shape of the original intelligent wearable device can not be changed, a new shell does not need to be designed again, the upgrading cost of the product is reduced, and the production efficiency is improved.

In an embodiment of the present invention, the smart wearable device further includes: the M individual sign electrode plates 11 are respectively arranged on a non-contact position and a contact position on the equipment main body; the trigger detection module includes: the N pressure detection modules 21 are respectively and electrically connected with the main control module 30, and the N pressure detection modules 21 are closely arranged corresponding to at least one sign electrode plate arranged at a non-contact position one by one; wherein M is greater than or equal to N;

the pressure detection module 21 is configured to detect a pressure borne by the sign electrode sheet 11 correspondingly disposed thereon, and output a corresponding pressure detection signal;

the main control module 30 is configured to determine a corresponding target detection parameter when it is determined that the pressure applied to the corresponding physical sign electrode pad is greater than a preset pressure according to at least one pressure detection signal, and control the parameter processing module 12 to determine a human body parameter corresponding to the target detection parameter according to the plurality of human body bioelectrical signals, and output a corresponding human body parameter detection signal.

Referring to fig. 3, in the present implementation, the device body may be a case 40, and the contact position on the case 40 may be a position where the device is in direct contact with the skin of the user when worn, for example, the bottom of a dial case of a smart watch. The non-contact location on the housing 40 may be the upper surface, peripheral sidewall, of the housing 40. The M individual feature electrode plates 11 may be respectively embedded in the upper surface, the peripheral side wall, and the bottom of the housing 40.

Specifically, referring to fig. 2, the wearable equipment of intelligence can be intelligent wrist-watch, and a plurality of electrode slices can set up on the surface of watchband, the side of dial plate and the bottom of dial plate, also can set up the upper surface at the dial plate, and human bioelectricity signal can include skin signal of telecommunication and finger bioelectricity signal. When the user takes the intelligent watch, the electrode slice at the bottom of the dial plate can be directly attached to the wrist skin of the user so as to detect the skin electric signal of the user. Meanwhile, the electrode pads embedded on the surface of the watchband, the side surface of the dial plate and the upper surface of the dial plate can be used for placing fingers of a user, and collecting finger bioelectricity signals of the fingers of the user when the fingers of the user are attached to the upper surface, so that the parameter processing module 12 determines human body parameters such as electrocardio parameters, EDA parameters, human body composition parameters and the like corresponding to target detection parameters according to at least one skin electric signal and/or finger bioelectricity signal under the control of the main control module 30, and outputs corresponding human body parameter detection signals.

In this embodiment, each pressure detection module 21 is configured to detect a pressure applied to the sign electrode pads 11, for example, electrode pads for placing fingers, disposed on the upper surface of the housing 40 and the side surfaces of the housing 40 in the above embodiments.

When the main control module 30 determines that the pressure applied to the corresponding one or more sign electrode slices 11 in a certain group of trigger electrode slice groups is greater than the preset pressure according to at least one pressure detection signal, it is determined that the group of trigger electrode slice groups is triggered by the user. Specifically, a pressure detection signal voltage value-pressure mapping table measured in advance by a developer is preset in the main control module 30, and the pressure currently borne by one or more physical sign electrode pads 11 is confirmed. Before the intelligent wearable device leaves the factory, the pressure sensor is calibrated in advance by research personnel, the voltage values of the pressure detection signals output under different pressure states are determined, and a pressure detection signal voltage value-pressure mapping table is manufactured to be prestored in the main control module 30.

When determining which group of trigger electrode plate sets the user triggers, the main control module 30 determines the target detection parameters the user wants to detect according to a preset trigger electrode plate set-target detection parameter mapping table. The preset pressure may be obtained through a plurality of experiments during the development and development of the research and development personnel and preset in the main control module 30.

For example: be provided with two sign electrode slices A, sign electrode slice B that are used for placing the finger and two pressure detection modules 21 that are used for detecting two sign electrode slices borne pressure on this wearable equipment of intelligence, this equipment can detect current user's electrocardio parameter, and trigger electrode piece group A that electrocardio parameter corresponds is sign electrode slice A. When a user presses a finger on the sign electrode slice a, the main control module 30 determines, by a pressure detection signal output by the corresponding pressure detection module 21, that the pressure applied to the current sign electrode slice a is greater than a preset pressure, and then the main control module 30 considers that the user is triggering the sign electrode slice a, that is, considers that the user is triggering the trigger electrode slice group a, and then the main control module 30 determines that the current target detection parameter is the electrocardiographic parameter according to a preset trigger electrode slice group-target detection parameter mapping table.

