CN111696686B - Remote medical detection control method and system - Google Patents

Abstract

The invention relates to the technical field of medical detection, in particular to a remote medical detection control method and a remote medical detection control system, wherein the remote medical detection control system comprises detection equipment of a user side and monitoring equipment of a background; the detection equipment comprises an MCU module, a first communication module, a GPS positioning module and a physiological parameter detection module, wherein the first communication module, the GPS positioning module and the physiological parameter detection module are respectively connected with the MCU module; the monitoring equipment comprises an ARM processor, a storage module, a second communication module and an interaction module, wherein the storage module, the second communication module and the interaction module are respectively connected with the ARM processor; the MCU module adds a time stamp and an identification code of the detection equipment to GPS positioning data and physiological parameters, packages the GPS positioning data and the physiological parameters into detection data, and the ARM processor sorts the detection data reported by at least one detection equipment according to time and the identification code to generate a database; when the interaction module detects an input query instruction, the detection data in the database is displayed according to the query instruction, and the system and the method can monitor a large number of users and provide real-time physiological condition management.

Description

Remote medical detection control method and system

Technical Field

The disclosure relates to the technical field of medical detection, in particular to a remote medical detection control method and a remote medical detection control system.

Background

With the development of medical technology, various medical detection devices are currently available on the market, and various physiological parameters can be detected through various existing probes, however, most of these devices are only convenient for personal health detection, and for management institutions such as nursing centers and medical departments, physiological monitoring needs to be performed on a large number of users at the same time, and real-time physiological condition management is provided. Existing medical detection methods cannot meet such requirements.

Disclosure of Invention

The present disclosure is directed to a method and a system for remote medical detection control, which solve one or more technical problems in the prior art, and at least provide a beneficial choice or creation condition.

In order to achieve the above object, the present disclosure provides the following technical solutions:

the system comprises detection equipment of a user side and monitoring equipment of a background;

the detection apparatus includes: the system comprises an MCU module, a first communication module, a GPS positioning module and a physiological parameter detection module, wherein the MCU module is respectively connected with the first communication module, the GPS positioning module and the physiological parameter detection module;

the GPS positioning module is used for acquiring GPS positioning data and transmitting the GPS positioning data to the MCU module;

the physiological parameter detection module is configured to detect a physiological parameter and send the physiological parameter to the MCU module, where the physiological parameter includes: blood oxygen, body temperature, heart rate and number of steps;

the first communication module is used for establishing communication connection with the monitoring equipment;

the MCU module is used for adding a time stamp and an identification code of the detection equipment to the GPS positioning data and the physiological parameter, packaging the GPS positioning data and the physiological parameter into detection data, and reporting the detection data to the monitoring equipment through the first communication module;

the monitoring device includes: the ARM processor, the storage module, the second communication module and the interaction module; the storage module, the second communication module and the interaction module are all connected with the ARM processor;

the second communication module is used for establishing communication connection with at least one detection device;

the ARM processor is used for sequencing the detection data reported by at least one detection device according to time and the identification code to generate a database;

the storage module is used for storing the database;

the interaction module is used for responding to the input query instruction and displaying the detection data in the database according to the query instruction.

Further, the physiological parameter detection module includes: the blood oxygen saturation probe, the body temperature probe, the optical heart rate sensor and the acceleration sensor are respectively connected with the blood oxygen saturation probe, the body temperature probe, the optical heart rate sensor and the acceleration sensor by the MCU module.

Further, the ARM processor is further configured to: judging whether the physiological parameter in the database exceeds a set threshold value, inquiring detection equipment corresponding to the physiological parameter when the physiological parameter exceeding the set threshold value exists in the database, and sending reminding information to the detection equipment, wherein the reminding information comprises the physiological parameter exceeding the set threshold value and a risk warning message;

the detection equipment further comprises a display module connected with the MCU module;

the MCU module is also used for: when the reminding information is received, the display module is controlled to display the reminding information.

