The present invention relates to a system, method, and article utilizing an intelligent sensing fabric, which can be used for detecting physiological function, posture, state of the ambient environment and state of the sensing fabric itself, and can be used in sports medicine, fitness, health care, entertainment, industrial safety and other fields. The system starts to sense itself and the surrounding environment since leaving the factory, and the information in use can be accumulated and recorded continuously. Finally, if there is a problem with the system, the user or the monitoring center can be informed. Thus, the function of an intelligent fabric sensing system is achieved.
As disclosed in US Patent No. 201500126834 A1, patterns have been used on fabrics or skin as a sensor. We use a pattern or body painting applied to the skin as a transmission wire or an electrode, which can produce insulation effect or the effect of generating and eliminating static electricity. The system on the fabric can interact with it. In other words, the two can operate in parallel. It is also a back-up.
U.S. Pat. No. 8,193,465 B2 discloses a fabric having a switch thereon and a sensor on the switch; or the switch is used on fabrics to detect changes in posture.
US Patent No. 20100170704 A1 discloses a fabric having a crevice. The crevice has conductive materials on its two sides, which can change and detect its change with an external force.
U.S. Pat. No. 8,331,097 B2 discloses a fabric that can be used as a capacitor; the capacitor is chargeable and a battery can be used. Accessories are not necessarily disposed on the same piece of fabric, but can be separately disposed on two pieces of fabrics. Meanwhile, electromagnetic induction can be realized, and there is also a reference area to detect leakage. Said patent does not mention that electromagnetic induction can be achieved on a single piece of fabric.
U.S. Pat. No. 7,750,790 B2 relates to a strain gauge. When an external force acts on the fabric, the geometrical properties of the at least one conductive yarn alter so that a corresponding change of an electric property is sensed. Said sensing is impedance (resistance, capacitance, inductance), or magnetic flux or electric flux is sensed. In our present patent, it can be a transmission wire, it can be converted to energy for storage, and it can also be used as an antenna for wireless transmission.
US Patent No. 20130066168 A1 discloses a system for generating physiological signals using a fabric capacitive sensor. A capacitive sensor is formed between a conductive fabric and a human body. No details are given as to the effect of static electricity between the human body and the fabric.
US Patent No. 20140343392 A1 discloses heartbeat detection or whether electrodes are in good contact. Dry electrode or capacitive coupling is based on a change in state between the electrode and the environment or the human body to choose which signal is used for processing. The electrode or the fabric, connecting wire, suspension strip around the electrode can be used as an antenna. To measure the impedance between the electrode and the body surface, the impedance between the two electrodes and body surface rather than the impedance between a single electrode and the body surface is measured.
US Patent No. 2012015076 A1 discloses a technique for detecting physiological function and posture. According to said patent, only one physiological signal is read at a time.
US Patent No. 20140084045 A1 discloses pattern-making, packaging and manufacturing of fabric electronization.
US Patent No. US 20110282164 A1 discloses a sensing device comprising a substrate material layer and a plurality of sensors provided on the substrate material layer. According to said patent, two output ends are necessary, detection will only start when an external force is applied, and the detected values must be different. The present patent provides detection without a force being applied. More importantly, for the same sensor, detection is possible even if the values are the same. In the absence of application of a force, stress or action, information can also be read. The problem that the same detected values cannot be read has been resolved. At the same time, two output ends can be reduced to one. Furthermore, wireless transmission is also possible such that the control box can save more power.
In addition to the preferred examples or embodiments disclosed below, the present invention can be implemented or otherwise carried out in various ways. Therefore, it is understood that the present invention is not to be construed as limited by the details of configuration and the layout of components described in the following description or shown in the drawings. If there is only one embodiment, as described herein, the claims should not be limited to that embodiment. In addition, the claims are not strictly limited unless there is clear and convincing evidence of exclusion, restriction or disclaimer. The objective of the present invention is to read any external environmental changes and internal information, which can be read regardless of whether it is affected by external forces with fewer wires. The sensing system of the present invention can be applied to fabrics, leather, garments, bed sheets, seats and the like. They have fewer connectors so that the user can be more comfortable; they can also detect responses of the external environment. Any abnormality of sensing components can be immediately notified to the user, and deficiencies of the equipment and points for attention can be sensed. Human or animal behaviors can be detected, and therefore it can be used as an identity card and in behavioral medicine.
In view of the above shortcomings, an objective of the present invention is to provide a sensing system that can detect and read information even if the values are the same, with or without application of a force, stress or action. It has fewer connectors so that the user feels more comfortable; responses of the external environment can also be detected.
Another objective of the present invention is to provide removal of electrostatic interference and even storage of electricity. Electrostatic effect can also be used to measure physiological signals by the fabric adhering to the body.
Another objective of the present invention is to provide using a pattern or body painting applied to the skin as a transmission wire or an electrode, which can produce an insulation effect or an effect of generating and eliminating static electricity. Our system on the fabric can interact with it. In other words, the two can operate in parallel. This also serves as a back-up. Another objective of the present invention is to provide a method of generating a physiological signal by using a fabric resistance sensor or an impedance plethysmogram sensor.
Another objective of the present invention is to provide generation of electricity by electromagnetic induction on the fabric.
Another objective of the present invention is to provide a transmission wire that can be used as a sensor, can be converted to energy for storage, and can also be used as an antenna for wireless transmission.
Another objective of the present invention is to provide a system through which the measurement of an impedance between electrode and body surface is performed by measuring an impedance between a single electrode and the body surface.
Another objective of the present invention is to provide a system that can be used as an identification of human or animal, which can replace an identity card. The above description is only a brief overview of the technical aspects of the present invention. In order to further understand these and other objectives and technical aspects of the present invention, and to implement the present invention based on the description, we provide the following embodiments and drawings:
Part 1: Reduction of Connection Wires
The existing SPI or I2C interface is designed to meet this one-wire requirement. However, both SPI and I2C require a micro-controller and an appropriate power supply. To make the wearer feel comfortable and move without interference, the sensor must be very small, the connection wire must be very few, and it is difficult to have a power supply. With so many limitations, it is difficult to connect multiple sensors using known SPI or I2C. The present invention discloses a circuit architecture, in which a micro-controller can connect multiple (analog) sensors at the same time by using two wires, and can detect the responses of the sensors respectively.
For example, the sensor suitable for use in the following embodiments may be a microphone (for picking up cardiopulmonary sounds or voices), a physiological electrode, a hygrometer, a thermistor, a resistor or a capacitive strain gauge, a photoresistor, photodiode (with optical filters of different wavelengths, becoming UV light, visible light or infrared light sensors to sense the brightness of the environment), barometric sensors, gas sensors (alcohol, carbon monoxide or carbon dioxide sensors).
