KR101510058B1 - System and method for discrete event system specification based embeded device modeling and simulation - Google Patents

Abstract

The system and method for discrete event system specification based embedded device modeling and simulation are delivered. For the discrete event system specification(DEVS) based embedded system, the embedded device modeling and simulation system may include an embedded model management to save and manage the model specification information of embedded device and appurtenant model based on the discrete event system specification; user interface where the design information is entered to design the embedded model and embedded simulation system based on the model specification information and embedded simulation interface to provide the user interface in order to receive the simulation plan information; and embedded simulation management to record the result of simulation based on the simulation plan information and thus to visualize and provide the operation pattern of embedded simulation system.

Description

Technical Field [0001] The present invention relates to a system and method for modeling and simulating an embedded device based on discrete event system specification,

One embodiment of the present invention relates to a technique for designing a simulated embedded system by using or creating a model of an embedded device designed based on a discrete event standard in a simulated development, education, and learning process in a system based on an embedded device .

The embedded system, which can be embedded in a specific product or solution to perform a given task, is a core technology field that is developed and commercialized in various fields due to the miniaturization of hardware and the improvement of computation processing capability along with the development of information technology. The education of the embedded system is being used in the course of learning as a part of creative education.

In particular, unlike general systems, embedded systems have hardware and computational processing capabilities suited to the purpose they are intended to use. They also include the way in which each part operates according to its hardware components and the configuration and design of software that controls it A difference occurs. The characteristics of these embedded systems can only be mastered by directly handling the associated accessories, devices, and control software.

However, in order to increase the proficiency, training of the actual equipment and accessories of the embedded system or writing the control software is an additional burden for securing, maintaining and managing the equipment for this purpose.

Therefore, it is necessary to create a simulation model for the devices and accessories constituting the embedded system, to create control software by simulation, and to provide means for training and skill improvement through a virtual embedded system capable of simulating the operation of the actual devices need.

The embedded system, which can be embedded in a specific product or solution to perform a given task, is a core technology field that is developed and commercialized in various fields due to the miniaturization of hardware and the improvement of computation processing capability along with the development of information technology. The education of the embedded system is being used in the course of learning as a part of creative education.

In particular, unlike general systems, embedded systems have hardware and computational processing capabilities suited to the purpose they are intended to use. They also include the way in which each part operates according to its hardware components and the configuration and design of software that controls it A difference occurs. The characteristics of these embedded systems can only be mastered by directly handling the associated accessories, devices, and control software.

However, in order to increase the proficiency, training of the actual equipment and accessories of the embedded system or writing the control software is an additional burden for securing, maintaining and managing the equipment for this purpose.

Therefore, it is necessary to create a simulation model for the devices and accessories constituting the embedded system, to create control software by simulation, and to provide means for training and skill improvement through a virtual embedded system capable of simulating the operation of the actual devices need.

The embedded system, which can be embedded in a specific product or solution to perform a given task, is a core technology field that is developed and commercialized in various fields due to the miniaturization of hardware and the improvement of computation processing capability along with the development of information technology. The education of the embedded system is being used in the course of learning as a part of creative education.

In particular, unlike general systems, embedded systems have hardware and computational processing capabilities suited to the purpose they are intended to use. They also include the way in which each part operates according to its hardware components and the configuration and design of software that controls it A difference occurs. The characteristics of these embedded systems can only be mastered by directly handling the associated accessories, devices, and control software.

However, in order to increase the proficiency, training of the actual equipment and accessories of the embedded system or writing the control software is an additional burden for securing, maintaining and managing the equipment for this purpose.

Therefore, it is necessary to create a simulation model for the devices and accessories constituting the embedded system, to create control software by simulation, and to provide means for training and skill improvement through a virtual embedded system capable of simulating the operation of the actual devices need.

According to the present invention, a virtual embedded system can be operated as an actual device by creating a virtual embedded system using a simulated embedded device composed of a discrete event-based model.