It can be understood that the preset trigger electrode plate set-target detection parameter mapping table may be preset in advance by the research and development personnel during the research and development period, or may be set by the user according to personal preference.

After the main control module 30 determines the current target detection parameters, the parameter processing module 12 is controlled to determine human body parameters corresponding to the target detection parameters according to the plurality of human body bioelectric signals, and output corresponding human body parameter detection signals. It can be understood that, when the parameter processing module determines the human body parameter corresponding to the target detection parameter according to the plurality of human body bioelectric signals, the parameter processing module may only need the skin electric signal acquired and output by the electrode sheet attached to the skin of the user in the above embodiment, or may need the skin electric signal acquired and output by the electrode sheet attached to the skin of the user and the finger bioelectric signal acquired and output by the electrode sheet when the finger of the user is pressed against the electrode sheet. Therefore, in practical application, whether the finger of the current user presses the corresponding touch pad set or not can be effectively identified through a pressure detection mode, and the target detection parameter required to be detected is determined according to the difference of the touch pad sets pressed by the user. Simultaneously, pressure measurement only can and sign electrode piece 11 between have physical connection through casing 40 etc. exist, and there is not the electricity to be connected, consequently pressure measurement is when the pressure that detects sign electrode piece 11 and bear, can not influence sign electrode piece 11 and normally gather and output the finger bioelectricity signal of the user finger that places on it, so need not additionally to set up the sign electrode piece 11 that is used for detecting the user and presses specially on the wearable equipment of intelligence, the structure of the wearable equipment of intelligence has been simplified, in addition, when upgrading and upgrading the product of old generation and pushing out new money, also need not to set up the new casing of design 40 again, and need not to open the mould again, the upgrading cost of product has been reduced, the efficiency of production has been improved.

It should be understood that in daily life, the sign electrode pads on the smart wearable device worn by the user may accidentally bump into other people or be pressed by the user unintentionally, which may cause the main control module 30 to misunderstand that the current user needs to perform the human parameter detection.

For this reason, in another embodiment, the main control module 30 is further configured to determine a corresponding target detection parameter according to at least one pressure detection signal when the duration that the pressure applied to the corresponding sign electrode plate 11 is greater than the preset pressure reaches the preset duration, and control the parameter processing module to determine a human body parameter corresponding to the target detection parameter according to the plurality of human body bioelectric signals, and output a corresponding human body parameter detection signal.

In this embodiment, only when a user presses a corresponding sign electrode pad 11 in a certain touch panel set with a finger for a long time (a time longer than a preset time), the main control module 30 determines that the current touch panel set is pressed by the finger of the user, and determines the target detection parameter and the control parameter processing module to obtain the corresponding human body parameter according to the content of the above embodiment. Therefore, the risk that the human body detection function of the intelligent wearable device is triggered by mistake is effectively reduced, and the working reliability and stability of the intelligent wearable device are guaranteed.

Referring to fig. 3, in an embodiment of the present invention, a circuit board 50 is disposed in the casing 40, N pressure detection modules 21 are disposed on the circuit board 50, and a silicone piece 60 is further disposed between the pressure detection modules 21 and the positions corresponding to the sign electrode pads 11 on the inner wall of the casing 40

In this embodiment, the silicone member 60 is disposed on the pressure detection module 21, which is helpful for transmitting the pressure of the user pressing on the electrode plate to the pressure detection module 21, and meanwhile, the pressure detection module can be protected, so as to achieve the shockproof effect.

It is understood that, in the present embodiment, the electrode pads provided corresponding to the pressure detection module 21 establish electrical connection with the circuit board 50 through the connector 70

In this embodiment, the connector 70 may be a metal connector 70, such as a POGO PIN, a metal spring PIN, an elastic sheet, etc., so that when the electrode sheet is electrically connected with the parameter processing module on the circuit board 50, the electrode sheet can be further kept stable in structure, and the reliability of the overall structure of the intelligent wearable device is improved.

