Abstract  Reconfigurable architectures such as FPGAs are flexible alternatives to DSPs or ASICs used in mobile devices for which energy is a key performance metric. Reconfigurable architectures offer several design parameters such as operating frequency, precision, amount of memory, degree of parallelism, etc. These parameters define a large design space that must be explored to find energy-efficient solutions. It is also challenging to predict the energy variation at the early design phases when a design is modified at algorithm level. Efficient traversal of such a large design space requires high-level modeling to facilitate rapid estimation of system-wide energy. However, FPGAs do not exhibit a high-level structure like, for example, a RISC processor for which high-level as well as low-level energy models are available. To address this scenario, we propose a domain-specific modeling technique for energy-efficient kernel design that exploits the knowledge of the algorithm and the target architecture family for a given kernel to develop a high-level model. This model captures architecture and algorithm features, parameters affecting energy performance, and power estimation functions based on these parameters. A system-wide energy function is derived based on the power functions and cycle specific power state of each building block of the architecture. This model is used to understand the impact of various parameters on system-wide energy and can be a basis for the design of energy-efficient algorithms. Our high-level model is used to quickly obtain fairly accurate estimate of the system-wide energy dissipation of data paths configured using FPGAs. We demonstrate our modeling methodology by applying it to four domains.