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Marc Raibert

Marc Raibert (born December 22, 1949) is an American roboticist renowned for pioneering dynamic legged robotics and founding Boston Dynamics, a leading company in advanced mobile robots capable of navigating unstructured environments. Raibert earned a B.S. in electrical engineering from Northeastern University in 1973 and a Ph.D. from the Massachusetts Institute of Technology (MIT) in 1977, where his dissertation focused on motor control and learning through state-space models. As a graduate student at MIT over 50 years ago, he began his career by developing software for robot manipulator dynamics, laying early foundations in robotic control systems. Early in his academic tenure, Raibert served as an associate professor of and at (CMU), where he established the Leg Laboratory in 1980 to explore bio-inspired locomotion. He later became a professor of and at from 1986 to 1995, founding the MIT Leg Laboratory and advancing research on self-balancing, one-legged hopping robots that demonstrated principles of dynamic . In 1992, Raibert spun off from the Leg Lab to co-found in , initially as a simulation and firm; he served as president and CEO from 1992 until 2019, transitioning to chairman. Under his leadership, the company developed groundbreaking robots, including (2005), a quadruped for rough terrain funded by ; (2013 onward), a excelling in agility and balance; (2019, commercially launched 2020), a versatile four-legged inspector; (2017), a mobile manipulator; and (2021), a warehouse robot. These innovations emphasized robust, animal-inspired mobility, influencing fields from military applications to . In 2022, following Motor Group's acquisition of , Raibert founded and became of the , a research organization dedicated to advancing for physical systems. In February 2025, the Institute partnered with to advance capabilities for the humanoid robot. His work has earned numerous accolades, including election to the in 2008 for contributions to multi-legged robots, the IEEE Pioneer in Robotics and Award in 2022, the Joseph F. Engelberger Award in 2022, and the IEEE and Award in 2025. He was also named one of TIME's 100 Most Influential People in in 2023 for driving the integration of with physical . As a founding fellow of the Association for the Advancement of , Raibert's career spans over four decades, fundamentally shaping the evolution of autonomous, dynamic machines.

Early life and education

Birth and family background

Marc Raibert was born on December 22, 1949, in the United States. Public details about Raibert's family background and early life are limited. His father aspired to be an aerospace engineer but pursued other paths; he maintained a home workshop filled with tools and machines, fostering Raibert's early interest in building and engineering. It is known that his wife and daughter are both alumni of Northeastern University, reflecting a family connection to the institution where Raibert began his academic journey.

Academic degrees and early research

Marc Raibert earned a in from in 1973. He continued his studies at the (), where he obtained a in and in 1977. Raibert's doctoral dissertation, titled Motor Control and Learning by the State Space Model, was completed at MIT's Artificial Intelligence Laboratory. The work introduced a computational framework for addressing challenges in , learning, and equivalence, utilizing a state space formulation to represent sensorimotor processes. Key concepts included a set of movement primitives that could be combined to generate diverse actions, with learning achieved through a procedure that adjusted parameters based on performance feedback. This early research, influenced by the interdisciplinary environment of the MIT AI Lab and mentors such as , emphasized dynamic modeling of biological movement control, providing foundational ideas for and in complex systems. Raibert's simulations of motor behaviors in the thesis demonstrated how state-based representations could enable strategies, paving the way for his subsequent explorations in .