In addition, the sensors described in the following embodiments are also applicable to various actuators, such as vibration motors, LEDs, horns, buzzers, cuffs containing an airbag, electrode resuscitation devices or electrodes used in transcutaneous nerve electric stimulators (TENS) etc.
A first configuration of the present invention is shown in
One of the selectors (such as G3) can also be omitted in
A second configuration of the present invention is shown in
One of the selectors (such as G3) can also be omitted in
Those from the previous patents US8193465B2, US20100170704A1 and US8331097B2 can all be used as selectors, but under a condition that an external three must be applied in order to start the detection of signals or to provide therapeutic heating.
The selectors are implemented by LC band pass filters.
As shown in
The frequency generator V is a constant voltage source with adjustable frequency. When the frequency generator V generates a frequency of 100 Hz, the impedance of selector G1 approaches zero, while selectors G2 and G3 approach 200K Ω. If sensors S1, S2 and S3 are 1 Ω thermistors, the series impedance of G1 & S1 is 1,001 Ω, while the series impedance of G2 & S2 and G3 & S3 is 200.001K Ω. In other words, the interference generated by the two groups of sensors and selectors, G2 & S2 and G3 & S3, is one percent of the sensing signal of G1 & S1. Similarly, when the frequency generator V generates a frequency of 10K Hz, the main sensing signals come from G2 & S2. When the frequency generator V generates a frequency of 1 M Hz, the main sensing signals will come from G3 & S3. For applications not requiring relatively high accuracy, interferences caused by the other two groups are negligible, and the results obtained directly at a certain frequency approximate the theoretical value; for applications requiring high accuracy, three measurement results can be obtained using three frequencies, and then more accurate S1, S2, S3 can be obtained by solving simultaneous equations with three variables. The above circuits can be simulated by SPICE (which is widely used in the electronics industry) to get results very close to actual ones to facilitate circuit design.
The selector may be implemented by a ceramic or quartz band pass filter, which is characterized by a narrow frequency band and can accommodate many sensors at the same time.
Or it can be implemented by a reverse-biased Zener diode whose dynamic impedance is negligible.
It is also possible to implement the selector with a constant voltage component such as LM385 or a reed switch or a multiplexer.
Take reed switch for example. A thermistor is placed at an armpit of a side of a top. A magnet is placed on the inside of the sleeve on this side, and a reed switch is placed on the outside of this side. When the arm is in a sagging posture on this side, the temperature of the armpit is close to the core temperature of the body. Meanwhile, the magnet is close to the reed switch to form a connected state. At this time, M can sense the correct body temperature.
As shown in the circuit of
The selectors are implemented by rectifier diodes in opposite directions
An effect similar to Zener diode effect can also be formed by using different types of diodes having different forward biases as shown in
S5 is directly connected to the voltameter without a selector therebetween. When the bias and amplitude are less than 0.2V, only S5 will be sensed by the voltameter, while the other sensors are not turned on. Because D1˜D4 are not turned on, the value of S5 is obtained. When the frequency generator gives a bias of +0.3V, S4 plus S5 can be obtained. Similarly, S5 can also be the electrode of an electrocardiogram, electromyogram or electroencephalogram. Because the amplitude of these physiological signals is much less than 0.2 V, D1˜D4 will not be turned on and confusion with the signals of other sensors will not occur.
S5 in
Two conductive fabrics S5 in contact with the human body can also measure breathing (patent US 20130066168 A1). Further, S1 and S2 can be connected to two capacitive sensors to read breathing, heartbeat, posture or movement. The two capacitive sensors can measure the capacitance therebetween using a sinusoidal wave or a pulse wave as described in patents U.S. Pat. Nos. 8,331,097 B2, 7,750,790 B2, US 20130066168 A1.
The conductive fabric can also be connected in parallel to a resistive sensor, and the sensor does not need to be connected in series to a selector and can be distinguished by DC and AC.
When the capacitance between the conductive fabric and the human body is difficult to read due to sweat, S1/D1 and S2/D2 can be connected in parallel in the present invention. After a slight bias is applied, S1, S2 and the capacitive electrode can be selected. Although there is a bias, it is still predictable and estimable.
If S2 can be an active component such as a microphone, as long as the body impedance between the two electrodes is greater than the output impedance of the microphone, D2 that is originally connected to S2 can be omitted. S2 and the electrodes are connected in parallel, and the wires can still be shared.
When the capacitance between the conductive fabric and the human body is difficult to read due to sweat, an impedance plethysmogram can be read instead in the present invention, and the breathing, body motion and the like can still be obtained. In this case, a resistance (R, real part) and an inductive reactance (X, imaginary part) are obtained at the same time. It can also be used to estimate body fat or body water, that is, to achieve multi-function and multi-purpose, such as J Intern Med Taiwain 2012; 23: 245-253. Alternatively, a resistance value can be measured using a DC current, and the skin resistance or sweat can be measured.
In
The above electrodes can also be used as ECG electrodes to achieve multi-function. For example, as shown in prior patents: direct current resistance (sweat degree) is measured when initiating, and capacitance is measured in the case of an alternating current. If it is wet enough, a traditional ECG circuit is used. If it is too dry, a capacitively coupled electrocardiogram circuit is substituted, and a separate feedback electrode is started. The feedback electrode can be connected in series to a capacitor.
To distinguish between two sensors (also electrodes), one can be added with a capacitor (S2+cap), the other one is without a capacitor (S1). Thus, S1 is measured in the case of DC and S2 is measured in the case of AC.
As shown in
Impedance plethysmogram is a method of generating a physiological signal using a fabric resistance sensor or an impedance plethysmogram sensor, and it is characterized in that it comprises at least one fabric, at least one conductive area is disposed on said fabric, and a signal circuit is provided. The conductive fabric forms a resistance or impedance with the human body, and the fabric resistance sensor or the impedance plethysmogram sensor is connected in series or in parallel to a resistor R, a capacitor C, an inductor L, an operational amplifier, a diode, a Schmitt trigger, a CMOS field effect crystal, a transistor, or an integrated circuit to form a charge/discharge circuit to change the frequency, period, voltage or current. When there is pressure, pulling force, torque or tension between the human body and the fabric, the circuit sends a signal. The system receives a change in a value of the resistance sensor or the impedance plethysmogram sensor between the conductive fabric and the human body, and said change is represented by a change of frequency, voltage or current. At least one of the information of physiology, medium (sweat, blood, lip balm), posture changes, medium changes between the human body and the fabric, or the force received is analyzed through the change in frequency, voltage or current.
