CN219249244U - Motion-sensing jacket - Google Patents

Abstract

The application discloses motion-sensing jacket includes: a coat body and a distributed strain sensor; the coat main body comprises a plurality of clothing cutting pieces; the plurality of clothing cut pieces comprise a first cut piece which is of a whole piece type design and has elasticity; the first cut-off piece covers at least the following whole or partial areas on the main body of the coat: the region of the upper garment body corresponding to the back of the human body, the region of the upper garment body corresponding to the shoulder of the human body and the region of the upper garment body corresponding to the outer side of the upper arm of the human body; the distributed strain sensor is arranged on the first cutting piece and used for detecting the deformation of the first cutting piece so as to sense the human body action. The first cut-parts of setting whole piece formula cover main detection position, can avoid distributed strain sensor to set up the concatenation position between different clothing cut-parts and lead to distributed strain sensor to receive comparatively concentrated shear stress to produce the condition that damages or detects the precision and reduce, can improve distributed strain sensor's detection precision, improve holistic durable degree and the processing degree of difficulty.

Description

Motion-sensing jacket

Technical Field

The application relates to the technical field of motion sensing, in particular to a motion sensing jacket.

Background

Motion capture refers to a technique of recording and processing the motion of a person or other object using optical, inertial, or other methods. With the development of technologies such as virtual reality, man-machine interaction, network communication and the like, the application range of the motion capture technology is also becoming wider, and the market demand of motion capture devices is also increasing year by year. For example, the motion sensing coat is characterized in that the sensor is arranged on the coat, so that the motion of the upper body of a user can be captured after the user wears the coat, and the activity condition of the user can be detected.

Existing motion-sensing blouse generally comprises a plurality of cut pieces, and a downward concave seam or an upward convex seam exists at the splicing position between different cut pieces, so that a sensor arranged at a nearby position is easy to damage or reduce detection precision due to more concentrated shear stress.

Disclosure of Invention

In view of this, the purpose of this application is to provide a motion-sensing jacket for solve current motion-sensing jacket and have a plurality of cut-parts splice position and make the sensor receive splice position's shear stress easily and damage or detect the problem that the precision reduces.

To achieve the above technical object, the present application provides a motion-sensing coat, comprising: a coat body and a distributed strain sensor;

the upper garment body comprises a plurality of garment cut pieces;

the plurality of clothing cut pieces comprise first cut pieces which are of a whole piece type design and have elasticity;

the first cut-parts cover at least the following whole or partial areas on the coat body: the region of the upper garment body corresponding to the back of the human body, the region of the upper garment body corresponding to the shoulder of the human body and the region of the upper garment body corresponding to the outer side of the upper arm of the human body;

the distributed strain sensor is arranged on the first cutting piece and used for detecting deformation of the first cutting piece so as to sense human body actions.

Further, the plurality of garment panels further comprises: the second cut piece and the third cut piece;

the second cut piece covers the region of the upper garment body corresponding to the abdomen and the chest of the human body;

the third cut-parts cover the region corresponding to the human body side abdomen on the coat main body, and the front end and the rear end are respectively connected with the second cut-parts and the first cut-parts.

Further, the third cut piece comprises a fourth cut piece, a fifth cut piece and a sixth cut piece which are sequentially connected from top to bottom;

the fifth panel is inwardly cinched as compared to the fourth and sixth panels.

Further, the plurality of garment panels further comprises: a seventh cut piece;

the seventh cutting piece covers the neck area from the position between the two shoulder blades corresponding to the back of the human body to the two sides on the coat main body and is connected with the first cutting piece;

the seventh cut-parts are made of elastic mesh cloth.

Further, the plurality of garment panels further comprises: eighth cut-parts;

the eighth cut piece covers the region corresponding to the human clavicle on the coat main body and is connected with the first cut piece and the second cut piece;

the eighth cut-parts are made of elastic mesh cloth.

