With human exploration of the moon and Mars on the horizon, research considerations for space suit redesign have surfaced. The portable life support system (PLSS) used in conjunction with the space suit during the Apollo missions may have influenced the dynamic balance of the gait pattern. This investigation explored potential issues with the PLSS design that may arise during the Mars exploration. A better understanding of how the location of the PLSS load influences the dynamic stability of the gait pattern may provide insight, such that space missions may have more productive missions with a smaller risk of injury and damaging equipment while falling. We explored the influence the PLSS load position had on the dynamic stability of the walking pattern. While walking, participants wore a device built to simulate possible PLSS load configurations. Floquet and Lyapunov analysis techniques were used to quantify the dynamic stability of the gait pattern. The dynamic stability of the gait pattern was influenced by the position of load. PLSS loads that are placed high and forward on the torso resulted in less dynamically stable walking patterns than loads placed evenly and low on the torso. Furthermore, the kinematic results demonstrated that all joints of the lower extremity may be important for adjusting to different load placements and maintaining dynamic stability. Space scientists and engineers may want to consider PLSS designs that distribute loads evenly and low, and space suit designs that will not limit the sagittal plane range of motion at the lower extremity joints.
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September 2009
Research Papers
Walking in Simulated Martian Gravity: Influence of the Portable Life Support System’s Design on Dynamic Stability
Melissa M. Scott-Pandorf,
Melissa M. Scott-Pandorf
Laboratory of Integrated Physiology, Health, and Human Performance,
e-mail: mmscottp@gmail.com
University of Houston
, Houston, TX 77204
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Daniel P. O’Connor,
Daniel P. O’Connor
Laboratory of Integrated Physiology, Health, and Human Performance,
University of Houston
, Houston, TX 77204
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Charles S. Layne,
Charles S. Layne
Laboratory of Integrated Physiology, Health, and Human Performance,
University of Houston
, Houston, TX 77204
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Krešimir Josić,
Krešimir Josić
Department of Mathematics,
University of Houston
, Houston, TX 77204
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Max J. Kurz
Max J. Kurz
Laboratory of Integrated Physiology, Health, and Human Performance,
e-mail: mkurz@unmc.edu
University of Houston
, Houston, TX 77204; Laboratory of Motion Analysis, Munroe-Meyer Institute, University of Nebraska Medical Center
, Omaha, NE 68198-5450
Search for other works by this author on:
Melissa M. Scott-Pandorf
Laboratory of Integrated Physiology, Health, and Human Performance,
University of Houston
, Houston, TX 77204e-mail: mmscottp@gmail.com
Daniel P. O’Connor
Laboratory of Integrated Physiology, Health, and Human Performance,
University of Houston
, Houston, TX 77204
Charles S. Layne
Laboratory of Integrated Physiology, Health, and Human Performance,
University of Houston
, Houston, TX 77204
Krešimir Josić
Department of Mathematics,
University of Houston
, Houston, TX 77204
Max J. Kurz
Laboratory of Integrated Physiology, Health, and Human Performance,
University of Houston
, Houston, TX 77204; Laboratory of Motion Analysis, Munroe-Meyer Institute, University of Nebraska Medical Center
, Omaha, NE 68198-5450e-mail: mkurz@unmc.edu
J Biomech Eng. Sep 2009, 131(9): 091005 (10 pages)
Published Online: August 5, 2009
Article history
Received:
August 22, 2008
Revised:
May 1, 2009
Published:
August 5, 2009
Citation
Scott-Pandorf, M. M., O’Connor, D. P., Layne, C. S., Josić, K., and Kurz, M. J. (August 5, 2009). "Walking in Simulated Martian Gravity: Influence of the Portable Life Support System’s Design on Dynamic Stability." ASME. J Biomech Eng. September 2009; 131(9): 091005. https://doi.org/10.1115/1.3148465
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