CN109490547B - Body detection system for auxiliary test of blood sugar - Google Patents

Abstract

The invention provides a body test system for assisting in testing blood glucose, comprising: the body detection equipment is used for detecting the physiological index of the user according to a preset detection period to obtain a detection result corresponding to each detection period; the background server is used for analyzing whether each physiological index in the detection result corresponding to each detection period falls into a preset physiological index or not; when a physiological index which does not fall into a preset physiological index exists, sending the physiological index which does not fall into the preset physiological index, a detection cycle identifier corresponding to the physiological index and a detection result to a monitoring terminal; the distribution server is used for receiving an information acquisition request sent by the monitoring terminal, wherein the information acquisition request comprises identification information of a background server to be accessed by the monitoring terminal, and the distribution server establishes connection between the monitoring terminal and the background server to be accessed according to the information acquisition request.

Description

Body detection system for auxiliary test of blood sugar

Technical Field

The invention relates to the technical field of data analysis, in particular to a body detection system for assisting in testing blood sugar.

Background

It is well known that controlling blood glucose concentration throughout the day in the normal range is critical to diabetic patients to prevent complications, and therefore, diabetic patients need regular blood glucose monitoring.

Research shows that hyperglycemia can cause accelerated heartbeat, weak pulse and great change of blood pressure and blood oxygen. In current medical care. Most patients adopt rapid fingertip tips to monitor blood sugar, most of the strategies require that the patients feel fussy and painful for a plurality of times a day, and blood sugar is taken instantly and has one-sidedness and uncertainty.

The current research shows that certain relation exists between physiological indexes such as heart rate, blood pressure, blood oxygen and the like and blood sugar. However, the prior art lacks a monitoring technology which can be known in time when the physiological index of the user is abnormal, and the monitoring technology is generally manual, so that the efficiency is low, and more manpower is occupied.

Disclosure of Invention

In order to solve the above technical problems, the present invention provides a body test system for assisting in testing blood glucose, which provides a technique that can be known in time when an abnormality occurs in a physiological index of a user.

The embodiment of the invention provides a body detection system for assisting in testing blood sugar, which comprises:

the body detection equipment is used for detecting the physiological index of the user according to a preset detection period to obtain a detection result corresponding to each detection period;

the background server is used for analyzing whether each physiological index in the detection result corresponding to each detection period falls into a preset physiological index or not; when a physiological index which does not fall into a preset physiological index exists, sending the physiological index which does not fall into the preset physiological index, a detection cycle identifier corresponding to the physiological index and a detection result to a monitoring terminal;

the distribution server is used for receiving an information acquisition request sent by the monitoring terminal, wherein the information acquisition request comprises identification information of a background server to be accessed by the monitoring terminal, and the distribution server establishes connection between the monitoring terminal and the background server to be accessed according to the information acquisition request.

In one embodiment, the system may further comprise a blood glucose monitoring terminal comprising a housing;

a detection unit is arranged in the box body; the detection unit is provided with two electrodes and is used for contacting the skins of two different areas of a human body and calculating the potential difference between the two skins;

the inside circuit management unit that still is provided with of box body, the circuit management unit includes:

the potential difference measuring circuit is connected with the detecting unit and is used for measuring and calculating the potential difference between the two pieces of skin;

the potential difference measuring circuit measures and calculates potential difference and transmits the potential difference to the micro-processing circuit; the micro-processing circuit is internally provided with a relational expression of blood sugar value and potential difference, and calculates the corresponding blood sugar value according to the potential difference transmitted by the potential difference measuring circuit and outputs the calculated blood sugar value;

the power supply circuit is used for supplying power to the circuit management unit and comprises a solar cell panel, a photoelectric conversion device and a storage battery; the solar cell panel is used for receiving sunlight energy; a photoelectric conversion device for converting light energy of sunlight received by the solar cell panel into electric energy; the storage battery is used for storing the electric energy converted by the photoelectric conversion device; the solar cell, the photoelectric conversion device and the storage battery are sequentially connected in series;

the circuit management unit also comprises a clock circuit and transmits clock information to the micro-processing circuit;

a microprocessor circuit including a plurality of relational expressions between blood glucose levels and potential differences, the relational expressions between blood glucose levels and potential differences corresponding to different times, the microprocessor circuit selecting the relational expression between blood glucose levels and potential differences corresponding to clock information based on the clock information of the clock circuit and calculating the blood glucose level of the user;

after the blood sugar monitoring terminal calculates the blood sugar value of the user, the blood sugar value is sent to the background server, sent to the monitoring terminal by the background server and displayed to a manager by the monitoring terminal.

In an embodiment, the background server is further configured to analyze whether the blood sugar of the user is at risk according to the detection result corresponding to each detection period and a preset blood sugar prediction model.

In one embodiment, the body detection device comprises a bracelet, on which a physiological index detection component is disposed, the physiological index detection component comprising any one or more of a heart rate detection component, a pulse detection component, a blood oxygen value detection component, and a blood pressure detection component.