In an embodiment of the present invention, the parameter processing module includes: the electrocardio parameter module is electrically connected with the main control module 30;

the M individual characteristic electrode plates 11 comprise a first finger electrode plate, a first skin electrode plate and a second skin electrode plate, and the first finger electrode plate, the first skin electrode plate and the second skin electrode plate are respectively and electrically connected with the electrocardio parameter module;

the trigger detection module 20 is configured to output an electrocardiograph trigger signal when detecting that the first finger electrode piece is triggered by a user;

the main control module 30 is configured to determine a target detection parameter as an electrocardiographic parameter when receiving an electrocardiographic trigger signal, control the electrocardiographic parameter module to determine an electrocardiographic parameter of a user according to a plurality of human bioelectrical signals acquired by the first finger electrode pad, the first skin electrode pad and the second skin electrode pad, and output a corresponding human parameter detection signal;

and/or the presence of a gas in the gas,

the parameter processing module comprises: the EDA parameter module is electrically connected with the main control module 30;

the M individual symbolic electrode slices 11 comprise a second finger electrode slice, a third skin electrode slice and a fourth skin electrode slice, and the second finger electrode slice, the third skin electrode slice and the fourth skin electrode slice are respectively and electrically connected with the EDA parameter module;

the trigger detection module 20 is configured to output an EDA trigger signal when detecting that the second finger electrode pad is triggered by a user;

the main control module 30 is configured to determine that the target detection parameter is an EDA parameter when receiving the EDA trigger signal, control the EDA parameter module to determine an EDA parameter of the user according to the plurality of human bioelectric signals collected by the third skin electrode patch and the fourth skin electrode patch, and output a corresponding human parameter detection signal;

and/or the presence of a gas in the gas,

the parameter processing module further comprises: the human body composition parameter module is electrically connected with the main control module 30;

the M-body characteristic electrode sheet 11 includes: a third finger electrode pad, a fourth finger electrode pad, a fifth skin electrode pad and a sixth skin electrode pad; the human body composition parameter module is electrically connected with the third finger electrode plate, the fourth finger electrode plate, the fifth skin electrode plate and the sixth skin electrode plate respectively;

the trigger detection module 20 is further configured to output a human body component trigger signal when detecting that the third finger electrode pad and the fourth finger electrode pad are both triggered by the user;

the main control module 30 is further configured to determine that the target detection parameter is a human body composition parameter when the human body composition trigger signal is received, control the human body composition parameter module to determine the human body composition parameter of the user according to a plurality of human body bioelectrical signals acquired by the third finger electrode pad, the fourth finger electrode pad, the fifth skin electrode pad and the sixth skin electrode pad, and output a corresponding human body parameter detection signal.

In this embodiment, when the parameter processing module is an electrocardiographic parameter module, the trigger electrode plate group a corresponding to the electrocardiographic parameter is a first finger electrode plate. When a user needs to measure an electrocardiogram parameter, only a finger of a non-device wearing hand needs to be pressed on the first finger electrode piece, the trigger detection module 20 detects that the first finger electrode piece is triggered and outputs an electrocardiogram trigger signal, and the main control module 30 confirms that the first finger electrode piece is triggered at present after receiving the electrocardiogram trigger signal, that is, the current trigger electrode piece set is triggered by the user, and then confirms that the current user wants to measure the electrocardiogram parameter according to the process of the embodiment, controls the electrocardiogram parameter module to perform corresponding work and outputs a human parameter detection signal representing the electrocardiogram parameter.

Specifically, referring to fig. 4, the trigger detection module 20 is illustrated as a pressure detection module, and the trigger detection module 20 includes: the first pressure detection module 21A is closely attached to the inner wall of the casing 40 at a position corresponding to the first finger electrode pad 11A, and is used for detecting the pressure borne by the first finger electrode pad 11A and outputting a corresponding first pressure detection signal;

in this embodiment, when it is determined that the first finger electrode pad 11A is pressed by the user according to the above process, the main control module 30 determines that the current target detection parameter is an electrocardiographic parameter, and controls the electrocardiographic parameter module 12 to start working, the electrocardiographic parameter module 12 calculates a potential difference between the unworn hand and the wrist of the unworn hand according to the skin electrical signal collected and output by the first skin electrode pad 11C and the second skin electrode pad 11D (when the intelligent wearable device is worn by the user, the first/second skin electrode pad 11D is closely attached to the skin of the user, for example, the wrist skin), and the finger bioelectric signal of the unworn finger collected and output by the first finger electrode pad 11A, and obtains the electrocardiographic parameter of the user according to the change of the potential difference and a preset ECG algorithm, and uses the electrocardiographic parameter detection result in the form of a digital signal (for example, SPI signal, I is ² C signal, etc.) output the corresponding human body parameter detection signal to the main control module 30.

