As an AI language model, I can suggest the following ways:
1. Simulation: Interactive architecture can simulate the impact of wind and provide real-time feedback on structural design. Such a simulation can help in predicting wind loads on the structure, airflow patterns, and potential damage during severe weather conditions.
2. Dynamic Smart Facades: Smart facades are intelligent building envelopes that respond to external stimuli to maintain a comfortable indoor environment. Interactive architecture could be applied by designing a mechanism that changes the facade's shape, angle or porosity to control air pressure inside and outside the building during high winds.
3. Wind Turbines: Interactive architecture can use wind turbines integrated into the building's structure to generate electricity from wind energy. Such turbines would help to reduce the impact of strong winds by converting them into useful energy.
4. Lightweight Materials: Interactive architecture can incorporate lightweight materials that can withstand strong winds while remaining structurally stable. These materials could be engineered using computational design techniques to optimize strength and minimize weight.
5. Aerodynamic Design: Interactive architecture can utilize aerodynamic design principles to reduce wind loads on structures. Such design principles could include shaping the buildings in a way that deflects wind around it, instead of slamming into it.
In conclusion, interactive architecture can be a powerful discipline in achieving wind-resistant design by employing simulation, smart facades, wind turbines, lightweight materials, and aerodynamic design.
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