CN111223578A - Wearable diagnosis device, data management method thereof and computer storage medium - Google Patents

Abstract

The application discloses wearing formula diagnostic device and data management method, computer storage medium thereof, wherein, this wearing formula diagnostic device includes: a diagnostic component for diagnosing a human body to obtain diagnostic data; a memory for storing diagnostic data; the communication component is used for carrying out data interaction with an external mobile terminal; and the processor is coupled with the diagnosis component, the memory and the communication component and is used for sending the current diagnosis data acquired by the diagnosis component and/or the historical diagnosis data stored in the memory to the mobile terminal when the communication component is connected to an external mobile terminal or saving the current diagnosis data acquired by the diagnosis component to the memory when the communication component is not connected to the external mobile terminal. Through the mode, on one hand, the diagnostic data can be stored locally to avoid data loss, on the other hand, the diagnostic data can be uploaded flexibly, and treatment of patients is facilitated.

Description

Wearable diagnosis device, data management method thereof and computer storage medium

Technical Field

The present application relates to the field of medical diagnosis technologies, and in particular, to a wearable diagnostic apparatus, a data management method thereof, and a computer storage medium.

Background

The vital signs are used to determine the severity and criticality of the patient, including changes in heart rate, pulse, blood pressure, respiration, pupillary and corneal reflexes. The body temperature, respiration, pulse and blood pressure are called four vital signs of the human body. Only by comprehensively knowing the significance of the vital signs and timely mastering the change of the vital signs of the patient, the medical staff can take effective treatment measures in the first time.

The portable miniaturization design can facilitate the detection and monitoring of individuals and families, and can play a certain role in relieving the unbalanced distribution problem of medical resources caused by the wide territory in China, so that the portable miniaturization design has wider market space, and how to reduce the volume of equipment on the premise of ensuring the performance of the equipment is a great test for various control chips and manufacturing processes. The multi-parameter intelligent design enables the detection and monitoring of vital signs to be more comprehensive and convenient, and meets the requirements of the fast-paced life pace and the intelligent era of the current society.

However, a general portable diagnostic device can only check diagnostic data in real time or upload the diagnostic data to a server in real time through a mobile phone, and cannot store the diagnostic data in an off-line state.

Disclosure of Invention

The application mainly provides a wearable diagnosis device, a data management method thereof and a computer storage medium, which can realize the storage and uploading of data so as to scientifically manage the data.

A technical scheme that this application adopted provides a wearing formula diagnostic device, and this wearing formula diagnostic device includes: a diagnostic component for diagnosing a human body to obtain diagnostic data; a memory for storing diagnostic data; the communication component is used for carrying out data interaction with an external mobile terminal; and the processor is coupled with the diagnosis component, the memory and the communication component and is used for sending the current diagnosis data acquired by the diagnosis component and/or the historical diagnosis data stored in the memory to the mobile terminal when the communication component is connected to an external mobile terminal or saving the current diagnosis data acquired by the diagnosis component to the memory when the communication component is not connected to the external mobile terminal.

Another technical solution adopted by the present application is to provide a data management method for a wearable diagnostic device, including: detecting whether to connect to an external mobile terminal; if yes, sending the acquired current diagnostic data and/or stored historical diagnostic data to the mobile terminal; if not, storing the acquired current diagnosis data.

Another technical solution adopted by the present application is to provide a computer storage medium, in which a computer program is stored, and when the computer program is executed by a processor, the data management method is implemented.

The application provides a wearable diagnostic device includes: a diagnostic component for diagnosing a human body to obtain diagnostic data; a memory for storing diagnostic data; the communication component is used for carrying out data interaction with an external mobile terminal; and the processor is coupled with the diagnosis component, the memory and the communication component and is used for sending the current diagnosis data acquired by the diagnosis component and/or the historical diagnosis data stored in the memory to the mobile terminal when the communication module is connected to the external mobile terminal, or saving the current diagnosis data acquired by the diagnosis component into the memory when the communication module is not connected to the external mobile terminal. Through the mode, on one hand, the diagnostic data can be stored locally to avoid data loss, on the other hand, the diagnostic data can be uploaded flexibly, and treatment of patients is facilitated.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts. Wherein:

FIG. 1 is a schematic structural diagram of a first embodiment of a wearable diagnostic device provided herein;

FIG. 2 is a schematic structural diagram of a second embodiment of a wearable diagnostic device provided herein;

FIG. 3 is a data segment schematic of a first data format;

FIG. 4 is a data segment schematic of second data;

fig. 5 is a schematic flowchart of an embodiment of a data management method of a wearable diagnostic device provided in the present application;

FIG. 6 is a schematic structural diagram of an embodiment of a computer storage medium provided in the present application.

