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Human Engineering Research Laboratories 2

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HERL
OriginPittsburgh, Pennsylvania, United States
Years active1994–present
Partners
Websiteherl.pitt.edu

The Human Engineering Research Laboratories (HERL) is a joint research institution under the U.S. Department of Veterans Affairs (VA), the University of Pittsburgh, and the University of Pittsburgh Medical Center (UPMC) that specializes in continuously improving the mobility and function of people with disabilities through advanced engineering in clinical research and medical rehabilitation.

Located in Pittsburgh, PA, HERL acts as the VA's lead laboratory for assistive technology testing and research. It includes the VA Center for Wheelchairs and Assistive Robotics Engineering. July 23rd, 2024 will mark the laboratories' 30th anniversary.

History

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In 1980, Director Rory Cooper, PhD, a U.S. Army veteran, began designing assistive technology when a spinal cord injury during his military service left him partially paralyzed at the age of 20. By 1989, Cooper was an assistant bioengineering professor at Sacramento State University, which helped pave the way for the eventual creation of HERL in 1994. The labs were initially located in an old VA facility on the _____, and were moved three times before expanding into the current site at Bakery Square.

Research

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A HEL researcher and an Army soldier conduct tests inside a M113 Armored Personnel Carrier.
HEL researcher Georges Garinther (left) measures background noise as part of a communications test inside of a M113 armored personnel carrier.

The Human Engineering Laboratory was responsible for providing the Army with human factors engineering support in the design of combat vehicles, aviation, artillery air defense, weapons, equipment, and more.[1] Human factors engineering places more support in considering the needs and convenience of the operator early in the design phase of weapons and equipment in order to reduce training time, labor, and human error. Researchers at HEL and its field offices conducted human performance tests at Aberdeen Proving Ground or other military installations and later work with material developers and contractors in the material acquisition process to apply their findings in material design.[2] For these human performance tests, researchers brought in non-commissioned officers from the Army’s major military specialties as well as regular combat troops and soldiers who completed basic training to help evaluate how an equipment would fare in a battlefield environment.[3]

HEL’s research covered areas such as the following: acoustics research, communications-electronics, fire support control, forward area supply and transfer, human visual aspects, learning and memory, logistics systems, military operations on urbanized terrain, physiological and gender factors, robotics, selective attention, stress research, systems integration, target acquisition, test bed vehicle development, text and graphic displays, visual performance, and visual search.[4]

HEL initially had three directorates to govern its research and responsibilities. The Behavioral Research Directorate managed basic human factors research that studied systems from a soldier’s point of view. Researchers focused on factors such as vision, hearing, endurance, stress, strength, height, and weight, and recorded their findings in a large data bank that other Defense agencies could access. The Systems Performance and Concepts Directorate maintained research teams that performed tests on various weapons and equipment. Considering everything from noise levels produced by a gun to the ease with which an operator could reach a vehicle’s brake pedal, researchers in this directorate evaluated the man–machine interface for gaps in safety and efficiency. Finally, the Human Engineering Applications Directorate worked directly with military installations to ensure that all projects took human factors engineering into account during the design process. In addition to aiding the design and development of military technologies, HEL researchers also conducted troubleshooting to identify human engineering problems whenever soldiers in the field reported issues with operating or maintaining a piece of equipment.[5]

By the late 1980s, HEL was reorganized and divided into six technical divisions: Aviation and Air Defense, Behavioral Research, Close Combat-Light and Heavy, Combat Service Support, Fire Support and Target Acquisition, and Field Support.[6]

Aviation and Air Defense

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The Aviation and Air Defense Division featured teams of engineers, computer scientists, and psychologists that worked together to enhance the operator interface of aviation and air defense material. The division’s three main teams—the Aviation team, Air Defense team, and Systems Simulation team—applied human factors engineering to the Army’s combined arms counter-air approach to air defense.[6]