Further, the plurality of garment panels further comprises collar panels;

the collar cutting piece is connected with the eighth cutting piece and the seventh cutting piece and is positioned on one side, close to the neck, of the eighth cutting piece and the seventh cutting piece.

Further, the plurality of garment panels further comprises a ninth panel;

the ninth cut piece covers the region corresponding to the inner side of the human arm on the upper garment body and is connected with the first cut piece to form sleeves of the upper garment body;

the hem of the sleeves and the hem of the coat main body are subjected to anti-skid treatment.

Further, a slit is arranged at the lower hem of the sleeve.

Further, the first cut-parts and/or the second cut-parts are provided with light reflecting strips.

Further, a plurality of holes for ventilation are formed in the first cut piece.

Further, the distributed strain sensor includes: a stretchable conductor unit;

the stretchable conductor unit is arranged on the first cutting piece and is used for generating electrical property change along with the deformation of the first cutting piece.

Further, the stretchable conductor unit includes: a plurality of concentrated sensing areas, a plurality of conductor lines and an interface area;

the concentrated induction areas, the conductor lines and the interface areas are all arranged on the first cutting piece;

the interface area is provided with a plurality of ports;

each concentrated sensing area is connected with first ends of a plurality of conductor lines;

the other end of each conductor circuit is connected with a plurality of ports in one-to-one correspondence;

the concentrated induction area and the conductor circuit are used for following the deformation of the first cutting piece to generate the change of the electrical performance parameters.

Further, the plurality of concentrated sensing regions include: the first sensing area, the second sensing area and the third sensing area;

the first sensing area is arranged on the first cutting piece and corresponds to the area of human latissimus dorsi;

the second sensing area is arranged on the first cut-off piece in an area corresponding to trapezius muscles of a human body;

the third sensing area is arranged on the first cutting piece and corresponds to the region of the biceps brachii of the human body.

Further, the plurality of concentrated sensing regions further includes: a fourth sensing region;

the fourth sensing area and the first sensing area are respectively and correspondingly arranged on the upper side and the lower side of the area, corresponding to the human latissimus dorsi, of the first cutting piece.

Further, the plurality of concentrated sensing regions further includes: the fifth sensing region, the sixth sensing region and the seventh sensing region;

the second sensing area, the fifth sensing area, the sixth sensing area and the seventh sensing area are arranged on the first cutting piece in an area corresponding to human trapezius muscle, and are distributed at intervals along the trapezius muscle from bottom to top.

Further, the plurality of concentrated sensing regions further includes: an eighth sensing region;

the third sensing area and the eighth sensing area are respectively and correspondingly arranged on the left side and the right side of the area, corresponding to the biceps brachii muscle of the human body, on the first cutting piece.

According to the technical scheme, the application provides a motion sensing jacket, which comprises: a coat body and a distributed strain sensor; the upper garment body comprises a plurality of garment cut pieces; the plurality of clothing cut pieces comprise first cut pieces which are of a whole piece type design and have elasticity; the first cut-parts cover at least the following whole or partial areas on the coat body: the region of the upper garment body corresponding to the back of the human body, the region of the upper garment body corresponding to the shoulder of the human body and the region of the upper garment body corresponding to the outer side of the upper arm of the human body; the distributed strain sensor is arranged on the first cutting piece and used for detecting deformation of the first cutting piece so as to sense human body actions. The first cut-parts of setting whole piece formula cover main needs detection position, can avoid distributed strain sensor to set up the concatenation position between different clothing cut-parts and lead to distributed strain sensor to receive comparatively concentrated shear stress and produce the condition that damages or detection precision reduces, can improve distributed strain sensor's detection precision, improve the holistic durable degree of motion-sensing jacket and reduce the holistic processing degree of difficulty of motion-sensing jacket.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive faculty for a person skilled in the art.