Detailed Description

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the application. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is explicitly and implicitly understood by one skilled in the art that the embodiments described herein can be combined with other embodiments.

Referring to fig. 1, fig. 1 is a schematic structural diagram of a first embodiment of a wearable diagnostic device 10 provided in the present application, where the wearable diagnostic device includes a diagnostic component 11, a memory 12, a communication component 13, and a processor 14. Wherein, the processor 14 is coupled with the diagnosis component 11, the memory 12 and the communication component 13 respectively.

It is understood that the wearable diagnostic device 10 can be a watch, a bracelet, a badge, or eyeglasses, and is not limited thereto. Taking a wristwatch as an example, the wearable diagnostic device 10 includes a wristwatch body and a wristband, and the diagnostic unit 11, the memory 12, the communication unit 13, and the processor 14 are provided inside the wristwatch body. In addition, the wearable diagnostic device 10 may also include a display screen for displaying diagnostic data.

The diagnosis component 11 is used for diagnosing a human body to obtain diagnosis data; the memory 12 is used for storing diagnostic data; the communication component 13 is used for data interaction with an external mobile terminal. In particular, the communication component 13 is used for transmitting diagnostic data to an external mobile terminal.

With reference to fig. 2, fig. 2 is a schematic structural diagram of a second embodiment of the wearable diagnostic apparatus provided in the present application, and in this embodiment, the wearable diagnostic apparatus 10 includes a diagnostic component 11, a memory 12, a communication component 13, and a processor 14.

The diagnosis module 11 specifically includes at least one of a body temperature detection module 111, a blood pressure detection module 112, a blood oxygen detection module 113, a pulse detection module 114, and a nasal discharge detection module 115.

Optionally, the body temperature detecting module 111 may be a temperature sensor disposed on a side of the wearable diagnostic device 10 close to the human body to obtain the temperature of the human body, and in addition, the body temperature detecting module 111 may also be an infrared sensor for measuring the body temperature by using the radiation principle, and the infrared sensor only absorbs the infrared rays radiated by the human body without emitting any rays to the outside, and senses the body temperature of the human body by a non-contact method.

Alternatively, the blood pressure detecting module 112 may be a pressure sensor, and may also be disposed on a side of the wearable diagnostic device 10 close to the human body to obtain the blood pressure of the human body by detecting the pressure.

Optionally, the blood oxygen detecting module 113 is disposed on a side of the wearable diagnostic apparatus close to the human body, and includes a light emitter and a light receiver; specifically, the light emitter is used for emitting specific light to the human body, the light receiver is used for receiving the emitted light, and the processor is further used for analyzing blood oxygen based on the light signals received by the receiver to obtain diagnosis data. Optionally, in a specific embodiment, the wavelength of the specific light is 660 nm.

Alternatively, the pulse detection module 114 can be a finger clip connected to the processor 14 of the wearable diagnostic device 10 via a data cable. The finger clip device can be clipped on the finger through elastic force or sleeved on the finger to detect the pulse. Optionally, in one embodiment, the pulse detection assembly 114 is removable, and may be removed during the day to facilitate the user's life, and may be attached to and clipped or fitted over a finger for detection during sleep at night.

The nasal aspiration flow detection module 115 can include a detection body device and a nasal aspiration tube connected to detect airflow in the nasal aspiration tube. Optionally, the wearable diagnostic device 10 includes a first data interface, the nasal inhalation detection module 115 (detection subject device) includes a second data interface, and the wearable diagnostic device 10 and the nasal inhalation detection module 115 are detachably connected through the first data interface and the second data interface. For example, the first and second data interfaces may be USB data interfaces.

The above listed diagnostic modules are only examples and are not intended to limit the type and number of diagnostic modules, and it is understood that the diagnostic modules for detecting vital sign data of a human body should be within the scope of the present disclosure.