Similarly, in another embodiment, when the parameter processing module is an EDA parameter module, the trigger electrode pad B corresponding to the EDA parameter is a second finger electrode pad. When a user needs to measure an EDA parameter, only a finger of a non-device wearing hand needs to be pressed on the second finger electrode plate, the trigger detection module 20 detects that the second finger electrode plate is triggered and outputs an EDA trigger signal, and the main control module 30 confirms that the second finger electrode plate is triggered at present after receiving the EDA trigger signal, that is, the current trigger electrode plate group B is triggered by the user, and then confirms that the current user wants to measure the EDA parameter according to the process of the embodiment, controls the EDA parameter module to perform corresponding work, and outputs a human parameter detection signal representing the EDA parameter.

Similarly, in another embodiment, when the parameter processing module is a body composition parameter module, the trigger electrode pads C corresponding to the body composition parameters are a third finger electrode pad and a fourth finger electrode pad. When a user needs to measure the human body composition parameters, only the fingers of the non-equipment wearing hand need to be pressed on the third finger electrode plate and the fourth finger electrode plate, the trigger detection module 20 can detect that the third finger electrode plate and the fourth finger electrode plate are triggered and output the human body composition trigger signal, after receiving the human body composition trigger signal, the main control module 30 can confirm that the third finger electrode plate and the fourth finger electrode plate are triggered at present, namely the current trigger electrode plate group C is triggered by the user, then confirm that the current user wants to measure the human body composition parameters according to the process of the embodiment, control the human body composition parameter module to perform corresponding work, and output the human body parameter detection signal representing the human body composition parameters.

It can be understood that, in practical application, a plurality of parameter detection modules can be arranged on one wearable device, so that when a plurality of different human parameters are detected, partial sign electrode plates can be shared, the number of the sign electrode plates is saved, and the effect of simplifying the structure of the device is achieved.

Therefore, in this embodiment, when the parameter processing module 12 includes an electrocardiographic parameter module and an EDA parameter module, the first skin electrode pad and the third skin electrode pad are the same sign electrode pads, and the second skin electrode pad and the fourth skin electrode pad are the same sign electrode pads;

in this embodiment, because two skin electrode pads and one finger electrode pad are required for both the electrocardiographic parameter detection and the EDA parameter detection, repeated skin electrode pads can be combined together. Only two different first finger electrode pieces and second finger electrode pieces are arranged as trigger electrode piece sets corresponding to two different human body parameters, namely, the trigger electrode piece set corresponding to the electrocardio parameters is the first finger electrode piece, and the trigger electrode piece set corresponding to the EDA parameters is the second finger electrode piece. When the user triggers the first finger electrode pad, the main control module 30 can execute corresponding actions according to the above embodiments, so that the ecg parameter module outputs a detection signal corresponding to the ecg parameter. When the user triggers the second finger electrode pad, the main control module 30 can execute corresponding actions according to the above embodiments, so that the EDA parameter detection module outputs a detection signal corresponding to the detection of the EDA parameter.

Specifically, on the basis of the embodiment of fig. 4, referring to fig. 5, the trigger detection module 20 is still taken as an example of the pressure detection module.

The M-body patch sheet 11 further includes: the second finger electrode plate 11B, the first skin electrode plate 11C and the second skin electrode plate 11D are respectively electrically connected with the EDA parameter module 13;

the trigger detection module 20 further includes: the second pressure detection module 21B is closely attached to the inner wall of the casing 40 at a position corresponding to the second finger electrode pad 11B, and is used for detecting the pressure borne by the second finger electrode pad 11B and outputting a corresponding second pressure detection signal;

the main control module 30 is configured to determine, according to the second pressure detection signal, that the pressure applied to the second finger electrode pad 11B is greater than the preset pressure and reaches the preset time, that the target detection parameter is an EDA parameter, control the EDA parameter module 13 to determine an EDA parameter of the user according to the plurality of human bioelectrical signals collected by the first skin electrode pad 11C and the second skin electrode pad 11D, and output a corresponding human parameter detection signal.