FIG. 1 is a front view of a motion-inducing jacket according to an embodiment of the present application;

FIG. 2 is a rear view of a motion-inducing jacket according to an embodiment of the present application;

fig. 3 is a schematic diagram of an arrangement situation of a first cut piece and a distributed strain sensor of a motion sensing jacket according to an embodiment of the present application;

FIG. 4 is a schematic diagram of a stretchable conductor unit of a motion-inducing jacket according to an embodiment of the present application;

in the figure: 10. a main body; 11. a first cut-out; 12. a second cut piece; 13. a third cut-part; 14. a fourth cut piece; 15. a fifth cut piece; 16. a sixth cut piece; 17. a seventh cut piece; 18. eighth cut-parts; 19. a ninth cut-parts; 110. a reflective strip; 111. collar cutting pieces; 112. a fork opening; 113. opening holes; 20. a distributed strain sensor; 21. a stretchable conductor unit; 211. a concentrated induction area; 212. a conductor line; 213. an interface region; 214. a port.

q1, a first induction zone; q2, a second induction zone; q3, a third induction zone; q4, a fourth induction zone; q5, a fifth induction zone; q6, a sixth sensing region; q7, seventh sensing region; q8, eighth sensing region.

Detailed Description

The following description of the embodiments of the present application will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are some, but not all, of the embodiments of the present application. All other embodiments, which can be made by one of ordinary skill in the art without undue burden from the embodiments of the present application, are within the scope of the claimed utility model.

In the description of the embodiments of the present application, it should be noted that, directions or positional relationships indicated by terms such as "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., are based on directions or positional relationships shown in the drawings, are merely for convenience of describing the embodiments of the present application and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific direction, be configured and operated in the specific direction, and thus should not be construed as limiting the embodiments of the present application. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the embodiments of the present application, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, interchangeably connected, integrally connected, mechanically connected, electrically connected, directly connected, indirectly connected through an intermediary, or in communication between two elements. The specific meaning of the terms in the embodiments of the present application will be understood by those of ordinary skill in the art in a specific context.

Referring to fig. 1 to 3, a first aspect of an embodiment of the present application provides a motion-sensing jacket, including: a coat body 10 and a distributed strain sensor 20; the coat body 10 includes a plurality of garment cut pieces; the plurality of garment panels comprises a first panel 11 of one-piece design and having elasticity. The first cut-off 11 covers at least the following whole or partial areas on the main body 10: the region of the upper garment body 10 corresponding to the back of the human body, the region of the upper garment body 10 corresponding to the shoulders of the human body, and the region of the upper garment body 10 corresponding to the outer side of the upper arm of the human body; the distributed strain sensor 20 is disposed on the first cut-parts 11 and is used for detecting deformation of the first cut-parts to sense human body motion.

In this embodiment, the motion-sensing coat may be an elastic compression coat formed by combining a plurality of garment cut pieces. The first cut piece 11 for setting the distributed strain sensor 20 may cover the corresponding back, shoulder and outer side of the upper arm of the human body, so that the first cut piece 11 covers the positions including, but not limited to, trapezius, deltoid, part of latissimus dorsi, part of biceps brachii and triceps brachii of the human body, thereby enabling the distributed strain sensor 20 to cover the muscle group mainly corresponding to the upper body when the human body moves to detect various actions of the upper body of the human body. The first cut-parts 11 may cover only any one or two positions corresponding to the back, shoulder and outer side of the upper arm of the human body, so that the movement condition of the corresponding position of the wearing user can be detected in a targeted manner.

In application, the first panel 11 may also extend to the elbow region and lower arm region, such that the distributed strain sensor 20 may be arranged to extend to the elbow and lower arm positions. Meanwhile, the provision of the integral first cut segment 11 can avoid the following problems caused by the provision of the distributed strain sensor 20 in the clothing cut segment sewing region:

(1) There are downwardly concave seams or upwardly convex seams between the different garment panels, which results in the distributed strain sensor 20 in the above location being vulnerable to concentrated shear stress;

(2) When the distributed strain sensor 20 is pressed onto the clothing cut pieces to be fixed, the distributed strain sensor 20 is pressed onto the clothing cut pieces simultaneously, so that the processing difficulty is increased, and the position of the distributed flexible sensor 20 is easily deviated due to difficult alignment, so that the processing precision is reduced;

(3) The distributed strain sensor 20 is easily preloaded with a certain tensile force during the process of fixing the distributed strain sensor 20 on a plurality of garment cut pieces, which results in a certain deformation of the sensor after the fixing is completed, thus affecting the detection accuracy of the sensor.

