CN111053302A - Intelligent underpants for monitoring physiological condition of male - Google Patents

Abstract

The invention discloses an intelligent underpants for monitoring the physiological condition of men, which comprises an underpants body, wherein a circuit module is arranged on the underpants body, and the circuit module comprises a processor, and an analog-to-digital conversion unit, a wireless communication unit and a power supply unit which are respectively connected with the processor; the crotch part of the underwear body is provided with a flexible pressure sensor, the flexible pressure sensor comprises a first conductive cloth, a second conductive cloth and an elastic insulating layer arranged between the first conductive cloth and the second conductive cloth, and the elastic insulating layer is provided with a plurality of through holes penetrating through the elastic insulating layer; the first conductive cloth and the second conductive cloth are connected with the analog-to-digital conversion unit. The invention can solve the problem of complex structure of the prior underpants for monitoring the physiological status of men.

Description

Intelligent underpants for monitoring physiological condition of male

Technical Field

The invention relates to the technical field of underpants, in particular to an intelligent underpants for monitoring the physiological condition of men.

Background

Flexible sensors are new sensors that have emerged in recent years, including flexible pressure sensors, flexible gas sensors, flexible humidity sensors, and the like. Flexible pressure sensors are common, and are widely used in wearable devices or clothing to detect data indicative of a health condition of a human body.

In some specific use scenarios, the flexible sensor is also applied to underpants, as disclosed in chinese patent application No. CN105054942A, which relates to an intelligent monitoring underpants for evaluating male sexual function, wherein the male erection status is monitored by an array type piezoresistive flexible film sensor. Due to the use of the array sensors, the overall structure of the underpants is complex, and the production cost is increased.

Disclosure of Invention

The invention provides an intelligent underpants for monitoring the physiological condition of a male, which solves the problem of complex structure of the conventional underpants for monitoring the physiological condition of the male.

The embodiment of the invention provides an intelligent underpants for monitoring the physiological condition of men, which comprises an underpants body, wherein a circuit module is arranged on the underpants body, and the circuit module comprises a processor, and an analog-to-digital conversion unit, a wireless communication unit and a power supply unit which are respectively connected with the processor; the crotch part of the underwear body is provided with a flexible pressure sensor, the flexible pressure sensor comprises a first conductive cloth, a second conductive cloth and an elastic insulating layer arranged between the first conductive cloth and the second conductive cloth, and the elastic insulating layer is provided with a plurality of through holes penetrating through the elastic insulating layer; the first conductive cloth and the second conductive cloth are connected with the analog-to-digital conversion unit.

Preferably, the first conductive cloth is attached to the front surface of the elastic insulating layer, and the second conductive cloth has a plurality of discrete fixing areas fixed to the back surface of the elastic insulating layer.

Preferably, the first conductive cloth and the second conductive cloth are both connected with conductive strips, and the first conductive cloth and the second conductive cloth are both connected with the analog-to-digital conversion unit through the conductive strips.

Preferably, the conductive strip is sewn on the first conductive cloth and the second conductive cloth, and the conductive strip is made of a conductive cloth material.

Preferably, the through holes are uniformly distributed on the surface of the elastic insulating layer, and the elastic insulating layer is elastic woven cloth or elastic silica gel.

Preferably, the circuit module further comprises a status indicator lamp and a memory which are respectively connected with the processor, and the power supply unit is further connected with a USB charging interface.

Preferably, the controller is configured to perform the following method: and analyzing the erection times, the maximum erection time, the average erection time and the total erection time of the user according to the erection data detected by the flexible pressure sensor.

Preferably, the controller is configured to perform the following method: recording the daily erection times, the maximum erection time, the average erection time, the total erection time, the daily sleep time, the exercise time, the diet degree, the couple life and the masturbation times of the terminal equipment; when the recorded days reach the preset days, dividing the data recorded on the preset days into K types through a clustering algorithm, wherein the eigenvector is (time _ i, avertime _ i), the time _ i is the erection times of the ith day, and the avertime _ i is the erection average time of the ith day; according to the divided classes, the ranges of the erection times, the erection average time, the sleeping time, the falling asleep time, the exercise time, the diet degree, whether the couple lives and the masturbation times of each class are determined, and the optimal physiological condition of the user is obtained in a self-adaptive manner.

Preferably, the controller is configured to perform the following method: when a state query request sent by a terminal device is received, finding out L points closest to a (time, alert) point in a preset training data set according to a distance formula, and setting a class L 'with the most points in the L points as the class L' of the (time, alert), wherein the distance formula is as follows:

adding (times, avertimel, L') to the preset training data set, determining common characteristics of each data in the same class, and updating the range of each data;

and determining the physiological condition of the user according to the updated class data, and sending a physiological suggestion to the terminal equipment according to the physiological condition and the optimal physiological condition.

