CN111329458A - Monitored object parameter acquisition system and monitored object data transmission system - Google Patents

Abstract

The application relates to a monitored object parameter acquisition system and a monitored object data transmission system. The monitoring object parameter acquisition system comprises an acquisition terminal and a local data acquisition device. The acquisition terminals are respectively arranged on the corresponding living objects and are used for acquiring the behavior parameters and the physiological parameters of the living objects and sending the behavior parameters and the physiological parameters to the local side data acquisition unit. The local side data acquisition unit can be in communication connection with a plurality of acquisition terminals, can store data transmitted by each acquisition terminal, and can transmit the data transmitted by each acquisition terminal to a PC (personal computer), a server and the like. Based on the method, the manual measurement mode can be changed, the accuracy and the real-time performance of experimental data acquisition are improved, and the labor cost is saved; for the management aspect of an animal laboratory, the safe, reliable and accurate data management can avoid repeated work; for monitoring application occasions where guardians are high risk groups with infection risks, the embodiment of the application can timely know related physiological parameters and effectively avoid the risk of cross infection.

Description

Monitored object parameter acquisition system and monitored object data transmission system

Technical Field

The application relates to the technical field of living object monitoring, in particular to a monitored object parameter acquisition system and a monitored object data transmission system.

Background

The living subject monitoring mainly includes monitoring of a person who needs special monitoring (hereinafter, referred to as "monitor"), and monitoring of some common experimental animals such as mice, rabbits, and the like. The scene of the guardian includes general work, study, living environment, etc., and the traditional technology needs to acquire data manually. For animals, most animal laboratories are equipped with monitoring and special personnel to observe the animals under test. In the conventional technology, data are collected regularly in a manual mode, and a laboratory technician performs comparative analysis on the collected data and manually records the data into a computer system.

In the implementation process, the inventor finds that at least the following problems exist in the conventional technology: in the process of monitoring an object by the traditional technology, the acquired data is not accurate enough and real-time.

Disclosure of Invention

Therefore, it is necessary to provide a monitored object parameter acquisition system and a monitored object data transmission system for solving the problem that the acquired data is not accurate enough and real-time in the process of monitoring the object in the conventional technology.

In order to achieve the above object, in one aspect, an embodiment of the present application provides a monitored object parameter acquisition system, including:

the acquisition terminal is used for being arranged on the living body object; the acquisition terminal comprises a terminal control unit, a behavior sensor unit, a physiological parameter sensor unit and a terminal communication unit; the terminal control unit is electrically connected with the behavior sensor unit, the physiological parameter sensor unit and the terminal communication unit respectively;

the local side data acquisition unit comprises a local side control unit, a data storage unit, a local side communication unit and a data interaction unit; the local side control unit is electrically connected with the data storage unit, the local side communication unit and the data interaction unit respectively; the local side communication unit is used for being in communication connection with the terminal communication unit; the data interaction unit is used for being in communication connection with the PC and/or the cloud server.

In one embodiment, the acquisition terminal further comprises a physiological stimulation unit for transmitting a stimulation signal to the living subject;

the terminal control unit is electrically connected with the physiological stimulation unit.

In one embodiment, the acquisition terminal further comprises a terminal power supply unit and a terminal display unit;

the terminal control unit is electrically connected with the terminal power supply unit and the terminal display unit respectively.

In one embodiment, the behavior sensor unit includes a displacement sensor;

the terminal control unit is electrically connected with the displacement sensor.

In one embodiment, the physiological parameter sensor unit comprises a temperature sensor and a heart rate sensor;

and the terminal control unit is electrically connected with the temperature sensor and the heart rate sensor respectively.

In one embodiment, the local side data collector further comprises a local side power supply unit, a local side display unit and an input unit;

the local side control unit is electrically connected with the local side power supply unit, the local side display unit and the input unit respectively.

In one embodiment, the data interaction unit comprises a USB interface and/or an RS232 interface;

the local side control unit is electrically connected with the USB interface and the RS232 interface respectively.

In one embodiment, the terminal communication unit and the local side communication unit are in communication connection by adopting wireless transmission;

the wireless transmission includes at least one of Wi-Fi, bluetooth, and mobile communication.

On the other hand, an embodiment of the present application further provides a monitored object data transmission system, including:

the monitoring object parameter acquisition system is as above;

and the PC is in communication connection with the monitored object parameter acquisition system.