Behavioral Research

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The Behavioral Research Division researched the psychological and psychophysiological capabilities and limitations of Soldiers. Topics of particular interest included the soldier–machine interface, performance in stressful environments, and human information processing. Within the division, four major teams carried out the research. The Auditory Performance team studied the mechanisms by which noises affect soldiers. The Remote Operations and Information Processing team conducted research that improved the effectiveness of systems that rely on indirect or altered presentations of visual information. The Stress and Performance team generated performance data that quantified the effects of stress. The Visual Performance team examined new methods to enhance how soldiers process visual stimuli, such as conducting research into eye movements.[6]

Close Combat - Light and Heavy

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The Close Combat–Light and Heavy Division evaluated Army weapons, clothing, equipment, and combat vehicles to increase the individual’s survivability and efficacy on the battlefield. The Individual Soldier and Equipment team focused on individual weapons including small arms and light antitank weapons as well as clothing and ancillary equipment such as backpacks and sleeping bags. The Nuclear Biological Chemical Defense team oversaw protective equipment such as chemical protective overgarments, masks, and test kits. The Armor team was responsible for human factors engineering considerations in tracked and wheeled combat vehicles, such as tanks, trucks, and jeeps. The Modeling Applications and Analysis team and the Systems Integration team developed ergonomic models and analysis technologies, respectively, that helped inform new designs.[6]

Combat Service Support

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The Combat Service Support Division consisted of teams that conducted research related to artificial intelligence and robotics. The Robotic Sciences and Military Applications team explored robotic applications to improve survivability in adverse environments, the Intelligence Machine Interface team developed the knowledge base for interfacing the soldier with various robotic devices, and the Tactical Logistics Systems team handled the application of AI to logistical systems.[6]

Fire Support and Target Acquisition

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The Fire Support and Target Acquisition Division directed efforts to improve the quality and quantity of artillery fire support while also simplifying the tasks necessary to provide this artillery fire support. Researchers often utilized commercially available test bed technologies to evaluate solutions to soldier and machine interface problems. The Test Bed Development team created new systems to evaluate concepts intended to reduce crew size and training requirements as well as increase survivability and firing platform responsiveness. The Combined Arms Command and Control team investigated new methods to simplify the planning of supporting artillery fires and enhance their responsiveness by improving the command and control interface. The Studies and Concepts team devised new fire support systems concepts, which enabled the team to define fire support system errors and develop a novel Global Positioning System artillery fuze concept.[6]

Field Support

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The Field Support Division consisted of 16 field detachments and offices across AMC. Researchers assigned to these detachments and field offices provided human factors advice to material developers and prepared Manpower and Personnel Integration assessments of Army material systems. The division also hosted three developmental shop facilities at Aberdeen which provided direct engineering and prototype fabrication support to researchers.[6]

HELBAT

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As part of its mission, HEL managed the Human Engineering Laboratory Battalion Artillery Test (HELBAT) program, a series of field experiments designed to study the capabilities of the Army’s field artillery battalions. Conducted during the Army’s operational readiness tests, the HELBAT not only enabled HEL to isolate and identify sources of human error during artillery fire but also provided researchers with an opportunity to improve how the artillery evaluations were conducted. Furthermore, it allowed the Army to establish a systematic and repeatable procedure for collecting reliable data of artillery operations on the battalion scale.[7]

In 1969, HEL launched HELBAT I, which took place at Fort Hood with battalions of M109 self-propelled 155mm howitzers from the 1st Armored Division.[7] Although the first HELBAT was limited to the study of surprise predicted fire, it revealed that the biggest source of error, about 50 percent of the total system error, was the forward observer’s inability to locate themselves and their targets accurately. The test found that soldiers often made errors when estimating range at long distances and had difficulty reading the M2 artillery compass.[7][8] Following HELBAT I, HEL worked with the Frankford Arsenal to develop a laser range finder for the forward observer that could not only measure distances but also locate targets using an azimuth scale. Two years later, HEL conducted HELBAT II, which saw a reduction in average target location errors from 490 meters to 21 meters with the laser range finder.[7][8]

