WO2015139522A1

WO2015139522A1 - Wrist-type apparatus used for health monitoring

Info

Publication number: WO2015139522A1
Application number: PCT/CN2015/070722
Authority: WO
Inventors: 辛勤
Original assignee: 辛勤
Priority date: 2014-03-21
Filing date: 2015-01-15
Publication date: 2015-09-24
Also published as: CN103892804A

Abstract

A wrist-type apparatus used for health monitoring comprises a physiological parameter measurement device (100), an intelligent matching terminal (200), a first flexible wrist band (300), and a second flexible wrist band (400). The physiological parameter measurement device (100) is used for acquiring a physiological parameter of a human body and sending the physiological parameter to the intelligent matching terminal (200). The intelligent matching terminal (200) is used for connecting to the wireless Internet and uploading the physiological parameter to a background server (201) through the wireless Internet, and is further used for receiving a feedback result for the physiological parameter from the background server (201) through the wireless Internet and displaying the feedback result. The physiological parameter measurement device (100), the intelligent matching terminal (200), the first flexible wrist band (300), and the second flexible wrist band (400) are integrally combined to form an annular wrist-type wearing structure surrounding a wrist of the human body.

Description

Wrist device for health monitoring

Technical field

The present invention relates to the field of medical sensing technology and electronic communication, and more particularly to a wrist device for health monitoring.

Background technique

At present, with the improvement of living standards and people's attention to personal health conditions, medical measuring devices that are convenient for the general public are widely used. Human physiological parameters are a series of indicators that measure the physiological state of the human body in medicine, including pulse, blood pressure, blood sugar, and blood oxygen saturation. The physiological parameters macroscopically reflect the physical condition of the human body, and have very important early warning and guidance for disease prediction and body maintenance. Usually the physiological parameters are obtained by people undergoing physical examinations at the hospital. However, with the advancement of technology, more and more miniaturized and family-based portable physiological parameter measuring devices have been introduced, which are favored by people.

In the prior art, a portable physiological parameter measuring device is often used in conjunction with a smart phone, and the data processing capability and data display capability of the smart phone are used in conjunction with the portable physiological parameter measuring device, and the smart phone communicates with the portable physiological parameter measuring device via Bluetooth, and receives The physiological parameters measured by the portable physiological parameter measuring device. Bluetooth is a wireless technology for short-distance communication. Therefore, when using the portable physiological parameter measuring device based on the above, the user needs to carry the portable physiological parameter measuring device and the smart phone at the same time, but the prior art does not provide an effective and convenient method. The structural combination scheme enables the user to carry the portable physiological parameter measuring device and the smart phone described above at the same time.

Summary of the invention

In order to overcome the above-mentioned drawbacks in the prior art, the present invention provides a wrist device for health monitoring, the wrist device comprising a physiological parameter measuring device, an intelligent matching terminal, a first flexible wristband and a second flexible wristband ,among them:

The physiological parameter measuring device is configured to obtain a physiological parameter of a human body, and send the physiological parameter to the smart matching terminal;

The smart matching terminal is configured to access a wireless internet and pass the wireless internet The physiological parameter is uploaded to the background server, and is further configured to receive, by using the wireless internet, a feedback result of the background server for the physiological parameter, and display the feedback result;

The two ends of the first flexible wristband are respectively connected to the physiological parameter measuring device and the smart matching terminal, and the two ends of the second flexible wristband are respectively connected to the physiological parameter measuring device and the smart matching terminal. The physiological parameter measuring device, the smart matching terminal, the first flexible wristband and the second flexible wristband are integrally combined as an annular wrist wearing structure for wrapping around a wrist of a human body.

According to an aspect of the invention, the physiological parameter measuring device in the wrist device includes a sealed casing, the light emitting and receiving unit and the processing unit are disposed inside the sealed casing; the sealed casing A waterproof window is disposed thereon through which the measurement light of the at least one wavelength penetrates from the inside of the sealed casing to the outside of the sealed casing.

According to another aspect of the present invention, obtaining, by the portable measuring device in the wrist device, the physiological parameter of the measured object includes: the portable measuring device transmitting the measuring light of the at least one wavelength to the body surface skin of the measured object, And receiving the reflected light of the measurement light; and the portable measurement device processes the reflected light to obtain the physiological parameter.