Preferably, the controller is configured to perform the following method: calculating the variance of the erection times and the erection average duration of the latest preset days according to the updated data in the classes, determining that the erection condition of the user is stable if the variance is less than 1, and sending a state keeping suggestion to the terminal equipment; and when the average value of the erection times of the preset days and the average value of the erection average duration are lower than the preset values, determining that the erection condition of the user is abnormal, and sending a medical advice to the terminal equipment.

According to the invention, the adopted flexible pressure sensor mainly comprises three layers of structures, namely the first conductive cloth, the second conductive cloth and the elastic insulating layer, and the whole structure of the flexible pressure sensor is simpler by sensing pressure through whether the first conductive cloth and the second conductive cloth are in contact with each other or not. Meanwhile, the related circuits are integrated in one circuit module and can be used after being directly electrically connected with the conductive cloth, so that the structure of the underpants for monitoring the physiological condition of the male is simplified, and the production cost is also reduced.

Drawings

FIG. 1 is a schematic structural diagram of an intelligent underpants for monitoring physiological status of male in one embodiment of the invention;

FIG. 2 is a schematic circuit diagram of an intelligent underpants for monitoring physiological status of male according to an embodiment of the invention;

FIG. 3 is a block diagram of a processor according to an embodiment of the invention;

fig. 4 is a schematic structural diagram of a voltage dividing unit according to an embodiment of the invention.

Detailed Description

The present invention will be described in further detail with reference to the following detailed description and accompanying drawings.

An embodiment of the present invention provides an intelligent underpants for monitoring male physiological condition, as shown in fig. 1, comprising anunderpants body 100, wherein theunderpants body 100 may be made of pure cotton, bamboo fiber, Coolmax, blended fabric or modal, and may be a triangular underpants or a flat angle underpants, and generally has a relativelyloose crotch position 101, and the male penis is located inside thecrotch position 101. At this crotch position 101 a flexible pressure sensor is arranged, which may be located on the inner side or the outer side of thegear position 101, but for comfort and aesthetic reasons thecrotch position 101 may have a two-layer structure with the flexible pressure sensor located between the two layers. The flexible pressure sensor comprises a firstconductive cloth 1, a secondconductive cloth 2 and anelastic insulating layer 3 arranged between the firstconductive cloth 1 and the secondconductive cloth 2, and a three-layer structure is formed. The firstconductive cloth 1 and the secondconductive cloth 2 may be conductive fiber cloth which is made of fiber cloth (generally, commonly used polyester fiber cloth) as a base material and has metal characteristics by applying a metal plating layer after a pre-treatment, and has a soft texture and is conductive. The shapes and the sizes of the firstconductive cloth 1, the secondconductive cloth 2 and the elastic insulatinglayer 3 can be kept the same, and the whole flexible pressure sensor can be made into any shape such as a rectangle, a circle and the like as required. Theelastic insulating layer 3 has elasticity, and its elasticity nature can make flexible pressure sensor reset after the deformation, and simultaneously, theelastic insulating layer 3 is insulating. Theelastic insulating layer 3 is provided with a plurality of throughholes 30 penetrating the elastic insulatinglayer 3 in the thickness direction of theelastic insulating layer 3.

Theunderwear body 100 is provided with a circuit module 4, and the circuit module 4 may include a housing, and related circuits are integrated in the housing, and specifically include aprocessor 41, and an analog-to-digital conversion unit 42, awireless communication unit 43 and apower supply unit 44 which are respectively connected to theprocessor 41. Theprocessor 41 may be a single chip, a DSP or other processing chip for data calculation and instruction transmission, the analog-to-digital conversion unit 42 is configured to convert an analog signal into a digital signal required by theprocessor 41, thewireless communication unit 43 may be a communication module such as bluetooth, and thepower supply unit 44 is configured to supply power to theprocessor 41 and other units requiring power consumption. The firstconductive cloths 1 and the secondconductive cloths 2 are connected with the analog-to-digital conversion unit 42, and if the voltage values of the sensing signals generated by the firstconductive cloths 1 and the secondconductive cloths 2 are too large, avoltage division unit 45 may be disposed between the flexible sensor and the analog-to-digital conversion unit 42 to reduce the voltage values generated by the firstconductive cloths 1 and the secondconductive cloths 2.