Academic career

Role at Carnegie Mellon University

After earning his PhD from MIT in 1977, Marc Raibert joined Carnegie Mellon University (CMU) as an associate professor in the Computer Science Department and the Robotics Institute in 1980. In this role, he focused on advancing the emerging field of mobile robotics, particularly emphasizing dynamic control systems for legged machines, which built on his dissertation work in motor control and manipulation. His appointment came shortly after the establishment of CMU's Robotics Institute in 1979, where he contributed to its early development as a hub for interdisciplinary robotics research. In 1980, Raibert founded the CMU Leg Laboratory, a pioneering research group dedicated to exploring the principles of legged through dynamic rather than static . The lab's initial projects centered on one-legged hopping robots, such as the planar prototype, which demonstrated controlled hopping and landing to maintain upright posture without relying on multiple legs for support. A key advancement was the 3D one-legged hopper (1983-1984), which achieved autonomous hopping and running at speeds up to approximately 2.2 meters per second, along with precise turning maneuvers in without external support. These experiments highlighted the challenges of dynamic , where robots had to actively manage momentum and external forces during motion, laying groundwork for more complex multi-legged systems. Key prototypes from this period included early dynamically machines capable of demonstrating running gaits, such as planar biped models that executed bounding or alternating leg patterns while regulating speed and height, and the initial development of the quadruped with trotting gaits in 1984. Raibert's seminal , "Dynamically Stable Legged , detailed these innovations, including strategies for hopping height, forward velocity, and body attitude, which became foundational for subsequent research. Through the Leg Lab, Raibert collaborated closely with graduate students, mentoring them on hands-on prototyping and algorithms, which helped shape CMU's curriculum by integrating practical dynamic topics into coursework and seminars. This emphasis on experimental validation influenced the training of a generation of roboticists at the institution.

Establishment of MIT Leg Laboratory

In 1986, Marc Raibert joined the (MIT) as a professor of and and a member of the Laboratory. This appointment marked a pivotal transition in his academic career, building on his prior work at (CMU), where he had founded the Leg Laboratory in 1980 as an early precursor to advanced dynamic research. The Leg Laboratory was relocated and expanded at in , enabling Raibert to scale up investigations into legged with greater resources and interdisciplinary collaboration. This expansion continued and advanced focus on multi-legged configurations, including the quadruped—a four-legged running machine designed to mimic animal-like gaits. The quadruped demonstrated trotting, pacing, and bounding motions, achieving stable running speeds and seamless transitions between gaits by , which highlighted the lab's progress in scaling control algorithms across multiple limbs. Central to the lab's research during this period were strategies for maintaining in dynamic environments, emphasizing subsystems for . Vertical force was employed to regulate hopping height and ensure consistent ground reaction forces during stance phases, while body attitude adjustment utilized differential leg thrusts and hip torques to stabilize and counteract disturbances. These strategies, generalized from one-legged to multi-legged platforms, drew inspiration from biomechanical data on like and humans to achieve symmetric, energy-efficient motion.

Professional career

Founding and leading Boston Dynamics

In 1992, Marc Raibert founded as a spin-off from the Leg Laboratory, where he had previously directed research on dynamic legged systems; the new company initially concentrated on advanced simulation tools and research and development to bridge academic innovations with practical applications. Raibert served as CEO from 1992 until 2019, guiding the organization through its evolution from a research-focused entity to a leader in mobile , securing substantial funding from the and other government and private sources to support projects spanning and civilian automation. He became chairman in 2020 and held that role until 2022. Under his leadership, emphasized robust, terrain-adaptive machines, leveraging early contracts to pioneer technologies that could operate in unstructured environments beyond the capabilities of wheeled or tracked vehicles. Key milestones during Raibert's tenure highlighted the company's progress in legged . In 2005, unveiled , a quadruped capable of carrying heavy loads across rough at speeds up to 4 miles per hour while maintaining balance on slopes and uneven ground, funded primarily by for potential military resupply roles. This was followed in 2013 by Atlas, an advanced developed specifically for the Challenge, designed to perform complex manipulation tasks in disaster-response scenarios, such as navigating debris and using tools. In 2017, the company introduced , a wheeled-and-legged optimized for warehouse environments, enabling efficient palletizing and material handling with a payload capacity of up to 15 kilograms per arm. These developments underscored Raibert's vision of integrating dynamic control systems—rooted in his Leg Lab work—for real-world deployment. Raibert's strategic oversight also facilitated Boston Dynamics' shift toward commercialization amid multiple ownership changes. Acquired by Google in 2013 to bolster its robotics portfolio, the company retained operational independence under Raibert, allowing continued innovation in advanced mobility. In 2017, SoftBank purchased the firm from Alphabet (Google's parent), providing resources to accelerate product maturation without military constraints. By 2019, this culminated in the commercial launch of Spot, a versatile quadruped robot for industrial inspection and data collection, marking Boston Dynamics' entry into the consumer market with over 400 units deployed initially. The 2021 acquisition by Hyundai Motor Group for $1.1 billion further aligned the company with automotive and logistics applications, where Raibert actively championed the transition from prototypes to scalable, revenue-generating products before transitioning from chairman in 2022.