Further, the ARM processor is further configured to:

judging whether GPS positioning data and physiological parameters contained in detection data reported by the detection equipment are complete or not;

when the detection data is in data missing, judging the duration of the occurrence of the data missing;

when the duration of the occurrence of the data missing exceeds a set threshold value, judging that the detection equipment corresponding to the detection data has faults;

predicting a module with faults according to the missing detection data, and generating prediction information, wherein the module with faults is one or more of a GPS positioning module and a physiological parameter detection module;

sending prediction information to the detection equipment, wherein the prediction information comprises module information for predicting faults and fault warning information;

and the MCU module is also used for controlling the display module to display the prediction information when receiving the prediction information.

A telemedicine detection control method applied to any one of the telemedicine detection control systems described above, the method comprising:

the GPS positioning module acquires GPS positioning data and transmits the GPS positioning data to the MCU module;

the physiological parameter detection module detects physiological parameters and sends the physiological parameters to the MCU module, wherein the physiological parameters comprise: blood oxygen, body temperature, heart rate and number of steps;

the MCU module adds a time stamp and an identification code of the detection equipment to the GPS positioning data and the physiological parameter, packages the GPS positioning data and the physiological parameter into detection data, and reports the detection data to the monitoring equipment through the first communication module;

the ARM processor sorts the detection data reported by at least one detection device according to time and the identification code to generate a database;

the storage module stores the database;

and when the interaction module detects an input query instruction, displaying detection data in the database according to the query instruction.

Further, the method further comprises:

the ARM processor judges whether the physiological parameter in the database exceeds a set threshold, and when the physiological parameter exceeding the set threshold exists in the database, the MCU module inquires detection equipment corresponding to the physiological parameter and sends reminding information to the detection equipment, wherein the reminding information comprises the physiological parameter exceeding the set threshold and a risk warning message;

when the MCU module receives the reminding information, the MCU module controls the display module to display the reminding information.

Further, the method further comprises:

the ARM processor judges whether GPS positioning data and physiological parameters contained in detection data reported by the detection equipment are complete or not;

when the detection data is in data missing, the ARM processor judges the duration of the occurrence of the data missing;

when the duration of the occurrence of the data missing exceeds a set threshold value, the ARM processor judges that the detection equipment corresponding to the detection data fails;

the ARM processor predicts a failed module according to the missing detection data and generates prediction information, wherein the failed module is one or more of a GPS positioning module and a physiological parameter detection module;

the ARM processor sends prediction information to the detection equipment, wherein the prediction information comprises module information for predicting faults and fault warning information;

and when the MCU module receives the prediction information, controlling the display module to display the prediction information.

The beneficial effects of the present disclosure are: the present disclosure provides a remote medical detection control method and system, which adopts structured data to process detection data, thereby facilitating the inquiry and use of medical staff; the position of the user can be directly inquired through the GPS positioning data, so that the time for positioning the user is reduced to the maximum extent, and the medical staff can conveniently visit in time. The technical scheme provided by the disclosure can simultaneously carry out physiological monitoring on a large number of users and provide real-time physiological condition management.

Drawings

The above and other features of the present disclosure will become more apparent from the detailed description of the embodiments illustrated in the accompanying drawings, in which like reference numerals designate like or similar elements, and which, as will be apparent to those of ordinary skill in the art, are merely some examples of the present disclosure, from which other drawings may be made without inventive effort, wherein:

FIG. 1 is a block diagram illustrating a remote medical detection control system in accordance with an embodiment of the present disclosure;

fig. 2 is a schematic flow chart of a remote medical detection control method according to an embodiment of the disclosure.

Detailed Description

The conception, specific structure, and technical effects produced by the present disclosure will be clearly and completely described below in connection with the embodiments and the drawings to fully understand the objects, aspects, and effects of the present disclosure. It should be noted that, in the case of no conflict, the embodiments and features in the embodiments may be combined with each other.

