Publications

Buerger, Stephen B.; Hobart, Clinton G.; Spencer, Steven; Kuehl, Michael K.; Mazumdar, Anirban; quigley, morgan q.; smith, jesper s.; bertrand, sylvain b.; pratt, jerry p.

Abstract not provided.

IEEE Transactions on Robotics

Hobart, Clinton G.; Mazumdar, Anirban; Spencer, Steven; Quigley, Morgan; Smith, Jesper P.; Bertrand, Sylvain; Pratt, Jerry; Kuehl, Michael K.; Buerger, Stephen B.

Legged humanoid robots promise revolutionary mobility and effectiveness in environments built for humans. However, inefficient use of energy significantly limits their practical adoption. The humanoid biped walking anthropomorphic novelly-driven efficient robot for emergency response (WANDERER) achieves versatile, efficient mobility, and high endurance via novel drive-trains and passive joint mechanisms. Results of a test in which WANDERER walked for more than 4 h and covered 2.8 km on a treadmill, are presented. Results of laboratory experiments showing even more efficient walking are also presented and analyzed in this article. WANDERER's energetic performance and endurance are believed to exceed the prior literature in human-scale humanoid robots. This article describes WANDERER, the analytical methods and innovations that enable its design, and system-level energy efficiency results.

IEEE Sensors Journal

Mazumdar, Anirban; Chen, Yi; van Bloemen Waanders, Bart G.; Brooks, Carlton F.; Kuehl, Michael K.; Nemer, Martin N.

Epoxies and resins can require careful temperature sensing and control in order to monitor and prevent degradation. To sense the temperature inside a mold, it is desirable to utilize a small, wireless sensing element. In this paper, we describe a new architecture for wireless temperature sensing and closed-loop temperature control of exothermic polymers. This architecture is the first to utilize magnetic field estimates of the temperature of permanent magnets within a temperature feedback control loop. We further improve performance and applicability by demonstrating sensing performance at relevant temperatures, incorporating a cure estimator, and implementing a nonlinear temperature controller. This novel architecture enables unique experimental results featuring closed-loop control of an exothermic resin without any physical connection to the inside of the mold. In this paper, we describe each of the unique features of this approach, including magnetic field-based temperature sensing, extended Kalman filtering for cure state estimation, and nonlinear feedback control over time-varying temperature trajectories. We use experimental results to demonstrate how low-cost permanent magnets can provide wireless temperature sensing up to ∼ 90°C. In addition, we use a polymer cure-control testbed to illustrate how internal temperature sensing can provide improved temperature control over both short and long time-scales. This wireless temperature sensing and control architecture holds value for a range of manufacturing applications.

IEEE Robotics and Automation Letters

Mazumdar, Anirban; Spencer, Steven; Hobart, Clinton G.; Dabling, Jeffrey D.; Blada, Timothy; Dullea, Kevin; Kuehl, Michael K.; Buerger, Stephen B.

This paper describes the design and performance of a synthetic rope on sheave drive system. This system uses synthetic ropes instead of steel cables to achieve low weight and a compact form factor. We demonstrate how this system is capable of 28-Hz torque control bandwidth, 95% efficiency, and quiet operation, making it ideal for use on legged robots and other dynamic physically interactive systems. Component geometry and tailored maintenance procedures are used to achieve high endurance. Endurance tests based on walking data predict that the ropes will survive roughly 247,000 cycles when used on large (90 kg), fully actuated bipedal robot systems. The drive systems have been incorporated into two novel bipedal robots capable of three-dimensional unsupported walking. Robot data illustrate effective torque tracking and nearly silent operation. Finally, comparisons with alternative transmission designs illustrate the size, weight, and endurance advantages of using this type of synthetic rope drive system.

Mazumdar, Anirban; Spencer, Steven; Hobart, Clinton G.; Kuehl, Michael K.; Brunson, Gregory; Coleman, Nadia; Buerger, Stephen B.

Abstract not provided.

ASME 2016 Dynamic Systems and Control Conference, DSCC 2016

Mazumdar, Anirban; Spencer, Steven; Hobart, Clinton G.; Kuehl, Michael K.; Brunson, Gregory; Coleman, Nadia; Buerger, Stephen B.

Electric motors are a popular choice for mobile robots because they can provide high peak efficiencies, high speeds, and quiet operation. However, the continuous torque performance of these actuators is thermally limited due to joule heating, which can ultimately cause insulation breakdown. In this work we illustrate how motor housing design and active cooling can be used to significantly improve the ability of the motor to transfer heat to the environment. This can increase continuous torque density and reduce energy consumption. We present a novel housing design for brushless DC motors that provides improved heat transfer. This design achieves a 50% increase in heat transfer over a nominal design. Additionally, forced air or water cooling can be easily added to this configuration. Forced convection increases heat transfer over the nominal design by 79%with forced air and 107% with pumped water. Finally, we show how increased heat transfer reduces power consumption and we demonstrate that strategically spending energy on cooling can provide net energy savings of 4%-6%.

Proceedings - IEEE International Conference on Robotics and Automation

Mazumdar, Anirban; Spencer, Steven; Salton, Jonathan R.; Hobart, Clinton G.; Love, Joshua A.; Dullea, Kevin; Kuehl, Michael K.; Blada, Timothy; Quigley, Morgan; Smith, Jesper; Bertrand, Sylvain; Wu, Tingfan; Pratt, Jerry; Buerger, Stephen B.

In this paper we introduce STEPPR (Sandia Transmission-Efficient Prototype Promoting Research), a bipedal robot designed to explore efficient bipedal walking. The initial iteration of this robot achieves efficient motions through powerful electromagnetic actuators and highly back-drivable synthetic rope transmissions. We show how the addition of parallel elastic elements at select joints is predicted to provide substantial energetic benefits: reducing cost of transport by 30 to 50 percent. Two joints in particular, hip roll and ankle pitch, reduce dissipated power over three very different gait types: human walking, human-like robot walking, and crouched robot walking. Joint springs based on this analysis are tested and validated experimentally. Finally, this paper concludes with the design of two unique parallel spring mechanisms to be added to the current STEPPR robot in order to provide improved locomotive efficiency.

Rempe, Susan R.; Rogers, David M.; Buerger, Stephen B.; Kuehl, Michael K.; Hatch, Anson H.; Abhyankar, Vinay V.; Mai, Junyu M.; Dirk, Shawn M.; Brozik, Susan M.; De Sapio, Vincent D.; Schoeniger, Joseph S.

Sandia's scientific and engineering expertise in the fields of computational biology, high-performance prosthetic limbs, biodetection, and bioinformatics has been applied to specific problems at the forefront of cancer research. Molecular modeling was employed to design stable mutations of the enzyme L-asparaginase with improved selectivity for asparagine over other amino acids with the potential for improved cancer chemotherapy. New electrospun polymer composites with improved electrical conductivity and mechanical compliance have been demonstrated with the promise of direct interfacing between the peripheral nervous system and the control electronics of advanced prosthetics. The capture of rare circulating tumor cells has been demonstrated on a microfluidic chip produced with a versatile fabrication processes capable of integration with existing lab-on-a-chip and biosensor technology. And software tools have been developed to increase the calculation speed of clustered heat maps for the display of relationships in large arrays of protein data. All these projects were carried out in collaboration with researchers at the University of Texas M. D. Anderson Cancer Center in Houston, TX.