Creation of Boston Dynamics AI Institute

In 2022, following Motor Group's acquisition of in 2021, Marc Raibert transitioned from his role as chairman of the company to establish the AI Institute as an independent research organization dedicated to advancing in . The institute, headquartered in , received an initial investment exceeding $400 million from and to support long-term fundamental research. Raibert serves as , leveraging his decades of at to guide the institute's focus on integrating AI with robotic systems for real-world applications. The institute's mission centers on tackling core challenges in AI-robotics integration, including , , and human-robot , to develop smarter autonomous systems capable of operating in complex, unstructured environments. Key research areas encompass cognitive intelligence for generalization and , athletic intelligence for dynamic and , and organic hardware mimicking human capabilities, all aimed at creating agile, perceptive, and safer machines. Initial projects have emphasized techniques; for instance, in January 2024, the institute demonstrated advancements in whole-body using its robot to handle heavy tires through sampling-based optimization and learning algorithms. To accelerate progress, the AI Institute—now operating as the and AI Institute (RAI)—has pursued collaborations with and academic institutions. A notable announced on February 5, 2025, involves applying to enhance the electric humanoid robot, targeting sim-to-real transfer for agile locomotion, loco-manipulation tasks like operating doors and levers, and full-body contact strategies for dynamic behaviors. Raibert has emphasized that this work will expand humanoid capabilities by broadening skillsets and optimizing skill acquisition processes. The institute continues to seek partnerships with universities and corporate labs to address ethical considerations and societal impacts of advanced . In 2025, the RAI Institute expanded its initiatives, including a collaboration with to attract top talent in AI-robotics research (announced September 2025) and exploration of generative AI for solving complex robotics problems, as highlighted in Raibert's July 2025 interviews. Additionally, the institute launched a public pop-up robot lab at CambridgeSide mall in summer 2025 to demonstrate advancements and engage the community.

Scientific contributions

Advancements in dynamic legged locomotion

Marc Raibert's research pioneered dynamic legged locomotion, a where robots achieve and mobility through active mechanisms rather than relying on static stability, drawing inspiration from the efficient, energy-conserving gaits observed in . Unlike static walkers that maintain multiple points of contact to prevent tipping, dynamic systems operate near the edge of , using rapid and adjustments to sustain periodic motions such as hopping or running. This approach emphasizes the separation of into components—height, speed, and —allowing legged machines to traverse uneven terrain with agility and robustness. Central to Raibert's framework are three key principles applied across one-legged, bipedal, and quadrupedal systems. Vertical hopping regulates height by modulating during the stance to compensate for energy losses, ensuring consistent flight trajectories; for instance, in one-legged , this involves adjusting the delivered by the to maintain a desired height. Forward speed is achieved by positioning the foot relative to the during the flight , with the angle at determining propulsion—earlier placement accelerates forward motion, while later placement decelerates it. stability corrects for and roll disturbances using hip torques or differential in multi-legged configurations, enabling the to remain upright even under external perturbations, as demonstrated in early bipedal prototypes that bounded at speeds up to 1.8 m/s. These principles generalize from the simplest one-legged to more complex quadrupeds, where pairs coordinate to mimic trotting or galloping gaits. Raibert's work evolved from theoretical models developed starting in 1980 at , where he analyzed ballistic hopping in two dimensions as part of his research in the newly established Leg Laboratory, to physical prototypes in the at MIT's Leg Laboratory. Early simulations explored resonant oscillations in spring-mass systems, leading to the construction of a one-legged planar machine in 1980 that achieved stable hopping at 1.2 m/s, followed by a three-dimensional version in 1983 capable of running at 2.2 m/s while balancing on one leg. By the mid-, this progressed to bipedal and quadrupedal designs, including a 35 kg four-legged that executed dynamic like pronking. A hallmark of in these systems is the approximate of stance and flight times, which simplifies control by aligning the periods of ground contact and aerial phases; mathematically, for a symmetric , stance duration t_s \approx t_f, where t_f = 2\sqrt{2h/g} (with h as hop and g as ), ensuring the center of mass returns to the same horizontal position relative to the foot at each touchdown. This relation, derived from in the flight phase, facilitated robust locomotion without precise timing synchronization. Raibert's principles have profoundly influenced modern , providing the foundational strategies for agile maneuvers in advanced legged platforms, such as backflips and in and quadruped robots. These concepts underpin the dynamic stability seen in systems like the Atlas and quadruped, enabling real-world applications in inspection and exploration.