Therefore, the motion sensing coat according to the embodiment of the present utility model, through the design of the cut-parts structure, enables the single distributed strain sensor 20 to cover the single first cut-part 11, thereby avoiding the above-mentioned problems on the premise of realizing the motion capturing and dimension detecting functions.

It should be noted that the distributed strain sensor 20 has stretchable elasticity and can follow the deformation of the first cut piece 11 and detect the deformation of the first cut piece 11 to map the movement of the wearer.

In one embodiment, the distributed strain sensor 20 includes: a stretchable conductor unit 21; the stretchable conductor unit 21 is disposed on the first cut piece 11, and is configured to follow the deformation of the first cut piece 11 to generate a change in the electrical performance parameter. The distributed strain sensor 20 provided in this embodiment has good elastic performance and bending performance.

After the data box is electrically connected with the stretchable conductor unit 21, the change condition of the stretchable conductor unit 21 can be obtained by obtaining the electrical performance parameters of the stretchable conductor unit 21 in the stretching process, so as to obtain the deformation condition of the first cut piece 11 and map the shoulder action, the back action and the hand action of the user after wearing the motion-sensitive jacket. The electrical performance parameter may refer to a capacitance value or a resistance value, in this scheme, the electrical performance parameter is a resistance value. Specifically, the stretchable conductor unit 21 is made of a stretchable conductor material including, but not limited to, a stretchable conductive silver paste material, a stretchable carbon nanomaterial, a stretchable conductive polymer material, a liquid metal material, and the like.

In a more specific embodiment, the plurality of garment panels of the motion-inducing jacket further comprises: the second cut piece 12 and the third cut piece 13; the second cut-parts 12 are covered on the upper garment body 10 in the areas corresponding to the abdomen and chest of the human body; the third cut-parts 13 cover the region of the upper garment body 10 corresponding to the abdomen of the human body, and the front and rear ends are respectively connected with the second cut-parts 12 and the first cut-parts 11.

In a further improved embodiment, the third panel 13 comprises: the fourth cut piece 14, the fifth cut piece 15 and the sixth cut piece 16 are sequentially connected from top to bottom; the fifth panel 15 is fastened inwardly as compared to the fourth panel 14 and the sixth panel 16.

In the embodiment, the motion sensing jacket is tightly designed, so that the distributed strain sensor 20 on the first cut-off piece 11 can be tightly attached to the skin of a user; when a user makes an action, the distributed strain sensor 20 can be significantly deformed so as to accurately and sensitively detect the action of the user.

Specifically, the motion sensing upper garment of the present embodiment is provided with the fifth cut pieces 15 on both sides of the waist, and since the fifth cut pieces 15 are tightened inward compared to the fourth cut pieces 14 and the sixth cut pieces 16, the motion sensing upper garment can have a waisted effect by providing the fifth cut pieces 15, so that the motion sensing upper garment can better fit the human body, and a better detection effect is brought.

Further, the plurality of garment panels further comprises: a seventh cut piece 17; the seventh cut piece 17 covers the region from the shoulder blades corresponding to the back of the human body to the neck on the coat main body 10 and is connected with the first cut piece 11; the seventh cut-parts 17 are made of elastic mesh cloth.

Specifically, the first cut piece 11 is an M-shaped back of the motion-sensitive jacket; the seventh cut-parts 17 are T-shaped and connected with the first cut-parts 11, so that the overall comfort and ventilation of the motion-sensing coat can be improved.