As shown in fig. 1, the present disclosure provides a telemedicine detection control system, which includes a detection device at a user side and a monitoring device at a background;

the detection apparatus includes: the system comprises an MCU module, a first communication module, a GPS positioning module and a physiological parameter detection module, wherein the MCU module is respectively connected with the first communication module, the GPS positioning module and the physiological parameter detection module;

the GPS positioning module is used for acquiring GPS positioning data and transmitting the GPS positioning data to the MCU module;

the physiological parameter detection module is configured to detect a physiological parameter and send the physiological parameter to the MCU module, where the physiological parameter includes: blood oxygen, body temperature, heart rate and number of steps;

the first communication module is used for establishing communication connection with the monitoring equipment;

the MCU module is used for adding a time stamp and an identification code of the detection equipment to the GPS positioning data and the physiological parameter, packaging the GPS positioning data and the physiological parameter into detection data, and reporting the detection data to the monitoring equipment through the first communication module;

the monitoring device includes: the ARM processor, the storage module, the second communication module and the interaction module; the storage module, the second communication module and the interaction module are all connected with the ARM processor;

the second communication module is used for establishing communication connection with at least one detection device;

the ARM processor is used for sequencing the detection data reported by at least one detection device according to time and the identification code to generate a database;

the storage module is used for storing the database;

the interaction module is used for responding to the input query instruction and displaying the detection data in the database according to the query instruction.

When the remote terminal is used, the MCU module is used as a data processing and switching center, necessary communication protocols and operation systems are loaded, the data transmitted by each module are subjected to interactive processing, the GPS positioning data and the physiological parameters are packaged, the processed data are reported to the remote terminal in real time through the first communication module, so that the remote transmission of the data is realized, and the physiological parameters are conveniently and automatically reported. In the embodiment, the structural data is adopted to process the detection data, so that the medical staff can inquire and use the detection data conveniently; the position of the user can be directly inquired through the GPS positioning data, so that the time for positioning the user is reduced to the maximum extent, and the medical staff can conveniently visit in time. The technical scheme provided by the embodiment can simultaneously carry out physiological monitoring on a large number of users and provide real-time physiological condition management.

In a preferred embodiment, the physiological parameter detection module comprises: the blood oxygen saturation probe, the body temperature probe, the optical heart rate sensor and the acceleration sensor are respectively connected with the blood oxygen saturation probe, the body temperature probe, the optical heart rate sensor and the acceleration sensor by the MCU module.

In the use, medical personnel need accomplish initiative management to the physiological condition of a large amount of users, need in time accomplish the risk early warning to the physiological condition of each user to with the accurate conveying of risk warning message for corresponding user, the user also need accomplish in time to self health risk and know, in the prior art, not only expend time through the mode of manual monitoring database, does not have timeliness yet, in order to solve this problem, in a preferred embodiment, ARM treater still is used for:

judging whether the physiological parameter in the database exceeds a set threshold value, inquiring detection equipment corresponding to the physiological parameter when the physiological parameter exceeding the set threshold value exists in the database, and sending reminding information to the detection equipment, wherein the reminding information comprises the physiological parameter exceeding the set threshold value and a risk warning message;

the detection equipment further comprises a display module connected with the MCU module;

and the MCU module is used for controlling the display module to display the reminding information when receiving the reminding information.

The set threshold in this embodiment is determined according to the normal ranges of blood oxygen, body temperature and heart rate, and whether the physical risk of the user occurs is obtained by judging whether the physiological parameter exceeds the set threshold, and when the physical risk of the user is judged, the user can be reminded in time.

