Work-in-Progress: Hierarchical Ensemble Learning for Resource-Aware FPGA Computing

Recent years witness the rapid development in hardware/software codesign that integrates machine learning (ML) models with hardware systems [1]-[4]. Despite the booming trend in building neuromorphic computing systems [2], decision trees still attract much attention in ML communities, from both software [5], [6] and hardware [1], [7], [8] approaches. A single tree model may not be as accurate as desired. One effective way to remedy this is to apply ensemble methods [5]-[7], [9]-[11], such as the Random Forest (RF) [5]. Larger tree ensembles typically improve accuracy, but demand more computation resources, especially for hardware implementation. Many methods have been proposed to address this issue. The motivation arouses from the fact that tree models usually demands much less computation resource comparing to neural networks, making them extremely potential for wearable devices and embedded systems at the edge nodes of the IoT [7], [11], [12]. Moreover, due to their inherent structures, tree ensembles are ideal for exploiting the computational parallelism on FPGA [1], [4], [7]-[9], [11], [13].