In one embodiment, the PC is used for being connected with the cloud server in a communication mode.

One of the above technical solutions has the following advantages and beneficial effects:

the monitoring object parameter acquisition system comprises an acquisition terminal and a local data acquisition device. The acquisition terminals are respectively arranged on the corresponding living objects and are used for acquiring the behavior parameters and the physiological parameters of the living objects and sending the behavior parameters and the physiological parameters to the local side data acquisition unit. The local side data acquisition unit can be in communication connection with a plurality of acquisition terminals, can store data transmitted by each acquisition terminal, and can transmit the data transmitted by each acquisition terminal to a PC (personal computer), a server and the like. Based on the method, the manual measurement mode can be changed, the accuracy and the real-time performance of experimental data acquisition are improved, and the labor cost is saved; for the management aspect of an animal laboratory, the safe, reliable and accurate data management can avoid repeated work; for monitoring application occasions where guardians are high risk groups with infection risks, the embodiment of the application can timely know related physiological parameters and effectively avoid the risk of cross infection.

Drawings

Other features, objects and advantages of the present application will become more apparent upon reading of the following detailed description of non-limiting embodiments thereof, made with reference to the accompanying drawings in which:

FIG. 1 is a first schematic block diagram of a monitored object parameter acquisition system in one embodiment;

FIG. 2 is a second schematic block diagram of a monitored object parameter acquisition system in one embodiment;

FIG. 3 is a third schematic block diagram of a monitored object parameter acquisition system in one embodiment;

FIG. 4 is a fourth schematic block diagram of a monitored object parameter acquisition system in one embodiment;

FIG. 5 is a fifth schematic block diagram of a monitored object parameter acquisition system in one embodiment;

FIG. 6 is a first schematic block diagram of a monitored object data transmission system in one embodiment;

fig. 7 is a second schematic configuration diagram of a monitored object data transmission system in one embodiment.

Detailed Description

To facilitate an understanding of the present application, the present application will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present application are shown in the drawings. This application may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "connected" to another element, it can be directly connected to the other element and be integral therewith, or intervening elements may also be present. The terms "electrically connected," "communicatively connected," and the like as used herein are for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used herein in the description of the present application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

At present, in the aspect of physiological detection of laboratory animals, the physiological detection is based on monitoring of animals, and real intelligent measuring equipment and a real intelligent measuring system are not available. In some daily life places of non-medical institutions, when certain guardians need to collect data in a centralized manner, corresponding intelligent collection systems are lacked, and labor cost is high. In order to obtain more accurate data, realize real-time dynamic follow-up and save labor cost, the embodiment of the application fixes a portable terminal, such as a device similar to an intelligent bracelet, on a living object; the terminal equipment sends data to a local side data collector in a wireless communication mode; the collector can analyze data through system software, and meanwhile, the data can be stored in a local storage, a Personal Computer (PC) or a cloud server. Based on this, this application embodiment can provide more accurate data for the laboratory technician, is convenient for make more authoritative judgement and analysis processing.

In one embodiment, there is provided a monitored object parameter acquisition system, as shown in fig. 1, including:

the acquisition terminal is used for being arranged on the living body object; the acquisition terminal comprises a terminal control unit, a behavior sensor unit, a physiological parameter sensor unit and a terminal communication unit; the terminal control unit is electrically connected with the behavior sensor unit, the physiological parameter sensor unit and the terminal communication unit respectively.

The local side data acquisition unit comprises a local side control unit, a data storage unit, a local side communication unit and a data interaction unit; the local side control unit is electrically connected with the data storage unit, the local side communication unit and the data interaction unit respectively; the local side communication unit is used for being in communication connection with the terminal communication unit; the data interaction unit is used for being in communication connection with the PC and/or the cloud server.

Particularly, the monitoring object parameter acquisition system can set at least one acquisition terminal for each living object according to requirements, and can also set a local side data acquisition unit according to a monitoring range so as to ensure that the signal range of the local side data acquisition unit covers each corresponding acquisition terminal. According to the actual monitoring requirement, the living body object can be provided with one or more acquisition terminals, the data types acquired by the acquisition terminals can be different, and the flexibility and the applicability of the system are improved.

