In this study, a flexure-based bonder head was designed to achieve the high alignment accuracy required in next-generation fine-pitch semiconductor packaging processes, and its performance was evaluated using the finite element method (FEM). Conventional thermo-compression bonding (TCB) systems have difficulty achieving sub-micrometer precision alignment due to mechanical errors and stage drive limitations. To address these challenges, the proposed bonder head integrates a bridge-type flexure tip/tilt stage for Rx-Ry tilt compensation and a decoupled flexure XY stage for X-Y position compensation. Each stage is equipped with high-resolution encoders and linear scales to enable feedbackbased control, while minimizing parasitic motion to enhance precision. FEM analysis results indicate that the designed stages provide a tilt compensation range of ±0.1° and a position compensation range of ±15 μm, with a predicted natural frequency above 70 Hz. This work demonstrates the feasibility of a flexure-based bonder head at the design and analysis levels for achieving the required bonding precision, and highlights its potential for application in future high-density semiconductor packaging processes.