The method is exactly the same as the prior capacitor patent US 20130066168 A1, except that the former is to measure a capacitance, and now the impedance between the conductive fabric and the human body is measured, so the details are the same as in the above patent and will not be described herein.
In the above system, a switch is connected to the conductive fabric or the switch itself is a resistance sensor or an impedance plethysmogram sensor.
In the above system, changes in physiological state, posture and force can be measured by changes in frequency and voltage-current curves.
In the above system, there are at least two said conductive fabrics, one of which is a reference conductive area, and said reference conductive area is grounded.
In the above system, the system can be used to detect posture, and can also be used to detect physiological information such as heartbeat, breathing, humidity, swallowing, sweating, body temperature and cough.
The above system can also be used for positioning, that is, to know where a physiological signal is generated in the body.
In the above system, the conductive area can be further used as a physiological signal sensor, that is, an electrode used to detect heartbeat, respiration, brain wave, electromyogram, electrocardiogram, body fat content or sweat; or the conductive fabric is used as an treatment electrode to produce transcutaneous nerve electrical stimulation, heat or cooling.
In the above system, the conductive fabric is designed on garments, hats, socks, shoes, bed sheets, gloves, steering wheels, crutches, table cloths, carpets, or prostheses.
The above system can also be used to detect changes in resistance or impedance caused by sweat, wounds, sweating, medicine application and powder makeup.
The above system can also detect joint angle, angular velocity, and angular acceleration.
The above system can also detect a person's position, speed, acceleration or distance traveled.
The above method can also be used to detect gait, gait stability, fall, sleep activity map or movement.
The conductive fabric may not be in direct contact with the human body, and a fabric, a rubber, a plastic film, a waterproof fabric, a coated fabric and printed material may be placed between the conductive fabric and the human body.
As shown in
Meanwhile, a fabric inductive pneumograph can be used to measure breathing or body motion. It can also be an antenna or an electromagnetic wave or magnetic field sensor, so that posture, stature, whether a weight is being carried, and how much weight in the handbag can be measured. Similarly, the inductive pneumograph can be connected in parallel to a thermistor, so that body temperature or ambient temperature can be measured at the same time.
The human body can be wrapped with multiple inductive pneumograph sensors, which can not only read the breath, but also read the changes in the contraction at this place. There is also mutual inductance between inductive pneumograph sensors, which can also be used to measure the mutual motion between various parts of the body, as shown in FIG. (9-1) and FIG. (9-2).
As shown in
In
The present invention can also use the stray capacitance between the control box and the human body to connect the reference electrodes, that is, one of the contacts can be omitted, so that there are only one physical wire and one connection point, as shown in
As shown in
If there is an electrode in the lower row to be used as the sensing electrode instead of as a reference electrode, electronic components (such as capacitors, inductors, diodes, LC, etc.) can be connected in series, and the potential can be separated from the reference potential. The capacitor is as an example in
The L or C filter, plus two diodes in different directions, can accommodate multiple sets of sensing electrodes. As long as the bias is applied in different directions, one set can be turned on and the other set can be turned off. Similarly, a Zener diode of different reverse collapse voltages or a rectifier diode of different cut-in voltages can be used to parallel multiple sets of sensing electrodes without interfering with each other.
The conductive fabric is used as an electrode to pick up the physiological electrical signal, and the different frequencies of the signal itself can be used to realize the simultaneous transmission of multiple signals in one line. For example, an electrocardiogram electrode can share the same set of wires with an EMG, as shown in
For example, an electrocardiogram electrode includes two types: a dry electrode and a capacitor electrode. The dry electrode can read the physiological electrical signal via a cotton conductive fabric with high water absorption. Carbon fiber and conductive silicone fabrics are suitable for capacitive electrodes. On the various parts of the body, the degree of sweating is different and the skin quality is different, so the area of the dry electrode is required to be different. The impedance of the finger skin is low, and the skin impedance of the baby is low, so the electrode area can be reduced. Since the measured skin impedance is 10 MΩ via the stainless steel wire and is 2 MΩ when the skin is very wet, the ECG can be read when the impedance of dry electrode ECG is less than 5 MΩ. According to this characteristics, the stainless steel wire can be used as the transmission wire of the ECG. No coating is required and it will not interfere with the reading. If the dry electrode needs to maintain water saturation for a long time in actual human body measurement, it can be coated with water-saturated materials such as PVA or crystal mud, or waterproof materials such as PU, which are added to the dry electrode to ensure the moisture release within two days so as to realize that the impedance of the surface conductive fabric is within 5 MΩ.
The previous US 20140343392 A1 fabric has a mesh fabric on the periphery of the electrode, as shown in
The electrocardiogram electrodes are attached to the sides of the body, and the EMG electrodes are placed on the left upper arm. In order to reduce the interactive interference of the two sets of electrophysiological signals, in the present invention, a resistor can be connected at one end of the electrode in series and then connected the common wire. The signal is transmitted to the input (P and N) of the positive and negative terminals of the instrumentation amplifier on the control box, and then two band pass filters of different frequencies are used. The ECG frequency band is 0.6˜40 Hz, and the EMG frequency band is 50˜300 Hz, which can be obtained separately.
Considering that the output impedance of the electrocardiogram or electromyogram signal obtained by the electrodes at different positions may be quite different, R4˜R7 in
As shown in
The fabric electrode contacting with the human body can be regarded as equivalent to a resistor and a capacitor in parallel. When the skin is dry, the contact resistance is large, but its capacitance still exists. When the skin is dry, it is difficult to obtain a good signal with a conventional electrocardiogram amplifying circuit, at this time, it is possible to switch to a capacitively coupled electrocardiogram circuit which will be described later.
The above wires may also be optical fibers, bare wires, insulated wires, and the transmission wires may be printed circuits, conductive inks, optical fibers, conductive films, conductive fibers, conductive silicone, conductive rubber, and the like.
The aforementioned transmission wires and various types of sensors can also be replaced by optical fibers and optical fiber sensors, which have the advantages of not only being less susceptible to radio wave interference, but also can easily achieve multi-task simultaneous transmission with the same optical fiber, and the optical fiber itself can simultaneously sever as a sensor. If the above transmission wire is replaced by an optical fiber, the transmitted signal between the control box and the fabric can be easily realized by one contact point. For example, there are several fibers fused together on the fabric, as shown in FIG. (19), the sensor ends are emitting different colored lights (R, G, B) via LED, which are transmitted to the control box through a connector. The control box has beam splitter of the wavelength selective optical coating to send the different colored lights to different photodiodes for conversion to electrical signals for subsequent processing by the circuit in the control box.
For example, the fabric end does not have a light-emitting component, but the light is completely emitted by the control box. It enters into the optical fiber via the beam splitter, and the filter is placed inside the fabric, so that different colored lights enter different sensors. After the light is modulated by the sensor, it will be reflected back to the fiber, and then return to the control box for photoelectric conversion into electrical signals.