According to still another aspect of the present invention, in the wrist device, when the annular wrist wearing structure surrounds the wrist of the human body, the first flexible wristband and/or the second flexible wristband The length is configured such that the waterproof window is aligned with the radial artery skin and the smart mating terminal is located on a side of the wrist that is immediately adjacent to the back of the palm of the human body.

According to still another aspect of the present invention, the first flexible wristband and/or the second flexible wristband in the wrist device further includes a flexible wire encapsulated in the first flexible wristband and/or Or a body of the second flexible wristband; the physiological parameter measuring device transmits the physiological parameter to the smart matching terminal through the flexible wire

According to still another aspect of the present invention, the first flexible wristband and/or the second flexible wristband of the wrist device are provided with a limit buckle structure for adjusting the length.

According to still another aspect of the present invention, a connection of short-range wireless communication is established between the physiological parameter measuring device and the smart matching terminal in the wrist device, and the physiological parameter measuring device is connected through the short-range wireless communication Sending the physiological parameter to the smart matching terminal. .

According to still another aspect of the present invention, the short-range wireless communication in the wrist device includes Bluetooth communication.

According to still another aspect of the present invention, the measurement light of the at least one wavelength in the wrist device comprises: red light and/or infrared light.

According to still another aspect of the present invention, the wavelength of the red light in the wrist device ranges from 660 nm ± 3 nm; the wavelength of the infrared light ranges from 940 nm ± 10 nm, or the wavelength of the infrared light is 9600 nm.

According to still another aspect of the present invention, the smart matching terminal in the wrist device is a smart watch.

The wrist device for health monitoring provided by the invention has the following advantages: the physiological parameter measuring device and the smart matching terminal are mechanically connected and fixed by the first flexible wristband and the second flexible wristband to form a body-friendly wearing body. The ring-shaped wrist-worn structure is convenient for the user to carry around to enhance the portability of the wrist device.

DRAWINGS

Other features, objects, and advantages of the present invention will become more apparent from the Detailed Description of Description

Figure 1 is a perspective view of a wrist device for health monitoring in accordance with the present invention;

Figure 2 is a side view of the wrist device shown in Figure 1;

Figure 3 is a schematic view of the wrist device of Figure 1 corresponding to the wearing position of the human wrist;

4 is a schematic structural diagram of an intelligent terminal that can be used to implement the smart matching terminal in the wrist device provided in FIG. 1 or FIG. 2.

The same or similar reference numerals in the drawings denote the same or similar components.

detailed description

In order to better understand and explain the present invention, the present invention will be further described in detail with reference to the accompanying drawings.

Please refer to FIG. 1. FIG. 1 is a perspective view of a wrist device for health monitoring according to the present invention. The wrist device includes a physiological parameter measuring device 100, a smart matching terminal 200, a first flexible wristband 300 and a second flexible wrist. With 400, where:

The physiological parameter measuring device 100 is configured to obtain physiological parameters of the human body, and send the physiological parameters to the smart matching terminal 200;

The smart matching terminal 200 is configured to access the wireless Internet, and upload the physiological parameter to the background server 201 through the wireless internet, and is further configured to receive, by the wireless internet, the background server 201 for the physiological parameter. Feedback the results and display the feedback results;

The two ends of the first flexible wristband 300 are respectively connected to the physiological parameter measuring device 100 and the smart matching terminal 200, and the two ends of the second flexible wristband 400 are respectively connected to the physiological parameter measuring device 100 and the The smart matching terminal 200, the physiological parameter measuring device 100, the smart matching terminal 200, the first flexible wristband 300 and the second flexible wristband 400 are integrally combined for a ring around the wrist of the human body. Wrist-worn structure.

Specifically, the physiological parameter measuring apparatus 100 includes: a light emitting and receiving unit configured to transmit at least one wavelength of measurement light to the radial artery skin of the wrist of the human body, and receive the reflected light of the measurement light; And a processing unit, configured to process the reflected light to obtain the physiological parameter. Typically, the light emitting and receiving unit uses a light reflection method to measure various physiological parameters of the object to be measured, and the specific principle is to use the light emitter to transmit light waves to the human body tissue, and the light waves are reflected by the human body tissue to generate reflected light. The light receiver receives the reflected light and analyzes the physiological condition of the human body reflected by the reflected light, thereby achieving the purpose of measuring physiological parameters of the human body. Specifically, the term "physiological parameter" as referred to herein includes any one or combination of a pulse parameter, a blood pressure parameter, a blood glucose parameter, a blood oxygen saturation parameter.