In addition, a simulated execution plan for the generated virtual embedded system is established and a simulation is performed. Based on the result of the simulation, a user is provided with a state in which a virtual embedded system is operated for each discrete event time, It is possible to improve the education and proficiency of the operation method of the embedded system according to the control software configuration.

FIG. 1 is a block diagram illustrating an internal configuration of an embedded device simulation modeling and simulation system based on a discrete event specification, in an embodiment of the present invention.
FIG. 2 is a block diagram showing a detailed configuration of the embedded simulation interface unit of FIG. 1 according to an embodiment of the present invention.
FIG. 3 is a block diagram illustrating a detailed configuration of the embedded simulation model management unit of FIG. 1 according to an exemplary embodiment of the present invention.
4 is a block diagram illustrating a detailed configuration of the embedded simulation execution management unit of FIG. 1 according to an exemplary embodiment of the present invention.
FIG. 5 is a flowchart illustrating an embedded device simulation modeling and simulation method based on a discrete event system specification, in an embodiment of the present invention.
FIG. 6 is a flowchart illustrating the detailed operation of designing the embedded simulation model and the embedded simulation system of FIG. 5, in an embodiment of the present invention.
FIG. 7 is a flowchart illustrating a detailed operation for performing simulation for the embedded simulation system of FIG. 5, in an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Specific features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. Prior to this, terms and words used in the present specification and claims are to be interpreted in accordance with the technical idea of the present invention based on the principle that the inventor can properly define the concept of the term in order to explain his invention in the best way. It should be interpreted in terms of meaning and concept. It is to be noted that the detailed description of known functions and constructions related to the present invention is omitted when it is determined that the gist of the present invention may be unnecessarily blurred.

FIG. 1 is a block diagram illustrating an internal configuration of an embedded device simulation modeling and simulation system based on a discrete event specification, in an embodiment of the present invention.

Referring to FIG. 1, an embedded device simulation modeling and simulation system 100 may include an embedded simulation interface unit 102, an embedded simulation model management unit 103, and an embedded simulation execution management unit 104.

The embedded simulation interface unit 102 includes a user interface for designing an embedded simulation model based on the embedded device and its sub model and model specification information pre-stored in the embedded simulation model management unit 103, and design information for designing an embedded simulation system May be provided. Here, the embedded device, the sub model, and the model specification information may be created based on the discrete event system specification (DEVS) and stored in the embedded simulation model management unit 103 in advance.

The embedded simulation interface unit 102 may provide a user interface for receiving simulation execution plan information and may request the embedded simulation execution management unit 104 to perform simulation of the embedded simulation system in the simulation execution plan information .

For example, the embedded simulation interface unit 102 may design the embedded simulation model and the embedded simulation system based on the model specification information stored in the embedded simulation model management unit 103 by the user 101, A user interface can be provided that allows the system to be stored and edited. The embedded simulation interface unit 102 may provide a user interface for receiving simulation execution plan information so that the embedded simulation execution management unit 104 can perform simulation. At this time, as the simulation execution plan information is inputted, the embedded simulation interface unit 102 can request the embedded simulation execution management unit 104 to perform the simulation according to the inputted simulation execution plan information.

At this time, the embedded simulation interface unit 102 may provide a user interface for modifying simulation execution plan information. Then, as the simulation execution plan information is modified, the embedded simulation interface unit 102 can request the embedded simulation execution management unit 104 to perform the simulation based on the modified simulation execution plan information.

The embedded simulation interface unit 102 may provide a user interface for visualizing and providing simulation execution results performed by the embedded simulation execution management unit 104. [ For example, the embedded simulation interface unit 102 may display the execution result on a display of a desktop, a tablet PC, or the like used by the user.

The embedded simulation model management unit 103 can store and manage the model specification information of the previously created embedded device and the sub model based on the discrete event system specification.

The embedded simulation model management unit 103 can design a new embedded simulation model based on the design information about the new embedded simulation model input from the user 101 via the embedded simulation interface unit 102. [ Subsequently, the embedded simulation model management unit 103 can design a new embedded simulation system based on the new embedded simulation model.