The optical fiber itself can also be a sensor. Take S1 in the figure as an example. If S1 is a piece of optical fiber and there is a mirror at the end, when S1 is pulled, pressed or twisted, its structure will change and the transmission loss will increase, the magnitude of the force is known thereby.
The optical fiber can be used as the transmission wire and a sensor. In addition, it can also be used as a spare wire, and the switching method is as follows: the optical fiber is very thin and soft, which is very suitable for application on fabric. Therefore, it can simulate the the above the example to arrange another piece of optical fiber for backup on the side of the main transmission wire or optical fiber. The MUX1 and MUX2 in the above figure may choose a simple two-beam superposition, a mechanically-operated single-pole double throw switch (which can be switched by motor or manual), or a photoelectric switch (OE switch) which is electrically switched and contains photoelectric crystal. To switch the photoelectric switch, in addition to the directly electrical driving on the control box, a light can be transmitted from the optical fiber to the photoelectric switch, and then the filter is used to select a specific photoelectric switch as the above example. Next, the light is converted into power by a photosensitive diode to drive the photoelectric switch for switching. The optical fiber is in contact with the fiber to conduct light, form the horizontal line to vertical line, from the underwear to the outerwear (as shown in
Theoretically, the optical fiber can restrain the light from leaking out, but when the optical fiber is pressed by an external force, its structure changes, as a result, it is inevitable that light is leaked out at the pressed position. According to the characteristics, the signals can be transmitted from fabric to other places (such as beds or chairs) in the present invention, without having to transmit signals from the original optical fiber connectors or electrical connectors. As simulated the above example (the wires are criss-crossed), the optical fiber can also select a specific part to transmit signals.
Optical fiber can be used for signal transmission (e.g. ECG) or as an optical fiber sensor (sensing force)
For some signals which are originally electrical signals and are difficult to be directly captured by the light, such as an electrocardiogram, the electrical signal can still be converted into an optical signal through a simple electro-optical conversion circuit and then transmitted. Because light can be easily separated by different light colors, it is easier to transmit multiple sets of signals on the same optical fiber. Similarly, the transmission wire can also be used as signal transmission and as a sensor (sensing force), and can also be used as spare wire.
As shown in
For example, optical fiber is used to detect the fabric damage. Currently, there is a type of indoor lighting optical fiber commercially available, and it is designed to deliberately leak a small part of the light from the side. If this optical fiber is used, one inside and outside the fabric serves as the receiving terminal, one inside and outside the fabric serves as the transmitting terminal. When the ambient brightness is not strong, it can be used to detect the damage of the fabric. When the fabric is damaged more seriously, the light energy obtained at the receiving terminal is stronger.
Comparing DC, AC and pulse signals as a selector
Conducting ground conduction with human body conductivity
In general, a connection wire in the circuit is defined as a ground wire (Ground, abbreviated as GND). If the foregoing embodiment is applied to a wearable device, the human body can also be used as a ground wire. For high-frequency (frequency greater than 20K Hz) current, if it is less than 20 u amp, it will not harm the human body and will not make people feel. The conductive properties of the skin can be represented by a parallel connection of a resistor and a capacitor. The higher the frequency, the lower the impedance of the skin, which is more favorable for the current to flow into the human body. In this embodiment, a small piece of conductive fabric about 1 cm2 is placed on the fabric to connect with the sensor, and a capacitance (C1, C2, and C3) is formed in the body. After the current passes through the skin and enters the human body, it is conducted by the highly conductive blood vessel to the whole body (the blue line inside the red frame), just like the conductive copper foil of the circuit board. In this way, the conductivity of the human body is utilized, and a connecting wire that must be made on the fabric is omitted. As for the ground wire of the circuit on the control box (in the figure below (as shown in
If capacitive sensing is performed, such as respiratory sensing, as shown in the figure above (
Simultaneously starting more than two selectors to pick up sensor signals
In the above embodiment, only one selector is turned on, and one end of the sensor is grounded. In this embodiment, two or more signal generators (FG) are used to generate independent frequencies. After an adder (using an operational amplifier as the core), the signals of more than two sensors can be simultaneously captured, and the sensor is not necessary to be grounded, as shown in
The selector plus the detection circuit and the field effect crystal to pick up the electrophysiological signal of the living body
In the foregoing embodiment, the passive sensor is taken as an example. In this embodiment, the function of picking up an electrophysiological signal is further increased, as shown in FIG. (25). The aforementioned selector is connected to a detection circuit, and then connected to a field effect crystal to serve as an analog switch, DRCQ as an representative in
Each of the electrodes in
How to verify whether a single electrode is in good contact in this system. You can selectively turn on an electrode in the control box according to the above method, and then measure the impedance by using stray capacitance as GND. Those with high impedance can serve as capacitive sensor to measure breathing or body motion, and those with low impedance is suitable for serving as reference electrode. First select a single electrode and test with the stray capacitance, and then select two electrodes to test. If the noise is too high, the skin may be too dry, in this case, a capacitively coupled electrocardiograph can be considered. If the traditional electrocardiogram effect is not good, the user can be requested to add another connector to connect the feedback electrode to implement the capacitively coupled electrocardiograph.
The capacitively coupled electrode may be the above-mentioned wearable physiological electrode, which is mounted on the fabric in the form of fabric made of conductive yarn. When the skin is very dry, the DC resistance between the electrode and the skin is quite high, but the area is not small, so it is still capacitively coupled with the human body, that is, it can be regarded as a capacitively coupled electrode; the capacitively coupled electrode may also be the aforementioned wearable physiological electrode, which is mounted on a non-closed fitting fabric, a chair or a bed. If sweat does not wet through the closed fitting fabric, it can also be regarded as a capacitively coupled electrode; the capacitively coupled electrode may also be a wearable physiological electrode with a surface-coated or plated insulator, that is, a capacitively coupled electrode.
Another time when a capacitively coupled electrocardiograph must be used is that the user is allergic to the silver electrode, resulting in itchy or red skin, in this case, you can use a capacitively coupled electrode to avoid direct contact. The capacitively coupled electrodes can be connected in parallel with conventional electrodes to enhance the effect (
Static electricity elimination
The Electrostatic Discharge (ESD) of human body model (HBM) refers to the accumulation of static electricity on the human body when the human body walks on the ground or due to other factors. When such person touches the electronic parts, the static electricity will burn out the parts.