The collection terminal may be configured to collect data of a corresponding living object and send the data to the local data collector, and illustratively, the collection terminal may collect and send the data according to a certain period, and the collection terminal may further collect and send the data according to an instruction of the local data collector. In the acquisition terminal, the behavior sensor unit is used for acquiring behavior parameters of the living body object, and the behavior parameters can comprise position parameters, moving speed and the like; specifically, the behavior sensor unit may include a displacement sensor, an acceleration sensor, a vibration sensor, and the like, which are not particularly limited herein. The physiological parameter sensor unit is used for acquiring physiological parameters of a living object, and the physiological parameters can include temperature, heart rate, blood pressure and the like; specifically, the physiological parameter sensor unit may include a temperature sensor, a heart rate sensor, and the like, which are not particularly limited herein. The terminal communication unit can be used for carrying out data transmission with the local side data acquisition unit; specifically, the terminal communication unit may include at least one of a Wi-Fi (wireless internet access) module, a bluetooth module, and a mobile communication module, which is not particularly limited herein. The terminal control unit is used for acquiring the behavior parameters acquired by the behavior sensor unit and the physiological parameters acquired by the physiological parameter sensor unit and instructing the terminal communication unit to transmit the acquired data to the local side data acquisition unit; specifically, the terminal control Unit may be an MCU (micro controller Unit), a DSP (Digital Signal Processing), an FPGA (Field Programmable gate array), an ARM chip, or the like, and is not limited herein.

The local side data acquisition unit can be used for transmitting data transmitted by the acquisition terminal to the PC and/or the cloud server, and can also be used for configuring, controlling and the like the acquisition terminal according to the received instruction. In the local side data collector, the local side communication unit can be used for carrying out data transmission with the collection terminal; specifically, the office-side communication unit may include at least one of a Wi-Fi module, a bluetooth module, and a mobile communication module, which is not particularly limited herein. The local side control unit can be used for processing data transmitted by the acquisition terminal, such as data summarization, format conversion and the like; the local side control unit can also be used for configuring parameters of the acquisition terminal, such as the number of sampling channels, amplification factors, sampling frequency, filtering parameters, battery capacity and the like; specifically, the local side control unit may be an MCU, a DSP, an FPGA, or an ARM chip, and the like, which is not limited herein. The data storage unit can be used for storing data transmitted by the acquisition terminal, data obtained by processing of the local control unit and the like. The data interaction unit can be used for data interaction between the local side data acquisition unit and the PC or the cloud server; specifically, the data interaction unit may include a wired data transmission module and/or a wireless data transmission module, which is not specifically limited herein.

Based on the structure, the living body object to be monitored in the experiment system or the monitoring system is provided with the acquisition terminal, and meanwhile, the local side data acquisition device in the system covers each acquisition terminal. In one example, the acquisition terminal acquires data of a living object and transmits the data to the local side data acquisition device; the local side data acquisition unit can store data and forward the data to the PC and the cloud server when receiving the data of the acquisition terminal, and can also store and gather the data after acquiring the data of a plurality of acquisition terminals, and then send the data to the PC and the cloud server. In another example, the office data collector may send a corresponding instruction to the collection terminal based on the obtained external command, so as to implement control of parameter configuration, data collection, and the like.

Based on the above, the embodiment of the application can change the manual measurement mode, improve the accuracy and real-time performance of experimental data acquisition and save labor cost; for the management aspect of an animal laboratory, the safe, reliable and accurate data management can avoid repeated work; for monitoring application occasions where guardians are high risk groups with infection risks, the embodiment of the application can timely know related physiological parameters and effectively avoid the risk of cross infection. In addition, the acquired data can be recorded in the acquisition terminal, the local side data acquisition unit, the PC or the cloud server in time, and relevant data processing, data query, data analysis, data management and the like can be carried out on the basis of the equipment, so that the data can be conveniently queried by external terminal equipment, and the data loss is avoided.

