Controls Research Engineer

DYNA Robotics Inc

$120K — $150K *
Technical Services
Less than 5 years of experience
Job Overview by Ladders

Qualifications

  • MS or PhD in robotics, controls, machine learning, or a related field
  • Experience with learning-based control (e.g. reinforcement learning, imitation learning)
  • Strong foundation in classical control (PID, LQR, MPC) and state estimation
  • Proficiency in C++ and Python; experience with real-time systems
  • Experience deploying controllers or learned policies on physical hardware
  • Familiarity with simulation tools (MuJoCo, Isaac Sim, Drake, or similar)
  • Strong communication skills and ability to work across teams

Responsibilities

  • Design, implement, and tune control algorithms for semi-humanoid robots, emphasizing learning-based approaches
  • Build high-fidelity simulations and benchmarks to iterate on controller performance
  • Analyze actuator dynamics and sensor data to optimize motor functionality
  • Create internal tools for team visualization of control behavior
  • Collaborate with hardware engineers on actuator selection and sensor integration
  • Work with AI/ML researchers to link learned behaviors to motor control
  • Document methods for scalable insights across the organization

Benefits

  • Opportunity to work at the forefront of AI-driven robotics
  • Collaborative environment with cross-disciplinary teams of experts
  • Access to advanced technology and proprietary tools
  • Potential for significant impact on the future of robotic automation
  • Supportive culture that encourages innovation and knowledge sharing
Full Job Description
Position Overview

As a Controls Engineer, you are responsible for the robot's neuromuscular system. You will bridge the gap between high-level AI reasoning and low-level motor torque, ensuring our semi-humanoids move with unprecedented fluidity, speed, and safety.

This is a role for a modern controls expert who views "control" not just as a set of equations, but as the interface between learned policies and real-world physics.

What You'll Do
  • Modern Whole-Body Control: Design and implement whole-body control (WBC) frameworks that produce stable, high-bandwidth motion for redundant, high-DOF semi-humanoid platforms.
  • RL-to-Real Integration: Lead the deployment of learning-based controllers (RL, Imitation Learning) onto physical hardware. You will own the "Sim-to-Real" pipeline, ensuring learned behaviors translate into reliable, contact-rich robot interactions.
  • Dynamic Characterization: Perform system identification and design calibration processes to characterize high-performance actuators and complex system dynamics.
  • High-Fidelity Simulation: Build and optimize simulation environments (MuJoCo, Isaac, Pinocchio) to rapidly evaluate controller performance, stability margins, and failure modes.
  • Hardware-Software Co-Design: Collaborate with hardware engineers to define the next generation of robot platforms by quantifying how latency, sensor noise, and mechanical design impact control performance.
  • Interactive Tooling: Develop internal observability systems to visualize real-time control behavior, helping the broader AI team understand the physical impact of their models.
What You'll Bring
  • MS or PhD in Robotics/Controls: Or equivalent "in-the-trenches" experience building high-performance robots.
  • Modern Toolkit: Deep understanding of rigid body kinematics, spatial math (SO(3) / SE(3)), and dynamics libraries (e.g., Pinocchio, Drake, or MuJoCo).
  • AI-First Mindset: Proven experience with Reinforcement Learning or Imitation Learning for manipulation or locomotion. You know how to wrap a learned policy in a robust safety layer.
  • Real-Time Mastery: Proficiency in C++ and Python for latency-sensitive workloads running on edge compute.
  • Hands-on Grit: A track record of pushing physical hardware to its limits-faster movements, tighter stability, and better disturbance rejection.
Bonus Points For
  • Experience with Hybrid Motion-Force Control (Operational Space Control, Inverse Dynamics).
  • Deep understanding of low-level motor driver architectures and EtherCAT/CAN communication.
  • A portfolio of publications at RSS, CoRL, or ICRA showcasing state-of-the-art robot learning or control.


Don't let a checklist stop you. Data shows that underrepresented groups often only apply if they meet 100% of the criteria. We value problem-solving and grit over keyword matching. If you're passionate about the intersection of geometry and robotics, we want to hear from you-even if you don't check every box.

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