It is understood that our skin can tell us of emotional changes due to psychological changes or external stimuli through changes in skin resistance, for example, because of different sensations at different pictures, videos, events or other stimuli, which information can be positive or negative. Whether we are anxious, nervous, frightened, excited, confused or surprised, the conductivity of our skin, i.e. the electrical activity of the skin, changes subtly as long as there is mood fluctuation. Therefore, the change of the current skin electrical activity EDA can be confirmed according to the resistance value of the skin, and the current emotion of the user can be further determined.

In the present embodiment, corresponding to FIG. 4 described aboveSimilarly, when the main control module 30 determines that the second finger electrode pad 11B is pressed by the user according to the above process, it will determine that the current target detection parameter is an EDA parameter, and then control the EDA parameter module 13 to start working, and the EDA parameter module 13 will determine the skin resistance value between the first skin electrode pad 11C and the second skin electrode pad 11D according to the plurality of skin electrical signals collected by the first skin electrode pad 11C and the second skin electrode pad 11D, and determine the current emotion of the user according to the corresponding EDA algorithm, and use the emotion result as a digital signal (for example, as an SPI signal and an I signal) ² C signal, etc.) output the corresponding human body parameter detection signal to the main control module 30.

Similarly, in an embodiment, when the parameter processing module 12 includes an electrocardiogram parameter module and a body composition parameter module, the third finger electrode pad and the first finger electrode pad are the same sign electrode pad; the fifth skin electrode plate and the first skin electrode plate are the same sign electrode plate; the sixth skin electrode slice and the second skin electrode slice are the same sign electrode slices.

In this embodiment, because the electrocardiographic parameter detection module and the human body parameter detection module both need to use two skin electrode plates and one finger electrode plate. (the human body parameter detection module also needs to use one finger electrode slice additionally), therefore, the repeated skin electrode slices and the finger electrode slices can be combined together, namely, the device is provided with four electrode slices in total, namely a first finger electrode slice, a fourth finger electrode slice, a first skin electrode slice and a second skin electrode slice. The triggering electrode sheet set corresponding to the electrocardio-parameters is a first finger electrode sheet, and the triggering electrode sheet set corresponding to the human body components is a first finger electrode sheet and a fourth finger electrode sheet. When the user triggers the first finger electrode pad, the main control module 30 can execute corresponding actions according to the above embodiments, so that the ecg parameter module outputs a detection signal corresponding to the ecg parameter. When the user triggers the first finger electrode pad and the fourth finger electrode pad simultaneously, the main control module 30 can execute corresponding actions according to the above embodiments, so that the human body composition parameter detection module obtains a plurality of human body bioelectric signals according to the first finger electrode pad, the fourth finger electrode pad, the first skin electrode pad and the second skin electrode pad, and outputs a detection signal corresponding to the detection of the human body composition parameter.

Similarly, in an embodiment, when the parameter processing module 12 includes an EDA parameter module and a body composition parameter module, the second finger electrode pad and the third finger electrode pad are the same sign electrode pad; the third skin electrode plate and the fifth skin electrode plate are the same sign electrode plate; the fourth skin electrode plate and the sixth skin electrode plate are the same sign electrode plate.

In this embodiment, two skin electrode pads and one finger electrode pad are required for both the EDA parameter module and the human body parameter detection module. (the human body parameter detection module needs to additionally use one finger electrode slice), therefore, the repeated skin electrode slices and the finger electrode slices can be combined together, namely, the device is provided with four electrode slices in total, namely, a second finger electrode slice, a fourth finger electrode slice, a third skin electrode slice and a fourth skin electrode slice. The triggering electrode sheet set corresponding to the EDA parameters is a second finger electrode sheet, and the triggering electrode sheet set corresponding to the human body components is a second finger electrode sheet and a fourth finger electrode sheet. When the user triggers the second finger electrode pad, the main control module 30 can execute corresponding actions according to the above embodiments, so that the EDA parameter module outputs a detection signal corresponding to the EDA parameter. When the user triggers the second finger electrode pad and the fourth finger electrode pad simultaneously, the main control module 30 can execute corresponding actions according to the above embodiments, so that the human body composition parameter detection module obtains a plurality of human body bioelectric signals according to the second finger electrode pad, the fourth finger electrode pad, the third skin electrode pad and the fourth skin electrode pad, and outputs detection signals corresponding to human body composition parameter detection.

