CN111529923A - Wearable device providing electronic pulses and control method thereof - Google Patents

Abstract

The invention relates to a wearable device for providing electronic pulses and a control method thereof. A wearable device for providing electronic impulses comprises an acquisition module for acquiring physiological information; the control module is connected with the acquisition module and used for selecting a corresponding output mode according to the acquired physiological information and controlling the output of the electronic pulse; the electrode plate is arranged on one side, which is in contact with a human body, of the wearable device, and is connected with the control module and used for outputting electronic pulses; wherein the output pattern is determined by any one or any combination of frequency, pulse width, intensity, duration of the electronic pulses. A control method is used for the wearable device for providing the electronic pulse. The wearable device for providing the electronic pulse and the control method thereof can output the electronic pulse according to different conditions to carry out TENS/TEAS health care, and are convenient to carry and convenient to operate.

Description

Wearable device providing electronic pulses and control method thereof

Technical Field

The invention relates to the technical field of wearable equipment, in particular to wearable equipment for providing electronic pulse and a control method thereof.

Background

Electronic Acupuncture (TEAS) and electronic Nerve Stimulation (TENS) stimulate specific tissues, acupuncture points and nerves by electricity to achieve the effects of relieving pain and fatigue. At present, the traditional electronic acupuncture and acupuncture point therapeutic apparatus and equipment special for medical institutions or for household use can provide stimulation, vibration and massage functions of different parts of the body, acupuncture points and nerves through electronic acupuncture and acupuncture points, ultrasonic waves or laser, but the equipment is usually large in size, single in function and inconvenient to carry.

Disclosure of Invention

In view of the above, it is necessary to provide a wearable device for providing an electronic pulse and a control method thereof.

A wearable device for providing electronic impulses comprises an acquisition module for acquiring physiological information; the control module is connected with the acquisition module and used for selecting a corresponding output mode according to the acquired physiological information and controlling the output of the electronic pulse; the electrode plate is arranged on one side, which is in contact with a human body, of the wearable device, and is connected with the control module and used for outputting electronic pulses; wherein the output pattern is determined by any one or any combination of frequency, pulse width, intensity, duration of the electronic pulses.

Above-mentioned provide electronic pulse's wearable equipment gathers human physiological information through collection module to select suitable output mode according to the human physiological information who gathers, control electrode slice output electronic pulse, amazing human corresponding acupuncture point, carry out TENS/TEAS health care, portable, and the simple operation.

In one embodiment, the electrode pad may assist in acquiring physiological information.

In one embodiment, the electrode slice comprises a plurality of partitions, the plurality of partitions can be controlled independently, and the output mode further comprises activation information of each partition.

In one embodiment, the plurality of partitions of the electrode sheet are distributed in an array.

In one embodiment, the device further comprises a communication module, wherein the communication module is connected with the acquisition module and the control module and is used for sending the physiological information acquired by the acquisition module to a remote server and sending the received information of the remote server to the control module.

In one embodiment, the communication module is further used for positioning the wearable device, and the positioning is realized by long-distance radio (LORA).

In one embodiment, the communication module can also be in communication connection with other wearable devices.

In one embodiment, the wearable device is a wrist-worn wearable device.

A method of controlling a wearable device that provides an electronic pulse, comprising: collecting physiological information; selecting a corresponding output mode according to the acquired physiological information to control the output of the electronic pulse; outputting an electronic pulse; wherein the output pattern is determined by the frequency, pulse width, intensity, duration of the electronic pulses, and any combination thereof.

In one embodiment, the output mode further includes activation information of a partition of the electrode pad, the partition can be controlled independently, a corresponding output mode is selected according to the collected physiological information, and the output of the electronic pulse is controlled.

The control method of the wearable device capable of providing the electronic pulse can select different output modes according to different conditions, stimulate corresponding acupuncture points of a human body, perform TENS/TEAS health care, is used for the wearable device, is convenient to carry and is convenient and fast to operate.