In the present embodiment, the diagnostic data collected by the diagnostic component 11 may be one or more of the different types of diagnostic data collected by the different diagnostic components listed above. Specifically, the data may be body temperature data, blood pressure data, blood oxygen data, pulse data, nasal inhalation data, etc.

Optionally, in an embodiment, the memory 12 is a FLASH memory.

For example, the memory 12 adopts a W25Q64 fvsig chip as a data storage chip, the chip has a 64M BIT storage space, and is a large-capacity memory with low power consumption and high performance, meanwhile, the W25Q64 fvsig chip adopts an SPI communication protocol, data reading and writing are fast, power consumption during standby is as low as 1uA, and current during normal operation is as low as 3mA, so that the memory and power consumption design of the portable wearable device is of great advantage.

In the embodiment, the processor 14 is configured to send the current diagnostic data collected by the diagnostic component 11 and/or the historical diagnostic data already stored in the memory 12 to the mobile terminal when the communication component 13 is connected to the external mobile terminal, or save the current diagnostic data collected by the diagnostic component 11 to the memory 12 when the communication component 13 is not connected to the external mobile terminal.

Optionally, the communication module 13 is a bluetooth module, and the bluetooth module 13 is configured to automatically turn on when the wearable diagnostic device 10 is powered on, and detect whether to connect to an external mobile terminal.

The first situation is that when the wearable diagnostic device 10 is powered on, the bluetooth of the mobile phone is normally opened and a corresponding application program (APP) is started, so that the wearable diagnostic device 10 and the mobile terminal are connected to perform data transmission in real time, and if the current diagnostic component 11 obtains current diagnostic data, the current diagnostic data is transmitted to the mobile terminal in real time, and at this time, because the normal connection state of the communication component 13 and the mobile terminal is detected, the diagnostic data will not be stored in the local storage 12. Furthermore, on one side of the mobile terminal, when the mobile terminal is in an idle state, the diagnostic data can be further transmitted to the server, so that the tracking and statistics of the user diagnostic data are realized, and the user diagnostic data are never lost. And support is provided for the later doctor to remotely check the physical state and treatment condition of the user by accessing the server.

It can be understood that, the APP used with the wearable diagnostic apparatus 10 is installed on the mobile terminal, and the user can use the APP to check and analyze the diagnostic data, and the APP may also include some algorithms to analyze the diagnostic data to obtain the relevant diagnostic result.

In addition, when the wearable diagnostic device 10 is connected to the mobile terminal, if the current diagnostic module 11 does not perform real-time data acquisition, the wearable diagnostic device 10 may transmit the historical diagnostic data stored in the memory 12 to the mobile terminal. Further, if the current diagnostic module 11 is performing real-time data acquisition, the wearable diagnostic device 10 may also transmit the currently acquired current diagnostic data and the historical diagnostic data stored in the memory 12 to the mobile terminal.

Under the condition, when the diagnosis device is connected with the mobile terminal, the data collected in real time or the data stored locally can be uploaded to the server, on one hand, uploading of the real-time data is beneficial to a doctor to obtain the diagnosis data from the server in time, and on the other hand, uploading of the local data is beneficial to the doctor to analyze historical diagnosis data. When some special diseases are diagnosed, continuous multi-day diagnosis data are generally needed, and the purpose can be achieved by adopting the method, so that the continuous multi-day diagnosis data can be uploaded without leakage, the disease analysis can be more accurate, and the diagnosis of the disease of a user is facilitated.

The second situation is that when the wearable diagnostic device 10 is powered on, the user forgets to turn on the bluetooth of the mobile phone or the corresponding APP (application program), and then the diagnostic data of the user cannot be transmitted to the mobile terminal in real time, at this time, the wearable diagnostic device 10 will feed back to the processor 14 according to the connection state of the communication component 13, the bluetooth of the mobile terminal is not normally connected in the current state, the start history data storage mode is stored in the local computer, and the diagnostic data will be stored in the local computer.

Optionally, in an embodiment, the memory 12 is configured to store the diagnostic data within a set time period, and the processor 14 is further configured to delete the diagnostic data in the memory 12 that exceeds the set time period.