Similarly, in an embodiment, when the parameter processing module 12 includes an electrocardiographic parameter module, a body composition parameter module, and an EDA parameter module, the first finger electrode pad and the third finger electrode pad are the same sign electrode pad; the second finger electrode plate and the fourth finger electrode plate are the same sign electrode plate; the first skin electrode slice, the third skin electrode slice and the fifth skin electrode slice are the same sign electrode slices; the second skin electrode slice, the fourth skin electrode slice and the sixth skin electrode slice are electrode slices with the same physical sign.

In this embodiment, two skin electrode pads and one finger electrode pad are required for the ecg parameter module, the EDA parameter module, and the human body parameter detection module. (the human body parameter detection module needs to additionally use one finger electrode slice), therefore, the repeated skin electrode slices and the finger electrode slices can be combined together, namely the device is provided with four electrode slices in total, namely a first finger electrode slice, a second finger electrode slice, a first skin electrode slice and a second skin electrode slice.

The triggering electrode sheet set corresponding to the electrocardio-parameters is a first finger electrode sheet, the triggering electrode sheet set corresponding to the EDA-parameters is a second finger electrode sheet, and the triggering electrode sheet sets corresponding to the human body components are the first finger electrode sheet and the second finger electrode sheet. When the user triggers the first finger electrode pad, the main control module 30 can execute corresponding actions according to the above embodiments, so that the ecg parameter module outputs a detection signal corresponding to the ecg parameter. When the user triggers the second finger electrode pad, the main control module 30 can execute corresponding actions according to the above embodiments, so that the EDA parameter module outputs a detection signal corresponding to the EDA parameter. When the user triggers the first finger electrode pad and the second finger electrode pad simultaneously, the main control module 30 can execute corresponding actions according to the above embodiments, so that the human body composition parameter detection module obtains a plurality of human body bioelectric signals according to the first finger electrode pad, the second finger electrode pad, the first skin electrode pad and the second skin electrode pad, and outputs detection signals corresponding to human body composition parameter detection.

Specifically, as illustrated on the basis of the embodiments corresponding to fig. 4 and fig. 5, referring to fig. 6, the parameter processing module further includes: the human body composition parameter module 14 is electrically connected with the first finger electrode plate 11A, the second finger electrode plate 11B, the first skin electrode plate 11C, the second skin electrode plate 11D and the main control module 30 respectively;

the main control module 30 is configured to determine, according to the first pressure detection signal and the second pressure detection signal, that the pressure borne by the first finger electrode pad 11A is greater than the preset pressure for a preset duration and that the pressure borne by the second finger electrode pad 11B is greater than the preset pressure for the preset duration, determine that the target detection parameter is a body composition parameter, control the body composition parameter module 14 to determine the body composition parameter of the user according to a plurality of body bioelectrical signals acquired by the first finger electrode pad 11A, the second finger electrode pad 11B, the first skin electrode pad 11C, and the second skin electrode pad 11D, and output a corresponding body parameter detection signal.

In this embodiment, similarly to the process of the above embodiment, when it is determined that the first finger electrode pad 11A and the second finger electrode pad 11B are both pressed by the user according to the above process, the main control module 30 determines that the current target detection parameter is a body composition parameter, and controls the body composition parameter module 14 to start working, at this time, because two fingers of the non-wearing hand of the user press the first finger electrode pad 11A and the second finger electrode pad 11B, the first finger electrode pad 11A forms a complete loop between the human body and the first skin electrode pad 11C, and similarly, the second finger electrode pad 11B forms a complete loop between the human body and the second skin electrode pad 11D. The body composition parameter module 14 outputs a current signal having a preset current value from the first skin electrode pad 11C to the first finger electrode pad 11A, and obtains a voltage between the second finger electrode pad 11B and the second skin electrode pad 11D according to the body bioelectrical signal. Thus, the body impedance can be calculated according to the electrical value between the second finger electrode pad 11B and the second skin electrode pad 11D and the known preset current value, and body composition parameters, such as body weight, body fat, muscle rate, skeletal muscle weight, etc., can be obtained according to a preset body composition parameter algorithm. Finally, the human body composition parameter result is in the form of digital signal (such as SPI signal, I) ² C signal, etc.) output the corresponding human body parameter detection signal to the main control module 30.

Through the arrangement, when the user presses the electrode plate, the intelligent wearable device can directly acquire the human body parameters (electrocardio, EDA and human body components) required by the user according to the pressed electrode plate and output the human body parameters to the main control module 30, so that the main control module 30 directly prompts the human body parameters to the user, the user does not need to perform complex menu operation on the intelligent wearable device to enter a corresponding detection interface, and the convenience of the user for measuring the human body parameters by using the intelligent wearable device is improved.