Further, the plurality of garment panels further comprises: an eighth cut piece 18; the eighth cut piece 18 covers the upper garment body 10 at a position corresponding to the collarbone of the human body and connects the first cut piece 11 and the second cut piece 12; the eighth panel 18 is made of an elastic mesh. Namely, the seventh cut piece 17 and the eighth cut piece 18 are each made of an elastic mesh cloth excellent in air permeability, and their elastic modulus is relatively low.

Specifically, the first panel 11 is connected to the second panel 12 by a seventh panel 17 and an eighth panel 18. Through the shape design of the first cut-parts 11, the seventh cut-parts 17 made of the elastic mesh cloth cover the T-shaped areas below and at two sides of the neck, so that the problem that a user feels that the neck is restrained and the neck is inconvenient to act due to the tight design of the motion sensing coat is avoided, and the wearing comfort of the motion sensing coat is improved. In addition, since the elastic modulus of the seventh cut piece 17 is lower than that of the first cut piece 11, the first cut piece 11 in the shape of M is more easily stretched to both sides of the body when the user makes the shoulder action, thereby further improving the comfort.

Similarly, the eighth cut-parts 18 have the effect of improving the breathability, and the constraint feeling on the neck and shoulder portions can be reduced under the condition that the motion-sensitive jacket is sufficiently attached, so that the wearing comfort of the motion-sensitive jacket is improved.

In addition, as the motion sensing coat of the embodiment adopts a tight design, a fork is added at the cuffs so as to be convenient for a user to put on and take off.

Further, a neck cut piece 111 is also included; the collar cut piece 111 is provided at a position corresponding to the neck of the human body on the coat body 10, and connects the eighth cut piece 18 and the seventh cut piece 17 to the neck-approaching side. The neck of the coat body 10 is narrowed by the neck cut pieces 111 to fit the user.

Further, the plurality of garment panels further comprises a ninth panel 19; the ninth cut piece 19 covers the inner side area of the upper garment body 10 corresponding to the arm of the human body and is connected with the first cut piece 11 to form sleeves; the hem of the sleeve and the hem of the main body 10 are subjected to anti-slip treatment.

By performing the anti-slip treatment at the cuffs and the hem, when the user wears the motion sensing coat to perform the motion, the cuffs and the hem are not easy to slide, so that the first cut piece 11 can be deformed more greatly, and the detection effect of the distributed strain sensor 20 on the first cut piece 11 is improved.

Specifically, the anti-slip treatment may be that an anti-slip cloth and/or an anti-slip adhesive tape is stuck on the inner side of the cuff composed of the first cut piece 11 and the ninth cut piece 19; similarly, an anti-slip cloth and/or an anti-slip adhesive tape are adhered to the inner side of the lower hem composed of the first cut piece 11, the second cut piece 12 and the third cut piece 13.

Further, the first cut piece 11 and the ninth cut piece 19 are provided with a split 112 at the lower hem of the sleeve, which is convenient for the user to put on and take off.

Further, the first cut piece 11 and/or the second cut piece 12 are provided with light reflecting strips 110. The reflective strips arranged on the first cut-parts 11 and the second cut-parts 12 have an attractive effect on one hand, and the reflective patch has an auxiliary calibration effect when the spatial position of the motion sensing coat is calibrated in a combined optical mode on the other hand.

Further, the first cut-out 11 is provided with a plurality of openings 113 for ventilation. The openings 113 facilitate ventilation, and the outer circumference of the openings 113 may be provided with light reflecting strips 110.

In the above-mentioned scheme, only one piece of the first cut-parts 11, the second cut-parts 12, the seventh cut-parts 17 and the collar cut-parts 111 are provided in one piece of the motion-sensitive jacket; and the rest cut pieces are provided with two symmetrical pieces in one piece of motion sensing coat.

