Variational Neural Belief Parameterizations for Robust Dexterous Grasping under Multimodal Uncertainty

Figure 1: This paper develops a variational neural belief (VNB) parameterization for robust grasping, casting grasping as a sequential risk-sensitive decision process over an online contact-geometry belief. The grasp wrench space (GWS), \mathcal{W} , ( leftmost column ; axes omitted) is the convex hull of resistible hand wrenches. The dotted circle marks the terminal inscribed-ball radius, \varepsilon_{T} , reported in the bottom-right corner of each GWS figure. Larger hulls containing the origin indicate greater disturbance rejection. VNB (top row) iteratively refines contact, producing a for

Figure 3: Overview of Our Proposed Variational Neural Belief Grasping Framework. At each decision step, the neural belief dynamics update a latent embedding \mathbf{h}_{t} via a prediction network f_{\mathrm{trans}} conditioned on actions and a correction network f_{\mathrm{obs}} conditioned on observations (joint angles, pose estimate with covariance, and contact geometry). We then evaluate grasp robustness under multimodal uncertainty along separate but connected simulation and hardware axes, with simulation providing controlled evaluation under known friction regimes, and hardware trials va

Figure 2: Hardware Platform : Our platform comprises a FAIR Innovation FR3 cobot (6 DoF), RealHand L6 robotic hand (11 DoF), two calibrated RGB-D cameras (RealSense D435i and Orbbec Astra Pro Plus), and representative primitives and YCB objects. We compare VNB-MPC with a Gaussian baseline under object-pose uncertainty and report results in Section VI , with hardware grasps shown in Fig. 7 .

Figure 4: Per-Regime Performance Comparison. Grouped bar chart comparing Cem and Vnb across friction regimes. Vnb matches or exceeds Cem in all three regimes, with the largest gains under nominal and bimodal friction.

Figure 6: Grasp Comparison on Representative Objects. Top : Under friction uncertainty, Cem fails to achieve force closure ( \varepsilon{\approx}0 , 0.0022 ) and drops the object during lift. Bottom : Our risk-aware Vnb achieves robust grasps ( \varepsilon{=}0.15 , 0.0021 ) and sustains a 50 mm lift.