Drawings

Fig. 1 is a schematic diagram of an embodiment of a wearable device providing electronic pulses according to the present application;

FIG. 2 is a schematic structural diagram of one embodiment of a wearable device for providing electronic impulses according to the present application;

FIG. 3 is a schematic diagram of electrode pad zones of an embodiment of a wearable device providing electronic pulses according to the present application;

FIG. 4 is a schematic diagram of electrode pad zones of yet another embodiment of a wearable device providing electronic pulses according to the present application;

FIG. 5 is a flow chart of an embodiment of a method of controlling a wearable device that provides electronic pulses according to the present application;

fig. 6 is a flowchart of another embodiment of a method of controlling a wearable device that provides electronic pulses according to the present application.

Detailed Description

Referring to fig. 1 and fig. 2, fig. 1 is a schematic diagram of an embodiment of a wearable device for providing electronic pulses according to the present application, and fig. 2 is a block diagram of an embodiment of a wearable device for providing electronic pulses according to the present application. As shown, the wearable device 100 includes an acquisition module 110, a control module 120, and an electrode pad 130. The acquisition module 110, including but not limited to an acceleration sensor, a pressure sensor, a heart rate sensor, etc., is used for acquiring physiological information of the wearer, including clinical indicators, behavioral indicators, psychosocial indicators, etc. Clinical indicators include, but are not limited to, heart rate variability, respiration, blood pressure, etc.; behavioral indicators include, but are not limited to, sleep stage and quality, type and duration of exercise, etc.; psychosocial indicators include, but are not limited to, mood, stress, anxiety symptoms, and the like. The control module 120 is connected to the collecting module 130, and the control module 120 may be a microprocessor or other integrated circuit, and is configured to select a corresponding output mode according to the collected physiological information, and control the output of the electronic pulse. The output pattern is determined by any one or any combination of the frequency, pulse width, intensity, duration of the electronic pulses. For example, depending on the stress and anxiety symptoms collected, or on the heart rate and blood pressure conditions collected, when stress is greater, the relaxation mode is selected to help relax and improve sleep. The selection of the output mode may be performed by automatic matching selection according to a preset list, or may be manually set, for example, during learning, a concentration mode is selected to improve attention. Of course, the control module 120 may also generate a corresponding output mode according to the collected physiological information. The electrode sheet 130 is disposed on the wearable device 100 on a side contacting the human body, and is attached to the skin of the human body. The electrode pad 130 is connected to the control module 120 for outputting an electronic pulse according to a selected output mode.

Peripheral electrical stimulation can modulate the release of central neuropeptides as electrical stimulation can excite nerve fibers, which can be transmitted to the innervating muscles, thereby causing muscle contraction. The threshold stimuli causing nerve fiber and tissue excitation are different, so the output mode can be adjusted according to different scenes of application. Can be applied to daily health care, pain relief, muscle spasm relief, muscle fatigue relief, and muscle paralysis/atrophy and other scenes caused by motor neuron damage. According to the characteristics of low resistance of the acupuncture points and the phenomenon of channel-following sensing, the corresponding acupuncture points are stimulated to assist in determining that the wearable equipment is worn in place. For example, in one embodiment, the wearable device is a bracelet or a smart watch, the electrode plate is attached to a pericardium channel of hand jueyin on the inner side of the wrist of a human body to pass through an acupoint, namely Neiguan (the acupoint is located in a contact area of the electrode plate and the skin on the inner side of the wrist), and by outputting electronic pulses, the wearable device can help to improve insomnia, relieve stomach ache, vomiting and other discomforts.

The wearable equipment that provides electronic pulse of this application passes through collection module and gathers human physiological information to select suitable output mode according to the human physiological information who gathers, control electrode slice output electronic pulse stimulates the corresponding acupuncture point of human body, carries out TENS/TEAS health care, portable, and the simple operation.