In addition, the static electricity will also interfere with the signal of the wearable device line, and it is not good for the human body, therefore, there is a need to eliminate static electricity. In addition, static electricity has characteristics that can be utilized: because of the adsorption effect, the human body is a conductor, so the static electricity attracts the insulator to the human body. The materials on the periphery of electrode or sensor, or the materials containing static electricity themselves will be naturally adsorbed to the human body. The adsorption is better than the adhesion to the human body, and the transmitted signal will be more stable. The pattern or body painting applied on skin can create a static effect, and the electrodes on the fabric can interact with it (adsorption effect).
We can use the skin tattoo pattern or painting materials, which are conductive, so they can be used as electrodes, and can be added with static-containing materials to enhance the effect (adsorption effect). Skin tattoo pattern or painting can also be used for signal transmission of line, and it can also be added with anti-static agent to enhance the effect. The non-metal or organic materials can also be used for insulation. Painted materials include water-based (conductive) and non-water-based ones. The advantage of water-based materials is that they can achieve the conduction effect with conductive fabric. The non-water-based materials can be used for insulation effect, and anti-static agents can also be added to enhance the effect.
The shortcoming of pattern is that they are fixed and cannot be easily removed. The painting is easy to apply and convenient to remove.
Only the area where the sensor reads static electricity is kept, and the other unnecessary parts are coated with anti-static agent to prevent the damage of static electricity. In this way, the sensor can become the electrostatic sensor we want. The sensing components themselves can be the fabrics A, B and C shown in the in FIGS. (31-2) and (31-3). The difference is that A is all positively and negatively charged arrangement, B is positively charged, and C is either a component of fully negatively charged fabric, or made of plastic, rubber, silicone, film etc. For example, these positively and negatively charge will not move, therefore, if there is a negatively charged fabric on the outer of the fabric, it can attract the positive charge in the air to produce a clean effect.
In the winter, it is often dry, which usually causes static electricity.
After the relative humidity is greater than 55%, the object is hard to accumulate high-voltage electricity, so it is not easy to generate static electricity.
The effect of relative humidity on static electricity is that:
1. Relative humidity affects the conductivity of the body surface and air, thereby affecting the speed at which the accumulated net charge leaves the human body.
2. High relative humidity enhances the adsorption of water on the surface of the object, so that the friction of two different objects does not easily produce a distribution of net charge. The greater the humidity of the fabric, the less easy the electricity is to run. The wetness or dryness can be sensed by detecting the environmental changes in the season based on induction or triboelectric generation. The sensing component can be measured.
Because the advantage of smart fabric is that they are shielded by the electrostatic effect of conductive fabric (wire), and positive charge will disappear. Human being are conductors, and conductive fabric (wire) can prevent electromagnetic interference. When wearing smart fabric, the positions with organs shield by conductive fabric (wire) can be protected from electromagnetic waves, and the human body can prevent electromagnetic interference.
In the device designed by us (
The switch can also be changed to a diode to selectively charge positive/negative charge. The switches of
Similarly, the charger (capacitor) here can also be used as a sensor, that is to say, the conductive fabric above the charger can sense the change of static electricity, and can also the change of humidity. Conductive fabric can also be replaced by wires on the fabric. As long as there is induction, the wire can be connected to the charger (capacitor), and the change in the capacitance value is sensed to know the change in static electricity between the fabric and the human body. Since the capacitance capacity varies with the quantity of static electricity, the change measured in capacitance is the change in the quantity of static electricity. The measurement method is same as in the previous patent US 20130066168 A1.
The charger can be changed into a light-emitting material such as a light-emitting diode, an LED, a tungsten wire, etc., and the electric quantity can be expressed by the brightness, thereby eliminating the static electricity. It can also be changed into a heating wire to provide a heat insulating effect.
Therefore, this concept can also be formed under the contact of two or more pieces of fabric. Two pieces of conductive materials or fabrics are coated with an insulating paint on the outside. When a positively charged human body or control box contacts the sensing conductor, the adsorption effect causes the conductor or surrounding fabric to be negatively charged.
The conductive material on the edge of the charger is positively charged, so the charger can collect the electricity. The two pieces of fabric are continuously inductive and continuously charged, so that they can serve as the storage battery (as shown in
The human body often produces static electricity due to the friction of the fabric, especially when it is dry and cold. Animal fur also produces static electricity due to friction.
In addition, we are designing an electrostatic sensor, like a traditional electroscope, whose structure is shown in
Whether the object to be tested is charged, the electrical property of the object to be tested, and whether the object to be tested is a conductor.
It can also detect the movements, breathing, swallowing and other behaviors of the human body.
We designed an electrostatic sensor, in which the conductive material a (fabric or wire) is on the fabric, and the conductive column a″ communicates with the conductive material a (as shown in
When there is no external force, the shrapnel switch (b) is closed and not charged. When the positively charged human body, air or the control box contacts the induction, the shrapnel switch b automatically turns in positive charge, and the shrapnel (b) will touch the conductive material (c) to charge.
An additional remote or passive component can be added. When the battery is fully charged, the conductive material c can be moved down without touching the switch. If the control box does not touch the iron switch, the upper detection will become sensing value of sensor. By the positive charge in the air, it is automatically returned, and so repeatedly, it becomes an automatic switch and automatically charges. The above-described shrapnel switch b is, for example, a tin foil, a metal wire or a conductive wire. The conductive material c is, for example, an iron piece, and the insulating material d can also be changed to a conductive material c, at this time, it can replace the conductive material c, and this sensor can be placed outside the fabric or in the middle of the fabric.
That is to say, the conductive fabric (wire) a, when it is energized, the two pieces of conductive sheets (b) are separately contacted to the conductive material (d) of the outer wall to allow electricity to transmit to the battery (capacitor).
Another electrometer is also a closed space on the cloth as shown in FIG. (32-1), only two of the shrapnels are changed into a rotatable conductive strip, and the outer wall is also made of conductive material. Analyzed from the structural, it is a variable capacitor. Like the structure of the Braun electrostatics, we just do it on the fabric. When it is energized, the rotatable conductive strip can be charged when it touches the outer wall. Since the electrometer itself is also a capacitor, the electrometer is charged when it is connected in parallel at two points where the potential difference is not zero in the DC circuit. At the same time, a charger (capacitor) is connected to charge.
The following is a sort table for the loss/acquisition of electrons in common substances. It can be seen that:
Substance that are easily positively charged (substance that easily lose electrons):
Substances that are easily negatively charged (substances that are easily acquire electrons):
If two different substances generate static electricity due to contact with each other, this is called contact electrification. The triboelectric effect is one of contact electrification effect. Insulators and non-conducting objects are excellent materials for electrification (generation of static electricity) and retention of charge. The conductor will also generate static electricity. Because conductive objects are prone to lose charge, an insulator must be coated in order to retain the charge
Application and detection of static electricity:
Physical activity inevitably generates static electricity on the body. Although static electricity can damage electronic components, it can also be used to improve the quality of sensing. In addition to those described in the above table, it is also possible to use a suitable material and body friction on different materials to generate static electricity in the vicinity of the electrode, or to generate static electricity by producing a high voltage by an induction or transformer oscillating circuit so as promote the electrode to be in closer contact with the body and reduce body motion interference. Positive static electricity can attract negative ions in the air, that is, becoming an air cleaner.