Key patents in robotics

Marc Raibert has been a prolific inventor in robotics, contributing to numerous patents that underpin advancements in legged locomotion and actuator technologies, with listings on platforms like Justia Patents showing at least 18 granted under his name as inventor or co-inventor. These inventions focus on enabling dynamic, stable motion in robotic systems through innovative control and mechanical designs. One of Raibert's influential patents is US8126592B2, titled "Actuator system," issued in 2012 and assigned to Boston Dynamics. This patent describes an actuator subsystem for robotic or bionic linkages, featuring at least two actuators per joint—one for high-power output and another for compliance—allowing robots to achieve both forceful movements and adaptive responses to terrain. The design incorporates hydraulic or pneumatic elements that provide on-demand power while enabling energy storage and release, crucial for dynamic legged devices like quadrupeds to maintain balance during irregular locomotion. This compliant actuation approach has been integral to technologies enabling robots to navigate rough environments with stability. Another key patent is US6484068B1, titled "Robot apparatus and for controlling of robot device," issued in 2002 and jointly assigned to Sony Corporation and . Co-invented by Raibert along with Robert Playter and others, it outlines a structure using a four-point link mechanism with a as an elastic member to ensure a linear trajectory for the foot during jumps. The emphasizes independent of vertical and horizontal forces: vertical adjusts hopping height and via spring extension, while horizontal manages forward and directional changes, preventing tipping in multi-legged robots. This supports hopping in devices simulating animal-like gaits, building on Raibert's foundational research in dynamic balance. Raibert's early work in the 1980s at Mellon and , including filings related to running machines, laid the groundwork for later patents on legged systems, though specific grants from that era are less documented in public databases. Overall, his portfolio, exceeding dozens of filings through , has protected core technologies such as hydraulic actuators in products like the quadruped robot, which relies on high-force, compliant systems for load-carrying over uneven terrain. These patents have facilitated the commercialization of robust, agile , influencing defense and exploration applications.

Awards and honors

Professional recognitions

Marc Raibert is a Founding Fellow of the Association for the Advancement of Artificial Intelligence (AAAI), an honor bestowed for his pioneering work at the intersection of artificial intelligence and robotics. In 2008, he was elected to the National Academy of Engineering for his biomechanically motivated analysis, synthesis, control, and application of multi-legged robots, highlighting his foundational research during his academic tenure at institutions like Carnegie Mellon University and MIT. Raibert received the IEEE Pioneer in Robotics and Automation Award in 2022, recognizing his lifelong contributions to the development of dynamic legged locomotion and mobile systems. Furthermore, Raibert has served in advisory capacities for academic and industry initiatives, including as a mentor and expert for the MassRobotics Accelerator program, supporting emerging talent in the field.

Recent accolades

In 2022, Marc Raibert received the Joseph F. Engelberger Award in the Technology category from the Association for Advancing Automation (formerly the Robotics Industries Association), recognizing his foundational contributions to dynamic legged robots and leadership in advancing innovation through . Raibert was named one of TIME magazine's 100 Most Influential People in in 2023, highlighted for his role in developing agile, animal-inspired robots that integrate to perform complex tasks in real-world environments, underscoring his influence on the convergence of and . In October 2024, the IEEE and Society announced that Raibert would receive the 2025 IEEE and Award for pioneering and leading the field of dynamic legged locomotion, an honor he accepted at the 2025 Conference on and in , reflecting his ongoing impact on mobile amid his work at the Boston Dynamics Institute.