Improvements to other aspects of the artillery were made in subsequent HELBATs. During the 1970s, HEL conducted five more HELBATs, and HELBAT VIII took place in 1981.[9] HEL also conducted similar field tests on armor systems, infantry systems, and rotorcraft systems during the HEL Armor System Test (HELAST), the HEL infantry system test (HELIST), and the HEL helicopter armament test (HELHAT), respectively.[10]

Projects

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The Human Engineering Laboratory was involved in the development or testing of the following technologies:

  • Audio Tactile Display (ATD): In 1976, HEL developed the world’s first electronic calculator for the visually impaired.[11][12]
  • Auditory Hazard Assessment Algorithm for Humans (AHAAH): In 1987, HEL developed the first mathematical model of the human auditory system that can assess the noise hazard for the entire range of impulse noise relevant to the Army.[13]
  • Beretta 92SB: In response to the increasing number of female troops entering the service in the 1970s, HEL conducted testing on a wide range of handguns in order to find a suitable replacement for the M1911 pistol, the standard issue sidearm for the Army since 1911.[14] The data collected by HEL researchers helped influence the Army’s decision in 1985 to adopt the lighter Beretta 92SB as the new designated service pistol.[3][15]
  • FIM-43 Redeye: Starting in 1958, HEL provided human factors engineering support in the development of the Redeye anti-aircraft weapon system.[16]
  • Field Material Handling Robot (FMR): In cooperation with the National Institute of Standards and Technology and members of industry, HEL developed a six-axis, semi-autonomous robot during the late 1980s that was capable of lifting cargo as heavy as 1800kg as high as 9 meters.[17] Designed for loading and unloading operations at Army supply nodes, the FMR was the first of its kind and was recognized as the largest, most powerful robot in the world at the time.[6][18]
  • Integrated Helicopter Control System: During the 1970s, HEL invented a helicopter control system that enabled a pilot to fly the aircraft one-handed. The system debuted in 1976 on a OH-58 helicopter.[19][20][21]
  • M41 Walker Bulldog: During the mid-1950s, HEL performed a human factors evaluation of the M41A1 tank’s 76mm gun.[22]
  • M72 LAW: Starting in 1958, HEL provided human factors engineering support directed toward evaluating the configuration of the weapon system as well as address its sighting and noise problems.[16][23][24]
  • MGM-18 Lacrosse: During the late 1950s, HEL performed a human factors evaluation of the surface-to-surface guided missile system.[22][16] A total of 75 specific improvements were made, such as more efficient designs for cable connectors and knobs.[10]
  • MGM-29 Sergeant: Starting in 1957, HEL provided human factors engineering support in the development of the SERGEANT Artillery Guided Missile System.[16]
  • MIM-23 Hawk: In 1956, HEL was requested by Redstone Arsenal to monitor the human factors engineering aspect of the missile development.[22][16]
  • MIM-104 Patriot: Beginning in the mid-1960s, HEL supported the development of the Patriot system in various ways. HEL researchers created a system that faithfully simulated the Patriot engagement control console and devised solutions to its man-machine interface problems. In addition to facilitating the restructuring of the Patriot system’s display and controls, the simulator also helped train air defense console operators in testing the Patriot system. Various other human factors improvements were also made thanks to HEL’s efforts, including an automatic designation of priority threats which reduced operator reaction time, an enhanced layout of the graphical and tabular displays, and improved control coding and labeling.[25]
  • Nike Zeus: During the early 1960s, HEL provided human factors engineering support during the development of the Nike Zeus.[25]
  • PGM-19 Jupiter: Starting in 1958, HEL provided human factors engineering support in the development of the JUPITER Intermediate Range Ballistic Missile System. Although most of the design work was completed by this point, HEL’s efforts identified human factors requirements in the design of the system as well as possible design deficiencies.[16]