At this time, the embedded simulation model management unit 103 can modify and store the model specification information for the existing embedded simulation model that has been modified through the embedded simulation interface unit 102. Then, the embedded simulation model management unit 103 may modify and store the embedded simulation model and the embedded simulation system already designed and stored based on the modified model specification information.

The embedded simulation model management unit 103 may provide the embedded simulation execution unit 104 with an embedded simulation model that is designed and stored according to the model specification information so that the simulation can be performed with respect to the embedded simulation system.

The embedded simulation execution management unit 104 may store and manage the simulation execution plan information inputted or modified through the embedded simulation interface unit 102. [

Then, the embedded simulation execution management unit 104 can perform simulation according to the simulation execution plan information. At this time, the embedded simulation execution management unit 104 may measure an operation logically performed in the embedded simulation system through simulation, and record the measured information as the execution result of the simulation. Here, the embedded simulation system may represent a system designed and stored in the embedded simulation model management unit 103. [ The embedded simulation execution unit 104 may transmit the result of the execution to the embedded simulation interface unit 102 so that the execution result can be visualized and provided to the user.

FIG. 2 is a block diagram showing a detailed configuration of the embedded simulation interface unit of FIG. 1 according to an embodiment of the present invention.

2, the embedded simulation interface unit 200 may include an embedded simulation model configuration interface unit 201, an embedded simulation execution configuration interface unit 202, and an embedded simulation execution analysis interface unit 203.

The embedded simulation model configuration interface unit 201 provides a user with a user interface for designing a virtual embedded simulation model and system, and provides a user interface for inputting and modifying the embedded simulation model and the system .

For example, the embedded simulation model configuration interface unit 201 can load simulation model specification information created according to the discrete event system specification from the embedded simulation model management unit 103 into the embedded sub model and the embedded apparatus. The embedded simulation model configuration interface unit 201 may provide a user interface that allows the user to design an embedded simulation system that can be simulated by referring to the simulation model specification information loaded by the user.

Then, the embedded simulation model configuration interface unit 201 performs a modeling operation on the embedded sub-model and the embedded device necessary for the embedded simulation system that the user desires to design according to the discrete event system specification, And can provide a user interface for storing specification information. The embedded simulation model configuration interface unit 201 may provide a user interface that allows the stored model specification information to be reused

Next, the embedded simulation execution configuration interface unit 202 provides a user interface for receiving simulated execution plan information of an embedded simulated system designed from a workflow user, and for modifying inputted simulation execution plan information A user interface can be provided.

The embedded simulation execution configuration interface unit 202 may request the embedded simulation execution management unit 104 to perform a simulation of the embedded simulation system according to the simulation execution plan information.

The embedded simulation execution analysis interface unit 203 provides a user interface for visualizing the simulation execution result of the embedded simulation system to the user and analyzes the operation of the embedded simulation system designed by the user based on the visualized execution result The user interface can be provided.

For example, the embedded simulation execution analysis interface unit 203 may request the stored execution result by performing simulation of the embedded simulation system in the embedded simulation execution management unit 104. [ The embedded simulation execution analysis interface unit 203 can provide the execution result received from the embedded simulation execution management unit 104 to the user. The embedded simulation execution analysis interface unit 203 may provide a user interface for visualizing and providing an operation pattern of the embedded simulation system based on the execution result.

FIG. 3 is a block diagram illustrating a detailed configuration of the embedded simulation model management unit of FIG. 1 according to an exemplary embodiment of the present invention.

Referring to FIG. 3, the embedded simulation model management unit 300 may include an embedded simulation model storage unit 301, an embedded simulation model design unit 302, and an embedded simulation system design unit 303.

First, the embedded simulation model storage unit 301 can store and manage simulation model specification information created based on the discrete event system specification for the sub-models and the embedded devices constituting the embedded system.

The embedded simulation model designing unit 302 determines whether the model specification information corresponding to the embedded simulation model to be designed by the user is stored in the embedded simulation model storage unit 301 and designs an embedded simulation model capable of actual simulation .