In an embodiment, the analyzing whether the blood sugar of the user is at risk according to the detection result corresponding to each detection cycle and a preset blood sugar prediction model includes:

step 1: acquiring detection results corresponding to N1 continuous detection periods from the body detection equipment to obtain N1 detection results; determining whether the N1 is equal to or greater than N; if yes, continuing to step 2; otherwise, ending the flow;

step 2: determining the number of a first group of detection results of which the blood pressure value is greater than a preset blood pressure value from the N1 detection results; continuing to step 3 when the number of the first set of detection results is equal to or greater than N2; when the number of the first group of detection results is less than N2, deleting the N1 detection results, and reusing the body detection equipment for detection;

and step 3: when the number of the first group of detection results is equal to or larger than N2, judging whether the detection period corresponding to each detection result in the first group of detection results is adjacent; when not adjacent, returning to the step 1; when adjacent, continuing to step 4;

and 4, step 4: when the detection periods corresponding to each detection result in the first group of detection results are adjacent, determining the number of the second group of detection results when the organ of the user is in the sub-health state according to the N1 detection results; judging whether the number of the second group of detection results is equal to or larger than N3; when the number of the second group of detection results is equal to or greater than N3, recording the first organ in the sub-health state, and continuing to the step 5;

and 5: determining a second organ with a blood oxygen value equal to or less than a preset blood oxygen value from the N1 test results; judging the number of detection results that the blood oxygen value of the second organ is equal to or less than a preset blood oxygen value; when the number is equal to or greater than N4, recording a second organ, and continuing with step 6; when the number is less than N4 and greater than 1, returning to the step 5; when the number is equal to 0, ending the flow;

step 6: and taking the first organ, the second organ, the first group of detection results and the second group of detection results as a basis for judging whether the blood sugar of the user is at risk or not, analyzing whether the blood sugar of the user is at risk or not by combining a preset blood sugar prediction model, and generating an analysis report.

In one embodiment, the preset blood glucose prediction model at least includes a physiological index value range of a preset organ corresponding to each blood glucose value range;

the step 6 includes:

judging whether the first organ and the second organ contain the preset organ or not;

when the first organ and the second organ contain the preset organ, judging whether the physiological index corresponding to the first organ in the first group of detection results is located in a value range of the physiological index corresponding to the first organ and judging whether the physiological index corresponding to the second organ in the second group of detection results is located in a value range of the physiological index corresponding to the second organ; when the two judgment results are yes, generating a report that the blood sugar of the user is possibly at risk;

generating a report of euglycemia of the user when the preset organ is not included in the first organ and the second organ.

In one embodiment, the system further comprises a user information collecting module for collecting user information of the user, wherein the user information comprises gender and age;

the background server is further configured to send the user information of the user, the physiological index that does not fall within the preset physiological index, and the detection cycle identifier and the detection result corresponding to the physiological index to the monitoring terminal.

In one embodiment, the analyzing, by the background server, whether the blood sugar of the user is at risk according to the detection result corresponding to each detection cycle and a preset blood sugar prediction model includes:

the background server acquires a matching model matched with the gender and the age of the user from a preset blood sugar prediction model according to the gender and the age of the user;

and analyzing whether the blood sugar of the user has risks or not according to the detection result corresponding to each detection period and the matching model.

In one embodiment, the method for establishing a connection between a monitoring terminal and a background server to be accessed according to an information acquisition request includes:

the method comprises the steps that a distribution server obtains an information obtaining request transmitted by a monitoring terminal, wherein the information obtaining request comprises a network address range of a preset geographic area and the current geographic position of the monitoring terminal;

the distribution server searches for at least one background server with a network address located in the network address range of the preset geographic area; acquiring at least one target background server in an accessible state from the at least one background server, and distributing a server identifier for each target background server; transmitting the server identification of at least one target background server to the monitoring terminal for selection by a user of the monitoring terminal; the monitoring terminal receives a server identification selected by a user, the selected server identification is sent to a distribution server, the distribution server searches background server information matched with the server identification in a prestored information base according to the selected server identification, a network address range corresponding to each geographical area and all background server information belonging to each network address range are stored in the information base, and the background server information comprises the network address of the background server, the server identification, state information and geographical area information of the monitoring terminal which is allowed to access the background server; judging whether the current geographic position of the monitoring terminal is located in a geographic area of the monitoring terminal which allows the access of the matched background server, and if not, returning a notification of forbidding the access to the monitoring terminal; if so, acquiring the network address of the matched background server and sending the network address to the monitoring terminal, and establishing the connection between the matched background server and the monitoring terminal.

In one embodiment, the establishing of the connection between the matched background server and the monitoring terminal may be implemented as:

when the monitoring terminal registers to the transfer server, the transfer server and the monitoring terminal perform authentication and key agreement, and respectively generate authentication information for establishing a secure channel for the background server and the monitoring terminal; after the authentication information is generated, the transit server and the monitoring terminal respectively store the generated authentication information; the transfer server positions a management server of the monitoring terminal; the transfer server sends the generated authentication information and the identification of the monitoring terminal to a management server through a secure channel; when the monitoring terminal sends a data acquisition request to the background server within a preset time, the background server initiates inquiry to the management server to acquire the state of the monitoring terminal; if the monitoring terminal is in a login state, the management server returns an identifier of the monitoring terminal and authentication information required by the monitoring terminal and the background server to establish a secure channel besides returning the state of the monitoring terminal to the background server;

if the monitoring terminal is not logged in, the background server sends a first request message for requesting the monitoring terminal to log in to the management server, wherein the first request message comprises an identifier of the monitoring terminal and an identifier of the background server;

the management server sends a first request message to the transfer server through the secure channel;

the transfer server sends a first request message to the mobile equipment where the monitoring terminal is located;

when the mobile equipment receives the first request message, starting the monitoring terminal, and sending a second request message to the monitoring terminal, wherein the second request message comprises the identifier of the background server;

after receiving the second request message, the monitoring terminal, according to the identifier of the background server in the second request message,

judging whether the identification of the background server of the receiving party corresponding to the data acquisition request sent by the monitoring terminal is consistent with the identification of the background server in the second request message; when the network channels are consistent, a network channel from the monitoring terminal to the background server is established;

the monitoring terminal and the background server perform mutual authentication of the monitoring terminal and the background server based on the authentication information, and after the authentication is passed, end-to-end data security transmission connection between the monitoring terminal and the background server is formed.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.