In order to solve the problem, in a preferred embodiment, the ARM processor is further configured to:

judging whether GPS positioning data and physiological parameters contained in detection data reported by the detection equipment are complete or not;

when the detection data is in data missing, judging the duration of the occurrence of the data missing;

when the duration of the occurrence of the data missing exceeds a set threshold value, judging that the detection equipment corresponding to the detection data has faults;

predicting a module with faults according to the missing detection data, and generating prediction information, wherein the module with faults is one or more of a GPS positioning module and a physiological parameter detection module;

sending prediction information to the detection equipment, wherein the prediction information comprises module information for predicting faults and fault warning information;

and the MCU module is also used for controlling the display module to display the prediction information in real time when receiving the prediction information.

Referring to fig. 2, an embodiment of the present invention further provides a remote medical detection control method, which is applied to the remote medical detection control system described in any one of the above embodiments, and the method includes the following steps:

step S100, a GPS positioning module acquires GPS positioning data and transmits the GPS positioning data to an MCU module;

step 200, a physiological parameter detection module detects physiological parameters and sends the physiological parameters to an MCU module;

wherein the physiological parameters include: blood oxygen, body temperature, heart rate and number of steps;

step S300, the MCU module adds a time stamp and an identification code of the detection equipment to the GPS positioning data and the physiological parameter, packages the GPS positioning data and the physiological parameter into detection data, and reports the detection data to the monitoring equipment through the first communication module;

step S400, the ARM processor sorts the detection data reported by at least one detection device according to time and the identification code to generate a database;

step S500, a storage module stores the database;

and step S600, when the interaction module detects an input query instruction, displaying detection data in the database according to the query instruction.

In a preferred embodiment, the method further comprises:

the ARM processor judges whether the physiological parameter in the database exceeds a set threshold, and when the physiological parameter exceeding the set threshold exists in the database, the MCU module inquires detection equipment corresponding to the physiological parameter and sends reminding information to the detection equipment, wherein the reminding information comprises the physiological parameter exceeding the set threshold and a risk warning message;

when the MCU module receives the reminding information, the MCU module controls the display module to display the reminding information.

In a preferred embodiment, the method further comprises:

the ARM processor judges whether GPS positioning data and physiological parameters contained in detection data reported by the detection equipment are complete or not;

when the detection data is in data missing, the ARM processor judges the duration of the occurrence of the data missing;

when the duration of the occurrence of the data missing exceeds a set threshold value, the ARM processor judges that the detection equipment corresponding to the detection data fails;

the ARM processor predicts a failed module according to the missing detection data and generates prediction information, wherein the failed module is one or more of a GPS positioning module and a physiological parameter detection module;

the ARM processor sends prediction information to the detection equipment, wherein the prediction information comprises module information for predicting faults and fault warning information;

and when the MCU module receives the prediction information, controlling the display module to display the prediction information.

While the present disclosure has been described in considerable detail and with particularity with respect to several described embodiments, it is not intended to be limited to any such detail or embodiments or any particular embodiment, but is to be construed as providing broad interpretation of such claims by reference to the appended claims in view of the prior art so as to effectively encompass the intended scope of the disclosure.

Claims (2)

1. The remote medical detection control system is characterized by comprising detection equipment of a user side and monitoring equipment of a background;

the detection apparatus includes: the system comprises an MCU module, a first communication module, a GPS positioning module and a physiological parameter detection module, wherein the MCU module is respectively connected with the first communication module, the GPS positioning module and the physiological parameter detection module;

the GPS positioning module is used for acquiring GPS positioning data and transmitting the GPS positioning data to the MCU module;

the physiological parameter detection module is configured to detect a physiological parameter and send the physiological parameter to the MCU module, where the physiological parameter includes: blood oxygen, body temperature, heart rate and number of steps;

the first communication module is used for establishing communication connection with the monitoring equipment;

the MCU module is used for adding a time stamp and an identification code of the detection equipment to the GPS positioning data and the physiological parameter, packaging the GPS positioning data and the physiological parameter into detection data, and reporting the detection data to the monitoring equipment through the first communication module;