The principle is that the voltage of 110 v is input, and the rectifying and booster circuit passing the negative ion generator generates a high voltage of −2.5 KV at the end of the carbon fiber brush of the generator. Because the current is extremely small, it does not cause dangerous damage to the human body. In order to ionize the neutral atoms at high voltage, the air is decomposed into positive and negative ions. The positive ions of electron are heavier and absorbed by the brush to enter the circulating current. The negative ions are lighter and will be sent to the air along with the wind.
Therefore, the addition of negative ions in the air not only neutralizes and fills the positive ions in the air, making the body more energetic and the cells active, but also can also absorb impurities and smoke in the air. As a result, the air that is breathed can be cleaner, and the environment has also become clean.
The present invention is an electrometer with a closed space bottle as shown in
Because friction can generate static electricity (
A conductive fabric can be arranged at the intersection of fabric, pants, socks and shoes in the present invention. A battery or a large capacitor is arranged on the fabric, and the GND of the static electricity (collecting circuit) is connected to the shoe. A conductor is placed on the sole to contact the ground, and a transistor is arranged between the GND and the sole conductor for intermittent conducting, for example, 0.01 second conducting for one minute, which can collect electrostatic energy.
Magnets and coils can be arranged on the control box, the fabric, the belt, the necklace or the shoes & socks in the present invention. When there is relative motion (that is, the coil cuts the magnetic field lines), it can induce the electricity generation. As shown in
The application of flexible solar cells placed on the outer fabric can also generate electricity for use in the above circuits.
The electric energy generated in the above manner can be connected to the battery (capacitor) on the fabric for storage by the diodes through the electrical conductors on the fabric or connect to the batteries on the control box.
The above-mentioned action of generating electric energy also represents the movement, of the human body or the change of the environment. The present invention can selectively add a battery fuel gauge (
An embodiment of a diaper capable of simultaneously measuring urination and defecation, change in breathing and temperature, and posture
As shown in
Multifunctional Diaper Test Chart (A1.)
Referring to the multifunctional fabric chart A1. If the value measured by variable capacitor is basically 200˜500 pf when weight of adult is 60 kg, and when there is a foreign matter, about 10 grams will produce 800˜1200 pf, which can be used to measure the generation of defecation. In addition, when there is no micturition desire, the value of two exposed wires at the front end is close to 30˜80 pf. If there is 300cc of micturition desire, the value will reach 2 uF, so the smart diaper can multi-functionally detect the user's urination/defecation or sitting down, that is to say, when he stands up and has no micturition desire, the value will be less than 100 pf, and if sitting, the value will 200˜500 pf. At the same time, it can be washed repeatedly, as shown in the figure. There is conductive material to let the reusable diaper and the button are conducted to connect with the controller, and it can also be made in disposable type. In addition, two sensing electrodes are attached to the waist position to measure changes in the user's breathing. The user's posture change can be detected because the breathing changes are different when the user is standing, sitting or lying down. If the device fails to sense the breathing while the user wears it, it can alert or remind the carer to perform emergency treatment. In addition, the thermistor of this device can also sense changes in the user's body temperature. (As shown in
If the structure shown above is changed to 1 cm*12 cm two twilled plain woven silver fabrics spaced at 1.5 cm, and is placed in the center of the lower layer of the non-woven fabric on the diaper surface layer. The two pieces of conductive wires are connected to the switch button. In the actual measurement, there is 5 g wet defecation without human body pressure, and wetness sensed value is 3 nf, and urine wetness displayed value is 2 uf.
The above is just an embodiment. We can adjust the sensing materials, the relative position between the sensing materials, the placement position and size of sensing materials, and then the displayed value has different effects.
Similarly, the above example of diaper can adjust the urine, the urination/defecation, the breathing effect and the posture changes (such as: lying down, standing, sitting) in the structure.
The above method can also be used to measure breathing with electrodes, just like a capacitive patent (US 2013/0066168 A1). In addition, the electrode can also be used to measure ECG, heartbeat, sweat, etc. to replace or simultaneously measure breathing.
Capacitor battery (
Number in the figure: 1. Diode 2. Switch 3. Fabric capacitor battery 4. Fabric 5. Conductive silicone 6. Plain woven silver fabric 7. Packaging film 8. Conductive wire 9. Conductive wire
As shown in
Part 2: Wireless Signal Transmission
The system disclosed by the present invention preferentially uses the wired signal transmission when the wired communication can work normally, and starts the wireless signal transmission when the wired signal transmission fails.
There are often overlapping or contiguous parts on the garments, such as shoes and socks, socks and pants, pants and garment, underwear and shirts, etc., the signals of which can be transmitted by NFC (near field communication), or the signals are transmitted using capacitive coupling, inductive coupling, magnetic coupling, or optical coupling (LEDs and photodiodes).
Adopt a conventional NFC technology, such as RFID, to arrange a digital circuit (microcontroller, memory, such as SD memory, battery, coil, etc., can be fastened to the garment with a snap-fastener, in a way similar to the hung components as described in Part 4), and the signals are transferred from the garment to the control box in a digital mode. The digital circuit contains a memory, so that when the control box is not turned on or too busy to receive the signals, the signals can be digitized first and then stored in the memory, until the control box can receive the signals. The control box can also upload the signals received to a cloud database, to ensure that the data will not be lost even if the control box is damaged.
Transmitting a signal through a capacitor, inductor, magnetic coupling or optical coupling has two advantages: firstly, it is not required to physically connect with a wire or connector (such as a button), and it is convenient, comfortable, and unconstrained for use. Secondly, an analog or digital signal can be transmitted, or can even be applied to the previous embodiment, as long as the coupling is strong enough and the frequency is high enough, namely the digital circuit and connector can be omitted, which is convenient and comfortable for the user.
In the case of inductive coupling and coiled NFC, the present invention adds a magnetic shielding fabric (combined with a magnetic conductive substance, such as ferrite) between the human body and the inductive coil to prevent the magnetic field from affecting the human body function. Optionally, a coil can be added between the magnetic shielding fabric and the human body to sense whether there is a magnetic field or electromagnetic wave before transmission. If there is, it means that the magnetic shielding fabric is invalid, or when strong electromagnetic waves are detected outside, the control box will warn and remind the user to stay away. The magnetic shielding fabric can be attached to the fabric with a removable hook & loop.