In one embodiment, the acquisition module 110 may also acquire and monitor physiological information in real time. When the output mode is selected and enabled, the acquisition module 110 is triggered to perform real-time acquisition and monitoring, such as heart rate monitoring, and when the real-time monitored heart rate exceeds a certain threshold, an alarm message is provided or the output of the electronic pulse is stopped. Thereby can effectively guarantee the safety in utilization of the wearable equipment that provides electronic pulse. In one embodiment, the real-time acquisition and monitoring of the acquisition module 110 may be activated even when the output mode is not selected and enabled, i.e., no electronic pulse output, in which case the acquisition module 110 may continuously acquire and monitor physiological information and store the relevant information to provide more reliable data information for selection of a subsequent output mode.

In one embodiment, the electrode pad 130 may assist in acquiring physiological information. For example, the electrode sheet 130 may apply a weak current to the skin of the human body in contact therewith, and measure the skin resistance and other indexes of the corresponding position of the human body by the applied current. Since the skin resistance is closely related to the perspiration level and the mental stress, the skin resistance measurement can also monitor the exercise condition and/or the mental condition of the wearer in real time, and provide the exercise condition and/or the mental condition to the control module 120 as auxiliary physiological information, so as to be referenced by the control module 120 together with the physiological information (heart rate, blood pressure, etc.) collected by the collection module 110, so as to select the appropriate output mode more precisely.

Fig. 3 is a schematic diagram of electrode pad partitions of an embodiment of a wearable device for providing electronic pulses according to the present application. As shown, the electrode sheet 130 may include a plurality of partitions 131, 132, 133, each of which may individually control and output pulses, and an output pattern further includes activation information of each partition. The activation information may include any one or any combination of an activation status, an activation duration, and an activation timing. According to different output modes, partial partitions or combinations of different partitions can be selected to output the electronic pulse. For example, during a first time period, partition 131, 133 is activated to output an electronic pulse, and partition 132 does not output an electronic pulse; during a second time period, partition 132, 133 is activated to output an electronic pulse, partition 131 stops outputting an electronic pulse, and so on. Therefore, the stimulation effect can be more accurately and effectively realized under the condition that the acupuncture points are dense or the contact area of the electrode plate is large.

Fig. 4 is a schematic diagram of electrode pad partitions of an embodiment of a wearable device for providing electronic pulses according to the present application. As shown, the electrode pads 130 are divided into i rows and n columns in an array. The corresponding subareas are divided in an array mode, so that the control can be more accurate. In one embodiment, the electrode sheet 130 is not limited to a single sheet, but may be a plurality of electrode sheets, so that the control of the corresponding partition may also be the control of the plurality of electrode sheets.

In one embodiment, the wearable device 100 for providing the electronic pulse may further include a communication module 140, and the communication module 140 is connected to the acquisition module 110 and the control module 120, and is configured to transmit the physiological information acquired by the acquisition module 110 to a remote server (not shown), and transmit the received information from the remote server to the control module 120. By means of the communication module 140, the wearable device 100 providing the electronic pulse can be connected with a remote server, so that the physiological information collected by the collection module 110 can be sent to the remote server, and the analysis capability of the wearable device 100 can be expanded. For example, the remote server can perform big data analysis according to the received collected physiological information, calculate and recommend a proper output mode according to a certain algorithm and send the output mode to the control module, so that the selection of the output mode is more accurate. Further, by means of the communication module 140, the personal health information of the user can be customized and a personalized output mode can be generated by combining the physiological information collected and monitored in real time by the collection module 110 by means of the support function of the remote server, so that the applicability of the wearable device 100 is greatly improved.

In one embodiment, the communication module 140 may be further configured to connect with a mobile terminal (e.g., a smart phone) and receive information from the mobile terminal (e.g., via an application installed on the mobile terminal) and send the information to the control module 120. Further, the mobile terminal may connect with a remote server (e.g., through an application installed on the mobile terminal), transmit information received from the communication module 140 to the remote server, and transmit information received from the remote server to the communication module 140.