When a certain part of a human body applies pressure to the flexible pressure sensor, because the conductive cloth is soft, the part of one of the firstconductive cloth 1 and the secondconductive cloth 2 can penetrate through the throughhole 30 on the elastic insulatinglayer 3 and contact with the other conductive cloth, so that a circuit path is formed, and whether the pressure is applied to the flexible pressure sensor can be reflected by judging whether the circuit is conducted. The sensing signals generated by the firstconductive cloth 1 and the secondconductive cloth 2 are transmitted to the analog-to-digital conversion unit 42, the analog-to-digital conversion unit 42 converts the analog signals into digital signals and transmits the digital signals to theprocessor 41, and after theprocessor 41 processes the data, the related data can be transmitted to theterminal device 40 through thewireless communication unit 43. Theterminal device 40 may be a mobile phone, a personal computer, a smart watch, a tablet computer, etc., the user may operate theterminal device 40 to actively acquire data, and theprocessor 41 may also send the monitored data to theterminal device 40 in real time or at regular time.

Because the electrically conductive cloth texture is soft, when two electrically conductive cloths all hug closely onelastic insulation layer 3, the compliance of first electricallyconductive cloth 1 and second electricallyconductive cloth 2 is restricted, and the part of one of them electrically conductive cloth is difficult to pass through-hole 30 onelastic insulation layer 3 and contact with another electrically conductive cloth, can appear the condition that can't detect pressure. When the two pieces of conductive cloth are not tightly attached to the elastic insulatinglayer 3, the flexibility of the firstconductive cloth 1 and the secondconductive cloth 2 is too high, and there may be a situation that one piece of conductive cloth is far away from theelastic insulating layer 3, and even though a part of the other piece of conductive cloth can pass through the throughhole 30 on theelastic insulating layer 3, the other piece of conductive cloth may not be in contact with the other piece of conductive cloth, and the situation that the pressure cannot be detected may occur.

Therefore, the present embodiment will optimize the structure of the flexible pressure sensor described above. The firstconductive cloth 1 is tightly attached to the front surface of the elasticinsulating layer 3, specifically, the front surface of theelastic insulating layer 3 can be coated with an adhesive, so that the firstconductive cloth 1 is entirely attached to the front surface of theelastic insulating layer 3, and most of the structure of the firstconductive cloth 1 cannot generate displacement in the thickness direction of theelastic insulating layer 3. Meanwhile, a plurality ofdiscrete fixing regions 21 are provided on the secondconductive cloth 2, thefixing regions 21 being spaced apart from each other by a certain distance. Only thefixing area 21 is adhesively fixed on the reverse side of theelastic insulating layer 3, and the portion of the secondconductive cloth 2 other than thefixing area 21 can move relative to theelastic insulating layer 3. When the flexible pressure sensor is pressed, the part of the secondconductive cloth 2 outside thefixing area 21 can pass through the throughhole 30 on theelastic insulating layer 3, and the firstconductive cloth 1 is substantially fixed on theelastic insulating layer 3, so that the firstconductive cloth 1 and the secondconductive cloth 2 are easier to contact, and the detection sensitivity of the whole flexible pressure sensor is higher.

Thefixing regions 21 can be uniformly distributed on the secondconductive cloth 2, so that the stress distribution of the secondconductive cloth 2 is more uniform, and the sensitivity of the whole flexible pressure sensor is kept relatively uniform. Wherein thefixing area 21 may be provided in a circular or other shape.

When the whole flexible pressure sensor is provided to theunderwear body 100, it is preferable to provide the secondconductive cloth 2 to be adjacent to one side of the human body. It should be noted that the front and back surfaces are only used to indicate the two surfaces of theelastic insulating layer 3, and are not the front and back surfaces that ordinary consumers subjectively recognize.

In one embodiment, theconductive strips 11 are connected to the firstconductive cloth 1 and the secondconductive cloth 2, and theconductive strips 11 can conduct electricity, so that the firstconductive cloth 1 and the secondconductive cloth 2 can be electrically connected to the analog-to-digital conversion unit 42 through theconductive strips 11, and the whole flexible pressure sensor can be conveniently connected to the circuit module 4 through theconductive strips 11.

Theconductive strips 11 can be fixed on the firstconductive cloth 1 and the secondconductive cloth 2 by gluing or sewing. Theconductive strips 11 may also be made of a conductive cloth material and may be integrally connected to the firstconductive cloth 1 and the secondconductive cloth 2, respectively.

In one embodiment, theelastic insulation layer 3 may be an elastic fabric or an elastic silica gel, which has better flexibility.

In one embodiment, the throughholes 30 on theelastic insulation layer 3 are uniformly distributed on the surface of theelastic insulation layer 3, so that the detection sensitivity of the whole flexible pressure sensor is kept relatively uniform.