Part 3: Increase Reliability With Spare Components
In the present invention, an important component can be connected in parallel with a spare component socket (as shown in
A garment-based wearable sensor must be washed, and the components on the garment (conducting wire, sensing component, integrated circuit, etc.) are easily damaged, so that the present invention is provided with a functionally identical or similar spare component on the garment connected in series or parallel with the main component, as shown in
Taking the wire as an example, the spare component is arranged close to the main component, to realize the sensing function. If the main wire is a bare wire (without insulating layer) containing metal (such as silver), the spare wire is an insulated wire (with insulating layer).
Part 4: Electronization and Maintenance of Fabric
There are two methods to electronize the fabric. The first method is to use an external component (i.e. a traditional packaged electronic component) with pins bare, and then fix to the fabric by using the textile techniques disclosed in the prior patents (such as stitching). By using this method, the electronic components can be repaired in accordance with conventional electronic and textile techniques, such as cutting the original connecting wires, and then fixing the components and connecting wires with the heat shrinkable sleeves.
As for the second method, the fabric is used as a carrier to integrate the electronic components (such as resistors, transistors, switches, diodes, antennas, etc.) on the fabric by smearing, printing, etching, lithography, etc., similar to the fabrication of flexible liquid crystals. Taking a capacitor as an example, a conductive ink containing graphite can be printed on the fabric, and the dielectric can also be applied to the conductive ink, and then another layer of conductive ink is printed to form a capacitor. Taking a resistor as an example, a conductive ink containing graphite may be printed on the fabric, and a resistive material may also be coated on the conductive ink, and then another layer of conductive ink is printed to form a resistor. In this way, the component is not easy for replacing, and if it is damaged, it must be replaced by an external component. In the garment, a socket can be prearranged, and the socket is provided with a sheath. When the external component is inserted, the original component is no longer connected. The advantage of one-piece integration is that it is more aesthetic (the components are invisible), and the disadvantage is that it is not easy to disassemble.
The sensor on the fabric may age due to factors such as drying, washing, body friction, etc., and it needs to be corrected again, that is, the calibration curve of the database is to be modified. The present invention can predict the coefficient of aging over time, or take the normal activities (e.g., breathing) as default, and then make adjustments according to the extent of each physical activity. Or take the “not worn” (not tensioned) basic values as the baseline, or take fixed external force (such as the washing force of a washing machine) as a standard value for routine calibration.
Part 5: Multifunctional Spare Wires
Taking the wire as an example, the spare component is arranged close to the main component, to realize the sensing function. If the main wire is a bare yarn (without insulating layer) containing metal (such as silver), the spare wire is an insulated wire (with insulating layer).
One end of the insulated wire is connected in series with the above mentioned selector. In normal operation, the bare conductive yarn is used first. If the ECG signal is abnormal (for example, the signal is too weak or the noise is too strong), and the temperature and humidity are not low, there may be two reasons: one is that the conductive bare yarn is broken, and the other is that sweating causes short-circuit of ECG signal. At this point, the microcontroller can switch the selector to measure the DC resistance between adjacent conductive bare yarns. If it is low, it is known to be sweaty. If it is high, it is known to be an open circuit. At this time, it can be switched to the spare wire (insulated wire). On the other hand, for the condition caused by sweat, local heating can be caused by a large current to accelerate the evaporation of sweat, and the DC resistance can be re-measured at a certain interval (for example, 60 seconds) until the body surface sweat is evaporated. The time taken to dry the sweat can also be regarded as the degree of sweat. The microcontroller can accumulate the degree of sweat. If the degree of sweat reaches a certain level, it means that the degree of sweat is too high, in which case the user will be reminded of to drink water.
The wire can also be made of a specific alloy whose conductivity changes with the outside temperature and can be used to sense body temperature or ambient temperature. In addition, the thermistor of this device can also sense changes in the user's body temperature. Some conductive plastic materials, such as LDPE conductive carbon black, are known to have electrical resistance that varies with temperature. Therefore, it can be used as a conductive transmission wire and a temperature sensor or as a heater. As the temperature drops, its resistance decreases.
The spare wire itself can be used as a sweat or temperature sensor in addition to replacing the broken main conductor. The spare wire can be installed on different parts of the garment, and each spare wire can be switched by the system by an electronic selector (see Part 1), or a turntable or a drawstring can be set on the garment for the user to manually switch. To sense a part, the system automatically or the user manually switches to the spare wire where the part is located. Several spare wires may be arranged in parallel or in a grid shape, vertically in the inner layer and horizontally in the outer layer. When a vertical spare wire and a horizontal spare wire are selected, the degree of sweat can be detected for a specified position.
Regarding the above-mentioned drawstring mechanism, the string can be pulled manually or by a cylinder, hydraulic cylinder or threaded rod.
Spare wires in different layers of spare wires can be bare wires, used to selectively transmit physiological signals or environmental signals of a certain part, such as sweat.
For the human body signal (such as electrophysiological signal), the above-mentioned grid-shaped vertical and horizontal spare wires can also be used to select a specific part. The signal is transmitted from the underwear to the outerwear, transmitted to the chair or bed where the user sits or lies in, then analyzed and processed by the control box installed on the chair or bed. For example, as shown in
As for the wearable applications, electricity is an important factor. In order to ensure sufficient power supply, the present invention can connect an electric energy recovery wire (
The transmission wire can also serve as a radio frequency (RF) antenna, power transmission wire (DC), and transmission wire for the sensing signals (AC) (as shown in
In the above example, the transmission wire is also used as a radio frequency (RF) antenna, which will inevitably interfere with the physiological signals or the signals generated from various sensors on the body. For example, the commonly used Bluetooth communication adopts the SFK (Shift Frequency Key) technology to convert between 0 and 1, and the instantaneous interference is not small. In order to reduce such interference, the amplitude modulation (AM) technology is used alternatively, and AM is also better in saving electric energy.
Similarly, it can also be used to transmit the signal obtained from the inductive pneumograph sensor at the chest to the inductive pneumograph sensor at the abdomen or the control box on a chair or bed, or transmit the signal obtained from the inductive pneumograph sensor at the upper arm to the inductive pneumograph sensor at the lower arm.
