CN115524505A - Blood analyzer based on double-platform system work - Google Patents
Blood analyzer based on double-platform system work Download PDFInfo
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- CN115524505A CN115524505A CN202211047291.0A CN202211047291A CN115524505A CN 115524505 A CN115524505 A CN 115524505A CN 202211047291 A CN202211047291 A CN 202211047291A CN 115524505 A CN115524505 A CN 115524505A
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- 239000008280 blood Substances 0.000 title claims abstract description 56
- 210000004369 blood Anatomy 0.000 title claims abstract description 56
- 230000033001 locomotion Effects 0.000 claims abstract description 44
- 238000004891 communication Methods 0.000 claims abstract description 29
- 238000000034 method Methods 0.000 claims description 21
- 238000012545 processing Methods 0.000 claims description 20
- 230000000007 visual effect Effects 0.000 claims description 15
- 230000009977 dual effect Effects 0.000 claims description 12
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- 238000007405 data analysis Methods 0.000 abstract 1
- 238000013461 design Methods 0.000 description 8
- 238000004806 packaging method and process Methods 0.000 description 8
- 238000013500 data storage Methods 0.000 description 3
- 230000005540 biological transmission Effects 0.000 description 2
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- G01N35/00—Automatic analysis not limited to methods or materials provided for in any single one of groups G01N1/00 - G01N33/00; Handling materials therefor
- G01N35/00584—Control arrangements for automatic analysers
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N35/00—Automatic analysis not limited to methods or materials provided for in any single one of groups G01N1/00 - G01N33/00; Handling materials therefor
- G01N35/00584—Control arrangements for automatic analysers
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Abstract
The invention discloses a blood analyzer based on double-platform system work, which comprises an operating system platform and a core system platform; the operating system platform is in connection communication with the core system platform through a TCP/IP protocol, and performs information interaction after data analysis, splitting and other operations are performed through a defined protocol; the operating system platform sends a corresponding control command to the core system platform through a TCP/IP protocol, the core system platform analyzes the control command and then sends a corresponding collected motion instruction to the bottom layer motion module, the core system platform collects original data through a collection chip and then sends the original data to the algorithm module, and the core system platform sends the analyzed data to the operating system platform through the TCP/IP protocol for display, storage and other operations.
Description
Technical Field
The invention relates to the field of medical treatment, in particular to a blood analyzer based on double-platform system work.
Background
With the coming of the intelligent era, means such as intelligent information utilization and the like are provided for various industries to achieve new implementation means, and meanwhile, the living standard of people reaches a new step; the demand of informatization experience brought by the method is continuously improved.
In the medical field, the informatization use degree is more and more perfect, and simultaneously, bottlenecks such as speed, response and the like are slowly reached, because most of the prior products use application technologies such as single-system direct control calculation and the like to achieve the effects of overall operation, analysis and the like of the blood analyzer, the design usually generates time loss when large operation data and the like are operated, the requirement on the system or firmware is high, and the cost is greatly increased for the products. For a single system of blood analyzers, if the system fails, the entire system may fail to operate.
Disclosure of Invention
In order to solve the above problems, the present technical solution provides a blood analyzer based on dual-platform system work, the design can reduce the operation load of the blood analyzer, the dual-platform system enables the blood analyzer to be used and malfunction to be effectively handled separately, and a method of splitting multiple contents such as operation, storage and operation into two platforms to operate respectively due to the fact that other operations cannot be performed due to movement malfunction can be effectively avoided.
In order to achieve the purpose, the technical scheme is as follows:
a blood analyzer that operates based on a dual platform system, comprising:
the method comprises the steps that an operating system platform based on an Android environment is edited in a JAVA language and is visually programmed through a GUI (graphical user interface) frame, wherein the operating system platform can display a graphical operating interface;
the Linux environment-based core system platform is edited in C language, and the running program is encrypted in multiple layers by using an encryption algorithm, so that information leakage is prevented, and meanwhile, the system architecture is stable.
The core system platform is in communication connection with the operating system platform, can receive a task command sent by the operating system platform, processes the task command and feeds a result back to the operating system platform so that the operating system platform stores the result;
the core system platform controls the blood analyzer.
The operating system platform sends a corresponding control command to the core system platform through the TCP/IP protocol;
the core system platform analyzes the control command and then sends a corresponding motion acquisition instruction to the core system platform;
the core system platform collects original data through a collection chip and runs calculation, and the core system platform sends the analyzed and processed data to the operating system platform through a TCP/IP protocol to carry out a series of operations of displaying and storing.