In one embodiment, the circuit module 4 further includes astatus indicator lamp 46 and amemory 47 respectively connected to theprocessor 41, thestatus indicator lamp 46 may display an operating status of the circuit module 4, thestatus indicator lamp 46 may be turned on when the entire circuit module 4 is operating, and thestatus indicator lamp 46 may be turned off when the entire circuit module 4 is not operating. A switch is connected in series between thepower supply unit 44 and theprocessor 41, and the switch can be disposed on the surface of the housing of the circuit module 4, so as to facilitate control of whether the circuit module 4 operates. Thepower supply unit 44 is also connected to aUSB charging interface 48 so that thepower supply unit 44 can be charged through theUSB charging interface 48.

As shown in fig. 3, theprocessor 41 may be an nRF52832QFAA chip with its own analog-to-digital conversion function and bluetooth function. As shown in fig. 4, which is a schematic diagram of thevoltage dividing unit 45, voltage is divided by the resistor R62 and the resistor R61, the two ports ADC1 and ADC2 on the left side are electrically connected to the firstconductive cloth 1 and the secondconductive cloth 2, respectively, and the terminal of the ADC1 on the right side is connected to the 7 pin of the nRF52832QFAA chip.

For the intelligent underpants for monitoring the physiological condition of the male in the above embodiments, the functions of the intelligent underpants will be further explained. The flexible pressure sensor can detect erection data of a user in real time, after theprocessor 41 receives the erection data, the erection times time, the maximum erection time, the average erection time avertimeand the total erection time of the user are analyzed and calculated, a circuit between the firstconductive cloth 1 and the secondconductive cloth 2 is conducted once, the erection times are increased once, the continuous conduction time each time is the erection time of each erection, theprocessor 41 can record the total erection times in one day and the erection time of each erection, further the average erection time avertimeis calculated and can select the maximum erection time, and then the calculated data are stored and recorded in thememory 47.

Further, the circuit module 4 works in real time, and records the number of times of erection of each day, the maximum erection time, the average erection time and the total erection time of the user, the user can send the sleeping time, the exercise time, the diet degree, whether the couple lives and the masturbation times to the circuit module 4 through theterminal device 40, the diet degree can be quantified by numbers, the higher the number is, the lighter the diet is, otherwise, the heavier the diet is, whether the couple lives can also be quantified by numbers, the couple lives are carried out, the number is 1, the couple lives are not carried out, and the number is 0.

When the number of recorded days reaches a predetermined number of days (which may be set to 100 days), a sufficient amount of data is provided for the clustering algorithm. Theprocessor 41 classifies the data recorded in the predetermined number of days into K classes by a clustering algorithm, the feature vector of the object group is (time _ i, avertime _ i), the time _ i is the erection times of the ith day, and the avertime _ i is the erection average time of the ith day. For the divided classes, each class includes data of the number of erection times, mean erection time, sleeping time, exercise time, diet blandness, couple life and masturbation times. The maximum and minimum values of each data are the data range, so that the range of the erection times, the average erection time, the sleeping time, the exercise time, the diet blankness, the couple life and the consortium of each class can be determined. Meanwhile, theprocessor 41 determines the class closest to the Euclidean distance of the optimal feature vector by using the mean value of the number of times of each kind of erection and the mean duration of erection as the feature vector of the class, and the data of the number of times of erection, the mean duration of erection, the sleeping duration, the falling asleep time, the exercise duration, the diet degree, the couple life and the masturbation frequency of the class are the optimal physiological conditions adaptive to the user.

Further, after the number of recorded days exceeds a predetermined number of days, the user may transmit a status inquiry request through theterminal device 40 to request inquiry of the self status. After receiving the status query request, theprocessor 41 responds to the request, finds out L points closest to the (time, alert) point in the preset training data set according to the distance formula, and sets a class L' of the (time, alert) class having the most points among the L points, where the distance formula is:

adding (times, avertimee, L') into the preset training data set, performing deep learning, determining common characteristics of all data in the same class, and updating the range of all data;

according to the data in the updated class, the physiological condition of the user is determined, and according to the physiological condition and the optimal physiological condition, the determined physiological condition and physiological suggestion are sent to theterminal device 40. The actual data can be compared with the data corresponding to the optimal physiological condition, and then the physiological suggestion can be determined.

Specifically, theprocessor 41 calculates the variance of the number of erection times and the mean duration of erection for the last preset number of days (usually, the last 15 days) according to the updated data in the class, determines that the erection status of the user is stable if the variance is less than 1, and sends a status keeping suggestion to theterminal device 40 to represent that the status of the user is stable and needs to be kept in a stable state. When the average value of the erection times of the preset days and the average value of the erection average duration are both lower than the preset values, the user is determined to be abnormal in erection condition, and a medical advice is sent to theterminal device 40 to represent that the physiological condition of the user is abnormal and the user needs to be hospitalized as soon as possible.

