By name: stability-goal-obfuscation description: > Stability-goal obfuscation tradeoff methodology for autonomous agents. Addresses the problem that Lyapunov-stable goal-directed trajectories are inherently legible to Bayesian observers, leaking intent. Combines control Lyapunov functions (CLFs), probabilistic control barrier functions (PCBFs), and Rao-Blackwellized particle filter (RBPF) belief-state analysis to maintain task stability while obfuscating intent from passive observers. Use when: designing privacy-preserving autonomous systems, adversarial trajectory planning, intent privacy, safety-critical control, control barrier functions, Lyapunov stability with privacy constraints.
Stability-Goal Obfuscation Tradeoff
Framework for maintaining task stability while preventing intent inference by adversarial observers, based on Wang, Guralnik & Dixon (arXiv:2605.06630, May 2026).
Problem
Goal-directed agents under Lyapunov-based control are intrinsically legible: the contractive dynamics of a Lyapunov basin of attraction concentrates a Bayesian observer's posterior belief over the agent's latent intent parameters (goal location, radius, arrival time). Task-optimal trajectories are the most information-leaking.
Core Methodology
1. Dual-State Control Problem
Joint control on:
- Physical state x: agent dynamics ẋ ∈ u + d̄B (fully actuated, bounded disturbance)
- Belief state b: observer's RBPF belief over possible agent goals
The controller must satisfy both a tracking constraint (CLF) and a privacy constraint (PCBF) simultaneously.
2. KL-Based Information Leakage Measurement
- Observer uses Rao-Blackwellized particle filter (RBPF) with N particles over discrete goal samples
- Information leakage measured as KL divergence between prior and posterior over goals
- Online-computable at each RBPF update step
- Privacy requires maintaining leakage below a threshold with high probability
3. Probabilistic Control Barrier Functions (PCBFs)
Key innovation: derive separate PCBF conditions for:
- Bayesian update step: posterior concentration from new observations
- Resampling step: particle weight redistribution
Combined PCBF guarantees privacy across the full RBPF update cycle.
4. Joint Feasibility Analysis
The tracking envelope (physical feasibility) and privacy constraint (belief-state feasibility) interact:
- Tight privacy bounds shrink feasible control set
- Loose bounds may fail to obfuscate
- Feasibility depends on disturbance bounds d̄, RBPF particle count N, and measurement noise
Implementation Pattern
# QP formulation (per timestep):
# min ||u - u_nom||²
# s.t. ∂V/∂x · f(x,u) ≤ -α(V(x)) # CLF (stability)
# P[PCBF(b, u) ≥ 0] ≥ 1 - ε # PCBF (privacy, probabilistic)
# u ∈ U # input constraints
Where:
u_nom: nominal task-optimal controlV: control Lyapunov functionPCBF: probabilistic barrier function on belief stateε: acceptable privacy violation probability
When to Apply
- Autonomous vehicles operating in adversarial environments
- Military/aerospace systems requiring intent privacy
- Multi-agent systems where intent leakage compromises coordination
- Any Lyapunov-stable controller operating under observation
Key References
- arXiv:2605.06630 — Wang, Guralnik, Dixon (2026)
- Ames et al. (2016, 2019) — Control Barrier Functions
- Dragan et al. (2013) — Legible robot motion planning
- Wang et al. (2025b) — Intent inference via RBPF
Pitfalls
- RBPF requires sufficient particle count for accurate belief estimation
- Privacy constraint may be infeasible if disturbance bounds are too tight
- Joint feasibility analysis is problem-specific; no universal bounds
- PCBF derivation requires careful treatment of both update and resampling steps