It should be noted that the collection terminal (also referred to as an RT remote terminal) can comprehensively integrate the intelligent hardware, the wearable technology, the wireless communication technology, and the system application software, and can complete the data collection in the early stage of the experiment to the data analysis and processing in the later stage in one step. In addition, according to the characteristics of the living body object and the experimental requirements, the collecting terminal can be arranged on the living body object in a wearing, fixing or implanting mode, and the like, and the method is not particularly limited here. The local side data acquisition unit is used for data acquisition, summarization, processing and monitoring so as to achieve the purposes of control, optimization, scheduling and management. The local side data acquisition unit can be directly connected with a PC (personal computer), can also be in communication connection with the cloud server through a gateway, and can also be connected with the cloud server through the PC. Based on this, the embodiment of the application can reduce the labor burden of the experimenter, does not need to carry out large-scale reconstruction on the scenes such as the existing detection room and the like, and particularly does not need to carry out complex wiring; in addition, the number of the acquisition terminals and the number of the local data collectors can be configured according to the number of the living objects, that is, the embodiment of the present application is not limited by the number of the acquisition objects.

In one example, the RT remote end continuously collects and monitors basic vital physiological characteristic parameters of the experimental animal through a wearable detection sensor arranged on the experimental animal (the detection frequency and time can be set through a terminal), and then transmits data information acquired by the animal to a local data acquisition unit (also called COT local) in real time in a wireless transmission manner. The COT local side stores the collected data, and the data can be used for corresponding analysis of computer side software in the later period, so that experimenters can conveniently and accurately analyze experimental results. For example, before a toxicological analysis experiment needs to be performed on a mouse by using a contamination cabinet, some physiological parameters of an experimental object (mouse) can be collected one or two days before the experiment; after the contamination experiment is finished, data acquisition, tracking and observation are carried out for two days; through two times of big data analysis, engineers can be helped to better analyze the experimental results.

In one embodiment, as shown in fig. 2, the acquisition terminal further comprises a physiological stimulation unit for transmitting a stimulation signal to the living subject;

the terminal control unit is electrically connected with the physiological stimulation unit.

Specifically, the acquisition terminal also comprises a physiological stimulation unit electrically connected with the terminal control unit; the physiological stimulation unit is used for transmitting a stimulation signal to the living body object, such as a vibration signal, a wake-up signal, an audio signal or an electric shock signal; specifically, the physiological stimulation unit may include a shock unit, a vibration unit, an audio unit, and the like, which are not particularly limited herein. Based on this, this application embodiment accessible collection terminal carries out physiological stimulation to the live body object, satisfies multiple experiment demand, improves the functionality of this application embodiment, and further avoids experimenter and live body object's direct contact, improves the security of experiment.

In one example, an experimenter can send a stimulation instruction to an acquisition terminal through a PC (personal computer) or directly through a local side data acquisition device, and instruct the acquisition terminal to apply a physiological stimulation signal to a living object; the acquisition terminal acquires corresponding physiological parameters and feeds the physiological parameters back to the local side data acquisition device in the process of applying the stimulation signals, so that experimenters can record and analyze data.

In one embodiment, as shown in fig. 3, the acquisition terminal further includes a terminal power supply unit and a terminal display unit;

the terminal control unit is electrically connected with the terminal power supply unit and the terminal display unit respectively.

Specifically, the acquisition terminal further comprises a terminal power supply unit and a terminal display unit which are electrically connected with the terminal control unit. The terminal power supply unit is configured to supply power to each unit and device in the acquisition terminal, and specifically, may include a charging module, a voltage conversion module, and the like, which is not specifically limited herein. The terminal display unit can be used for displaying basic information of a terminal or a living object, and also can display acquired data or prompt abnormal conditions; specifically, the terminal Display unit may be a Light Emitting Diode (LED) Display unit, a Liquid Crystal Display (LCD) unit, and the like, and is not limited herein. Based on this, the acquisition terminal in the embodiment of the application is convenient to use and has long standby time, and can meet the experiment period.

In one embodiment, as shown in fig. 4, the behavior sensor unit includes a displacement sensor;

the terminal control unit is electrically connected with the displacement sensor.

Specifically, the behavior sensor unit includes a displacement sensor. Based on this, this application embodiment can gather action parameters such as the moving trajectory, the moving frequency of live body object, satisfies the monitoring demand.

In one embodiment, as shown in fig. 4, the physiological parameter sensor unit includes a temperature sensor and a heart rate sensor;

and the terminal control unit is electrically connected with the temperature sensor and the heart rate sensor respectively.