Referring to fig. 7, in an embodiment of the present invention, the smart wearable device further includes:

the indicating module 80, the indicating module 80 is arranged on the shell 40, and the indicating module 80 is electrically connected with the main control module 30;

the main control module 30 is further configured to control the indication module 80 to display the human body parameters corresponding to the target detection parameters according to the human body parameter detection signals corresponding to the target detection parameters.

In this embodiment, optionally, the indication module 80 may adopt a display screen to implement, for example, a dial display screen on an intelligent watch or a display screen on an intelligent bracelet, and after the main control module 30 controls the human parameter detection module 10 to output a human parameter detection signal corresponding to the target detection parameter, the human parameter detection signal to be received is output to the display screen, so that the display screen displays the human parameter detection signal. For example, when the user presses a finger on the first finger electrode pad 11A with a certain force and continues for a certain period of time, the main control module 30 determines that the current target detection parameter is an electrocardiographic human parameter, and then controls the electrocardiographic parameter module 12 to determine the electrocardiographic parameter of the user according to a plurality of human bioelectrical signals collected by the first finger electrode pad 11A, the first skin electrode pad 11C, and the second skin electrode pad 11D, and outputs a corresponding human parameter detection signal, so that the main control module 30 determines that the electrocardiographic parameter of the current user is 88 times/min, and directly displays the electrocardiographic parameter of 88 times/min on the display screen, so that the user can directly determine the electrocardiographic parameter.

Optionally, the indication module 80 may also adopt a voice prompt module to implement, for example, a digital-to-analog conversion module + a speaker, still for example, as shown in the above embodiment, after the main control module 30 determines that the current electrocardiographic parameter is 88 times/min, the voice prompt module is controlled to send a prompt sound "the current electrocardiographic parameter is 88 times/min", so that a user can directly determine the current human body parameter to be measured, and convenience in use of the user is improved.

The above description is only an alternative embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. A smart wearable device, the smart wearable device comprising:

the human body parameter detection module comprises a parameter processing module and M individual sign electrode plates electrically connected with the parameter processing module, and the sign electrode plates are used for collecting and outputting human body bioelectricity signals; wherein M is greater than or equal to 2; one or more sign electrode slices in the M sign electrode slices form at least one trigger electrode slice group, and each trigger electrode slice group is matched with one target detection parameter; the number of the target detection parameters is at least one;

the trigger detection module is used for outputting a corresponding trigger signal when detecting that any trigger electrode plate group is triggered by a user;

the main control module is respectively and electrically connected with the parameter processing module and the trigger detection module, and is used for determining the corresponding target detection parameter according to the received trigger signal and controlling the parameter processing module to output a human body parameter detection signal corresponding to the target detection parameter according to at least one human body bioelectricity signal.

2. The smart wearable device of claim 1, wherein the smart wearable device further comprises: the M sign electrode plates are respectively arranged on a non-contact position and a contact position on the equipment main body; the trigger detection module includes: the N pressure detection modules are respectively and electrically connected with the main control module, and are in one-to-one corresponding close arrangement with at least one sign electrode plate arranged on the non-contact position; wherein M is greater than or equal to N;

the pressure detection module is used for detecting the pressure born by the sign electrode slice arranged corresponding to the pressure detection module and outputting a corresponding pressure detection signal;

the main control module is used for determining the corresponding target detection parameter when the pressure born by the corresponding sign electrode plate is determined to be greater than the preset pressure according to at least one pressure detection signal, controlling the parameter processing module to determine the human body parameter corresponding to the target detection parameter according to the plurality of human body bioelectricity signals, and outputting the corresponding human body parameter detection signal.

3. The smart wearable device of claim 1, wherein the target detection parameters comprise at least one of electrocardiogram parameters, EDA parameters, and body composition parameters.

4. The intelligent wearable device according to claim 2, wherein the main control module is further configured to determine a corresponding target detection parameter when determining, according to at least one of the pressure detection signals, that a duration of time during which the pressure applied to the corresponding sign electrode pad is greater than a preset pressure reaches a preset duration, and control the parameter processing module to determine a human parameter corresponding to the target detection parameter according to the plurality of human bioelectrical signals, and output a corresponding human parameter detection signal.

