| Compositional Verification of Concurrent and Real-Time Systems 2002 Edition Contributor(s): Juan, Eric Y. T. (Author), Tsai, Jeffrey J. P. (Author) |
|
 |
ISBN: 140207025X ISBN-13: 9781402070259 Publisher: Springer OUR PRICE: $104.49 Product Type: Hardcover - Other Formats Published: April 2002 Annotation: With the rapid growth of networking and high-computing power, the demand for large-scale and complex software systems has increased dramatically. Since many of the software systems support or supplant human control of safety-critical systems (such as those found in flight control, space shuttle control, aircraft avionics, robotics, patient monitoring devices and nuclear power plants), failure of such systems could have disastrous effects. It is essential, therefore, that software used for safety-critical systems preserves high assurance properties. Compositional Verification of Concurrent and Real-Time Systems introduces important modeling and formal verification techniques for verifying the reliability and correctness of high-assurance software systems. The book focuses on the efficient analysis of large-scale systems based on the concept of "compositional verification" of modules. Compositional Verification of Concurrent and Real-Time Systems is an excellent resource for student and researchers who seek a comprehensive understanding of how formal methods can be applied to the problems of intellectual or industrial significance. The application areas include concurrent systems, distributed systems, embedded systems, and real-time systems. The analysis models used are Multiset Labeled Transition Systems and Time Petri Nets. |
| Additional Information |
| BISAC Categories: - Computers | Systems Architecture - Distributed Systems & Computing - Medical - Computers | Software Development & Engineering - Systems Analysis & Design |
| Dewey: 004.35 |
| LCCN: 2002023653 |
| Series: The Springer International Engineering and Computer Science |
| Physical Information: 0.7" H x 6.1" W x 9.68" (1.09 lbs) 196 pages |
| Descriptions, Reviews, Etc. |
| Publisher Description: With the rapid growth of networking and high-computing power, the demand for large-scale and complex software systems has increased dramatically. Many of the software systems support or supplant human control of safety-critical systems such as flight control systems, space shuttle control systems, aircraft avionics control systems, robotics, patient monitoring systems, nuclear power plant control systems, and so on. Failure of safety-critical systems could result in great disasters and loss of human life. Therefore, software used for safety- critical systems should preserve high assurance properties. In order to comply with high assurance properties, a safety-critical system often shares resources between multiple concurrently active computing agents and must meet rigid real-time constraints. However, concurrency and timing constraints make the development of a safety-critical system much more error prone and arduous. The correctness of software systems nowadays depends mainly on the work of testing and debugging. Testing and debugging involve the process of de- tecting, locating, analyzing, isolating, and correcting suspected faults using the runtime information of a system. However, testing and debugging are not sufficient to prove the correctness of a safety-critical system. In contrast, static analysis is supported by formalisms to specify the system precisely. Formal verification methods are then applied to prove the logical correctness of the system with respect to the specification. Formal verifica- tion gives us greater confidence that safety-critical systems meet the desired assurance properties in order to avoid disastrous consequences. |