Firmware Lead, Robotics

About the Team

We are building general-purpose robotics. In the short term, we are focused on robots to support skilled workers to build our future infrastructure. In the long term, we imagine everyone having a personal robot doing anything they need. Progress is rapid, and based on a foundation of co-design between robotics hardware and ML research.

As a Firmware Lead, you will define and drive the architecture of embedded systems for next-generation hardware products. You will own foundational firmware decisions across real-time execution, device bring-up, hardware interfaces, fault handling, safety mechanisms, and production readiness.

We’re looking for someone with deep experience building safety-critical or high-consequence systems, where failures can have meaningful consequences. You should be comfortable reasoning about risk, designing for diagnosability and graceful degradation, and creating engineering practices that raise the reliability bar for the entire team.

You should also be unusually good at moving fast. Sometimes the right answer is a carefully reviewed architecture that will endure for years; sometimes it is getting a rough-but-useful prototype working by the end of the afternoon so the team can learn something concrete tomorrow. We value engineers who know the difference, make that call well, and can operate credibly in both modes.

You will be both a technical leader and a hands‑on builder: setting direction, reviewing critical designs, unblocking the hardest problems, and writing production firmware when it matters most.

• Rapidly bring up new hardware and set execution pace for the team.
• Lead firmware architecture for embedded systems spanning boot, RTOS/runtime behavior, peripheral control, power management, communications, and field diagnostics.
• Define engineering standards for reliability, fault tolerance, observability, and maintainability across the firmware stack.
• Design and review safety‑critical mechanisms, including fault detection, recovery paths, watchdog strategies, redundancy where appropriate, and safe‑state behavior.
• Build quick, scrappy prototypes when speed of learning matters, then harden the right ideas into production‑quality systems.
• Partner closely with engineers in hardware, software, and AI research from early prototype through production.
• Build rigorous bring‑up, validation, and release processes for embedded platforms.
• Establish testing strategies across unit, hardware‑in‑the‑loop, integration, stress, and failure‑injection testing.
• Drive root‑cause analysis for subtle hardware, firmware, and system interactions.
• Make clear tradeoffs across performance, memory, power, schedule, and safety.
• Mentor firmware engineers and help shape a culture of urgency, technical rigor, practical judgment, and high‑quality execution.

• Have extensive experience developing firmware in an iterative environment.
• Get a thrill from bringing up new hardware and taking end‑to‑end ownership over ensuring it works.
• Have led architecture and delivery for complex embedded products that shipped to real users or operated in demanding production environments.
• Are deeply fluent in low‑level languages (we use Rust!) and comfortable working close to hardware under real‑time constraints.
• Understand embedded systems from first principles, including interrupts, scheduling, memory layout, buses, DMA, timing behavior, and failure modes.
• Have strong instincts for defensive design, fault containment, validation depth, and post‑deployment diagnosability.
• Know when to build the durable system and when to produce the fastest credible artifact that unlocks the next decision.
• Communicate clearly across disciplines and can turn ambiguity into sound technical direction.
• Care about building systems that are not only fast and capable, but also trustworthy.
• Make heavy use of Codex, Claude Code, or similar AI‑assisted coding systems to accelerate implementation, prototyping, debugging, and iteration.