CN105167744A - Embedded self-networking information acquisition system and embedded self-networking information acquisition method based on machine vision - Google Patents
Embedded self-networking information acquisition system and embedded self-networking information acquisition method based on machine vision Download PDFInfo
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- CN105167744A CN105167744A CN201510314593.3A CN201510314593A CN105167744A CN 105167744 A CN105167744 A CN 105167744A CN 201510314593 A CN201510314593 A CN 201510314593A CN 105167744 A CN105167744 A CN 105167744A
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Abstract
The invention relates to an embedded self-networking information acquisition system and an embedded self-networking information acquisition method based on machine vision. The embedded self-networking information acquisition system comprises the components of a physiological monitoring system, a miniature optical imaging system, a wireless self-networking system and a server platform. In a hospital diagnosis and treatment equipment information networking environment, the physiological monitoring system monitors the physiological parameter of a patient and furthermore displays the physiological parameter on a display panel. The miniature optical imaging system is used for imaging on the display panel. Imaging data are transmitted to the server platform through the wireless self-networking system. Finally the server platform performs analysis and processing on the imaging data. The physiological parameter of the human body is extracted and a report form is generated. The embedded self-networking information acquisition system and the embedded self-networking information acquisition method can realize extraction of required information from the physiological monitoring system, and performing analysis and processing for obtaining the corresponding report form. The embedded self-networking information acquisition system and embedded self-networking information acquisition method have functions of replacing manual record of medical care personnel for the physiological characteristic parameter of the patient, simultaneously recording the data of multiple patients, and well storing the data in the server platform.
Description
Technical field
The present invention relates to technology of Internet of things field, be specifically related to a kind of embedded MANET information acquisition system based on machine vision and method.
Technical background
These years along with the development of network technology and sensing technology, make Internet of Things obtain development at full speed, Internet of Things becomes the important component part of generation information technology, more and more inseparable with people.Internet of Things product day by day universal, the one side brought convenience to people's lives, also there is certain problem simultaneously, especially in hospital, hospital is as a Public place, hospital has a large amount of physiological monitoring systems, or is that same hospital also has the physiological monitoring system of many different brands, and this brings great trouble just to the record of data and preservation.
Patient will use physiological monitoring system when being in hospital or when performing the operation, and physiological monitoring system is used to monitor patient's physiological feature.And the position of the physiological parameter of the physiological monitoring system display of different brands, figure may be all different.But the physiological characteristic data of patient all must carry out preserving and checking.Just under these circumstances, when the physiological characteristic data of real-time monitor patients or when the physiological feature of patient is checked in review, can add to medical personnel a large amount of, repetitive work, also make the real-time monitoring of patient can not get definite guarantee simultaneously.
Summary of the invention
For the defect that prior art exists, the object of the present invention is to provide a kind of embedded MANET information acquisition system based on machine vision and method.From physiological monitoring system, extract the information needed, be stored on server platform, and treatment and analysis becomes corresponding form.Such as replace medical personnel data also can be made well to preserve to the real time record of patient's physiological feature parameter simultaneously, so not only can alleviate the workload of medical personnel, also reduce the error rate of medical personnel, the automatic business processing data of integration simultaneously provide very large convenience to the real-time preservation of data and analysis.
In order to achieve the above object, technical scheme of the present invention is as follows:
A kind of embedded MANET information acquisition system based on machine vision, comprise physiological monitoring system, micro-optical imaging system, wireless ad hoc network systems, server platform, physiological monitoring system is made up of multiple physiological monitor, micro-optical imaging system is made up of multiple wireless camera, in micro-optical imaging system, the imaging lens of each wireless camera aims at the display floater of a physiological monitor in physiological monitoring system, wireless ad hoc network systems be used for wireless receiving from micro-optical imaging system data and be transferred to server platform.
Described physiological monitoring system has the function of Real-time Interactive Demonstration, and the physiological parameter of multiple patient is presented on respective display floater by real time; Wireless ad hoc network systems is the network transmission platform of the embedded MANET information acquisition system of machine vision; Server platform monitors in real time in the embedded MANET information acquisition system of machine vision and stores the system of image that micro-optical imaging system transmitted by wireless self-networking or data.
The imaging lens of described micro-optical imaging system possesses auto-focusing, automatically regulates exposure function, and can catch in real time and wireless signal transmission, has independently supply module, wireless module.
