Customizing architectures for particular applications is a promising approach to yield highly energy-efficient designs for embedded systems. This work explores the benefits of architectural customization for a class of embedded architectures typically used in energy- and area-constrained application domains, such as sensor nodes and multimedia processing. We implement a process flow that performs an automatic synthesis and evaluation of the different architectures based on runtime profiles of applications and determines an efficient architecture, with consideration for both energy and area constraints. An expressive architectural model, used by our engine, is introduced that takes advantage of efficient opcode allocation, several memory addressing modes, and operand types. By profiling embedded benchmarks from a variety of sensor and multimedia applications, we show that the energy savings resulting from various architectural optimizations relative to the base architectures (e.g., MIPS and MSP430) are significant and can reach 50%, depending on the application. We then identify the set of architectures that achieves near-optimal savings for a group of applications. Finally, we propose the use of heterogeneous ISA processors implementing those architectures as a solution to capitalize on energy savings provided by application customization while executing a range of applications efficiently.

Customizing architectures for particular applications is a promising approach to yield highly energy-efficient designs for embedded systems. This work explores the benefits of architectural customization for a class of embedded architectures typically used in energy-constrained application domains such as sensor node and multimedia processing. We implement a process flow that analyzes runtime profiles of applications and combines this information with a model for our architectural design space providing a robust customization engine built upon a fully automated method for determining an efficient architecture (together with appropriate application transformations). By profiling embedded benchmarks from a variety of sensor and multimedia applications, the paper shows the relative energy savings resulting from various architectural optimizations and identifies the number of architectures that achieves near-optimal savings for a group of applications. This paper proposes the use of heterogeneous chip-multiprocessors as a cost-effective approach to capitalize on the potential energy savings provided by application customization while executing a range of applications efficiently.

Customizing architectures for particular applications is a promising approach to yield highly energy-efficient designs for embedded systems. This work explores the benefits of architectural customization for a class of embedded architectures typically used in energy-constrained application domains such as sensor node and multimedia processing. We implement a process flow that analyzes runtime profiles of applications and combines this information with a model for our architectural design space providing a robust customization engine built upon a fully automated method for determining an efficient architecture (together with appropriate application transformations). By profiling embedded benchmarks from a variety of sensor and multimedia applications, the paper shows the relative energy savings resulting from various architectural optimizations and identifies the number of architectures that achieves near-optimal savings for a group of applications. This paper proposes the use of heterogeneous chip-multiprocessors as a cost-effective approach to capitalize on the potential energy savings provided by application customization while executing a range of applications efficiently.