Drawings

FIG. 1 is a block diagram of a body test system for assisting in testing blood glucose provided by the present invention;

FIG. 2 is a flow chart of a background server process provided by the present invention;

FIG. 3 is a schematic view of a bracelet of the body test system for assisting in testing blood glucose according to the present invention;

FIG. 4 is a schematic structural view of a back cover of a bracelet of a body detection system for assisting in testing blood glucose according to the present invention;

fig. 5 is a schematic side view of a back cover of a bracelet of a body detection system for assisting in testing blood glucose according to the present invention.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.

According to the technical scheme, the long-term physiological trend is judged mainly through big data by using the pulse wave theory of the traditional Chinese medicine according to the acquired physiological data such as heart rate, blood pressure and blood oxygen data and the personal information of a user such as sex and age. The blood sugar prediction model judges the physiological change corresponding to each time through midnight-noon ebb-flow of the internal meridian of the yellow emperor in traditional Chinese medicine to judge the real-time state of organs, judges clinical diseases according to the real-time physiological change, for example, predicts the blood sugar risk, and can provide a blood sugar risk prompt for a user in advance.

An embodiment of the present invention provides a body detection system for assisting in testing blood glucose, as shown in fig. 1, including:

the body detection device 11 is used for detecting the physiological index of the user according to a preset detection period to obtain a detection result corresponding to each detection period; wherein the physiological index can be any one or more of heart rate, pulse, blood oxygen value and blood pressure.

The background server 12 is used for analyzing whether each physiological index in the detection result corresponding to each detection period falls into a preset physiological index; and when the physiological index which does not fall into the preset physiological index exists, sending the physiological index which does not fall into the preset physiological index, the detection cycle identifier corresponding to the physiological index and a detection result (hereinafter referred to as preset information) to the monitoring terminal.

The distribution server 13 is configured to receive an information acquisition request sent by the monitoring terminal, where the information acquisition request includes identification information of a background server to be accessed by the monitoring terminal, and establish a connection between the monitoring terminal and the background server to be accessed according to the information acquisition request.

The system can be timely known when the physiological index of the user is abnormal, the body of the user can be conveniently monitored, whether the physiological index exceeds the standard or not does not need to be manually checked, the labor is saved, and the monitoring efficiency is improved. In addition, the monitoring terminal can also acquire preset information from a master background server and a slave background server, so that users of the monitoring terminal, such as doctors, can conveniently acquire the preset information of each user, and the monitoring crowd range is improved.

In one embodiment, the background server is further configured to analyze whether the blood sugar of the user is at risk or not according to the detection result corresponding to each detection period and a preset blood sugar prediction model.

In one embodiment, the body detection device may be implemented as a bracelet on which the physiological index detection component is disposed, and the physiological index detection component includes any one or more of a heart rate detection component, a pulse detection component, a blood oxygen value detection component, and a blood pressure detection component. Other body detection devices are also possible, as long as the physiological index of the user can be detected, and the invention is not limited.

In an embodiment, the background server analyzes whether the blood sugar of the user is at risk according to the detection result corresponding to each detection period and a preset blood sugar prediction model, as shown in fig. 2, the steps may be implemented as follows 1 to 6:

step 1: acquiring detection results corresponding to N1 continuous detection periods from the body detection equipment to obtain N1 detection results; determining whether N1 is equal to or greater than N; if yes, continuing to step 2; otherwise, ending the flow;

the detection period may be calculated by day, for example, one detection period per day. Preferably, N may be a value set in advance such as 14, 21, 35, etc., preferably 21; n1 is preferably also 21, i.e. 21 days of detection can be obtained in step 1. When a certain number of detection results are available, the detection results can be used as an effective basis for subsequent prediction diagnosis, and if the number of the detection results is insufficient, the user is continuously detected.

Step 2: determining the number of the first group of detection results of which the blood pressure value is greater than the preset blood pressure value from the N1 detection results;

continuing to step 3 when the number of the first set of detection results is equal to or greater than N2;

and when the number of the first group of detection results is less than N2, deleting N1 detection results and reusing the body detection equipment for detection.

Among them, when N1 is equal to 21, N2 is preferably 7.

If the blood pressure value is larger than the preset blood pressure value, the blood pressure of the user is abnormal, and when more blood pressures in the detection result are abnormal, the subsequent step 3 needs to be continuously executed for prediction; when the abnormal blood pressure is less, the user is healthy, and the body of the user can be continuously detected.

And step 3: when the number of the first group of detection results is equal to or larger than N2, judging whether the detection period corresponding to each detection result in the first group of detection results is adjacent; when not adjacent, returning to the step 1; when adjacent, continue step 4.

That is, when the abnormal blood pressure condition of the user continuously appears, it indicates that the body of the user may have a problem, and the prediction needs to be continued to the subsequent step 4. When the abnormal condition of the blood pressure of the user is not continuous, the body of the user is indicated to have no big obstacle, and the body detection of the user is continued.

And 4, step 4: when the detection periods corresponding to each detection result in the first group of detection results are adjacent, determining the number of the second group of detection results of the sub-health state of the organ of the user according to the N1 detection results; judging whether the number of the second group of detection results is equal to or larger than N3;

when the number of second set of test results is equal to or greater than N3, the first organ in sub-health state is recorded and step 5 is continued.

Wherein preferably N3 is 15.

And 5: determining a second organ having a blood oxygen value equal to or less than a predetermined blood oxygen value from the N1 test results; and judging the number of detection results that the blood oxygen value of the second organ is equal to or less than the preset blood oxygen value; when the number is equal to or greater than N4, recording a second organ, and continuing with step 6; when the number is less than N4 and greater than 1, returning to the step 5; when the number is equal to 0, the flow ends.