Specifically, the physiological parameter sensor unit comprises a temperature sensor and a heart rate sensor which are electrically connected with the terminal control unit. Based on this, this application embodiment can gather physiological parameters such as live body object's body temperature, rhythm of the heart, satisfy the monitoring demand.

In one embodiment, the acquisition terminal includes a waterproof housing.

The terminal control unit, the behavior sensor unit, the physiological parameter sensor unit, the terminal communication unit and the like of the acquisition terminal are all arranged in the waterproof shell. Based on this, the embodiment of the application can be applied to various application environments.

In one example, the acquisition terminal may be adapted for use with a human, rat, mouse, rabbit, cat, dog, monkey, and the like. And the acquisition terminal can be to adopting the setting that integrates, and the equipment that obtains is small, light in weight, and can use the power supply of small volume high capacity battery, the installation and carry of being convenient for. Illustratively, the signal transmission distance of the acquisition terminal can be 5 meters to 100 meters and can be penetrated through a wall. The number of sampling channels, amplification factor, sampling frequency, filtering parameters and battery capacity of the acquisition terminal can be modified according to the specific requirements of a user, and the battery can adopt a wireless charging technology. In addition, the acquisition terminal can also have the following characteristics:

the data can be stored in a mass mode, and all the data can be played back again;

unique digital signal processing techniques, providing reliable raw measurement data;

the low power consumption design is adopted, so that the service life of the battery is prolonged to the maximum extent;

volume <2.5cm × 2.2cm × 0.5.5 cm (cm);

power supply: the micro battery with the volume larger than 180mAh (milliampere hour) can be repeatedly charged and recycled, and can continuously work for more than 8 hours;

sampling rate: programmable, maximum 1 KHz;

safety: the waterproof level reaches the IPV4 requirement.

It should be noted that in addition to the above features, the acquisition terminal may be customized according to actual experimental needs.

In one embodiment, as shown in fig. 5, the office data collector further includes an office power supply unit, an office display unit, and an input unit;

the local side control unit is electrically connected with the local side power supply unit, the local side display unit and the input unit respectively.

Specifically, the local side data collector comprises a local side power supply unit, a local side display unit and an input unit which are electrically connected with the local side control unit. The office power supply unit is configured to supply power to each unit and device of the office data collector, and specifically, may include a charging module, a voltage conversion module, and the like, which is not limited specifically here. The local side display unit can be used for displaying the basic information of the collector or the collection terminal, and can also display the collected data or prompt abnormal conditions; specifically, the terminal display unit may be an LED display unit, an LCD display unit, or the like, and is not particularly limited herein. The input unit can be used for acquiring an external instruction; specifically, the input unit may include a touch screen, a key, and the like, which are not particularly limited herein. Based on this, the office side data collector in the embodiment of the application can accept manual setting and remote setting, and further improves convenience.

In one embodiment, the data interaction unit includes a USB (Universal Serial Bus) interface and/or an RS232 interface;

the local side control unit is electrically connected with the USB interface and the RS232 interface respectively.

Specifically, the central office control unit may perform data interaction with the PC through a wired connection method such as a USB interface or an RS232 interface. Based on this, the embodiment of the application can improve the reliability of data interaction, and meanwhile, the data can be transmitted to the server, the external terminal and the like by means of the PC.

In one embodiment, the terminal communication unit and the local side communication unit are in communication connection by adopting wireless transmission;

the wireless transmission includes at least one of Wi-Fi, bluetooth, and mobile communication.

Specifically, the acquisition terminal and the local data acquisition unit can transmit data through wireless communication modes such as Wi-Fi, Bluetooth and mobile communication, and different data transmission requirements are met.

In one example, the local side data collector can adopt an industrial grade 32-bit microprocessor as a core circuit and acts as a relay service for data storage, query and upper and lower end communication. Illustratively, the local side data collector can adopt a 10-inch resistance touch screen, and can perform operations such as inquiry, setting and the like on the collection terminal off line (computer). In addition, the local side data acquisition unit can also have the following characteristics:

the signal transmission distance is 5-100 m, and the wall can be penetrated;

parameters such as the number of sampling channels, amplification factor, sampling frequency, filtering parameter, battery capacity and the like of the acquisition terminal can be remotely modified;

the data can be stored in a mass mode, all the data can be played back again, and the data can be read and written in a USB Host mode to be exported;

and the USB or RS232 interface is adopted to communicate with the PC.