5. The intelligent wearable device according to claim 2, wherein a circuit board is arranged in the device body, the N pressure detection modules are all arranged on the circuit board, and a silicone piece is further arranged between the pressure detection modules and a position, corresponding to the sign electrode sheet, arranged at the non-contact position.

6. The smart wearable device according to claim 5, wherein the sign electrode pads provided in correspondence with the pressure detection module are electrically connected to the circuit board by a connector.

7. The smart wearable device of claim 1, wherein the parameter processing module comprises: the electrocardio parameter module is electrically connected with the main control module;

the M sign electrode plates comprise a first finger electrode plate, a first skin electrode plate and a second skin electrode plate, and the first finger electrode plate, the first skin electrode plate and the second skin electrode plate are respectively and electrically connected with the electrocardio parameter module;

the trigger detection module is used for outputting an electrocardio trigger signal when detecting that the first finger electrode piece is triggered by a user;

the main control module is used for determining the target detection parameter as an electrocardio parameter when receiving the electrocardio trigger signal, controlling the electrocardio parameter module to determine the electrocardio parameter of the user according to a plurality of human body bioelectricity signals acquired by the first finger electrode plate, the first skin electrode plate and the second skin electrode plate, and outputting a corresponding human body parameter detection signal;

and/or the presence of a gas in the gas,

the parameter processing module comprises: the EDA parameter module is electrically connected with the main control module;

the M sign electrode plates comprise a second finger electrode plate, a third skin electrode plate and a fourth skin electrode plate, and the second finger electrode plate, the third skin electrode plate and the fourth skin electrode plate are respectively and electrically connected with the EDA parameter module;

the trigger detection module is used for outputting an EDA trigger signal when detecting that the second finger electrode piece is triggered by a user;

the main control module is used for determining the target detection parameters as EDA parameters when receiving the EDA trigger signals, controlling the EDA parameter module to determine the EDA parameters of the user according to the plurality of human body bioelectricity signals collected by the third skin electrode plate and the fourth skin electrode plate, and outputting corresponding human body parameter detection signals;

and/or the presence of a gas in the gas,

the parameter processing module further comprises: the human body composition parameter module is electrically connected with the main control module;

m sign electrode slice includes: a third finger electrode pad, a fourth finger electrode pad, a fifth skin electrode pad and a sixth skin electrode pad; the human body composition parameter module is electrically connected with the third finger electrode plate, the fourth finger electrode plate, the fifth skin electrode plate and the sixth skin electrode plate respectively;

the trigger detection module is further configured to output a human body component trigger signal when detecting that the third finger electrode pad and the fourth finger electrode pad are both triggered by a user;

the main control module is further configured to determine that the target detection parameter is a human body composition parameter when the human body composition trigger signal is received, control the human body composition parameter module to determine the human body composition parameter of the user according to a plurality of human body bioelectrical signals acquired by the third finger electrode pad, the fourth finger electrode pad, the fifth skin electrode pad and the sixth skin electrode pad, and output a corresponding human body parameter detection signal.

8. The smart wearable device of claim 7, wherein when the parameter processing module comprises the electrocardiographic parameter module and the EDA parameter module, the first skin electrode pad and the third skin electrode pad are the same sign electrode pad, the second skin electrode pad and the fourth skin electrode pad are the same sign electrode pad;

when the parameter processing module comprises the electrocardio parameter module and the human body composition parameter module, the third finger electrode plate and the first finger electrode plate are the same sign electrode plate; the fifth skin electrode plate and the first skin electrode plate are the same sign electrode plate; the sixth skin electrode plate and the second skin electrode plate are the same sign electrode plate.

9. The smart wearable device of claim 7, wherein when the parameter processing module comprises the EDA parameter module and the body composition parameter module, the second finger electrode pad and the third finger electrode pad are the same sign electrode pad; the third skin electrode plate and the fifth skin electrode plate are the same sign electrode plate; the fourth skin electrode plate and the sixth skin electrode plate are the same sign electrode plate.

10. The smart wearable device of claim 7, wherein when the parameter processing module comprises the electrocardiogram parameter module, the body composition parameter module, and the EDA parameter module, the first finger electrode pad and the third finger electrode pad are the same sign electrode pad; the second finger electrode plate and the fourth finger electrode plate are the same sign electrode plate; the first skin electrode pad, the third skin electrode pad and the fifth skin electrode pad are the same physical sign electrode pad; the second skin electrode plate, the fourth skin electrode plate and the sixth skin electrode plate are the same sign electrode plate.

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