In one embodiment, the communication module 140 is also used for positioning the wearable device 100, and the positioning is performed by long-range radio (load), which is lower in power consumption and more accurate in positioning compared to the conventional GPS positioning, so that the cruising ability of the wearable device 100 can be extended and the cost is lower.

In one embodiment, the communication module 140 can also perform communication connection with other wearable devices, and the connection can be contact type or non-contact type. Such as physical connection via a connection line, or connection via wireless communication. In this case, if the wearer wears other wearable devices (e.g., a smart helmet) besides the wearable device 100 providing the electronic pulse according to the present application, and the smart helmet collects certain physiological information, the physiological information collected by the smart helmet can be received by the communication module 140 and provided to the control module 120, so that the selection of the output mode is more accurate. In this way, the wearable device 100 for providing electronic pulses of the present application can be used not only independently, but also in combination with other wearable devices, so as to improve the extensibility thereof and enable the output to be more accurate and effective.

Please refer to fig. 5, which is a flowchart illustrating an embodiment of a method for controlling a wearable device providing electronic pulses according to the present application. The control method comprises the following steps:

step S110 collects physiological information. The physiological information includes clinical index, behavior index, psychosocial index, and the like. Clinical indicators include, but are not limited to, heart rate variability, respiration, blood pressure, etc.; behavioral indicators include, but are not limited to, sleep stage and quality, type and duration of exercise, etc.; psychosocial indicators include, but are not limited to, mood, stress, anxiety symptoms, and the like.

Step S130 selects a corresponding output mode according to the collected physiological information, and controls the output of the electronic pulse. For example, depending on the stress and anxiety symptoms collected, or on the heart rate and blood pressure conditions collected, when stress is greater, the relaxation mode is selected to help relax and improve sleep. The selection of the output mode may be performed by automatic matching selection according to a preset list, or may be manually set, for example, during learning, a concentration mode is selected to improve attention. The output pattern is determined by the frequency, pulse width, intensity, duration of the electronic pulses, and any combination thereof.

Step S150 outputs an electronic pulse to realize the stimulation of the acupuncture points.

Peripheral electrical stimulation can modulate the release of central neuropeptides as electrical stimulation can excite nerve fibers, which can be transmitted to the innervating muscles, thereby causing muscle contraction. The threshold stimuli causing nerve fiber and tissue excitation are different, so the output mode can be adjusted according to different scenes of application. Can be applied to daily health care, pain relief, muscle spasm relief, muscle fatigue relief, and muscle paralysis/atrophy and other scenes caused by motor neuron damage. The control method of the wearable device capable of providing the electronic pulse can select different output modes according to different conditions, stimulate corresponding acupuncture points of a human body, perform TENS/TEAS health care, and is used for the wearable device, convenient to carry and convenient to operate.

In one embodiment, collecting physiological information includes collecting and monitoring physiological information in real-time. When the output mode is selected and started, physiological information is collected and monitored in real time, for example, heart rate monitoring is carried out, and when the heart rate monitored in real time exceeds a certain threshold value, alarm information is provided or the electronic pulse is stopped being output. Thereby can effectively guarantee the safety in utilization of the wearable equipment that provides electronic pulse. In one embodiment, the physiological information can be collected and monitored in real time even without selecting and activating the output mode, i.e., without the electronic pulse output, in which case more reliable data information is provided for selection of the subsequent output mode by continuously collecting and monitoring the physiological information and storing the relevant information.

In one embodiment, the output mode further includes activation information of a partition of the electrode pad, the step S300 selects a corresponding output mode according to the collected physiological information, and the controlling of the output of the electronic pulse further includes activating a corresponding partition of the electrode pad. In this embodiment, the electrode sheet may include a plurality of partitions, and each partition may individually control and output pulses. The electronic pulse can be output by selecting partial partitions or combinations of different partitions according to different output modes, and the output modes can further comprise activation time sequences of different partitions. Therefore, the stimulation effect can be more accurately and effectively realized under the condition that the acupuncture points are dense or the contact area of the electrode plate is large.

