Perceiving 3D Human-Object Spatial Arrangements from a Single Image in the Wild
This addresses the challenge of 3D scene understanding from 2D images for applications in robotics and AR/VR, though it is incremental as it builds on existing monocular 3D reconstruction methods.
The paper tackles the problem of inferring 3D spatial arrangements and shapes of humans and objects from a single uncontrolled image without 3D supervision, achieving results that dramatically reduce ambiguity in likely configurations.
We present a method that infers spatial arrangements and shapes of humans and objects in a globally consistent 3D scene, all from a single image in-the-wild captured in an uncontrolled environment. Notably, our method runs on datasets without any scene- or object-level 3D supervision. Our key insight is that considering humans and objects jointly gives rise to "3D common sense" constraints that can be used to resolve ambiguity. In particular, we introduce a scale loss that learns the distribution of object size from data; an occlusion-aware silhouette re-projection loss to optimize object pose; and a human-object interaction loss to capture the spatial layout of objects with which humans interact. We empirically validate that our constraints dramatically reduce the space of likely 3D spatial configurations. We demonstrate our approach on challenging, in-the-wild images of humans interacting with large objects (such as bicycles, motorcycles, and surfboards) and handheld objects (such as laptops, tennis rackets, and skateboards). We quantify the ability of our approach to recover human-object arrangements and outline remaining challenges in this relatively domain. The project webpage can be found at https://jasonyzhang.com/phosa.