Wherein the operating system platform comprises:
the work order module is used for editing the work tasks and sending control commands;
the information result display module is used for processing data;
the service module is used for providing services;
the hospital system module is used for connecting a hospital main system;
wherein the service module comprises:
the setting module is used for configuring system parameters;
the fault module is used for fault processing and warning;
and the debugging module is used for debugging the system.
Wherein, the core system platform includes:
the USB communication module is used for controlling the data acquisition of the blood analyzer by the core system platform;
and the bottom layer motion module is used for data acquisition. Hardware such as a control point machine, an electromagnetic valve, a diaphragm pump and the like, and original data are acquired through an acquisition chip;
the algorithm module is used for processing data;
the auxiliary module is used for receiving fault information;
wherein, the bottom layer motion module includes:
the bottom layer control module is used for realizing basic motion operation of the blood analyzer, such as sample feeding and discharging actions;
the collection module is used for returning the original data collected by the blood analyzer collection chip to the core system platform;
the motion response module is used for judging whether the blood analyzer is executed according to the predefined action in the operation process of the blood analyzer and feeding back the execution result so as to judge whether the next step needs to be executed or whether the failure is judged;
the work sheet module sends a task to the core system platform, the core system platform sends the task to the bottom layer motion module through the USB communication module, the algorithm module processes task data, and the information result display module displays the data processed by the algorithm module.
The operating system platform is connected and communicated with the core system platform through a TCP/IP protocol, the operating system platform sends a task command through the first sending unit, data packaging and sending are carried out through the packaging unit, the core operating platform receives data sent by the packaging unit and completes data translation, the core data platform extracts task data through the data acquisition unit and carries out data processing through the algorithm unit of the core system platform, the core system platform sends the processed data to the operating system platform through the algorithm unit, the operating system platform stores the processed data and sends the processed data to the second packaging unit, and the specific operation steps are as follows: commands, responses, file transfers, and events;
commands for controlling information data of the blood analyzer;
responding, information feedback for the core system platform to the operating system platform;
file transmission, the operating system platform sends file type information to the core system platform;
events, faults in the operation process of the blood analyzer, and series phenomena of system upgrading, such as system faults.
The first sending unit is used for operating a work order module of the GUI visual interface in the operating system platform, editing a work task and sending a control command;
the first storage unit is used for storing the work task information in the work list into a data table chain of the database module by the GUI program of the operating system;
the first encapsulation unit is used for the operating system platform, and the database encapsulates the corresponding work task information in a beta type format and then sends the information to the core system platform by utilizing the TCP/IP protocol;
the translation unit is used for translating the received work task information sent by a TCP/IP protocol by the core system platform;
the core system platform sends a work order task to the bottom control module in a USB communication mode to realize the movement work of the blood analyzer;
the bottom layer control module utilizes an acquisition chip to acquire data of a work order task and returns the data to the core system platform in the movement process;
the core system platform sends the received original data returned through USB communication to the algorithm module to be converted into visual data;
the core system platform sends the converted visual data to the operating system GUI program through the TCP/IP protocol;
the operating system GUI program receives the visual data sent by the core system platform through the TCP/IP protocol;
the data matching unit is used for extracting the work order task data stored in the database in the step S2 by the GUI program of the operating system to match and correspond to the visual data sent by the core system platform;
the second storage unit is used for storing the matched data to the database again by the GUI program of the operating system;
the operating system GUI program queries the database through the result display module, extracts the latest stored result data and displays the latest stored result data through a graphical interface;
and the operating system GUI program inquires corresponding data in a database through the hospital system module and sends the data to the hospital system module through H7 protocol encapsulation.
A GUI (graphical user interface) in the operating system platform receives the fault information fed back by the core system platform through a response event, and the fault information is displayed on the GUI in the operating system platform;
s1: the bottom layer control module controls the movement to have a fault, and the control movement does not operate according to the original setting;
s2: the bottom layer control module sends the fault information to the auxiliary module in the core system platform for processing through a USB communication module;
s3: the auxiliary module of the core system platform sends the received fault information to a GUI program of the operating system platform through a TCP/IP communication module;
s4: the GUI program of the operating system platform classifies the received fault information through the fault module in the service module;
s5: the fault module displays the fault information through a GUI program and prompts fault problem information;
s6: the GUI program of the operating system platform sends a corresponding processing mode to the core system platform through the TCP/IP communication module through the fault information;
s7: the core system platform receives the corresponding processing mode sent by the fault module in the operating system platform and then sends the corresponding control content to the bottom control module through a USB communication module;
s8: the bottom layer control module performs corresponding control operation on the operation of the blood analyzer;
s9: the fault alarm prompt can be carried out through the buzzer.
