Mobile networks and user equipments continuously evolve to circumvent the data traffic growth and the increasing number of users. However, the complexity and heterogeneity of such systems (3G, LTE, LTE-A, etc.) makes power one of the most critical metric. In this context, power estimation has become an unavoidable task in the design process. In this paper, a dynamic power estimation methodology for FPGA-based systems is presented. It aims at providing accurate and fast power estimations of an entire system prior to its implementation. It also aims at making design space exploration easier. We introduce an innovative scenario-level in order to facilitate the comparison of domain-specific systems. We show the effectiveness of our approach on several LTE baseband configurations which leads to a low absolute error, compared to classic estimations. It also exhibits a high speed-up factor which is determinant during design space exploration. I. INTRODUCTION Today, the data traffic that is generated on mobile networks continues to grow rapidly. According to [1], global mobile data increases of 69% in 2014 and it will have a compound annual growth rate of 57% from 2014 to 2019. To deal with these issues, mobile networks and user equipments tend to constantly adapt their processing capabilities. Among all possible solutions, a popular example is the LTE standard. The complexity of systems like LTE makes their design and development a challenging task, especially when they are implemented in embedded systems in which specific constraints have to be taken into account (power, size, performance , etc.). The number of parameters that can have an impact over power consumption makes the power estimation even more difficult. As the new technologies clearly enhance the performance in terms of throughput, QoS, it also implies a higher power consumption and more heat dissipation. One of the most popular families of digital circuits in embedded systems are the Field Programmable Gate Arrays (FPGA). These devices represent an attractive technology and make it possible to implement complex systems due to their high density of gates and heterogeneous resources. As compare to ASIC that can achieve better performance [2], FPGAs offer more flexibility. FPGA-based systems can be made of IP (Intellectual Property) which are hardware cores that facilitate design reuse and speed up development time. Their power consumption is generally divided into static and dynamic power. Static power comes from leakage currents whereas dynamic power is generated by the transistors switching activity as soon as the circuit is active.