In a more specific embodiment, referring to fig. 4, stretchable conductor unit 21 comprises: a plurality of concentrated sensing regions 211, a plurality of conductor lines 212, and an interface region 213; the concentrated induction areas 211, the conductor lines 212 and the interface areas 213 are all distributed on the first cut piece 11; the interface area 213 is provided with a plurality of ports 214; each concentrated sensing region 211 is connected to a first end of a plurality of conductor lines 212; the other end of each conductor line 212 is connected with a plurality of ports in one-to-one correspondence; the concentrated sensing area 211 and the conductor line 212 are used to follow the deformation of the first cut piece 11 to generate a change in electrical properties.

Specifically, when the first cut piece 11 is pulled by the movement of the wearer, the stretchable conductor unit 21 deforms following the pulling of the first cut piece 11, thereby generating a change in electrical properties; after the external data box is connected to the stretchable conductor unit 21 through the port 214 and the electrical performance parameter is measured, the stretching deformation condition of the first cut-off segment 11 is known according to the variation condition of the electrical performance parameter, so that the movement condition of the wearer is mapped. And, the concentrated sensing region 211 may be a loop circuit formed by patterning and arranging conductive wires. The data box is used for being in communication connection with external processing equipment and can collect the change condition of the electrical performance parameters generated by the stretchable conductor unit 21 following the deformation of the first cut piece 11.

In one embodiment, the concentrated sensing region 211 may be considered the primary sensing region; in order to reduce the influence of the change of the electrical performance parameters of the deformed conductor line 212, a fine-diameter wire can be selected for the concentrated induction area 211, and a coarse-diameter wire with a larger diameter than the fine-diameter wire is selected for the conductor line 212, so that the elastic modulus of the conductor line 212 is larger, the change of the electrical performance parameters of the deformed conductor line 212 is smaller, the influence of the conductor line 212 on the concentrated induction area 211 is reduced, and the detection accuracy of the concentrated induction area 211 is improved.

In another embodiment, the concentrated sensing region 211 has a wire diameter that is consistent with the wire diameter of the conductor line 212, and a wire having a thin wire diameter is used. Thus, in this embodiment, the concentrated sensing area 211 can detect the deformation of the first cut piece 11, and the position where the conductor lines 212 are arranged can also detect the deformation of the first cut piece 11. In addition, among the plurality of concentrated sensing regions 211 and the plurality of conductor lines 212, the detection object of each concentrated sensing region 211 and each conductor line 212 is not unique; because the single action of the user can cause the plurality of concentrated sensing areas 211 to deform, besides detecting the arrangement positions of the concentrated sensing areas 211 and the plurality of conductor lines 212, the situation that the concentrated sensing areas 211 and the conductor lines 212 are pulled together because the first cutting piece 11 is pulled can also exist, so that the concentrated sensing areas 211 and the conductor lines 212 around the detection part can be used for assisting in measuring the movement condition of the detection part, and the detection accuracy is improved.

In embodiments where both the concentrated sensing region 211 and the conductor line 212 are formed of fine-wire-diameter conductors, the conductors in the concentrated sensing region 211 are more sensitive to strain at their location based on their structural design. Also, the signals measured by the stretchable conductor lines 212 distributed outside the concentrated sensing region 211 can also map the user's actions, and it can also map the user's stature.

In one embodiment, the plurality of concentrated sensing regions 211 comprises: the first sensing region q1, the second sensing region q2 and the third sensing region q3; the first sensing area q1 is arranged on the first cut piece 11 and corresponds to the area of human latissimus dorsi; the second sensing area q2 is arranged on the first cut piece 11 and corresponds to the area of the trapezius muscle of the human body; the third sensing region q3 is disposed on the first cut piece 11 in a region corresponding to the biceps brachii muscle of the human body.

The first sensing area q1 arranged at the position corresponding to the latissimus dorsi can detect the back action of the user; the second sensing area q2 arranged at the position corresponding to the trapezius muscle can detect the shoulder and neck actions of the user; the third sensing region q3 provided at the position corresponding to the biceps brachii can detect the elbow motion of the user.

