Objectives: To investigate the feasibility of using eddy current damping (ECD) technology as a portable and rapid alternative for detecting the location of cerebral hemorrhage. Methods: This study leveraged the significant conductivity difference between hemorrhagic and normal brain tissue. ECD technology involved the application of alternating current to a coil, generating a time-varying magnetic field that induces eddy currents in conductive tissues such as hemorrhagic regions. These eddy currents produced a secondary magnetic field that opposes the original, resulting in measurable changes in the ECD signal. Using COMSOL simulations, detailed models of the head, brain, hemorrhage, and coil were constructed to analyze electromagnetic coupling. Changes in coil resistance and inductance due to hemorrhagic tissue were quantified to evaluate the detectability of ECD signals. Results: Simulation results confirmed that cerebral hemorrhages generate measurable eddy current responses,  which alter the resistance and inductance of the detection coil. These changes provide quantifiable ECD signals that can potentially indicate both the location and volume of hemorrhagic lesions. Conclusions: The findings demonstrate the feasibility of using ECD technology as a portable, rapid, and non-invasive method for detecting cerebral hemorrhage. Pending clinical validation, this approach could serve as a practical alternative to conventional imaging, particularly in emergency settings where speed and mobility are essential.