The core system platform does not influence the operation and use of a GUI interface in the operating system platform by controlling the motion process of the blood analyzer, and is only limited to a module without mechanical motion control interaction.
The beneficial effect of this application does:
the blood analyzer which is originally controlled to operate by a single system is divided into two systems to complete the operation process, the operation, the storage, the operation and the motion control are separated, and an operation system platform carries out work task operation, data storage, data display and the like; the core system platform performs data operation and blood analyzer motion control. The operation load of operating the blood analyzer is reduced, the experience of a user is increased, the system is independent and used separately, the blood analyzer is used and is effectively separated from faults, and other operations which cannot be performed due to movement faults can be effectively avoided.
Drawings
In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below.
FIG. 1 is a general structural topology of the dual platform system design of the present invention;
FIG. 2 is a flow chart of the design operation of the dual platform system of the present invention;
FIG. 3 is a flow chart of the dual platform system design response of the present invention;
FIG. 4 is a topological diagram of an operating system architecture in the design of a dual platform system of the present invention;
FIG. 5 is a core system and underlying topology of the dual platform system design of the present invention;
Detailed Description
In order to make the technical problems, technical solutions and advantageous effects solved by the present invention more clearly apparent, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.
Referring to fig. 1-5, a blood analyzer operating based on a dual platform system includes:
the operating system platform based on the Android environment can display a graphical operating interface;
a core system platform based on a Linux environment uses an encryption algorithm to carry out multi-layer encryption on an operating program; information leakage is prevented.
The core system platform is in communication connection with the operating system platform, can receive a task command sent by the operating system platform, processes the task command and feeds a result back to the operating system platform so that the operating system platform stores the result;
the core system platform controls the blood analyzer.
The operating system platform sends a corresponding control command to the core system platform through the TCP/IP protocol;
the core system platform analyzes the control command and then sends a corresponding motion acquisition instruction to the core system platform;
the core system platform collects original data through a collection chip and runs calculation, and the core system platform sends the analyzed and processed data to the operating system platform through a TCP/IP protocol to carry out a series of operations of display and storage.
Wherein the operating system platform comprises:
the work sheet module is used for editing the work task and sending a control command;
the information result display module is used for processing data;
the service module is used for providing services;
the hospital system module is used for connecting a hospital main system;
wherein the service module comprises:
the setting module is used for configuring system parameters;
the fault module is used for fault processing and warning;
and the debugging module is used for debugging the system.
Wherein, the core system platform includes:
the USB communication module is used for controlling the data acquisition of the blood analyzer by the core system platform;
and the bottom layer motion module is used for data acquisition. Hardware such as a control point machine, an electromagnetic valve, a diaphragm pump and the like, and original data are acquired through an acquisition chip;
the algorithm module is used for processing data;
the auxiliary module is used for receiving fault information;
wherein, the bottom layer motion module includes:
the bottom layer control module is used for realizing basic motion operation of the blood analyzer, such as sample feeding and discharging actions;
the collection module is used for returning the original data collected by the blood analyzer collection chip to the core system platform;
the motion response module is used for judging whether the blood analyzer is executed according to the predefined action in the operation process of the blood analyzer and feeding back the execution result so as to judge whether the next step needs to be executed or whether the failure is judged;
the work sheet module sends a task to the core system platform, the core system platform sends the task to the bottom layer motion module through the USB communication module, the algorithm module processes task data, and the information result display module displays the data processed by the algorithm module.
The operating system platform is connected and communicated with the core system platform through a TCP/IP protocol, the operating system platform sends a task command through the first sending unit, data packaging and sending are carried out through the packaging unit, the core operating platform receives data sent by the packaging unit and completes data translation, the core data platform extracts task data through the data acquisition unit and carries out data processing through the algorithm unit of the core system platform, the core system platform sends the processed data to the operating system platform through the algorithm unit, the operating system platform stores the processed data and sends the processed data to the second packaging unit, and the specific operation steps are as follows: commands, responses, file transfers, and events;
commands for controlling information data of the blood analyzer;
responding, information feedback for the core system platform to the operating system platform;
file transmission, the operating system platform sends file type information to the core system platform;
and events, such as faults and system upgrading series phenomena in the operation process of the blood analyzer.