For example, if the time period set in the memory 12 is 7 days, the diagnostic data stored in the memory 12 is data for a total of 7 days including the current day, and the previous data is deleted. For example as shown in the following table:

optionally, in another embodiment, the memory 12 is configured to store diagnostic data for a set time period, and the processor 14 is further configured to delete a part of the historical storage data stored in the memory 12 when new diagnostic data is stored in the memory 12.

For example, the memory 12 can support local storage of 7 days of historical data at the longest, when the 7 days are exceeded, the data of the 7 th day is moved up to the storage field of the 6 th day, the data of the 6 th day is moved up to the 5 th day, and so on, and the storage field of the 7 th day stores the diagnostic data of the 8 th day (current), so that the stored data of the 7 th day is ensured to be the latest diagnostic data used by the user, if the mobile terminal is normally connected during midway detection, the local storage of the diagnostic data is terminated, and the synchronous uploading mode of the current diagnostic data and the historical diagnostic data is started, that is, the current diagnostic data is uploaded, and meanwhile, the historical diagnostic data stored before is also simultaneously transmitted to the mobile terminal.

In addition, the diagnostic data is stored locally or uploaded to the mobile terminal in a different format. Specifically, the processor 14 is specifically configured to store the diagnostic data in the first data format to the memory 12, or send the diagnostic data in the second data format to the mobile terminal; the first data format comprises diagnosis time corresponding to the diagnosis data; the second data format does not include a diagnostic time corresponding to the diagnostic data.

Under the condition, the collected data can be stored locally when the diagnosis device is not connected with the mobile terminal, so that the disappearance of the diagnosis data is avoided, and the local data is uploaded when the diagnosis device is connected with the mobile terminal, so that a doctor can analyze historical diagnosis data. When some special diseases are diagnosed, continuous multi-day diagnosis data are generally needed, and the purpose can be achieved by adopting the method, so that the continuous multi-day diagnosis data can be uploaded without leakage, the disease analysis can be more accurate, and the diagnosis of the disease of a user is facilitated.

Referring to fig. 3 and 4, fig. 3 is a schematic diagram of a data segment of a first data format, and fig. 4 is a schematic diagram of a data segment of a second data format.

The first data format comprises a data start bit, a data length bit, a device type, a device number, a Bluetooth connection state, diagnostic data 1, diagnostic data 2 and …, a data check bit and an end bit which are connected in sequence. The second data format comprises a data start bit, a data length bit, a device type, a device number, a Bluetooth connection state, a collection timestamp, diagnostic data 1, diagnostic data 2 and …, a data check bit and an end bit which are connected in sequence.

Compared with the first data format, the second data format has one more acquisition timestamp, the locally stored data is stored locally according to the acquisition timestamps in the format sequence, and the W25Q64 fvsig chip is still taken as an example, the chip can support the maximum storage of 7 days of data, so that no influence is generated on the storage of the diagnostic data under various conditions such as connection with bluetooth or disconnection for a period of time in the middle, and the like, the continuity of the data can be completely ensured, as long as the mobile terminal retrieves that the bluetooth connection state in the data is unconnected, the data can be placed on the storage space corresponding to the timestamp, and the data uploaded before and the historical data uploaded after are linked up due to the time information, the data can be seamlessly linked up, and the linked up data can be uploaded to the cloud server when the mobile terminal is idle.

Because each piece of data has diagnostic timestamp information, seamless butt joint can be formed between the mobile terminal and real-time data, when the detection historical diagnostic data are completely uploaded, the cache is automatically cleared, the single-line real-time data transmission is switched to, and if the connection is disconnected again, the local storage of the diagnostic data is started as the previous detection mechanism. Meanwhile, the mobile terminal of the mobile phone can transmit the diagnosis data to the server for storage when the mobile terminal is idle.

The disease condition can be judged based on the diagnosis data of a plurality of diseases on a certain day, and doctors need to analyze the disease condition and the severity of the disease condition of patients according to the diagnosis data of the patients continuously diagnosing for a period of time, and the conditions can be improved after auxiliary treatment. But to many wearable devices do not have the function of saving the diagnostic data offline, can only upload the data through real-time data transmission, if do not connect application end data then can't save, can hardly avoid in the use like this that patient forgets to open mobile terminal's bluetooth function or open corresponding APP, then can lead to the data of treatment can't exist and be saved, does not have the data doctor end also can't analyze patient's state of an illness.