Referring to fig. 6, a flow chart of another embodiment of a method of controlling a wearable device providing electronic pulses according to the present application is shown. In this example, the method further includes step S220 of sending the collected physiological information to a remote server, and step S230 of selecting a corresponding output mode according to the received information of the remote server, and controlling the output of the electronic pulse. In the embodiment, the analysis capability of the wearable device can be expanded by sending the collected physiological information to the remote server, for example, the remote server can perform big data analysis according to the received collected physiological information, and calculate and recommend a proper output mode according to a certain algorithm, so that the selection of the output mode is more accurate. Furthermore, by sending the collected physiological information to the remote server, the personal health information of the user can be customized and an individualized output mode can be generated by combining the physiological information collected and monitored in real time by depending on the support function of the remote server, so that the applicability of the wearable device 100 is greatly improved.

In one embodiment, the control method of the wearable device providing the electronic pulse according to the present application performs positioning by long-range radio (load), which has lower power consumption and more accurate positioning compared to the conventional GPS positioning, thereby prolonging the cruising ability of the wearable device 100 and reducing the cost.

The wearable device described above includes, but is not limited to, a wristband type wearable device (e.g., a smart watch, a smart bracelet), a smart helmet, glasses, and the like, wherein the electrode sheet may be disposed on any surface of the wearable device that is in contact with the skin, and is not limited to the inside of the dial plate of the smart watch, and may also be disposed on a watchband, and the like, which is not particularly limited thereto.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. A wearable device for providing electronic impulses, comprising

The acquisition module is used for acquiring physiological information;

the control module is connected with the acquisition module and used for selecting a corresponding output mode according to the acquired physiological information and controlling the output of the electronic pulse; and

the electrode plate is arranged on one side, which is in contact with a human body, of the wearable device, and is connected with the control module and used for outputting the electronic pulse;

wherein the output pattern is determined by any one or any combination of frequency, pulse width, intensity, duration of the electronic pulses.

2. The wearable device providing electronic pulses according to claim 1, wherein the electrode pads may assist in acquiring physiological information.

3. The wearable device providing electronic pulses according to claim 1, wherein the electrode pad comprises a plurality of zones, the plurality of zones being individually controllable, the output pattern further comprising activation information for each of the zones.

4. The wearable device providing electronic pulses according to claim 3, wherein the plurality of segments of the electrode pad are distributed in an array.

5. The wearable device for providing electronic pulse according to claim 1, further comprising a communication module connected to the collection module and the control module for transmitting the physiological information collected by the collection module to a remote server and transmitting the received information of the remote server to the control module.

6. The wearable device providing electronic impulses according to claim 5, characterized in that the communication module is also used for the positioning of the wearable device, said positioning being realized by long distance radio (LORA).

7. The wearable device for providing electronic pulses according to claim 5, wherein the communication module is further capable of being communicatively coupled to other wearable devices.

8. Wearable device providing electronic impulses according to any of the claims 1 to 7, characterized in that it is a wrist band wearable device.

9. A method of controlling a wearable device that provides an electronic pulse, comprising:

collecting physiological information;

selecting a corresponding output mode according to the acquired physiological information, and controlling the output of the electronic pulse;

outputting an electronic pulse; wherein the output pattern is determined by a frequency, a pulse width, an intensity, a duration of the electronic pulse, and any combination thereof.

10. The control method according to claim 9, wherein the output pattern further includes activation information of a section of an electrode pad, the section being individually controllable, the corresponding output pattern being selected to control output of the electronic pulse according to the collected physiological information, and further including activating the corresponding section of the electrode pad.

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