The first sending unit is used for operating a work order module of the GUI visual interface in the operating system platform, editing a work task and sending a control command;
the first storage unit is used for storing the work task information in the work list into a data table chain of the database module by the GUI program of the operating system;
the first encapsulation unit is used for the operating system platform, and the database encapsulates the corresponding work task information in a beta type format and then sends the information to the core system platform by utilizing the TCP/IP protocol;
the translation unit is used for translating the received work task information sent by a TCP/IP protocol by the core system platform;
the core system platform sends a work order task to the bottom control module in a USB communication mode to realize the movement work of the blood analyzer;
the bottom layer control module utilizes an acquisition chip to acquire data of a work order task and returns the data to the core system platform in the movement process;
the core system platform sends the received original data returned by the USB communication to the algorithm module to be converted into visual data;
the core system platform sends the converted visual data to the operating system GUI program through the TCP/IP protocol;
the operating system GUI program receives the visual data sent by the core system platform through the TCP/IP protocol;
the data matching unit is used for extracting the work order task data stored in the database in the step S2 by the GUI program of the operating system to match and correspond to the visual data sent by the core system platform;
the second storage unit is used for storing the matched data to the database again by the GUI program of the operating system;
the GUI program of the operating system inquires the database through the result display module, extracts the latest stored result data and displays the latest stored result data through a graphical interface;
and the operating system GUI program inquires corresponding data in a database through the hospital system module and sends the data to the hospital system module through H7 protocol encapsulation.
A GUI interface in the operating system platform receives the fault information fed back by the core system platform through a response event, and the fault information is displayed on the GUI interface in the operating system platform;
s1: the bottom layer control module controls the movement to have a fault, and the control movement does not operate according to the original setting;
s2: the bottom layer control module sends the fault information to the auxiliary module in the core system platform for processing through a USB communication module;
s3: the auxiliary module of the core system platform sends the received fault information to a GUI program of the operating system platform through a TCP/IP communication module;
s4: the GUI program of the operating system platform classifies the received fault information through the fault module in the service module;
s5: the fault module displays the fault information through a GUI program and prompts fault problem information;
s6: the GUI program of the operating system platform sends a corresponding processing mode to the core system platform through the TCP/IP communication module through the fault information;
s7: the core system platform receives the corresponding processing mode sent by the fault module in the operating system platform and then sends the corresponding control content to the bottom control module through a USB communication module;
s8: the bottom layer control module performs corresponding control operation on the operation of the blood analyzer;
s9: the fault alarm prompt can be carried out through the buzzer.
The core system platform does not influence the operation and use of a GUI interface in the operating system platform by controlling the motion process of the blood analyzer, and is only limited to a module without mechanical motion control interaction.
The blood analyzer which is originally controlled to operate by a single system is divided into two systems to complete the operation process, the operation, the storage, the operation and the motion control are separated, and an operation system platform carries out work task operation, data storage, data display and the like; the core system platform performs data operation and blood analyzer motion control. The operation load of operating the blood analyzer is reduced, the experience of a user is increased, the system is independent and used separately, the blood analyzer is used and is effectively separated from faults, and other operations which cannot be performed due to movement faults can be effectively avoided.
The invention aims to extract an equipment operation control part for individuation for user experience operation, wherein the part comprises the steps of system data storage, configuration file storage of an information adjusting module, a work list module, an information result module, a service module, a hospital system module and the like which are integrated into a system and are displayed by a unilateral GUI frame program system in a graphical interface design; so as to achieve the purpose that the user can use the operation simply and conveniently; therefore, the motion machine, the acquisition module, the control module, the core algorithm module and other modules aiming at the bottom layer mechanical motion, the core operation and the like are integrated into a system; the management is convenient, the labor division is clear, and the user experience of operators is improved. When the two systems operate independently, the communication between the two systems is established through a TCP/IP protocol to realize mutual interaction, and the core system greatly lightens the operation load of the system due to the fact that the storage module, the operation display module and the like are extracted independently.
The above description is only for the purpose of illustrating the preferred embodiments of the present application and is not intended to limit the scope of the present application, which is within the scope of the present application, except that the same or similar principles and basic structures as the present application may be used.