Of course, theprocessor 41 may also send the recorded data to theterminal device 40, and theterminal device 40 performs data processing and calculation to determine the physiological condition and physiological recommendation of the user.

The foregoing is a more detailed description of the present invention that is presented in conjunction with specific embodiments, and the practice of the invention is not to be considered limited to those descriptions. It will be apparent to those skilled in the art that a number of simple derivations or substitutions can be made without departing from the inventive concept.

Claims (10)

1. An intelligent underpants for monitoring the physiological condition of male, characterized in that: the underwear comprises an underwear body, wherein a circuit module is arranged on the underwear body, and the circuit module comprises a processor, and an analog-to-digital conversion unit, a wireless communication unit and a power supply unit which are respectively connected with the processor; the crotch part of the underwear body is provided with a flexible pressure sensor, the flexible pressure sensor comprises a first conductive cloth, a second conductive cloth and an elastic insulating layer arranged between the first conductive cloth and the second conductive cloth, and the elastic insulating layer is provided with a plurality of through holes penetrating through the elastic insulating layer; the first conductive cloth and the second conductive cloth are connected with the analog-to-digital conversion unit.

2. The intelligent underpants for monitoring physiological condition of men according to claim 1, wherein: the first conductive cloth is tightly attached to the front surface of the elastic insulating layer, the second conductive cloth is provided with a plurality of discrete fixing areas, and the fixing areas are fixed to the back surface of the elastic insulating layer.

3. The intelligent underpants for monitoring physiological condition of men according to claim 1, wherein: and the first conductive cloth and the second conductive cloth are both connected with conductive strips, and are connected with the analog-to-digital conversion unit through the conductive strips.

4. The intelligent underpants for monitoring physiological condition of men according to claim 3, wherein: the conductive strips are sewn on the first conductive cloth and the second conductive cloth and made of conductive cloth materials.

5. The intelligent underpants for monitoring physiological condition of men according to claim 1, wherein: the through holes are uniformly distributed on the surface of the elastic insulating layer, and the elastic insulating layer is elastic woven cloth or elastic silica gel.

6. The intelligent underpants for monitoring physiological condition of men according to claim 1, wherein: the circuit module further comprises a status indicator lamp and a memory which are respectively connected with the processor, and the power supply unit is further connected with a USB charging interface.

7. The intelligent underpants for monitoring physiological condition of male according to any one of claims 1-6, wherein said controller is configured for executing the following method: and analyzing the erection times, the maximum erection time, the average erection time and the total erection time of the user according to the erection data detected by the flexible pressure sensor.

8. The intelligent pant of claim 7, wherein the controller is configured to perform the method of: recording the daily erection times, the maximum erection time, the average erection time, the total erection time, the daily sleep time, the exercise time, the diet degree, the couple life and the masturbation times of the terminal equipment; when the recorded days reach the preset days, dividing the data recorded on the preset days into K classes by a clustering algorithm, wherein the characteristic vector is (times)_i，avertime_i)，times_iIs the number of puffs on day i, avertime_iMean duration of erection on day i; according to the divided classes, the ranges of the erection times, the erection average time, the sleeping time, the falling asleep time, the exercise time, the diet degree, whether the couple lives and the masturbation times of each class are determined, and the optimal physiological condition of the user is obtained in a self-adaptive manner.

9. The intelligent pant of claim 8, wherein the controller is configured to perform the method of: when a state query request sent by a terminal device is received, finding out L points closest to a (time, alert) point in a preset training data set according to a distance formula, and setting a class L 'with the most points in the L points as the class L' of the (time, alert), wherein the distance formula is as follows:

adding (times, avertimel, L') to the preset training data set, determining common characteristics of each data in the same class, and updating the range of each data;

and determining the physiological condition of the user according to the updated class data, and sending a physiological suggestion to the terminal equipment according to the physiological condition and the optimal physiological condition.

10. The intelligent pant monitoring male physiological conditions according to claim 9, wherein the controller is configured to perform the method of: calculating the variance of the erection times and the erection average duration of the latest preset days according to the updated data in the classes, determining that the erection condition of the user is stable if the variance is less than 1, and sending a state keeping suggestion to the terminal equipment; and when the average value of the erection times of the preset days and the average value of the erection average duration are lower than the preset values, determining that the erection condition of the user is abnormal, and sending a medical advice to the terminal equipment.

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