In an embodiment, the communication component 13 is further configured to obtain a diagnosis type sent by the mobile terminal; the processor 14 is further configured to send the diagnostic data within a set time period corresponding to the type of diagnosis to the mobile terminal using the communication component 13.

Optionally, the processor 14 is specifically configured to obtain historical diagnostic data of the set time period from the memory 12, and send the historical diagnostic data to the mobile terminal through the communication component.

Optionally, the processor 14 is specifically configured to obtain current diagnostic data collected by the diagnostic component 11, obtain historical diagnostic data from the memory 12, and send the current diagnostic data and the historical diagnostic data of a total set time period to the mobile terminal.

For example, the diagnostic data required for the type of diagnosis transmitted by the mobile terminal acquired by the communication component 13 is 3-day diagnostic data. In one case, the processor 14 retrieves historical diagnostic data for the last three days from the memory 12 and transmits the historical diagnostic data to the mobile terminal via the communication component 13. In another case, the processor 14 obtains the diagnostic data for the current day from the diagnostic component 11 and the historical diagnostic data for the last two days from the memory 12 and sends the diagnostic data for a total of three days to the mobile terminal via the communication component 13.

Different from the prior art, the wearable diagnostic device provided by the embodiment includes: a diagnostic component for diagnosing a human body to obtain diagnostic data; a memory for storing diagnostic data; the communication component is used for carrying out data interaction with an external mobile terminal; and the processor is coupled with the diagnosis component, the memory and the communication component and is used for sending the current diagnosis data acquired by the diagnosis component and/or the historical diagnosis data stored in the memory to the mobile terminal when the communication module is connected to the external mobile terminal, or saving the current diagnosis data acquired by the diagnosis component into the memory when the communication module is not connected to the external mobile terminal. Through the mode, on one hand, the diagnostic data can be stored locally to avoid data loss, on the other hand, the diagnostic data can be uploaded flexibly, and treatment of patients is facilitated.

Further, the present application also provides a data management method of a wearable diagnostic device, as shown in fig. 5, fig. 5 is a schematic flow chart of an embodiment of the data management method of the wearable diagnostic device provided by the present application, and the method includes:

step 51: it is detected whether an external mobile terminal is connected.

If the result of the detection in step 51 is yes, step 52 is executed, and if the result of the detection in step 51 is no, step 53 is executed.

Step 52: and sending the collected current diagnosis data and/or the stored historical diagnosis data to the mobile terminal.

Step 53: and storing the acquired current diagnosis data.

Optionally, in another embodiment, the method may further include: storing the diagnosis data in the first data format to the memory or sending the diagnosis data in the second data format to the mobile terminal

Optionally, in another embodiment, the method may further include: acquiring a diagnosis type sent by a mobile terminal; and transmitting the diagnosis data in the set time period corresponding to the diagnosis type to the mobile terminal by utilizing the communication component.

Referring to fig. 6, fig. 6 is a schematic structural diagram of an embodiment of a computer storage medium provided in the present application, a computer program 61 is stored in the computer storage medium 60, and when the computer program 61 is executed by a processor, the following method is implemented:

detecting whether to connect to an external mobile terminal; if yes, sending the acquired current diagnostic data and/or stored historical diagnostic data to the mobile terminal; if not, storing the acquired current diagnosis data.

Alternatively, in another embodiment, the computer program 61, when executed by a processor, implements the method of: storing the diagnosis data in the first data format to the memory or sending the diagnosis data in the second data format to the mobile terminal

Alternatively, in another embodiment, the computer program 61, when executed by a processor, implements the method of: acquiring a diagnosis type sent by a mobile terminal; and transmitting the diagnosis data in the set time period corresponding to the diagnosis type to the mobile terminal by utilizing the communication component.

Embodiments of the present application may be implemented in software functional units and may be stored in a computer readable storage medium when sold or used as a stand-alone product. Based on such understanding, the technical solution of the present application may be substantially implemented or contributed by the prior art, or all or part of the technical solution may be embodied in a software product, which is stored in a storage medium and includes instructions for causing a computer device (which may be a personal computer, a server, a network device, or the like) or a processor (processor) to execute all or part of the steps of the method according to the embodiments of the present application. And the aforementioned storage medium includes: a U-disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk or an optical disk, and other various media capable of storing program codes.