The transmission wire itself can also be used as an inductive pneumograph sensor. The preferred embodiment is that the wire is arranged in a “Z ” shape to make sufficient allowance for expansion and contraction. It can not only be used to inject current, but also be used for transmitting the signal from the outerwear to the underwear by using the wire structure as shown in
The above-mentioned grid lines can also be used to measure changes in the local part of body, for example, injecting a current into the entire coil and observing the self-inductance value of the entire coil to determine the changes in the body circumstance. If only the inductive change of front chest is observed by using the grid line, the result represents only the changes in the local part of chest. Similarly, other parts can be determined by using the same method, or measured separately as shown in the Figure. In addition, as shown in
Inductive pneumograph sensors can also be installed on the underwear and outerwear respectively at the same position of body. The mutual inductance between the two sensors represents the relative movement between the underwear and outerwear, such as the action of undressing or dressing, or a backpack pressing there, or the garment being too loose there, or the relative position change being caused by the movement of limb.
Similarly, inductive pneumograph sensors can be placed on a garment and a bed respectively. The mutual inductance between the two sensors can represent the relative movement between this bed and the person wearing this garment, and can be used for sleep monitoring or for representing the relative distance between two persons. Similarly, they can also be used for representing the relative movement between an animal and a person, or between animals.
In the above example, the mutual inductance between the two sensors can also be used for transmitting signals. For example, the chest breathing signal can be transmitted from the underwear to the outerwear, while the control box is connected between the inductive pneumograph sensors installed on the underwear and the outerwear, namely the outerwear can receive the breathing signal from the underwear. Similarly, the underwear can also receive signals from the outerwear via mutual inductance.
In the same way, the above-mentioned mutual inductance based transmission signal technology can also be used to transmit signals by using a coupling capacitor between the wires.
U.S. Pat. No. 7,750,790 B2 discloses a fabric strain gauge whose impedance changes with stress. The present invention can make a wire by using this strain gauge, and the impedance of this strain gauge also changes with the degree of moisture (sweat or humidity), so that it can also serve as a moisture sensor at the same time. The present invention can utilize the frequency domain to distinguish between breathing and moisture. The respiratory rate is usually greater than 0.1 Hz (six times per minute), while the moisture usually changes very slowly (evaporation usually takes hours), much less than 0.1 Hz. The bandpass filter can be used to distinguish between them. Similarly, the strain gauge can sense movements in other parts of the body such as raising hands and lifting legs. As in the above-mentioned example, the wire contained in this strain gauge can be made of an alloy with a large temperature coefficient, that is, it can also serve as a thermometer. The impedance of this strain gauge also changes with the electrolyte contained in the moisture (sodium, potassium, chloride ions, laundry detergent), namely it can also be used as an electrolyte sensor. Upon this principle, this strain gauge can also detect changes in the surface of skin, such as wound healing or enlargement, bleeding, iodine application, or residual detergent on garment.
Magnets are arranged in the inner layer of garment, and a coil is placed in the outer layer of garment. The interaction between the magnet and coil will produce an induced current. Therefore, the mutual movement between the two pieces of fabric can be known, and the message can also be transmitted. In principle, the greater the mutual movement between the two magnets and the coil, the greater the current generated. As shown in
Optical fiber has such advantages: it is not susceptible to interference from wireless batteries or electric fields or magnetic fields! Similarly, the two optical fibers are respectively installed in the outer layer and inner layer of the garment, and can also conduct light when touched. That is to say, the above-mentioned effects can also be achieved by using optical fibers.
Part 6: Method for Using Fabric to Generate Electrical Energy
Magnetic materials (conductive materials, made of electromagnetic materials) are oscillated on the fabric to generate electricity. On a piece of fabric, install a sealing device that contains a piece of magnetic material. The sealing device has a winding conductive coil outside, and another magnetic material is mounted on the fabric above the sealing device. The magnetic material can swing freely. Therefore, if the two magnetic materials are same in magnetic poles, and the magnetic material is on the right side, the magnetic material in the sealing device will slide to the left side due to repulsion (as shown in
The principle in the following figure (
Part 7: Normal Operating Procedures and Functions
The normal operating procedure of the present invention begins with the purchase of garment by the user, as described below.
1. The garment itself has a sensor. Once it is moved (taken down from a hanger), the digital circuit on the garment is activated and begins to conduct self-check. In addition, even if it is not subjected to external force, it can detect the entire system from time to time. Thus the user can learn about how long it has been from the time of manufacture to sale, and whether the functions inside have declined. For example, if the foregoing circuit inspection wires and sensors are damaged, the spare components will be used as substitutes, with results displayed. For example, the green light is normal, and the red light means some abnormalities. The control box is turned on, the self-cheek is performed first, and then the communication with the garment is established. The wired communication is preferentially used. If the wired communication cannot be used, the wireless communication is then used.
2. When a user buys a garment and tries it on, the sensor on the garment will start to work. If it is too loose or too tight, the user will be reminded and recommended with an appropriate size. If there is still a slight discomfort, the user will be reminded to modify and adjust the strap string or the hook & loop, etc., to ensure the optimized effects based on the signals detected.
It is not necessary to wear the garment for another method. The user can use a 3D dynamic fitting system to dynamically try it on in front of the computer supported dressing mirror to correct the size of the model, and then try it on again before purchase, saving time and improving efficiency.
3. Once the garment is confirmed as fitted, the system will conduct self-correction (passive correction). The results are stored in the memory as described above, and are uploaded to the cloud database at proper time.
4. After the self-correction is completed, the aforementioned energy pick-up mechanism is activated, to determine the physiological parameters (electrocardiogram, respiration, body temperature, etc.) and environmental parameters (room temperature, humidity, etc.) as described above. The physiological and environmental parameters acquired will be uploaded to the cloud database at proper time, and then can be used for long-term trend analysis.
5. The control box checks the signal quality and advises the user to make appropriate adjustments. The controller itself can be placed directly on the garment and be formed in one piece with the garment. Taking the ECG as an example, if the signal/noise ratio is too low, the reason is that the electrode is not properly attached to the human body, and then the user may be advised to slightly tighten the strap to improve the quality of the electrocardiogram. At the same time, based on the database of the aging of the relevant components, the aging of the component can be estimated, and the response curve can be adjusted to obtain the best measurement accuracy. The set values after adjusted will be uploaded to the cloud database at proper time, and then can be used for long-term trend analysis.
6. The information stored in the memory on the digital circuit of garment will be uploaded at proper time as described above, or the memory may be a SD memory or alike which can be connected or disconnected freely.
7. If the user wears it for a long time, or if the ambient temperature or humidity change in a wide range, leading to any potential deviations from the set values, the garment can conduct self-correction automatically.
8. When the user takes off the garment and prepares for washing, the digital circuit in the garment will operate continuously to record the environment conditions, such as washing, drying or being stored in the closet, or the washing power, drying temperature and humidity, etc. These factors will affect the response curve and service life of the sensor. The response curves can be adjusted according to such records, and can be used for estimating the residual life of sensor, to remind the user to repair it at proper time.