Wherein preferably N4 is 10.

Step 6: and taking the first organ, the second organ, the first group of detection results and the second group of detection results as a basis for determining whether the blood sugar of the user is at risk, analyzing whether the blood sugar of the user is at risk or not by combining a preset blood sugar prediction model, and generating an analysis report.

The system provided by the embodiment of the invention can predict the blood sugar of the user according to the body detection result, provides an intelligent auxiliary means, has scientific basis, can ensure the prediction accuracy, and can timely evaluate the blood sugar risk of the user.

In one embodiment, the preset blood sugar prediction model includes a physiological index value range of a preset organ corresponding to each blood sugar value range;

and step 6, comprising:

judging whether the first organ and the second organ contain a preset organ or not;

when the first organ and the second organ contain preset organs, judging whether the physiological index corresponding to the first organ in the first group of detection results is located in the value range of the physiological index corresponding to the first organ and judging whether the physiological index corresponding to the second organ in the second group of detection results is located in the value range of the physiological index corresponding to the second organ; when the two judgment results are yes, generating a report that the blood sugar of the user is abnormal; when at least one of the two judgment results is negative, generating a report that the blood sugar of the user possibly has risks;

when the preset organ is not contained in the first organ and the second organ, a report of euglycemia of the user is generated.

In the system, the blood sugar prediction model is established in advance, so that a relatively accurate prediction means is provided for the prediction of the blood sugar risk.

In one embodiment, the system further comprises a user information collecting module for collecting user information of the user, wherein the user information comprises gender and age; the background server is further configured to send the user information of the user, the physiological index that does not fall within the preset physiological index, and the detection cycle identifier and the detection result corresponding to the physiological index to the monitoring terminal. The personnel at the monitoring terminal can conveniently acquire the user information, so that the medical measures can be taken for the user in a targeted manner.

In one embodiment, the step of analyzing whether the blood sugar of the user has a risk or not by the background server according to the detection result corresponding to each detection period and a preset blood sugar prediction model includes:

the background server acquires a matching model matched with the gender and the age of the user from a preset blood sugar prediction model according to the gender and the age of the user;

and analyzing whether the blood sugar of the user has risks or not according to the detection result and the matching model corresponding to each detection period.

The system can predict the user according to the information of the user such as gender, age and the like and the corresponding blood sugar prediction model, fully considers the differences and individuality of different genders and ages in blood sugar diagnosis, and improves the prediction accuracy.

In one embodiment, the system may further include:

and the client is in communication connection with the background server and is used for acquiring the blood glucose risk of the user obtained by the analysis of the background server and displaying the analysis result to the user.

Therefore, the user can obtain the blood sugar risk of the user at any time and know the situation in time.

In one embodiment, the background server is further configured to send the analysis result to the client when the blood glucose risk of the user is obtained. For example, when the analysis result shows that the blood sugar of the user may be at risk, the analysis result is sent to the client; when the analysis result shows that the blood sugar of the user is normal, the analysis result is not sent to the client; therefore, the information can be selectively sent, the processing load on the background server is reduced, the information interaction between the background server and the client is reduced, and the network resources between the background server and the client are saved.

In one embodiment, the system further comprises:

the user working time acquisition module is used for acquiring the working time of the user in each detection period; for example, the working time of the user in each detection period is obtained from a working time counting server of a unit where the user is located;

and the server is also used for analyzing whether the blood sugar of the user has risks or not according to the detection result corresponding to each detection period, the working time of the user in each detection period and a preset blood sugar prediction model. Specifically, for example, when a report indicating whether the blood sugar of the user is at risk is generated according to the detection result corresponding to each detection cycle and the preset blood sugar prediction model, further, the sum of the working time of the user in all the detection cycles may be determined, and when the sum is equal to or greater than the preset time, a report indicating that the user is a high risk group with abnormal blood sugar is generated. Thus, a reference standard can be provided for prediction according to the working intensity of the user.

In one embodiment, as shown in fig. 3, the bracelet includes two wristbands and a bracelet body 31 disposed between the two wristbands; of the two wristbands, the first wristband 32 is longer than the second wristband 33.

The first wrist strap 32 has an accommodating space 33 therein, and the accommodating space 33 is communicated with the outside through a hole on the first wrist strap 32; a bendable plate-like body 34, the plate-like body 34 being movably disposed in the accommodating space 33 and being detachable from the wrist band through the hole; a data plug 35 is arranged at one end of the plate-shaped body 34 close to the connecting end of the first wrist strap 32 and the first wrist strap 31, and a data jack 36 matched with the data plug 35 is arranged at one end of the first wrist strap 31 connected with the first wrist strap 32; a plurality of placing grooves 37 are formed in the inner surface of the plate-shaped body 34, a physiological index detecting assembly 38 is placed in each placing groove 37, and each physiological index detecting assembly 38 is connected with the data plug 35 through a data line arranged in the plate-shaped body 34; the plate-like body 34 is also provided with button cells 36, the button cells 36 being connected to each physiological index detecting assembly 38. When the plate-shaped body 34 is placed inside the first wrist strap 32, the data plug 35 is plugged into the data jack 36, and the inner surface of the first wrist strap 32 is provided with an opening matched with the physiological index detecting component 38, so that when the wrist wears the bracelet and the first wrist strap 32 is worn on the wrist, the physiological index detecting component 38 can also be contacted with the skin of the wrist, thereby achieving the purpose of detection.