The above description is only for the purpose of illustrating embodiments of the present application and is not intended to limit the scope of the present application, and all modifications of equivalent structures and equivalent processes, which are made by the contents of the specification and the drawings of the present application or are directly or indirectly applied to other related technical fields, are also included in the scope of the present application.

Claims (16)

1. A wearable diagnostic device, comprising:

a diagnostic component for diagnosing a human body to obtain diagnostic data;

a memory for storing diagnostic data;

the communication component is used for carrying out data interaction with an external mobile terminal;

and the processor is coupled with the diagnosis component, the memory and the communication component and used for sending the current diagnosis data collected by the diagnosis component and/or the historical diagnosis data stored in the memory to the mobile terminal when the communication component is connected to an external mobile terminal, or saving the current diagnosis data collected by the diagnosis component to the memory when the communication component is not connected to the external mobile terminal.

2. The wearable diagnostic device of claim 1,

the communication assembly is a Bluetooth module which is used for automatically starting when the wearable diagnosis device is started and detecting whether the wearable diagnosis device is connected to an external mobile terminal.

3. The wearable diagnostic device of claim 1,

the memory is a FLASH memory.

4. The wearable diagnostic device of claim 1 or 3,

the memory is used for storing the diagnostic data in a set time period, and the processor is also used for deleting the diagnostic data which exceed the set time period in the memory.

5. The wearable diagnostic device of claim 1 or 3,

the memory is used for storing diagnostic data with set time length, and the processor is also used for deleting part of historical storage data stored in the memory when new diagnostic data are stored in the memory.

6. The wearable diagnostic device of claim 1,

the processor is specifically configured to store the diagnostic data in a first data format to the memory, or send the diagnostic data in a second data format to the mobile terminal;

wherein the first data format and the second data format are different.

7. The wearable diagnostic device of claim 6,

the first data format comprises diagnosis time corresponding to diagnosis data;

the second data format does not include a diagnostic time corresponding to the diagnostic data.

8. The wearable diagnostic device of claim 1,

the communication component is also used for acquiring the diagnosis type sent by the mobile terminal;

the processor is further configured to send, to the mobile terminal, the diagnostic data within a set time period corresponding to the diagnostic type using the communication component.

9. The wearable diagnostic device of claim 8,

the processor is specifically configured to obtain historical diagnostic data of a set time period from the memory, and send the historical diagnostic data to the mobile terminal through the communication component.

10. The wearable diagnostic device of claim 8,

the processor is specifically configured to obtain current diagnostic data collected by the diagnostic component, obtain historical diagnostic data from the memory, and send the current diagnostic data and the historical diagnostic data of a total set time period to the mobile terminal.

11. The wearable diagnostic device of claim 1,

the diagnosis component comprises at least one of a body temperature detection module, a blood pressure detection module, a blood oxygen detection module, a pulse detection module and a nasal aspiration flow detection module.

12. The wearable diagnostic device of claim 11,

the blood oxygen detection module is arranged on one side of the wearable diagnostic device close to the human body and comprises a light emitter and a light receiver;

the light emitter is used for emitting specific light to a human body, the light receiver is used for receiving the emitted light, and the processor is further used for analyzing blood oxygen based on light signals received by the receiver to obtain diagnostic data.

13. The wearable diagnostic device of claim 12,

the wavelength of the specific light is 660 nm.

14. The wearable diagnostic device of claim 11,

the wearable diagnostic device comprises a first data interface, the nasal aspiration flow detection module comprises a second data interface, and the wearable diagnostic device and the nasal aspiration flow detection module are detachably connected through the first data interface and the second data interface.

15. A data management method of a wearable diagnostic device, comprising:

detecting whether to connect to an external mobile terminal;

if yes, sending the collected current diagnosis data and/or the stored historical diagnosis data to the mobile terminal;

if not, storing the acquired current diagnosis data.

16. A computer storage medium, in which a computer program is stored, which, when executed by a processor, implements the data management method of claim 15.

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