Media and cultural impact

Public appearances and talks

Marc Raibert delivered a notable discussion at TEDxMIT in April 2022 alongside Daniela Rus, director of MIT's and Laboratory, where they explored the evolution of and showcased capabilities of ' humanoid robot Atlas, including dynamic movements akin to demonstrated in the company's public videos from the . Raibert has been a prominent keynote speaker at IEEE conferences, including the 2013 International Conference on Intelligent Robots and Systems (IROS) in , where he presented updates on legged robots since the development of , and the 2023 International Conference on Robotics and Automation (ICRA) in , focusing on the integration of to enable more autonomous robotic systems. At EmTech MIT 2023, organized by , Raibert spoke on the future of and , drawing from his experience founding the AI Institute to discuss challenges in creating intelligent, athletic machines capable of real-world tasks. In September 2016, Raibert demonstrated the quadruped robot at Disrupt SF, highlighting its agility in navigating obstacles and potential for commercial applications such as inspection and delivery in confined spaces. Raibert provided insights into his career and the trajectory of robotics in a 2023 IEEE Spectrum interview, reflecting on transitions from dynamic locomotion research to AI-driven autonomy while leading the Boston Dynamics AI Institute. In the inaugural episode of the Automated podcast, released in September 2025 by the Association for Advancing Automation, Raibert discussed his half-century of contributions to robotics, from early MIT work to current efforts in physical AI, emphasizing persistent innovation amid technological shifts. In October 2024, at the AI + Robotics Summit in Washington, D.C., Raibert delivered a keynote titled "The Next 100 Years of Robotics," envisioning long-term advancements in AI-integrated mobile robots. At DeepFest 2025 in Riyadh, Saudi Arabia, in February 2025, Raibert participated in a fireside chat on the future of robotics and AI, discussing ethical implications and breakthroughs in physical intelligence.

Depictions in fiction and media

Marc Raibert and the robots developed under his leadership at have appeared in several documentaries highlighting advancements in . In the 2021 60 Minutes segment ": Inside the workshop where robots of the future are being built," Raibert discusses the company's and quadruped robots, including Atlas, emphasizing their potential to mimic animal and human movement. Similarly, Raibert featured in the 2013 episode "Making Stuff Wilder," where he showcased dynamic legged robots and their engineering challenges. A 2017 virtual reality documentary series by Within, titled "," explored the company's lab environment, with Raibert defending the realistic portrayal of robots' capabilities against public misconceptions of them as overly aggressive. Boston Dynamics' demonstration videos have frequently gone viral, amplifying Raibert's influence in popular media. The 2017 video of the Atlas robot performing a backflip garnered millions of views on YouTube and was widely shared across platforms, with coverage often attributing the breakthrough to Raibert's foundational work in dynamic locomotion. These clips, including earlier 2016 footage of Atlas navigating rough terrain, have shaped public perceptions of robotics, blending awe with occasional unease about agile machines. Raibert's creations have inspired fictional portrayals of robots in media, particularly emphasizing quadruped and humanoid agility. The 2017 Black Mirror episode "Metalhead" features relentless robotic "dogs" hunting humans in a post-apocalyptic setting, directly inspired by ' and prototypes, as confirmed by series creator , who cited the company's viral videos as a key influence. In the 2021 film , director drew from ' dancing robots to design the agile android protagonists, noting how the real demonstrations blurred lines between and emerging technology. While Raibert himself has limited direct roles in fiction, his robots' feats have contributed to sci-fi tropes of versatile, terrain-adapting machines in films and books exploring human-robot coexistence. Raibert is frequently depicted in news media as a "robotics visionary," underscoring his cultural impact through ' innovations. A 2023 TIME profile included him in the 100 Most Influential People in , praising his role in advancing practical, dynamic robots that bridge research and real-world applications. Similarly, a 2024 IEEE announcement for his Robotics and Technical Field Award described his "visionary approach" to legged locomotion as transformative, influencing global discussions on and automation. These portrayals highlight limited direct fictional cameos but emphasize his indirect shaping of narratives around agile, autonomous machines.