References

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  1. ^ Bailey, Virginia (May 1992). "Human Engineering Laboratory Director Retires". Army Research, Development & Acquisition Bulletin. Vol. 92, no. 3. p. 34.
  2. ^ Frezell, Thomas (September 1988). "U.S. Army Human Engineering Laboratory". Army Research, Development & Acquisition Bulletin. pp. 1–4.
  3. ^ a b Morring, Jr., Frank (November 13, 1988). "Where Army Puts Equipment Through Its Paces". The New York Times.
  4. ^ A Small Business Guide. U.S. Army Laboratory Command. 1987. p. 30.
  5. ^ Bant, Bruce (February 1980). "Human Engineering: Matching Up Man, Machine, Mission". Soldiers. Vol. 35, no. 2. pp. 24–26.
  6. ^ a b c d e f g h U.S. Army Human Engineering Laboratory. 1992.
  7. ^ a b c d Horley, Gary (1 January 1972). Human Engineering Laboratory Battalion Artillery Tests (HELBAT) (PDF) (Report). Human Engineering Laboratory. Report No. AD-750333 – via Defense Technical Information Center.
  8. ^ a b Bant, Bruce (March 1980). "Putting the HEL Into HELBAT". Soldiers. Vol. 35, no. 3. pp. 39–41.
  9. ^ Downs, Alan; Hirschberg, Morton (December 1982). A Sensitivity Analysis of the BRL Message Processing Model (BRLMPM) Data Inputs (PDF) (Report). Ballistic Research Laboratory. Report No. AD-A123355 – via Defense Technical Information Center.
  10. ^ a b Weisz, John (1973). "Man & Machine". ARMY Magazine. Vol. 23, no. 6. pp. 47–50.
  11. ^ Blazie, Deanie; Cranmer, T.V. (November 1976). "An audio-tactile display". Behavior Research Methods & Instrumentation. 8 (6): 491–494. doi:10.3758/BF03202194. S2CID 62668513.
  12. ^ "Invention Earns Human Engineering Lab Engineer 'Outstanding Young Men' Honor". Army Research and Development Newsmagazine. Vol. 17, no. 1. January 1978. p. 9.
  13. ^ Behring, Elizabeth (February 14, 2018). "Now hear this: Scientist pioneered noise research". Redstone Rocket.
  14. ^ Thompson, Leroy (2011). The Beretta M9 Pistol. Bloomsbury Publishing. p. 14. ISBN 9781849088374.
  15. ^ U.S. Army Armament, Munitions and Chemical Command Annual Historical Review. Historical Office, U.S. Army Armament Materiel Readiness Command. 1983. p. 22.
  16. ^ a b c d e f U.S. Army Research Office (1959). Biological, Medical, Social and Behavioral Sciences and Operations Research. Vol. 1. pp. 169–195.
  17. ^ Johnson, Daniel; Szabo, Sander; McClellan, Jr., Harry (1991). "Towards an Autonomous Heavy Lift Robot for Field Applications". Proceedings of the 8th International Symposium on Automation and Robotics in Construction. CiteSeerX 10.1.1.15.305.
  18. ^ Davison, Dave (January 1991). "Expo Showcases Technology as Deterrence". Army Research, Development & Acquisition Bulletin. pp. 12–14.
  19. ^ "Helicopter Control System". United States Army Aviation Digest. Vol. 24, no. 5. May 1978. p. 29.
  20. ^ "HEL Integrated Helicopter Control System Debuts". Army Research and Development Newsmagazine. Vol. 19, no. 1. January 1978. p. 8.
  21. ^ "'Integrated Helicopter Control System' Benefits Cited". Army Research and Development Newsmagazine. Vol. 17. May 1976. p. 11.
  22. ^ a b c Second Annual Army Engineering Psychology Conference. Vol. 2. Office of the Chief of Research and Development. 1956. pp. 40–43.
  23. ^ Giordano, Dominick (August 1975). "Gunner Errors When Using the M72A2 LAW Sight" (PDF). Defense Technical Information Center. ADA016864. Archived (PDF) from the original on April 23, 2022.
  24. ^ Giordano, Dominick (November 1, 1976). "Simplified Procedures for Engaging Moving Targets with the M72A2 LAW". Defense Technical Information Center. ADA034418. Archived from the original on April 23, 2022.
  25. ^ a b Erickson, John; Kurtz, Gary (May 1991). "HEL and the Patriot Air Defense System". Army Research, Development & Acquisition Bulletin. pp. 5–7.