the monitoring device includes: the ARM processor, the storage module, the second communication module and the interaction module; the storage module, the second communication module and the interaction module are all connected with the ARM processor;

the second communication module is used for establishing communication connection with at least one detection device;

the ARM processor is used for sequencing the detection data reported by at least one detection device according to time and the identification code to generate a database;

the storage module is used for storing the database;

the interaction module is used for responding to an input query instruction and displaying detection data in the database according to the query instruction;

the physiological parameter detection module includes: the MCU module is respectively connected with the blood oxygen saturation probe, the body temperature probe, the optical heart rate sensor and the acceleration sensor;

the ARM processor is further configured to: judging whether the physiological parameter in the database exceeds a set threshold value, inquiring detection equipment corresponding to the physiological parameter when the physiological parameter exceeding the set threshold value exists in the database, and sending reminding information to the detection equipment, wherein the reminding information comprises the physiological parameter exceeding the set threshold value and a risk warning message;

the detection equipment further comprises a display module connected with the MCU module;

the MCU module is also used for: when the reminding information is received, controlling the display module to display the reminding information;

the ARM processor is further configured to: judging whether GPS positioning data and physiological parameters contained in detection data reported by the detection equipment are complete or not;

when the detection data is in data missing, judging the duration of the occurrence of the data missing;

when the duration of the occurrence of the data missing exceeds a set threshold value, judging that the detection equipment corresponding to the detection data has faults;

predicting a module with faults according to the missing detection data, and generating prediction information, wherein the module with faults is one or more of a GPS positioning module and a physiological parameter detection module;

sending prediction information to the detection equipment, wherein the prediction information comprises module information for predicting faults and fault warning information;

the MCU module is also used for: and when the prediction information is received, controlling the display module to display the prediction information.

2. A telemedicine detection control method applied to the telemedicine detection control system as set forth in claim 1, characterized in that the method includes:

the GPS positioning module acquires GPS positioning data and transmits the GPS positioning data to the MCU module;

the physiological parameter detection module detects physiological parameters and sends the physiological parameters to the MCU module, wherein the physiological parameters comprise: blood oxygen, body temperature, heart rate and number of steps;

the MCU module adds a time stamp and an identification code of the detection equipment to the GPS positioning data and the physiological parameter, packages the GPS positioning data and the physiological parameter into detection data, and reports the detection data to the monitoring equipment through the first communication module;

the ARM processor sorts the detection data reported by at least one detection device according to time and the identification code to generate a database;

the storage module stores the database;

when the interaction module detects an input query instruction, displaying detection data in the database according to the query instruction;

the physiological parameter detection module includes: the MCU module is respectively connected with the blood oxygen saturation probe, the body temperature probe, the optical heart rate sensor and the acceleration sensor;

the method further comprises the steps of:

the ARM processor judges whether the physiological parameter in the database exceeds a set threshold, and when the physiological parameter exceeding the set threshold exists in the database, the MCU module inquires detection equipment corresponding to the physiological parameter and sends reminding information to the detection equipment, wherein the reminding information comprises the physiological parameter exceeding the set threshold and a risk warning message;

when the MCU module receives the reminding information, the MCU module controls the display module to display the reminding information;

the method further comprises the steps of:

the ARM processor judges whether GPS positioning data and physiological parameters contained in detection data reported by the detection equipment are complete or not;

when the detection data is in data missing, the ARM processor judges the duration of the occurrence of the data missing;

when the duration of the occurrence of the data missing exceeds a set threshold value, the ARM processor judges that the detection equipment corresponding to the detection data fails;

the ARM processor predicts a failed module according to the missing detection data and generates prediction information, wherein the failed module is one or more of a GPS positioning module and a physiological parameter detection module;

the ARM processor sends prediction information to the detection equipment, wherein the prediction information comprises module information for predicting faults and fault warning information;

and when the MCU module receives the prediction information, controlling the display module to display the prediction information.

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