The paper describes a unified formal framework for designing and reasoning about power-constrained, timed systems. The framework is based on process algebra, a formalism which has been developed to describe and analyze communicating, concurrent systems. The proposed extension allows the modeling of probilistic resource failures and power consumption by resources within the same formalism. Thus, it is possible to study several alternative power-consumption behaviors and tradeoffs in their timing and other characteristics. This paper describes the modeling and analysis techniques, and illustrates them with examples, including a power-aware ad-hoc network protocol
There has recently been significant progress in the development of timed process algebras for the sp...
The paper describes a formal framework for designing and reasoning about resource-constrained system...
This paper presents a general framework for analyzing and designing embedded systems with energy and...
The paper describes a unified formal framework for designing and reasoning about power-constrained, ...
The paper describes a formal approach for designing and reasoning about power-constrained, timed sys...
The paper describes a unified formal framework for designing and reasoning about power-constrained, ...
The paper describes a unified formal framework for designing and reasoning about power-constrained, ...
The paper describes a unified formal framework for designing and reasoning about power-constrained, ...
The paper describes a unified formal framework for designing and reasoning about power-constrained, ...
Abstract. The paper describes a formal approach for designing and rea-soning about power-constrained...
The paper describes a formal framework for designing and reasoning about resource-constrained system...
Timing and power are two metrics that have become increasingly important to system level designers e...
AbstractThe Algebra of Communicating Shared Resources (ACSR) is a timed process algebra which extend...
The Algebra of Communicating Shared Resources (ACSR) is a timed process algebra which extends classi...
This paper presents a general framework for analyzing and designing embedded systems with energy and...
There has recently been significant progress in the development of timed process algebras for the sp...
The paper describes a formal framework for designing and reasoning about resource-constrained system...
This paper presents a general framework for analyzing and designing embedded systems with energy and...
The paper describes a unified formal framework for designing and reasoning about power-constrained, ...
The paper describes a formal approach for designing and reasoning about power-constrained, timed sys...
The paper describes a unified formal framework for designing and reasoning about power-constrained, ...
The paper describes a unified formal framework for designing and reasoning about power-constrained, ...
The paper describes a unified formal framework for designing and reasoning about power-constrained, ...
The paper describes a unified formal framework for designing and reasoning about power-constrained, ...
Abstract. The paper describes a formal approach for designing and rea-soning about power-constrained...
The paper describes a formal framework for designing and reasoning about resource-constrained system...
Timing and power are two metrics that have become increasingly important to system level designers e...
AbstractThe Algebra of Communicating Shared Resources (ACSR) is a timed process algebra which extend...
The Algebra of Communicating Shared Resources (ACSR) is a timed process algebra which extends classi...
This paper presents a general framework for analyzing and designing embedded systems with energy and...
There has recently been significant progress in the development of timed process algebras for the sp...
The paper describes a formal framework for designing and reasoning about resource-constrained system...
This paper presents a general framework for analyzing and designing embedded systems with energy and...