The light emitting and receiving unit is configured to transmit at least one wavelength of measurement light to the brachial artery skin of the wrist of the human body, and receive the reflected light of the measurement light, so that the light emitting and receiving unit can use the photoelectricity capable of satisfying the above functions The sensor is implemented. For example, the physiological parameter currently required to be measured is a pulse parameter. According to the principle of measuring the pulse parameter by the light reflection method, the measurement light may be red light or infrared light, and thus the light emitting and receiving unit may be a photoelectric sensor capable of generating red light. It can also be a photoelectric sensor that can generate infrared light, or a photoelectric sensor that can generate both red light and infrared light; when the physiological parameter currently required to be measured is a blood oxygen saturation parameter, blood is measured according to the dual wavelength reflection method. The principle of the oxygen saturation parameter requires the combination of two wavelengths of measurement light to be realized. Therefore, the light emitting and receiving unit is a photoelectric sensor capable of generating measurement light of two different wavelengths of red light and infrared light; When the parameter is a blood glucose parameter, blood glucose is measured according to the light reflection method. The principle of the parameter, the measurement light can be realized using infrared light having a relatively large wavelength (for example, 9600 nm), and thus the light emitting and receiving unit is a photoelectric sensor capable of generating the above-described infrared light having a wavelength of 9600 nm. Correspondingly, if the physiological parameter currently required to be measured is a blood pressure parameter, the blood pressure parameter can be measured by the pulse parameter, so the hardware requirement for the light emitting and receiving unit in such a case is equivalent to measuring the pulse parameter.

Preferably, the measuring light of the at least one wavelength comprises: red light and/or infrared light. Typically, the light emitting and receiving unit can be implemented using an NJL5501R chip, which is a photosensor that produces red and infrared light. To meet the need to measure the physiological parameters, the wavelength of red light emitted by the NJL5501R chip is 660 nm ± 3 nm, and the wavelength of the infrared light is 940 nm ± 10 nm. Optionally, the light emitting and receiving unit further integrates a photosensor that emits infrared light having a wavelength of 9600 nm.

According to the functional requirements of the processing unit, the processing unit can be implemented using a common single chip, such as the MK20DN512VLK10 chip. It should be understood by those skilled in the art that the processing unit or the optical transmitting and receiving unit should include a suitable analog-to-digital conversion chip for converting the reflected optical signal received by the optical transmitting and receiving unit into a digital signal for The processing unit performs processing.

In order to ensure that various electronic components in the physiological parameter measuring device 100 can work normally with the wearer, as shown in FIG. 1, preferably the physiological parameter measuring device 100 includes a sealed housing 110, the light emitting and receiving unit And the processing unit is disposed inside the sealed housing 110; a waterproof window 120 is disposed on the sealed housing, and the at least one wavelength of measurement light passes through the waterproof window 120 from the inside of the sealed housing 110 It penetrates to the outside of the sealed casing 110.

Typically, the smart matching device 200 can be implemented using any of the existing smart watches including, but not limited to, terminal operations such as Symbian, Windows Mobile, iOS, Android, Maemo, WebOS, Palm OS, or Blackberry OS. The system's smart watch. Preferably, the smart watch has a waterproof package structure.

In order to facilitate the wearing and comfort of the human body, the first flexible wristband 300 and/or the second flexible wristband 400 are arranged in an adjustable length structure. Please refer to FIG. 2, which is the wrist shown in FIG. A side view of the device, in this embodiment, the first flexible wristband 300 has the above-mentioned adjustable length structure, and the first flexible wristband 300 is provided with a limit buckle structure 310 for adjusting the length, which is convenient for the user. According to a specific wrist outer diameter adjustment physiological parameter measuring device 100, the smart matching terminal 200, the first flexible wristband 300 and the second flexible wristband 400 are integrally combined for ringing around a wrist of a human body The inner diameter of the wrist-worn structure. Of course, in other embodiments, a structure similar to the limit button structure 310 can also be disposed on the second flexible wrist band 400. The first flexible wristband 300 and the second flexible wristband 400 may be composed of a combination of various components including metal, rubber, cloth, organic polymeric material, leather, and the like.