Correspondingly, corresponding to two sides of the upper body of the human body, each concentrated sensing area 211 is symmetrically arranged at the left side and the right side of the human body.

Further, the plurality of concentrated sensing regions 211 further includes: a fourth sensing region q4; the fourth sensing area q4 and the first sensing area q1 are respectively and correspondingly arranged on the upper side and the lower side of the area, corresponding to the human latissimus dorsi, of the first cut piece 11. By the fourth sensing region q4 and the first sensing region q1, the activity condition of the latissimus dorsi region can be better sensed.

Further, the plurality of concentrated sensing regions 211 further includes: a fifth sensing region q5, a sixth sensing region q6, and a seventh sensing region q7;

the second sensing area q2, the fifth sensing area q5, the sixth sensing area q6 and the sixth sensing area q6 are arranged in an area corresponding to the trapezius muscle of the human body on the first cut-off piece 11, and are distributed at intervals along the trapezius muscle from bottom to top. Similarly, the second sensing area q2, the fifth sensing area q5, the sixth sensing area q6 and the seventh sensing area q7 can better sense the activity condition of the trapezius muscle area.

Further, the plurality of concentrated sensing regions 211 further includes: an eighth sensing region q8; the third sensing area q3 and the eighth sensing area q8 are respectively and correspondingly arranged on the left side and the right side of the area, corresponding to the biceps brachii muscle of the human body, of the first cutting piece 11. The motion of the biceps region can be better sensed by the third sensing region q3 and the eighth sensing region q 8.

It should be noted that, the detected object corresponding to the concentrated sensing area 211 is not the only one, and the main detected object is described above, and since a single action of the user causes deformation of a plurality of concentrated sensing areas, for example, the shrugging action may cause significant deformation of the sixth sensing area q6 and the eighth sensing area q8, and also cause deformation of the second sensing area q2, the fifth sensing area q5 and the third sensing area q3 sufficient to be detected, the shrugging action of the user can be detected more accurately by the signals of the concentrated sensing area 211 at the same time.

Further, the conductor lines 212 may be shared between adjacent concentrated sensing regions 211, and the number of conductor lines may be reduced, thereby reducing the width of the interface region 213.

It should be noted that, in order to facilitate better connection of the ports 214 to the data box, the plurality of ports 213 located in the interface area 213 may be staggered back and forth.

While the present utility model has been described in detail with reference to the examples, it will be apparent to those skilled in the art that the foregoing examples can be modified or equivalents substituted for some of the features thereof, and any modifications, equivalents, improvements and substitutions made therein are intended to be within the spirit and principles of the present utility model.

Claims (16)

1. A motion-inducing jacket, comprising: a coat body and a distributed strain sensor;

the upper garment body comprises a plurality of garment cut pieces;

the plurality of clothing cut pieces comprise first cut pieces which are of a whole piece type design and have elasticity;

the first cut-parts cover at least the following whole or partial areas on the coat body: the region of the upper garment body corresponding to the back of the human body, the region of the upper garment body corresponding to the shoulder of the human body and the region of the upper garment body corresponding to the outer side of the upper arm of the human body;

the distributed strain sensor is arranged on the first cutting piece and used for detecting deformation of the first cutting piece so as to sense human body actions.

2. The motion sensing upper garment of claim 1, wherein the plurality of garment panels further comprises: the second cut piece and the third cut piece;

the second cut piece covers the region of the upper garment body corresponding to the abdomen and the chest of the human body;

the third cut-parts cover the region corresponding to the human body side abdomen on the coat main body, and the front end and the rear end are respectively connected with the second cut-parts and the first cut-parts.

3. The motion-inducing jacket of claim 2, wherein the third panel comprises a fourth panel, a fifth panel, and a sixth panel connected in sequence from top to bottom;

the fifth panel is inwardly cinched as compared to the fourth and sixth panels.