Claims (6)
1. A blood analyzer operating based on a dual platform system, comprising:
the operating system platform based on the Android environment can display a graphical operating interface;
a core system platform based on a Linux environment uses an encryption algorithm to encrypt the running program in multiple layers;
the core system platform is in communication connection with the operating system platform, can receive a task command sent by the operating system platform, processes the task command and feeds a result back to the operating system platform so that the operating system platform stores the result;
the core system platform controls the blood analyzer.
2. A blood analyzer operating based on a dual platform system according to claim 1,
the operating system platform sends a corresponding control command to the core system platform through a TCP/IP protocol;
the core system platform analyzes the control command and then sends a corresponding motion acquisition instruction to the core system platform;
the core system platform collects original data through a collection chip and runs calculation, and the core system platform sends the analyzed and processed data to the operating system platform through the TCP/IP protocol to carry out a series of operations of display and storage.
3. A blood analyzer operating based on a dual platform system according to claim 1,
the operating system platform includes:
the work sheet module is used for editing the work task and sending a control command;
the information result display module is used for processing data;
the service module is used for providing services;
the hospital system module is used for connecting a hospital main system;
the core system platform includes:
the USB communication module is used for controlling the data acquisition of the blood analyzer by the core system platform;
the bottom layer motion module is used for data acquisition;
the algorithm module is used for processing data;
the auxiliary module is used for receiving fault information;
wherein, the bottom layer motion module includes:
the bottom layer control module is used for realizing the basic motion operation of the blood analyzer;
the collection module is used for returning the original data collected by the blood analyzer collection chip to the core system platform;
the motion response module is used for judging whether the blood analyzer is executed according to the predefined action in the operation process of the blood analyzer and feeding back the execution result so as to judge whether the next step needs to be executed or whether the failure is judged;
the work sheet module sends a task to the core system platform, the core system platform sends the task to the bottom layer motion module through the USB communication module, the algorithm module processes task data, and the information result display module displays the data processed by the algorithm module.
4. A blood analyzer operating based on a dual platform system according to claim 3, wherein the service module comprises:
the setting module is used for configuring system parameters;
the fault module is used for fault processing and warning;
and the debugging module is used for debugging the system.
5. A blood analyzer operating on a dual platform system according to claim 3,
the first sending unit is used for operating a work order module of the GUI visual interface in the operating system platform, editing a work task and sending a control command;
the first storage unit is used for storing the work task information in the work list into a data table chain of the database module by the GUI program of the operating system;
the first encapsulation unit is used for the operating system platform, and the database encapsulates the corresponding work task information in a beta type format and then sends the information to the core system platform by utilizing the TCP/IP protocol;
the translation unit is used for translating the received work task information sent by a TCP/IP protocol by the core system platform;
the core system platform sends a work order task to the bottom control module in a USB communication mode to realize the movement work of the blood analyzer;
the bottom layer control module utilizes an acquisition chip to acquire data of a work order task and returns the data to the core system platform in the movement process;
the core system platform sends the received original data returned through USB communication to the algorithm module to be converted into visual data;
the core system platform sends the converted visual data to the operating system GUI program through the TCP/IP protocol;
the operating system GUI program receives the visual data sent by the core system platform through the TCP/IP protocol;
the data matching unit is used for extracting the work order task data stored in the database in the step S2 by the GUI program of the operating system to match and correspond to the visual data sent by the core system platform;
the operating system GUI program stores the matched data in the database again;
the operating system GUI program queries the database through the result display module, extracts the latest stored result data and displays the latest stored result data through a graphical interface;
and the operating system GUI program inquires corresponding data in a database through the hospital system module and sends the data to the hospital system module through H7 protocol encapsulation.
6. A failure processing method of a blood analyzer based on the operation of a double-platform system is characterized in that,
s1: the bottom layer control module controls the movement to have a fault;
s2: the bottom layer control module sends the fault information to the auxiliary module in the core system platform for processing through a USB communication module;
s3: the auxiliary module of the core system platform sends the received fault information to a GUI program of the operating system platform through a TCP/IP communication module;
s4: the GUI program of the operating system platform classifies the received fault information through the fault module in the service module;
s5: the fault module displays the fault information through a GUI program and prompts fault problem information;
s6: the GUI program of the operating system platform sends a corresponding processing mode to the core system platform through the TCP/IP communication module through the fault information;
s7: the core system platform receives the corresponding processing mode sent by the fault module in the operating system platform and then sends the corresponding control content to the bottom control module through a USB communication module;
s8: the bottom layer control module performs corresponding control operation on the operation of the blood analyzer;
s9: and the core system platform sends the fault event to the blood analyzer for fault alarm prompt.
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