In a preferred embodiment, the physiological parameter measuring device 100 and the smart matching device 200 communicate via short-range wireless communication, and the physiological parameter measuring device 100 transmits the physiological parameter to the device through the connection of the short-range wireless communication. The smart matching terminal 200 refers to any one of Bluetooth, ZigBee, UWB, IrDA, HomeRF, Wi-Fi or a combination thereof. In the embodiment illustrated in FIG. 2, the short-range wireless communication selects Bluetooth communication based on low power consumption and ease of development considerations.

In another embodiment, the first flexible wristband 300 and/or the second flexible wristband 400 further comprise a flexible wire encapsulated in the first flexible wristband and/or the second The body of the flexible wristband is in the body; the physiological parameter measuring device 100 transmits the physiological parameter to the smart matching terminal 200 through the flexible wire.

Preferably, when the annular wrist wearing structure surrounds the wrist of the human body, the length of the first flexible wristband 300 and/or the second flexible wristband 400 is configured such that the waterproof window 120 The brachial artery skin is aligned and the smart mating terminal 200 is located on the side of the wrist that is immediately adjacent to the back of the palm of the human body. Please refer to FIG. 3. FIG. 3 is a schematic diagram of the wrist device shown in FIG. 1 corresponding to the wearing position of the wrist of the human body. As shown in FIG. 3, the wrist device provided by the present invention can be worn on the wrist of the human body. The length of the first flexible wristband 300 and/or the second flexible wristband 400 is adjusted such that the waterproof window 120 is aligned with the radial artery skin 101 of the wrist of the human body in order to achieve an optimal measurement.

Please refer to FIG. 4. FIG. 4 is a schematic structural diagram of an intelligent terminal that can be used to implement the smart matching terminal in the wrist device provided in FIG. 1 or FIG. 2, and FIG. 4 schematically shows a common structure of the smart terminal. Figure 4 illustrates the internal components, software, and protocol structure of a common smart terminal.

The smart terminal has a processor 510 that is responsible for the overall operation of the smart terminal and can utilize any commercially available central processing unit, digital signal processor or any other electronic programmable logic Device implementation. Processor 510 has an associated memory 520 that includes, but is not limited to, RAM memory, ROM memory, EEPROM memory, flash memory, or a combination thereof. Memory 520 is controlled by processor 500 for a variety of purposes, one of which is to store program instructions and data for various software in the smart terminal.

The software layer of the smart terminal includes a real-time operating system 540, a driver for the human machine interface 560, an application processor 550, and various applications. The applications are, for example, a text editor 551, a handwriting recognition application 552, and various other multimedia applications 553, typically including other voice applications, video call applications, send and receive short message service (SMS) messaging applications, Multimedia Messaging Service (MMS) application or email application, web browser, instant messaging application, phonebook application, calendar application, control panel application, camera application, one or more video games, notepad application, and the like. It should be noted that two or more of the above applications may be performed as the same application.

The smart terminal also includes one or more hardware controllers for use with the driver of the human machine interface 560 with the display device 561, physical buttons 562, microphone 563, and various other I/O devices (such as speakers, vibrators, Bell generators, LED indicators, etc. cooperate to implement human-computer interaction of the smart terminal. Those skilled in the art will appreciate that the user can operate the smart terminal through the human machine interface 560 thus formed.

The software layer of the intelligent terminal may also include communication-related logic such as various modules, protocol stacks, drivers, etc., which are summarized as a communication interface 570 as shown in FIG. 3, for the wireless radio frequency interface 571 and optionally Bluetooth. Interface 572 and/or infrared interface 573 provides communication services (e.g., transmission, network, and connectivity) to enable network connectivity of the intelligent terminal. The radio frequency interface 571 includes internal or external antennas and appropriate radio circuitry for establishing and maintaining a wireless link to the base station. As is known to those skilled in the art, the radio circuit includes a series of analog and digital electronic components that together form a radio receiver and transmitter. These components include, for example, bandpass filters, amplifiers, mixers, local oscillators, low pass filters, AD/DA converters, and the like.