In one embodiment, the acquisition terminal comprises a terminal control unit, a behavior sensor unit, a physiological parameter sensor unit, a terminal communication unit, a physiological stimulation unit, a terminal power supply unit and a terminal display unit; the terminal control unit is respectively and electrically connected with the behavior sensor unit, the physiological parameter sensor unit, the terminal communication unit, the physiological stimulation unit, the terminal power supply unit and the terminal display unit.

The local side data collector comprises a local side control unit, a data storage unit, a local side communication unit, a data interaction unit, a local side power supply unit, a local side display unit and an input unit; the local side control unit is electrically connected with the data storage unit, the local side communication unit, the data interaction unit, the local side power supply unit, the local side display unit and the input unit respectively.

In one embodiment, the acquisition terminal comprises a terminal control unit, a behavior sensor unit, a physiological parameter sensor unit, a terminal communication unit, a physiological stimulation unit, a terminal power supply unit and a terminal display unit; the terminal control unit is respectively and electrically connected with the behavior sensor unit, the physiological parameter sensor unit, the terminal communication unit, the physiological stimulation unit, the terminal power supply unit and the terminal display unit. Wherein the behavior sensor unit includes a displacement sensor; the terminal control unit is electrically connected with the displacement sensor.

In one embodiment, the acquisition terminal comprises a terminal control unit, a behavior sensor unit, a physiological parameter sensor unit, a terminal communication unit, a physiological stimulation unit, a terminal power supply unit and a terminal display unit; the terminal control unit is respectively and electrically connected with the behavior sensor unit, the physiological parameter sensor unit, the terminal communication unit, the physiological stimulation unit, the terminal power supply unit and the terminal display unit. The physiological parameter sensor unit comprises a temperature sensor and a heart rate sensor; and the terminal control unit is electrically connected with the temperature sensor and the heart rate sensor respectively.

In one embodiment, the local side data collector comprises a local side control unit, a data storage unit, a local side communication unit, a data interaction unit, a local side power supply unit, a local side display unit and an input unit; the local side control unit is electrically connected with the data storage unit, the local side communication unit, the data interaction unit, the local side power supply unit, the local side display unit and the input unit respectively. The data interaction unit comprises a USB interface and/or an RS232 interface; the local side control unit is electrically connected with the USB interface and the RS232 interface respectively.

In one embodiment, the terminal communication unit comprises a terminal Wi-Fi module; the local side communication unit comprises a local side Wi-Fi module. And the terminal Wi-Fi module is used for being in communication connection with the local side Wi-Fi module.

In one embodiment, the terminal communication unit includes a terminal bluetooth module; the local side communication unit comprises a local side Bluetooth module. And the terminal Bluetooth module is used for being in communication connection with the local side Bluetooth module.

In one embodiment, the terminal communication unit includes a terminal mobile communication module; the local side communication unit comprises a local side mobile communication module. The terminal mobile communication module is used for being in communication connection with the local side mobile communication module.

In one embodiment, there is provided a monitored object data transmission system, as shown in fig. 6, including:

the monitoring object parameter acquisition system is as above;

and the PC is in communication connection with the monitored object parameter acquisition system.

Specifically, in the monitored object parameter acquisition system, a data interaction unit of a local side data acquisition unit performs data interaction with a PC; the PC can be used for data detection, analysis and the like. Based on the embodiment of the application, experimenters can perform data comparison through equipment detection and professional system software analysis, so that accurate judgment can be obtained more easily, and better decisions can be made. Namely, the PC can be used as a local side data platform, and corresponding data acquisition and analysis software can be deployed according to actual conditions.

In one example, the PC can perform real-time setting and query operations on the acquisition terminal through software, and observe the acquired data and the curve graph of the acquisition terminal in real time; and the mathematical modeling, data analysis and icon printing can be carried out on massive raw data through software. Specifically, the PC can perform real-time communication with the local data collector through a USB or RS232 and perform real-time transceiving processing on the original data; and, the PC may provide cloud or local server connectivity and access channels.

In one example, the PC may be developed using Microsoft Visual Studio development platform to obtain powerful and well-interfaced data analysis software for analyzing the obtained data.

In one embodiment, as shown in fig. 7, a PC is used to communicatively connect with the cloud server.

