PYRENEES SESSIONS
THE BRIEF
While navigating the rugged terrain of the French Pyrenees, an opportunity arose to conduct a high-altitude technical study of our mobile projection capabilities. The objective was to test the limits of our deployment rig in sub-zero, mountain environments—specifically focusing on the interaction between generative light and complex, snow-dusted textures. Inspired by the vertical geometry of the surrounding pine forests, we aimed to create a visual dialogue between the technical precision of our hardware and the raw, organic silhouettes of the mountain wilderness.
While navigating the rugged terrain of the French Pyrenees, an opportunity arose to conduct a high-altitude technical study of our mobile projection capabilities. The objective was to test the limits of our deployment rig in sub-zero, mountain environments—specifically focusing on the interaction between generative light and complex, snow-dusted textures. Inspired by the vertical geometry of the surrounding pine forests, we aimed to create a visual dialogue between the technical precision of our hardware and the raw, organic silhouettes of the mountain wilderness.
While navigating the rugged terrain of the French Pyrenees, an opportunity arose to conduct a high-altitude technical study of our mobile projection capabilities. The objective was to test the limits of our deployment rig in sub-zero, mountain environments—specifically focusing on the interaction between generative light and complex, snow-dusted textures. Inspired by the vertical geometry of the surrounding pine forests, we aimed to create a visual dialogue between the technical precision of our hardware and the raw, organic silhouettes of the mountain wilderness.
THE EXECUTION
This deployment served as a critical stress test for our off-grid power systems and long-throw optics in extreme cold. Utilizing a bespoke B&M-inspired visual set, we mapped the alpine treeline to create a luminous, architectural extension of the forest itself. The execution required surgical precision in alignment to account for the undulating topography and the atmospheric interference common at high elevations. By translating the rhythmic patterns of the trees into dynamic light data, we achieved a seamless integration of "The Rig" into the landscape. This study proved that our immersive environments aren't bound by city limits or traditional power grids—wherever the Captain can drive, the spectacle can be manifested.
This deployment served as a critical stress test for our off-grid power systems and long-throw optics in extreme cold. Utilizing a bespoke B&M-inspired visual set, we mapped the alpine treeline to create a luminous, architectural extension of the forest itself. The execution required surgical precision in alignment to account for the undulating topography and the atmospheric interference common at high elevations. By translating the rhythmic patterns of the trees into dynamic light data, we achieved a seamless integration of "The Rig" into the landscape. This study proved that our immersive environments aren't bound by city limits or traditional power grids—wherever the Captain can drive, the spectacle can be manifested.
This deployment served as a critical stress test for our off-grid power systems and long-throw optics in extreme cold. Utilizing a bespoke B&M-inspired visual set, we mapped the alpine treeline to create a luminous, architectural extension of the forest itself. The execution required surgical precision in alignment to account for the undulating topography and the atmospheric interference common at high elevations. By translating the rhythmic patterns of the trees into dynamic light data, we achieved a seamless integration of "The Rig" into the landscape. This study proved that our immersive environments aren't bound by city limits or traditional power grids—wherever the Captain can drive, the spectacle can be manifested.
