| Description |
1 online resource (xiii, 167 pages) : illustrations |
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text txt rdacontent |
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computer c rdamedia |
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online resource cr rdacarrier |
| Bibliography |
Includes bibliographical references and index. |
| Summary |
Model-driven Development for Embedded Software: Application to Communications for Drone Swarm describes the principles of model-oriented design used in the aeronautical field, specifically for the UAV (Unmanned Aerial Vehicle). The book focuses on designing an embedded system for drones to carry out ad hoc communication within a drone fleet. In this context, an original methodology for rapid prototyping of embedded systems is presented. This approach saves time for the verification and formal validation phases, contributing to certification of the Unmanned Aerial System (UAS). The book also addresses the more traditional verification phases that must be performed to verify accuracy of the system. This evaluation is carried out in simulation and by real experimentation. The various tools necessary for the implementation of this methodology are described to allow the reader to be able to implement independently. Finally, to illustrate the contribution of this original methodology, an example of embedded system development is presented in which the different phases of the methodology are explained to conceive, validate and test a new secure routing protocol developed for communications within a fleet of drones. |
| Note |
Online resource; title from digital title page (viewed on April 21, 2020). |
| Contents |
Chapter 1. State of the Art of Model-driven Development (MDD) as Applied to Aeronautical Systems; 1.1. Principle of MDD; 1.2. Use in avionics; 1.3. The case of drones (UAS -- Unmanned Aerial Systems); Chapter 2. Original Rapid Prototyping Method for Embedded Systems for UAVs; 2.1. Using models to auto-generate a system; 2.2. Formal verification of models; 2.3. Advantages of MDD (Model-driven Development) methodologies. |
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2.4. MDD contributions to UAS certification2.5. Choice of tools for applying MDD methodology; 2.6. AVISPA: a formal verification tool for security protocols; 2.7. The need for verification; 2.8. Additional tools: simulation and experimentation; Chapter 3. Application to Communications in a Drone Fleet; 3.1. Introduction; 3.2. Cooperating unmanned aeronautical systems; 3.3. Ad hoc communications architecture for a drone fleet; 3.4. Routing protocols in an ad hoc drone network; 3.5. Security in an ad hoc drone network. |
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3.6. Designing a new secure routing protocol for UAANETs (SUAP: Secure UAANET Routing Protocol)3.7. Using the AVISPA tool to verify the security properties of the SUAP protocol; 3.8. Implementation of the SUAP protocol; 3.9. Validation of the SUAP protocol by performance evaluation. |
| Subject |
Model-driven software architecture.
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Computer software -- Development.
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Architecture logicielle guidée par modèle.
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COMPUTERS -- Software Development & Engineering -- General.
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Computer software -- Development
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Model-driven software architecture
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| Added Author |
Ben Mahmoud, Mohamed Slim, author.
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Larrieu, Nicolas, author.
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| Other Form: |
Print version: Maxa, Jean-Aime. Model-driven development for embedded software : application to communications for drone swarm. London : ISTE, 2018 (1 volume (unpaged)) 9781785482632 (OCoLC)1030303161 |
| ISBN |
9780081023891 (electronic book) |
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0081023898 (electronic book) |
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9781785482632 (hardcover) |
| Standard No. |
AU@ 000062895122 |
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AU@ 000065066788 |
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UKMGB 018796351 |
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AU@ 000068211119 |
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