The first wrist strap 32 is connected to a first elastic strap 39 at an end (free end) away from the main body of the wrist strap, and the first elastic strap 39 is provided with a buckle connector 310. One end (free end) of the second wrist strap 33 far away from the wrist strap body is connected with a second elastic belt 311, and a fastening hole 312 adapted to the fastening head 310 is disposed on the second elastic belt 311.

In the above-described bracelet, the plate-like body 34 can be detached from the bracelet, and when the bioassay function is to be used, the plate-like body 34 is inserted into the first wristband 32, and when the bioassay function is not to be used, the plate-like body 34 is pulled out of the first wristband 32. The plate-shaped body 34 can be conveniently inserted into the data socket 36 of other mobile terminals, so that other mobile terminals can conveniently obtain physiological detection results.

In another embodiment, as shown in fig. 4 and 5, the bracelet main body includes a dial plate on which a display screen can be arranged, a power supply or other modules can be arranged inside the dial plate, and a back cover 41 is arranged at the bottom of the dial plate and is rectangular or square; the conventional back cover 41 is fixed at the bottom end of the dial plate through screws, but the back cover 41 can be opened only by a special screwdriver in the mode, which is inconvenient. The embodiment of the invention improves the rear cover and provides a back stage which is convenient to open and close, wherein the plate-shaped body 34 is made of hard material, such as metal, and is in a semi-annular shape (as shown in fig. 5).

One side of the back cover 41 is rotatably connected to the bottom end frame of the dial, the inner surface of the back cover 41 is further provided with a micro motor 42, a driving shaft 43 of the micro motor 42 penetrates through the other side of the back cover 41 (which belongs to the adjacent side with the one side of the back cover 41), the driving shaft 43 is perpendicular to the other side, a gear 44 penetrates through the driving shaft 43, and the gear 44 can be driven by the driving shaft 43 to rotate; the micro motor 42 is used for driving the driving shaft 43 to rotate; the micro-motor 42 is connected to a power supply within the dial. A processor 45 is also arranged in the dial, a key 46 is also arranged on the dial, and when the key 46 is pressed once, the processor 45 controls the micro motor 42 to drive the driving shaft 43 to rotate; when the button 46 is pressed next time, the processor 45 controls the micro motor 42 to drive the driving shaft 43 to stop rotating. The rotating drive shaft 43 rotates the gear 44.

The bottom end of the dial is provided with a groove 51 with the shape matched with that of the rear cover 41 of the associated gear 44; wherein, the lower end of the part of the groove 51 which is matched with the gear 44 is provided with a jack 52, and the jack 52 is matched with the shape of the data plug 35; in the use state, the back cover 41 with the gear 44 is positioned in the groove 51, so as to achieve the effect of closing the dial. The jack 52 may be a data jack adapted to the shape of the data plug 35, and in this case, it functions not only as a fixed rail but also as a spare jack for the data jack 36 by guiding data in the plate-like body into the bracelet body.

One circumferential edge of the inner surface of the plate-like body 34 is provided with a guide rail 53 (not shown) which is engaged with the gear 44;

when it is desired to open the rear cover 41, the semi-annular plate-like body is pulled out from the first wrist band 32, the data plug 35 is inserted into the insertion hole 52, and the guide rail 53 of the plate-like body faces the gear 44. When the user presses the button 46, the processor 45 controls the micro-motor 42 to drive the gear 44 to start rolling along the guide rail 53, and the guide rail 53 drives the gear 44 to continuously advance along the guide rail 53, so as to open the rear cover 41. After opening, the plate-like body 34 is pulled out from the insertion hole 52, and the rear cover 41 is manually pushed into the recess 51.

In the structure, the plate-shaped body additionally serves as the guide rail without additionally configuring a special guide rail, so that the whole structure of the bracelet is simplified, and the bracelet is convenient and quick to use.

In one embodiment, the system may further comprise a blood glucose monitoring terminal comprising a housing;

a detection unit is arranged in the box body; the detection unit is provided with two electrodes and is used for contacting the skins of two different areas of a human body and calculating the potential difference between the two skins;

the inside circuit management unit that still is provided with of box body, the circuit management unit includes:

the potential difference measuring circuit is connected with the detecting unit and is used for measuring and calculating the potential difference between the two pieces of skin;

the potential difference measuring circuit measures and calculates potential difference and transmits the potential difference to the micro-processing circuit; the micro-processing circuit is internally provided with a relational expression of blood sugar value and potential difference, and calculates the corresponding blood sugar value according to the potential difference transmitted by the potential difference measuring circuit and outputs the calculated blood sugar value;

the power supply circuit is used for supplying power to the circuit management unit and comprises a solar cell panel, a photoelectric conversion device and a storage battery; the solar cell panel is used for receiving sunlight energy; a photoelectric conversion device for converting light energy of sunlight received by the solar cell panel into electric energy; the storage battery is used for storing the electric energy converted by the photoelectric conversion device; the solar cell, the photoelectric conversion device and the storage battery are sequentially connected in series;

the circuit management unit also comprises a clock circuit and transmits clock information to the micro-processing circuit;

and a microprocessor circuit including a plurality of relational expressions between blood glucose levels and potential differences, the relational expressions between blood glucose levels and potential differences corresponding to different times, the microprocessor circuit selecting the relational expression between blood glucose levels and potential differences corresponding to the clock information based on the clock information of the clock circuit, and calculating the blood glucose level of the user.

After the blood sugar monitoring end calculates the blood sugar value of the user, the blood sugar value can be sent to the background server, the background server sends the blood sugar value to the monitoring terminal, the monitoring terminal displays the blood sugar value to a manager such as a doctor, the manager can conveniently obtain the blood sugar value calculated by the blood sugar monitoring end in time, and the manager such as the doctor can calculate the blood sugar value of the user according to the preset information and the blood sugar monitoring end to comprehensively evaluate the health condition of the user.

