Providing Security to Wireless Packet Networks by using Optimized Security Method

Now-a-days technology is growing very fast, due to rapid development of the technology in computer arena, communication through network become a habit to the users. Communication through network is happen using two channels i.e., by connection oriented and connection less. At present users prefer wireless networks for communication and transferring data due to its flexibility. So in this paper we are focusing on wireless networking, as it is not reliable we are proposing an optimized security technique to provide security to the communication on wireless. In this paper we mainly focus on packet scheduling which plays the vital role in the transmission of data over wireless networks. We are using optimized security technique to secure the packets at initial level itself while scheduling the packets. Keywords: Real-Time Packets, Packet Scheduling, Wireless Networks, Security, Cryptography, Secret key, Bandwidth

Planning and Resource Allocation for Hard Real-time, Fault-Tolerant Plan Execution

We describe the interface between a real-time resource allocation system with an AI planner in order to create fault-tolerant plans that are guaranteed to execute in hard real-time. The planner specifies the task set and all execution deadlines required to ensure system safety, then the resource utilization. A new interface module combines information from planning and resource allocation to enforce development of plans feasible for execution during a variety of internal system faults. Plans that over-utilize any system resource trigger feedback to the planner, which then searches for an alternate plan. A valid plan for each specified fault, including the nominal no-fault situation, is stored in a plan cache for subsequent real-time execution. We situate this work in the context of CIRCA, the Cooperative Intelligent Real-time Control Architecture, which focuses on developing and scheduling plans that make hard real-time safety guarantees, and provide an example of an autonomous aircraft agent to illustrate how our planner-resource allocation interface improves CIRCA performance.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/44010/1/10458_2004_Article_318111.pd

Combined Task and Message Scheduling in Distributed Real-Time Systems

This paper presents an algorithm for off-line scheduling of communicating tasks with precedence and exclusion constraints in distributed hard real-time systems. Tasks are assumed to communicate via message passing based on a time-bounded communication paradigm such as the real-time channel [1]. The algorithm uses a branch-and-bound (B&B) technique to search for a task schedule by minimizing maximum task lateness (defined as the difference between task completion time and task deadline), and exploits the interplay between task and message scheduling to improve the quality of solution. It generates a complete schedule at each vertex in the search tree, and can be made to yield a feasible schedule (found before reaching an optimal solution), or proceed until an optimal task schedule is found. We have conducted an extensive simulation study to evaluate the performance of the proposed algorithm. The algorithm is shown to scale well with respect to system size, and degree of intertask intera..

Placement, ordonnancement et mécanismes de migration de tâches temps-réel pour des architectures distribuées multicoeurs

Les systèmes temps-réel embarqués critiques intègrent un nombre croissant de fonctionnalités comme le montrent les domaines de l'automobile ou de l'aéronautique. Ces systèmes doivent offrir un niveau maximal de sûreté de fonctionnement en disposant des mécanismes pour traiter les défaillances éventuelles et doivent être également performants, avec le respect de contraintes temps-réel strictes. Ces systèmes sont en outre contraints par leur nature embarquée : les ressources sont limitées, tels que par exemple leur espace mémoire et leur capacité de calcul. Dans cette thèse, nous traitons deux problématiques principales de ce type de systèmes. La première porte sur la manière d'apporter une meilleure tolérance aux fautes dans les systèmes temps-réel distribués subissant des défaillances matérielles multiples et permanentes. Ces systèmes sont souvent conçus avec une allocation statique des tâches. Une approche plus exible effectuant des recon gurations est utile si elle permet d'optimiser l'allocation à chaque défaillance rencontrée, pour les ressources restantes. Nous proposons une telle approche hors-ligne assurant un dimensionnement adapté pour prendre en compte les ressources nécessaires à l'exécution de ces actions. Ces recon gurations peuvent demander une réallocation des tâches ou répliques si l'espace mémoire local est limité. Dans un contexte temps-réel strict, nous dé nissons notamment des mécanismes et des techniques de migration garantissant l'ordonnançabilité globale du système. La deuxième problématique se focalise sur l'optimisation de l'exécution des tâches au niveau local dans un contexte multicoeurs préemptif. Nous proposons une méthode d'ordonnancement optimal disposant d'une meilleure extensibilité que les approches existantes en minimisant les surcoûts : le nombre de changements de contexte préemptions et migrations locales) et la complexité de l'ordonnanceurCritical real-time embedded systems are integrating an increasing number of functionalities, as shown in automotive domain or aeronautics. These systems require high dependability including mechanisms to handle possible failures and have to be effective, meeting hard real-time constraints. These systems are also constrained by their embedded nature : resources are limited, such as their memory and their computing capacities. In this thesis, we focus on two main problems for this type of systems. The rst one is about a way to bring a better fault-tolerance in distributed real-time systems when multiple and permanent hardware failures can occur. In classical systems, the design is limited to a static task assignment. A more exible approach exploiting recon gurations is useful if it allows to optimize assignment at each failure for the remaining resources. We propose an off-line approach to obtain an adapted sizing taking into account necessary resources to execute these actions. These recon gurations may require to reallocate tasks or replicas if memory capacities are limited. In a hard real-time context, we de ne mechanisms and migration techniques to guarantee global schedulability of the system. The second problem focus on optimizing performance to run tasks at a local level in a multicore preemptive context. We propose an optimal scheduling method allowing a better scalability than existing approaches by minimizing overheads : the number of context switches (local preemptions and migrations) and the scheduler complexityTOULOUSE-INP (315552154) / SudocSudocFranceF