Specifically, the PC may be in communication connection with the cloud server, and upload local data to the cloud server via a network, and an external computer or mobile terminal may access related data via the cloud server. Based on the embodiment of the application, the user can check the data of the living body object in real time through the terminal.

In one example, an acquisition terminal is fixed on a living object, and required physiological data is measured; the acquisition terminal transmits information to a local side data acquisition unit (COT local side) through Bluetooth, Wi-Fi or 5G (5th generation mobile networks or 5th generation wireless systems, fifth generation mobile communication technology) and the like; the COT local side is connected with a local PC and transmits data to the PC; the PC can be provided with professional data analysis software for analyzing and processing data. Furthermore, the PC can upload data to the cloud server, so that data loss is avoided; meanwhile, management and query can be performed more conveniently by developing an application program of the mobile terminal.

In one example, according to the embodiment of the application, the mobile terminal can access the monitored object parameter acquisition system through an application program. Illustratively, applications may be divided into an experiment administrator version and a general user version; the common user version mainly provides the functions of inquiring and browsing experimental data; the laboratory administrator version has more authority and functions, for example, through setting, a camera of a laboratory can be remotely started when necessary, then real-time video observation is carried out, and some customized emergency messages can be received.

Based on the method, the monitored object data transmission system can change a manual measurement mode, improve the accuracy and the real-time performance of experimental data acquisition, save labor cost, and improve the efficiency and the accuracy of data processing by using a PC (personal computer) to detect and analyze data; for the management aspect of an animal laboratory, the safe, reliable and accurate data management can avoid repeated work; for monitoring application occasions where guardians are high risk groups with infection risks, the embodiment of the application can timely know related physiological parameters and effectively avoid the risk of cross infection.

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

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

Claims (10)

1. A monitored object parameter acquisition system, comprising:

the acquisition terminal is used for being arranged on the living body object; the acquisition terminal comprises a terminal control unit, a behavior sensor unit, a physiological parameter sensor unit and a terminal communication unit; the terminal control unit is electrically connected with the behavior sensor unit, the physiological parameter sensor unit and the terminal communication unit respectively;

the local side data acquisition unit comprises a local side control unit, a data storage unit, a local side communication unit and a data interaction unit; the local side control unit is electrically connected with the data storage unit, the local side communication unit and the data interaction unit respectively; the local side communication unit is used for being in communication connection with the terminal communication unit; the data interaction unit is used for being in communication connection with the PC and/or the cloud server.

2. The monitored object parameter acquisition system of claim 1, wherein the acquisition terminal further comprises a physiological stimulation unit for transmitting a stimulation signal to the living object;

the terminal control unit is electrically connected with the physiological stimulation unit.

3. The monitored object parameter acquisition system of claim 2, wherein the acquisition terminal further comprises a terminal power supply unit and a terminal display unit;

and the terminal control unit is electrically connected with the terminal power supply unit and the terminal display unit respectively.

4. The monitored object parameter acquisition system of claim 2, wherein the behavior sensor unit comprises a displacement sensor;

and the terminal control unit is electrically connected with the displacement sensor.

5. The monitored subject parameter acquisition system of claim 2, wherein the physiological parameter sensor unit comprises a temperature sensor and a heart rate sensor;

and the terminal control unit is electrically connected with the temperature sensor and the heart rate sensor respectively.

6. The monitored object parameter acquisition system according to claim 1, wherein the local side data acquisition unit further comprises a local side power supply unit, a local side display unit and an input unit;

the local side control unit is electrically connected with the local side power supply unit, the local side display unit and the input unit respectively.

7. The monitored object parameter acquisition system of claim 1, wherein the data interaction unit comprises a USB interface and/or an RS232 interface;

the local side control unit is electrically connected with the USB interface and the RS232 interface respectively.

8. The monitored object parameter acquisition system according to claim 1, wherein said terminal communication unit and said local side communication unit are in communication connection by wireless transmission;

the wireless transmission includes at least one of Wi-Fi, bluetooth, and mobile communication.

9. A monitored object data transmission system, comprising:

the monitored subject parameter acquisition system as claimed in any one of claims 1 to 8;

and the PC is in communication connection with the monitored object parameter acquisition system.

10. The monitored object parameter acquisition system of claim 1,

the PC is used for being in communication connection with the cloud server.

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