The blood sugar monitoring end has the beneficial effects that: adopt the non-invasive mode to carry out blood sugar monitoring and need not to prick the needle to the patient, only need through the skin of contact human body, acquire the potential difference between two skin districts, just can acquire patient's blood sugar value, pain when having reduced the patient and having adopted traditional blood sugar monitoring mode to above-mentioned blood sugar monitoring end need not to use the test paper strip, has practiced thrift blood sugar monitoring's cost.

In one embodiment, the circuit management unit further includes an analog-to-digital conversion circuit connected to the potential difference measurement circuit.

The circuit management unit also comprises a temperature and humidity measuring device which is connected with the micro-processing circuit and used for measuring and collecting human body temperature and humidity data and transmitting the human body temperature and humidity data to the micro-processing circuit;

the circuit management unit also comprises an alarm device which is connected with the micro-processing circuit, and when one or more of the detected human body temperature data and the blood sugar value data exceeds a preset threshold value, the micro-processing circuit controls the alarm device to carry out sound-light alarm;

the preset threshold values, including the human body temperature threshold value and the blood sugar value threshold value, are all set manually.

The circuit management unit also comprises a heart rate detection device which is connected with the micro-processing circuit;

the heart rate detection device comprises an average heart rate calculation module and a normal heart rate activity threshold range calculation module;

the average heart rate calculation module is used for calculating the normal heart rate of the user within a set time period to obtain heart rate average data a and updating the obtained heart rate average data in real time;

and the normal heart rate activity threshold range calculation module is used for calculating a normal heart rate activity range [ a-b, a + b ] by taking the acquired heart rate average data a as a reference, keeping the normal heart rate activity threshold range and the heart rate average data a in consistent change and updating, and b is a preset fixed value.

The solar cell panel comprises a crystalline silicon substrate, wherein the crystalline silicon substrate comprises a light facing surface and a light backing surface, the light facing surface and the light backing surface are respectively provided with two layers of amorphous wafers, the upper side of a first amorphous wafer is provided with a first amorphous silicon layer, the upper side of a second amorphous wafer is provided with a second amorphous silicon layer, the first amorphous silicon layer comprises a first conductive film, the second amorphous silicon layer comprises a second conductive film, and a transparent chalcogenide is arranged between the light facing surface of the crystalline silicon substrate and the first amorphous wafer or between the light backing surface and the second amorphous wafer. According to the technical scheme, the conversion efficiency of sunlight is effectively improved, the manufacturing procedure of the crystalline silicon substrate is simple, and the cost of the solar cell panel is reduced.

In one embodiment, there may be a plurality of monitoring terminals, and there may also be a plurality of backend servers, and when the monitoring terminal is an application program, each backend server is responsible for information transmission with the monitoring terminal registered in the backend server.

In another embodiment, a monitoring terminal that is not registered with a background server may also request the preset information from the background server, at this time, the allocation server receives an information acquisition request sent by the monitoring terminal, where the information acquisition request includes identification information of the background server to be accessed by the monitoring terminal, and establishes a connection between the monitoring terminal and the background server to be accessed according to the information acquisition request, including:

the method comprises the steps that a distribution server obtains an information obtaining request transmitted by a monitoring terminal, wherein the information obtaining request comprises a network address range of a preset geographic area and the current geographic position of the monitoring terminal;

the distribution server searches for at least one background server with a network address located in the network address range of the preset geographic area; acquiring at least one target background server in an accessible state from the at least one background server, and distributing a server identifier for each target background server; transmitting the server identification of at least one target background server to the monitoring terminal for selection by a user of the monitoring terminal; the monitoring terminal receives a server identification selected by a user, the selected server identification is sent to a distribution server, the distribution server searches background server information matched with the server identification in a prestored information base according to the selected server identification, a network address range corresponding to each geographical area and all background server information belonging to each network address range are stored in the information base, and the background server information comprises the network address of the background server, the server identification, state information and geographical area information of the monitoring terminal which is allowed to access the background server; judging whether the current geographic position of the monitoring terminal is located in a geographic area of the monitoring terminal which allows the access of the matched background server, and if not, returning a notification of forbidding the access to the monitoring terminal; if so, acquiring the network address of the matched background server and sending the network address to the monitoring terminal, and establishing the connection between the matched background server and the monitoring terminal.

After the connection between the matched background server and the monitoring terminal is established, information transmission can be realized between the matched background server and the monitoring terminal. The technical scheme can facilitate personnel to obtain the background server which is required to be accessed and is not registered through the monitoring terminal, and access is performed under the permission of the background server, so that the information security is ensured.

The establishing of the connection between the matched background server (hereinafter referred to as background server) and the monitoring terminal may be implemented as:

when the monitoring terminal registers to the transfer server, the transfer server and the monitoring terminal perform authentication and key agreement, and respectively generate authentication information for establishing a secure channel for the background server and the monitoring terminal; after the authentication information is generated, the transit server and the monitoring terminal respectively store the generated authentication information; the generation of the authentication information can be realized by adopting the prior art, and is not described in detail herein. The transfer server positions a management server of the monitoring terminal; the method of the transit server locating the management server may be obtained based on address information of the management server provided by the monitoring terminal in the transit server. The transfer server sends the generated authentication information and the identification of the monitoring terminal to a management server through a secure channel; when the monitoring terminal sends a data acquisition request to the background server within a preset time, the background server initiates inquiry to the management server to acquire the state of the monitoring terminal; if the monitoring terminal is in a login state, the management server returns an identifier of the monitoring terminal and authentication information required by the monitoring terminal and the background server to establish a secure channel besides returning the state of the monitoring terminal to the background server;