Described wireless ad hoc network systems is an Intranet system, and it wirelessly carries out alternately with micro-optical imaging system, and carry out the transmission of data.
Described server platform is connected by wired mode with wireless ad hoc network systems, and server platform has integral image and stores, processes and data statistics function.
Based on an embedded MANET information collecting method for machine vision, adopt the above-mentioned embedded MANET information acquisition system based on machine vision to gather, operating procedure is as follows:
A. physiological parameters of patients is gathered: physiological monitoring system is by the physiological parameter of its sensor acquisition patient, and the characteristics of human body's parameter transmission collected also is shown on a display panel to physiological monitor by wired mode by sensor;
B. image-forming information is caught: micro-optical imaging system carries out imaging by its Zoom optic lens to physiological monitoring system display floater;
C. the wireless transmission of information: miniature imaging system acquisition to image be transferred to server platform by wireless ad hoc network systems;
D. the process of image-forming information: server platform real-time storage image is also by the numeral in numeral and text recognition method extraction image and text message;
E. produce data sheet: last server platform will extract information---sick bed numbering, time, blood pressure and hrv parameter dynamically generate data sheet.
The present invention compared with prior art, has following outstanding substantive distinguishing features and significant progress:
The invention solves the feature of acquired signal manually, replace medical personnel to the real time record of patient's physiological feature parameter, also data can be made well to preserve simultaneously, so not only alleviate the workload of medical personnel, also reduce the error rate of medical personnel, the automatic business processing data of integration simultaneously provide very large convenience and accuracy to the real-time preservation of data and analysis simultaneously.
Accompanying drawing explanation
Fig. 1 is structured flowchart of the present invention.
Fig. 2 is the operating procedure schematic diagram of native system.
Detailed description of the invention
For making the object, technical solutions and advantages of the present invention clearly, below in conjunction with the preferred embodiment of the present invention and accompanying drawing, technical scheme of the present invention is clearly and completely described.
As shown in Figure 1, a kind of embedded MANET information acquisition system based on machine vision, comprise physiological monitoring system 1, micro-optical imaging system 2, wireless ad hoc network systems 3, server platform 4, physiological monitoring system 1 is made up of multiple physiological monitor, micro-optical imaging system 2 is made up of multiple wireless camera, in micro-optical imaging system 2, the imaging lens of each wireless camera aims at the display floater of a physiological monitor in physiological monitoring system 1, wireless ad hoc network systems 3 be used for wireless receiving from micro-optical imaging system 2 data and be transferred to server platform 4.
Described physiological monitoring system 1 has the function of Real-time Interactive Demonstration, and the physiological parameter of multiple patient is presented on respective display floater by real time; Wireless ad hoc network systems 3 is network transmission platforms of the embedded MANET information acquisition system of machine vision; Server platform 4 monitors in real time in the embedded MANET information acquisition system of machine vision and stores the system of image that micro-optical imaging system transmitted by wireless self-networking or data.
The universal physiological monitoring system that in the present embodiment, physiological monitoring system 1 adopts is the model of NihonKohden manufacturers produce is the product of PVM-2701.Universal physiological monitoring system is contacted with human body by sensor, and gather characteristics of human body's parameter and human parameters shown on a display panel, the physiological parameter possessing monitoring has electrocardio, blood oxygen saturation, pulse, body temperature.
The imaging lens of described micro-optical imaging system 2 possesses auto-focusing, automatically regulates exposure function, and can catch in real time and wireless signal transmission, has independently supply module, wireless module.Micro-optical imaging system 2, by automatic focus adjustable, makes image-forming information reach the most clear.Then the display information of physiological monitoring system is filmed.Be linked into route by wireless module, according to client's name section and the password of server-assignment, image information file, by File Transfer Protocol, uploads photographing information.
Wireless ad hoc network systems 3 is Intranet systems, and it wirelessly carries out with micro-optical imaging system 2 alternately, carries out the transmission of data.The LAN that such as whole hospital system sets up, wherein comprises wireless router and switch.