For example, when there is model specification information corresponding to an embedded simulation model that the user desires to designate in the embedded simulation model storage unit 301, the embedded simulation model design unit 302 determines, based on the stored model specification information, Can be designed. At this time, the embedded simulation model designing unit 302 can design an embedded simulation model based on the discrete event system specification so that simulation can be performed by collecting the model specification information and the design information inputted through the embedded simulation interface unit 102. Here, the design information may include simulation environment information and parameter information.

As another example, when there is no model specification information corresponding to the embedded simulation model to be designed by the user in the embedded simulation model storage unit 301, the embedded simulation interface unit 102 stores the model simulation information corresponding to the new simulation model And a user interface for receiving model specification information. Then, the embedded simulation model storage unit 301 stores new simulation model specification information, and the embedded simulation model design unit 302 can design a new embedded simulation model based on the new simulation model specification information and the new design information .

The embedded simulation system design section 303 can design an embedded simulation system based on the embedded simulation model designed in the embedded simulation model design section 302. [

For example, when the environment and parameter setting for the simulation execution are completed in the embedded simulation model designing unit 302, the embedded simulation system designing unit 303 loads the model specification information that has been set up from the embedded simulation model storage unit 301 (not shown). The embedded simulation system design unit 303 can design the embedded simulation system by connecting the embedded simulation models to each other based on the model specification information. In other words, the embedded simulation system design section 303 can design the embedded simulation system by connecting the embedded simulation models to each other according to the design conceived by the user.

4 is a block diagram illustrating a detailed configuration of the embedded simulation execution management unit of FIG. 1 according to an exemplary embodiment of the present invention.

Referring to FIG. 4, the embedded simulation execution management unit 400 may include an embedded simulation execution unit 401, an embedded simulation execution measurement unit 402, and an embedded simulation execution log unit 403.

The embedded simulation execution unit 401 can perform simulation on the embedded simulation system according to the simulation execution plan information input through the embedded simulation interface unit 102. [

For example, the embedded simulation execution unit 401 may configure the simulation execution plan information input through the embedded simulation interface unit 102 as simulation execution information for simulation. The embedded simulation execution unit 401 performs simulation based on the simulation execution information and can manage the progress of the simulation.

The embedded simulation execution measuring unit 402 can measure the simulation result as the simulation for the embedded simulation system proceeds.

Then, the embedded simulation execution log section 403 can store the simulation result measured through the simulation as the execution result. The embedded simulation execution log unit 403 may transmit the execution result to the embedded simulation interface unit 102 so that the execution result is displayed to the user in order to analyze the operation of the embedded simulation system.

For example, the embedded simulation execution log unit 403 records and stores the values measured through the simulation as execution results, and manages the execution results so that the user can view the execution results through the embedded simulation interface unit 102 have.

FIG. 5 is a flowchart illustrating an embedded device simulation modeling and simulation method based on a discrete event system specification, in an embodiment of the present invention.

In FIG. 5, an embedded device simulation modeling and simulation method may be performed by the embedded device simulation modeling and simulation system 100 of FIG.

First, in step 501, the embedded simulation model management unit 103 designates the embedded simulation model and the embedded simulation system based on the design information input through the embedded simulation interface unit 102 and the model specification information of the embedded device and the sub models can do. Here, the model specification information can be created and stored based on the discrete event system specification (DEVS).

In step 502, the embedded simulation execution management unit 104 may perform simulation on the designed embedded simulation system based on the simulation execution plan information. At this time, the embedded simulation execution management unit 104 may measure and record the simulation result as an execution result and store it.

In step 503, the embedded simulation execution management unit 104 may transmit the execution result to the embedded simulation interface unit 102. [ Then, the embedded simulation interface unit 102 may provide a user interface that allows the user to analyze simulation results of the embedded simulation system based on the execution result. At this time, the embedded simulation interface unit 102 can visually provide the execution result.

FIG. 6 is a flowchart illustrating the detailed operation of designing the embedded simulation model and the embedded simulation system of FIG. 5, in an embodiment of the present invention.

In other words, Fig. 6 is a flowchart provided for explaining step 501 of Fig. 5 in detail.