4. A motion sensing coat as claimed in claim 2 or claim 3, wherein a plurality of said garment panels further comprise: a seventh cut piece;

the seventh cutting piece covers the neck area from the position between the two shoulder blades corresponding to the back of the human body to the two sides on the coat main body and is connected with the first cutting piece;

the seventh cut-parts are made of elastic mesh cloth.

5. The motion sensing upper garment of claim 4, wherein the plurality of garment panels further comprises: eighth cut-parts;

the eighth cut piece covers the region corresponding to the human clavicle on the coat main body and is connected with the first cut piece and the second cut piece;

the eighth cut-parts are made of elastic mesh cloth.

6. The motion sensing upper garment of claim 5, wherein the plurality of garment panels further comprises a collar panel;

the collar cutting piece is connected with the eighth cutting piece and the seventh cutting piece and is positioned on one side, close to the neck, of the eighth cutting piece and the seventh cutting piece.

7. The motion-inducing jacket of claim 1, wherein a plurality of said garment panels further comprise a ninth panel;

the ninth cut piece covers the region corresponding to the inner side of the human arm on the upper garment body and is connected with the first cut piece to form sleeves of the upper garment body;

the hem of the sleeves and the hem of the coat main body are subjected to anti-skid treatment.

8. The motion-inducing jacket of claim 7, wherein the skirt is provided with a slit at the location of the skirt.

9. The motion-inducing jacket of claim 2, wherein the first panel and/or the second panel has reflective strips disposed thereon.

10. The motion-inducing jacket of claim 1, wherein the first panel is provided with a plurality of openings for ventilation.

11. The motion sensing coat of claim 1, wherein the distributed strain sensor comprises: a stretchable conductor unit;

the stretchable conductor unit is arranged on the first cutting piece and is used for generating electrical performance parameter changes along with the deformation of the first cutting piece.

12. The motion-inducing jacket of claim 11, wherein the stretchable conductor unit comprises: a plurality of concentrated sensing areas, a plurality of conductor lines and an interface area;

the concentrated induction areas, the conductor lines and the interface areas are all arranged on the first cutting piece;

the interface area is provided with a plurality of ports;

each concentrated sensing area is connected with first ends of a plurality of conductor lines;

the other end of each conductor circuit is connected with a plurality of ports in one-to-one correspondence;

the concentrated induction area and the conductor circuit are used for following the deformation of the first cutting piece to generate electric property change.

13. The motion sensing coat of claim 12, wherein the plurality of concentrated sensing regions comprises: the first sensing area, the second sensing area and the third sensing area;

the first sensing area is arranged on the first cutting piece and corresponds to the area of human latissimus dorsi;

the second sensing area is arranged on the first cut-off piece in an area corresponding to trapezius muscles of a human body;

the third sensing area is arranged on the first cutting piece and corresponds to the region of the biceps brachii of the human body.

14. The motion sensing coat of claim 13, wherein a plurality of the concentrated sensing zones further comprise: a fourth sensing region;

the fourth sensing area and the first sensing area are respectively and correspondingly arranged on the upper side and the lower side of the area, corresponding to the human latissimus dorsi, of the first cutting piece.

15. The motion sensing coat of claim 14, wherein a plurality of the concentrated sensing zones further comprise: the fifth sensing region, the sixth sensing region and the seventh sensing region;

the second sensing area, the fifth sensing area, the sixth sensing area and the seventh sensing area are arranged in the area, corresponding to the trapezius muscle, on the first cutting piece and are distributed at intervals from bottom to top along the position corresponding to the trapezius muscle.

16. The motion sensing upper garment of any of claims 13 to 15, wherein a plurality of the concentrated sensing zones further comprise: an eighth sensing region;

the third sensing area and the eighth sensing area are respectively and correspondingly arranged on the left side and the right side of the area, corresponding to the biceps brachii muscle of the human body, on the first cutting piece.

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