if the monitoring terminal is not logged in, the background server sends a first request message for requesting the monitoring terminal to log in to the management server, wherein the first request message comprises an identifier of the monitoring terminal and an identifier of the background server;

the management server sends a first request message to the transfer server through the secure channel;

the transfer server sends a first request message to the mobile equipment where the monitoring terminal is located;

when the mobile equipment receives the first request message, starting the monitoring terminal, and sending a second request message to the monitoring terminal, wherein the second request message comprises the identifier of the background server;

after receiving the second request message, the monitoring terminal, according to the identifier of the background server in the second request message,

judging whether the identification of the background server of the receiving party corresponding to the data acquisition request sent by the monitoring terminal is consistent with the identification of the background server in the second request message; when the network channels are consistent, a network channel from the monitoring terminal to the background server is established;

the monitoring terminal and the background server perform mutual authentication of the monitoring terminal and the background server based on the authentication information, and after the authentication is passed, end-to-end data security transmission connection between the monitoring terminal and the background server is formed.

The method for establishing the data security transmission connection can improve the security of information transmission between the monitoring terminal and the background server.

After the data security transmission connection is established, the background server encrypts preset information according to network transmission configuration information to obtain encrypted data, wherein the network transmission configuration information is used for carrying out encryption classification on the network data and configuring a security strategy;

the background server sends the encrypted data to the monitoring terminal through the data security transmission connection; and the monitoring terminal decrypts the encrypted data after receiving the encrypted data to obtain preset information. The transmission safety of the preset information is improved.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (7)

1. A body test system for aiding in testing blood glucose, comprising:

the body detection equipment is used for detecting the physiological index of the user according to a preset detection period to obtain a detection result corresponding to each detection period;

the background server is used for analyzing whether each physiological index in the detection result corresponding to each detection period falls into a preset physiological index or not; when a physiological index which does not fall into a preset physiological index exists, sending the physiological index which does not fall into the preset physiological index, a detection cycle identifier corresponding to the physiological index and a detection result to a monitoring terminal;

the distribution server is used for receiving an information acquisition request sent by the monitoring terminal, wherein the information acquisition request comprises identification information of a background server to be accessed by the monitoring terminal, and the distribution server establishes connection between the monitoring terminal and the background server to be accessed according to the information acquisition request;

the method comprises the following steps that the distribution server receives an information acquisition request sent by a monitoring terminal, the information acquisition request comprises identification information of a background server to be accessed by the monitoring terminal, and connection between the monitoring terminal and the background server to be accessed is established according to the information acquisition request, and the method comprises the following steps:

the method comprises the steps that a distribution server obtains an information obtaining request transmitted by a monitoring terminal, wherein the information obtaining request comprises a network address range of a preset geographic area and the current geographic position of the monitoring terminal;

the distribution server searches for at least one background server with a network address located in the network address range of the preset geographic area; acquiring at least one target background server in an accessible state from the at least one background server, and distributing a server identifier for each target background server; transmitting the server identification of at least one target background server to the monitoring terminal for selection by a user of the monitoring terminal; the monitoring terminal receives a server identification selected by a user, the selected server identification is sent to a distribution server, the distribution server searches background server information matched with the server identification in a prestored information base according to the selected server identification, a network address range corresponding to each geographical area and all background server information belonging to each network address range are stored in the information base, and the background server information comprises the network address of the background server, the server identification, state information and geographical area information of the monitoring terminal which is allowed to access the background server; judging whether the current geographic position of the monitoring terminal is located in a geographic area of the monitoring terminal which allows the access of the matched background server, and if not, returning a notification of forbidding the access to the monitoring terminal; if so, acquiring the network address of the matched background server and sending the network address to the monitoring terminal, and establishing the connection between the matched background server and the monitoring terminal;

the system can also comprise a blood sugar monitoring end which comprises a box body;

a detection unit is arranged in the box body; the detection unit is provided with two electrodes and is used for contacting the skins of two different areas of a human body and calculating the potential difference between the two skins;

the inside circuit management unit that still is provided with of box body, the circuit management unit includes:

the potential difference measuring circuit is connected with the detecting unit and is used for measuring and calculating the potential difference between the two pieces of skin;

the potential difference measuring circuit measures and calculates potential difference and transmits the potential difference to the micro-processing circuit; the micro-processing circuit is internally provided with a relational expression of blood sugar value and potential difference, and calculates the corresponding blood sugar value according to the potential difference transmitted by the potential difference measuring circuit and outputs the calculated blood sugar value;

the power supply circuit is used for supplying power to the circuit management unit and comprises a solar cell panel, a photoelectric conversion device and a storage battery; the solar cell panel is used for receiving sunlight energy; a photoelectric conversion device for converting light energy of sunlight received by the solar cell panel into electric energy; the storage battery is used for storing the electric energy converted by the photoelectric conversion device; the solar cell, the photoelectric conversion device and the storage battery are sequentially connected in series;

the circuit management unit also comprises a clock circuit and transmits clock information to the micro-processing circuit;

a microprocessor circuit including a plurality of relational expressions between blood glucose levels and potential differences, the relational expressions between blood glucose levels and potential differences corresponding to different times, the microprocessor circuit selecting the relational expression between blood glucose levels and potential differences corresponding to clock information based on the clock information of the clock circuit and calculating the blood glucose level of the user;

after the blood sugar monitoring terminal calculates the blood sugar value of the user, the blood sugar value is sent to a background server, sent to a monitoring terminal by the background server and displayed to a manager by the monitoring terminal;

