Tech Lead, Robotic AI Model

The Company

Faraday Future is a California-based technology company focused on the design, engineering, and development of intelligent, connected electric vehicles and related artificial intelligence‑enabled technologies. Founded in 2014, the Company’s mission is to disrupt the automotive and technology industries by creating user‑centric, technology‑first experiences. The Company operates across multiple technology‑driven areas, including AI electric vehicles, robotics, and its crypto business (AIXC), under its upgraded Global EAI Industry Bridge Strategy.

The Company aims to leverage the latest technologies and world’s best talent to realize exciting new possibilities across all of these lines. Faraday Future’s automotive business exemplifies its vision for luxury, innovation, and performance, while its FX strategy aims to introduce mass production models equipped with state‑of‑the‑art luxury technology derived from the FF brand, targeting a broader market with middle‑to‑low price range offerings.

FF is committed to redefining mobility through AI innovation.

We are building the next generation of intelligent robots. As a leader in Robotics AI Model, you will own the critical pipeline that transforms pretrained foundation models into deployable robot policies—turning general‑purpose AI into systems that can reliably manipulate objects, navigate environments, and perform complex physical tasks in the real world. This role sits at the intersection of embodied AI, robot learning, and foundation model adaptation.

You will work across the full post‑training lifecycle: curating demonstration data, fine‑tuning vision‑language‑action (VLA) models or world models, training reinforcement learning policies in simulation, validating behaviors on real hardware, and optimizing models for on‑robot inference. Your work will directly determine how capable, safe, and generalizable our robots are.

• Design and execute post‑training pipelines for VLA and visuomotor policy models (e.g., diffusion policies, ACT, flow matching), including supervised fine‑tuning (SFT), reinforcement learning (RL), and preference‑based optimization.
• Fine‑tune pretrained robot foundation models on task‑specific demonstration datasets for dexterous manipulation, locomotion, whole‑body control, and multi‑step task sequencing.
• Develop and iterate on reward functions, verifiers, and RL training loops (PPO, GRPO, RLVR) to improve policy success rate and robustness in simulation and real‑world deployment.
• Apply parameter‑efficient fine‑tuning methods (LoRA, QLoRA, OFT) to adapt large models to new tasks and robot embodiments under compute constraints.

• Build and manage large‑scale robot demonstration data pipelines: teleoperation data collection, action tokenization (e.g., FAST tokenizer), data augmentation, quality filtering, and dataset versioning.
• Define data collection strategies across robot platforms, collaborating with robot operators and data labeling teams to ensure dataset diversity and coverage.
• Integrate multi‑modal sensory data (RGB, depth, proprioception, force/torque, tactile) into coherent training datasets.

• Build and maintain simulation environments (Isaac Sim, Mu Jo Co , SAPIEN) for scalable policy training, including domain randomization, asset generation, and task definition.
• Address sim-to-real transfer challenges through visual augmentation, action space calibration, dynamics randomization, and systematic real‑world validation.
• Design and run large‑scale distributed RL training across GPU clusters for locomotion and manipulation policies.

• Build evaluation and benchmarking infrastructure: automated success‑rate tracking, sim evaluation harnesses, real‑robot A/B testing, and regression monitoring.
• Optimize models for on‑robot inference: quantization (INT8/FP8), action chunking, latency reduction, and real‑time control loop integration.
• Collaborate with controls, perception, and hardware teams to integrate learned policies into the full robot software stack.

• Track and adopt…