Referring to FIG. 6, in step 601, the embedded simulation interface unit 102 may load model specification information of all the embedded devices and embedded sub models stored in the embedded simulation model management unit 103.

In step 602, the embedded simulation model management unit 103 may determine whether or not model specification information corresponding to the embedded simulation model that the user desires to design exists in the loaded model specification information.

At this time, if the model specification information corresponding to the embedded simulation model to be designed exists (602: YES), the embedded simulation model management unit 103 stores the model specification information and the embedded simulation interface unit 102 in step 603, It is possible to design an embedded simulation model based on the design information input through the input device.

If there is no model specification information corresponding to the embedded simulation model to be designed by the user (602: NO), in step 604, the embedded simulation interface unit 102 generates a user interface for receiving the new simulation model specification information Can be provided. Then, in step 605, the embedded simulation model management unit 103 can design a new embedded simulation model based on the inputted new simulation model specification information and design information. At this time, the embedded simulation model management unit 103 may store the new simulation model specification information.

In step 606, the embedded simulation model management unit 103 may design an embedded simulation system based on the designed embedded simulation model.

At this time, in step 607, the embedded simulation model management unit 103 can determine whether or not the embedded simulation system design has been completed.

For example, if the design of the embedded simulation system is completed (YES at 607), the embedded simulation model management unit 103 ends the design process of the embedded simulation system and transmits the embedded simulation system designed for performing the simulation to the embedded simulation execution unit 104 ). At this time, in step 608, the embedded simulation model management unit 103 may store the designed embedded simulation system.

In other words, if the embedded simulation system design has not been completed (NO at 607), the embedded simulation model management unit 103 loads model specification information of all the embedded devices and embedded subsidiary models stored in the embedded simulation model management unit 103 the embedded simulation system design can be restarted. In other words, the embedded simulation model management unit 103 may return to step 601 and perform steps 601 to 605 again.

FIG. 7 is a flowchart illustrating a detailed operation for performing simulation for the embedded simulation system of FIG. 5, in an embodiment of the present invention.

In other words, Fig. 7 is a flowchart provided for explaining step 502 of Fig. 5 in detail

Referring to FIG. 7, in step 701, the embedded simulation execution management unit 104 may configure an environment for simulating the embedded simulation system based on the simulation execution plan information received from the embedded simulation interface unit 102.

In step 702, the embedded simulation execution management unit 104 may perform simulation of the embedded simulation system according to the environment configured for simulation and the simulation plan information.

For example, the embedded simulation interface unit 102 may provide a user interface for receiving simulation execution plan information. Then, as the simulation execution plan information is input, the embedded simulation interface unit 102 can request the embedded simulation execution unit 104 to perform the simulation of the embedded simulation system. At this time, the embedded simulation interface unit 102 may transmit the simulation plan information to the embedded simulation execution unit 104 in order to perform the simulation. Then, the embedded simulation execution management unit 104 can perform the simulation according to the simulation execution plan information.

In step 703, the embedded simulation execution management unit 104 may measure the result of performing the simulation.

In this case, in step 704, the embedded simulation execution management unit 104 may determine whether or not the simulation execution is completed according to the simulation execution plan information, and store the execution result. At this time, if there is a simulation to be further performed in the simulation execution plan information (704: NO), in step 705, the embedded simulation execution management unit 104 causes the embedded simulation execution management unit 104 to further execute simulation Can be performed to store the execution result.

If the simulation is completed (704: YES), in step 706, the embedded simulation execution management unit 104 ends the simulation and transmits the execution result to the embedded simulation interface unit 102 so as to analyze the simulation result have. Then, the embedded simulation interface unit 102 can visualize the execution result and provide it to the user.

As described above, according to the embodiments of the present invention, the embedded device simulation modeling and simulation system can be realized in the course of training the embedded system by using the embedded device and the sub-model designed based on the discrete event, Simulation system can be designed. In addition, the embedded device simulation modeling and simulation system can improve the convenience and efficiency in the training of the embedded system design and the skill improvement by performing the simulation based on the simulation plan information and providing the results of the simulation.