Described server platform 4 is connected by wired mode with wireless ad hoc network systems 3, and server platform 4 has integral image and stores, processes and data statistics function.Server platform 4 utilizes MicrosoftVisualStudio2010 development platform to carry out Storage and Processing to the image received, and wherein image procossing comprises several module: module is mated, Module recognition, date processing, and data show.Module coupling is the physiologic parameters monitor because hospital may use different production firm to produce, and the data transmitted according to micro-optical imaging system are mated from tape pool with program by program, and determines the manufacturer of production.Module recognition is by the meaning of each parameter in recognition imaging picture, and the numerical value of relevant parameter is how many.The parameter of identification and numerical value carry out processing the data becoming and can call in data disaply moudle by date processing.Data can be shown as multi-form data by data display, as form, and image etc.
As shown in Figure 2, a kind of embedded MANET information collecting method based on machine vision, adopt the above-mentioned embedded MANET information acquisition system based on machine vision to gather, operating procedure is as follows:
A. physiological parameters of patients is gathered: physiological monitoring system 1 is by the physiological parameter of its sensor acquisition patient, and the characteristics of human body's parameter transmission collected also is shown on a display panel to physiological monitor by wired mode by sensor;
B. image-forming information is caught: micro-optical imaging system 2 carries out imaging by its Zoom optic lens to physiological monitoring system 1 display floater;
C. the wireless transmission of information: the image that miniature imaging system 2 collects is transferred to server platform 4 by wireless ad hoc network systems 3;
D. the process of image-forming information: server platform 4 real-time storage image is also by the numeral in numeral and text recognition method extraction image and text message;
E. produce data sheet: last server platform 4 will extract information---sick bed numbering, time, blood pressure and hrv parameter dynamically generate data sheet.
Claims (6)
1. the embedded MANET information acquisition system based on machine vision, comprise physiological monitoring system (1), micro-optical imaging system (2), wireless ad hoc network systems (3), server platform (4), it is characterized in that: physiological monitoring system (1) is made up of multiple physiological monitor, micro-optical imaging system (2) is made up of multiple wireless camera, in micro-optical imaging system (2), the imaging lens of each wireless camera aims at the display floater of a physiological monitor in physiological monitoring system (1), wireless ad hoc network systems (3) be used for wireless receiving from micro-optical imaging system (2) data and be transferred to server platform (4).
2. the embedded MANET information acquisition system based on machine vision according to claim 1, it is characterized in that: described physiological monitoring system (1) has the function of Real-time Interactive Demonstration, the physiological parameter of multiple patient is presented on respective display floater by real time; Wireless ad hoc network systems (3) is the network transmission platform of the embedded MANET information acquisition system of machine vision; Server platform (4) monitors in real time in the embedded MANET information acquisition system of machine vision and stores the system of image that micro-optical imaging system transmitted by wireless self-networking or data.
3. the embedded MANET information acquisition system based on machine vision according to claim 1, it is characterized in that: the imaging lens of described micro-optical imaging system (2) possesses auto-focusing, automatically regulates exposure function, and can catch in real time and wireless signal transmission, there is independently supply module, wireless module.
4. the embedded MANET information acquisition system based on machine vision according to claim 1, it is characterized in that: described wireless ad hoc network systems (3) is an Intranet system, it wirelessly carries out alternately with micro-optical imaging system (2), and carry out the transmission of data.
5. the embedded MANET information acquisition system based on machine vision according to claim 1, it is characterized in that: described server platform (4) is connected by wired mode with wireless ad hoc network systems (3), server platform (4) has integral image and stores, processes and data statistics function.
6., based on an embedded MANET information collecting method for machine vision, adopt the embedded MANET information acquisition system based on machine vision according to claim 1 to gather, it is characterized in that, operating procedure is as follows:
A. physiological parameters of patients is gathered: physiological monitoring system (1) is by the physiological parameter of its sensor acquisition patient, and the characteristics of human body's parameter transmission collected also is shown on a display panel to physiological monitor by wired mode by sensor;
B. image-forming information is caught: micro-optical imaging system (2) carries out imaging by its Zoom optic lens to physiological monitoring system (1) display floater;
C. the wireless transmission of information: the image that miniature imaging system (2) collects is transferred to server platform (4) by wireless ad hoc network systems (3);
D. the process of image-forming information: server platform (4) real-time storage image is also by the numeral in numeral and text recognition method extraction image and text message;
E. produce data sheet: last server platform (4) will extract information---sick bed numbering, time, blood pressure and hrv parameter dynamically generate data sheet.
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Application publication date: 20151223 |