establishing the connection between the matched background server and the monitoring terminal, which can be implemented as follows:

when the monitoring terminal registers to the transfer server, the transfer server and the monitoring terminal perform authentication and key agreement, and respectively generate authentication information for establishing a secure channel for the background server and the monitoring terminal; after the authentication information is generated, the transit server and the monitoring terminal respectively store the generated authentication information; the transfer server positions a management server of the monitoring terminal; the transfer server sends the generated authentication information and the identification of the monitoring terminal to a management server through a secure channel; when the monitoring terminal sends a data acquisition request to the background server within a preset time, the background server initiates inquiry to the management server to acquire the state of the monitoring terminal; if the monitoring terminal is in a login state, the management server returns an identifier of the monitoring terminal and authentication information required by the monitoring terminal and the background server to establish a secure channel besides returning the state of the monitoring terminal to the background server;

if the monitoring terminal is not logged in, the background server sends a first request message for requesting the monitoring terminal to log in to the management server, wherein the first request message comprises an identifier of the monitoring terminal and an identifier of the background server;

the management server sends a first request message to the transfer server through the secure channel;

the transfer server sends a first request message to the mobile equipment where the monitoring terminal is located;

when the mobile equipment receives the first request message, starting the monitoring terminal, and sending a second request message to the monitoring terminal, wherein the second request message comprises the identifier of the background server;

after receiving the second request message, the monitoring terminal, according to the identifier of the background server in the second request message,

judging whether the identification of the background server of the receiving party corresponding to the data acquisition request sent by the monitoring terminal is consistent with the identification of the background server in the second request message; when the network channels are consistent, a network channel from the monitoring terminal to the background server is established;

the monitoring terminal and the background server perform mutual authentication of the monitoring terminal and the background server based on the authentication information, and after the authentication is passed, end-to-end data security transmission connection between the monitoring terminal and the background server is formed.

2. The body detecting system according to claim 1,

and the background server is also used for analyzing whether the blood sugar of the user has risks or not according to the detection result corresponding to each detection period and a preset blood sugar prediction model.

3. The system of claim 1,

the body detection equipment comprises a bracelet, wherein a physiological index detection assembly is arranged on the bracelet, and the physiological index detection assembly comprises any one or more of a heart rate detection assembly, a pulse detection assembly, a blood oxygen value detection assembly and a blood pressure detection assembly.

4. The system of claim 2,

analyzing whether the blood sugar of the user has risks according to the detection result corresponding to each detection period and a preset blood sugar prediction model, wherein the method comprises the following steps:

step 1: acquiring detection results corresponding to N1 continuous detection periods from the body detection equipment to obtain N1 detection results; determining whether the N1 is equal to or greater than N; if yes, continuing to step 2; otherwise, ending the flow;

step 2: determining the number of a first group of detection results of which the blood pressure value is greater than a preset blood pressure value from the N1 detection results; continuing to step 3 when the number of the first set of detection results is equal to or greater than N2; when the number of the first group of detection results is less than N2, deleting the N1 detection results, and reusing the body detection equipment for detection;

and step 3: when the number of the first group of detection results is equal to or larger than N2, judging whether the detection period corresponding to each detection result in the first group of detection results is adjacent; when not adjacent, returning to the step 1; when adjacent, continuing to step 4;

and 4, step 4: when the detection periods corresponding to each detection result in the first group of detection results are adjacent, determining the number of the second group of detection results when the organ of the user is in the sub-health state according to the N1 detection results; judging whether the number of the second group of detection results is equal to or larger than N3; when the number of the second group of detection results is equal to or greater than N3, recording the first organ in the sub-health state, and continuing to the step 5;

and 5: determining a second organ with a blood oxygen value equal to or less than a preset blood oxygen value from the N1 test results; judging the number of detection results that the blood oxygen value of the second organ is equal to or less than a preset blood oxygen value; when the number is equal to or greater than N4, recording a second organ, and continuing with step 6; when the number is less than N4 and greater than 1, returning to the step 5; when the number is equal to 0, ending the flow;

step 6: and taking the first organ, the second organ, the first group of detection results and the second group of detection results as a basis for judging whether the blood sugar of the user is at risk or not, analyzing whether the blood sugar of the user is at risk or not by combining a preset blood sugar prediction model, and generating an analysis report.

5. The system of claim 4,

the preset blood sugar prediction model at least comprises a physiological index value range of a preset organ corresponding to each blood sugar value range;

the step 6 includes:

judging whether the first organ and the second organ contain the preset organ or not;

when the first organ and the second organ contain the preset organ, judging whether the physiological index corresponding to the first organ in the first group of detection results is located in a value range of the physiological index corresponding to the first organ and judging whether the physiological index corresponding to the second organ in the second group of detection results is located in a value range of the physiological index corresponding to the second organ; when the two judgment results are yes, generating a report that the blood sugar of the user is possibly at risk;

generating a report of euglycemia of the user when the preset organ is not included in the first organ and the second organ.

6. The system of claim 1 or 2,

the system also comprises a user information acquisition module for acquiring user information of the user, wherein the user information comprises gender and age;

the background server is further configured to send the user information of the user, the physiological index that does not fall within the preset physiological index, and the detection cycle identifier and the detection result corresponding to the physiological index to the monitoring terminal.

7. The system of claim 6,

the background server analyzes whether the blood sugar of the user has risks according to the detection result corresponding to each detection period and a preset blood sugar prediction model, and the method comprises the following steps:

the background server acquires a matching model matched with the gender and the age of the user from a preset blood sugar prediction model according to the gender and the age of the user;

and analyzing whether the blood sugar of the user has risks or not according to the detection result corresponding to each detection period and the matching model.

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