In addition, the embedded device simulation modeling and simulation system can simulate a designed virtual embedded system by designing a simulated embedded system using or creating an accessory model of the embedded device designed based on the discrete event standard, It is possible to predict and analyze the operation of the configured embedded system. Also, the embedded device simulation modeling and simulation system may use the prediction and analysis results to allow the user to learn about the design and operation of the embedded system.

The method according to an embodiment may be implemented in the form of a program command that can be executed through various computer means and recorded in a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, and the like, alone or in combination. The program instructions to be recorded on the medium may be those specially designed and configured for the embodiments or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape; optical media such as CD-ROMs and DVDs; magnetic media such as floppy disks; Magneto-optical media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the embodiments, and vice versa.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. For example, it is to be understood that the techniques described may be performed in a different order than the described methods, and / or that components of the described systems, structures, devices, circuits, Lt; / RTI > or equivalents, even if it is replaced or replaced.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

100: Embedded Device Simulation Modeling and Simulation System
101, 200: an embedded simulation interface unit
102, 300: Embedded simulation model management unit
103, 400: Embedded simulation execution manager
201: Embedded Simulation Model Configuration Interface Unit
202: Embedded simulation execution configuration interface unit
203: Embedded simulation execution analysis interface unit
301: Embedded simulation model storage unit
302: Embedded Simulation Model Design Department
303: Embedded Simulation System Design Department
401: Embedded simulation execution component
402; Embedded Simulation Performance Measurement
403: Embedded simulation execution log

Claims (5)

In an embedded device simulation modeling and simulation system based on discrete event system specification (DEVS)
An embedded simulation model management unit for storing and managing model specification information of a previously created embedded device and an accessory model based on the discrete event system specification;
A user interface for receiving design information for an embedded simulation model and an embedded simulation system design based on the model specification information, and an user interface for receiving simulation execution plan information; And
An embedded simulation execution management unit that records an execution result according to execution of a simulation based on the simulation execution plan information and provides an operation pattern of the embedded simulation system based on the execution result,
Lt; / RTI >
The embedded simulation interface unit,
Providing a user interface for modifying the simulation performance plan information,
Requesting the embedded simulation execution management unit to perform a simulation of the embedded simulation system according to the simulation execution plan information,
Loading the model specification information of all embedded devices and sub models previously stored in the embedded simulation model management unit to determine whether the user has an embedded simulation model to be designed,
Providing an interface for visualizing and providing an operation pattern of the simulated system so that the user can analyze the operation of the embedded simulated system,
The embedded simulation model management unit,
The embedded simulation model is designed on the basis of the previously created model specification information as the model specification information corresponding to the embedded simulation model to be designed exists in the loaded model specification information and the designed embedded simulation model is connected, We design an embedded simulation system,
And the model specification information corresponding to the embedded simulation model to be designed by the user does not exist in the loaded model specification information, the new embedded simulation model is generated based on the design information and the model specification information inputted to generate the new embedded simulation model We design a model, design a new embedded simulation system based on the new embedded simulation model,
The embedded simulation system is transferred to the embedded simulation execution management unit in order to perform a simulation upon completion of the embedded simulation system design,
When the embedded simulation system design is not completed, the embedded simulation system design is restarted by loading all of the stored model specification information of all the embedded devices and the accessory models,
Modifying the model specification information based on user input through the embedded simulation interface unit, modifying the designed embedded simulation model and the embedded simulation system based on the modified model specification information,
Modifying the simulation plan information according to a request of the embedded simulation interface unit,
The embedded simulation execution management unit,
Executing the simulation based on the modified simulation execution plan information and providing a state in which the embedded device simulation modeling and simulation system operates at discrete event time based on the execution result. delete delete delete The method according to claim 1,
The embedded simulation model management unit,
An embedded device simulation modeling and simulation system for designing an embedded simulation model based on a discrete event system specification capable of simulation by collecting simulation environment information and parameter information included in the design information and stored simulation model information.

Images