The smart terminal may further include a card reading device 530. The card reading device 530 generally includes a processor, a data memory, and the like for reading information of the SIM card and thereby accessing the network provided by the operator according to the cooperative radio frequency interface 517. .

Further, the term "smart watch" mentioned in the present specification has a structure as shown in FIG. Those skilled in the art should understand that the device referred to by the term "smart watch" can refer to existing Wearable smart devices to achieve.

It is apparent to those skilled in the art that the present invention is not limited to the details of the above-described exemplary embodiments, and the present invention can be embodied in other specific forms without departing from the spirit or essential characteristics of the invention. Therefore, the present embodiments are to be considered as illustrative and not restrictive, and the scope of the invention is defined by the appended claims instead All changes in the meaning and scope of equivalent elements are included in the present invention. Any reference signs in the claims should not be construed as limiting the claim. In addition, it is to be understood that the term "comprising" does not exclude other elements, elements or steps. A plurality of components, units or devices recited in the system claims can also be implemented by one component, unit or device by software or hardware.

The above is only the preferred embodiments of the present invention, and the scope of the present invention is not limited thereto, and thus equivalent changes made in the claims of the present invention are still within the scope of the present invention.

Claims

A wrist device for health monitoring, the wrist device comprising a physiological parameter measuring device, an intelligent matching terminal, a first flexible wristband and a second flexible wristband, wherein:

The physiological parameter measuring device is configured to obtain a physiological parameter of a human body, and send the physiological parameter to the smart matching terminal;

The smart matching terminal is configured to access the wireless Internet, and upload the physiological parameter to the background server through the wireless internet, and is further configured to receive, by using the wireless internet, a feedback result of the background server for the physiological parameter, And display the feedback result;

The two ends of the first flexible wristband are respectively connected to the physiological parameter measuring device and the smart matching terminal, and the two ends of the second flexible wristband are respectively connected to the physiological parameter measuring device and the smart matching terminal. The physiological parameter measuring device, the smart matching terminal, the first flexible wristband and the second flexible wristband are integrally combined as an annular wrist wearing structure for wrapping around a wrist of a human body.
The wrist device of claim 1, wherein the physiological parameter measuring device comprises:

a light emitting and receiving unit, configured to transmit at least one wavelength of measurement light to the brachial artery skin of the wrist of the human body, and receive the reflected light of the measurement light;

And a processing unit, configured to process the reflected light to obtain the physiological parameter.
The wrist device of claim 2 wherein:

The physiological parameter measuring device includes a sealed housing, and the light emitting and receiving unit and the processing unit are disposed inside the sealed housing;

A waterproof window is disposed on the sealed casing, and the at least one wavelength of measurement light penetrates from the inside of the sealed casing to the outside of the sealed casing through the waterproof window.
The wrist device of claim 3 wherein:

When the annular wrist wearing structure surrounds the wrist of the human body, the length of the first flexible wristband and/or the second flexible wristband is configured to align the waterproof window with the cymbal Arterial skin, And the smart matching terminal is located on a side of the wrist that is immediately adjacent to the back of the palm of the human body.
The wrist device of claim 1 wherein:

The first flexible wristband and/or the second flexible wristband further comprise a flexible wire encapsulated within the band of the first flexible wristband and/or the second flexible wristband;

The physiological parameter measuring device transmits the physiological parameter to the smart matching terminal through the flexible wire.
A wrist device according to claim 1, 4 or 5, wherein:

A limit buckle structure for adjusting the length is disposed on the first flexible wristband and/or the second flexible wristband.
The wrist device of claim 1 wherein:

A connection of the short-range wireless communication is established between the physiological parameter measuring device and the intelligent matching terminal, and the physiological parameter measuring device sends the physiological parameter to the smart matching terminal through the connection of the short-range wireless communication.
The wrist device of claim 7 wherein:

The short range wireless communication includes Bluetooth communication.
The wrist device of claim 1 wherein said at least one wavelength of measurement light comprises:

Red and / or infrared light.
The wrist device of claim 9 wherein:

The wavelength of the red light is in the range of 660 nm ± 3 nm;

The wavelength of the infrared light is in the range of 940 nm ± 10 nm, or the wavelength of the infrared light is 9600 nm.
A wrist device according to any one of claims 1, 4 or 7, wherein:

The smart matching terminal is a smart watch.