Sage Journals: Discover world-class research

Abstract

Objective

The purpose of this investigation was to elucidate the role of button-response complexity to targets in a response inhibition task.

Background

Response inhibition is the ability to correctly inhibit an overt response to a target. The U.S. military is actively pursuing development of armed, combat robots as a force multiplier, which may present challenges to operators of combat robots in the form of response inhibition errors.

Method

A total of 15 participants completed two 51-min versions of a modified sustained attention to response task (SART). Participants were outfitted with an electrocardiogram to index heart-rate variability and completed the NASA–Task Load Index (NASA-TLX) to index workload.

Results

The results demonstrated that the complex SART reduced errors of commission (4%) and slowed response times (874 ms) to correct Go targets relative to the simple SART (14%, 739 ms). The NASA-TLX did not show differences between the modified SARTs; however, heart-rate variability did demonstrate that Soldiers had an increased autonomic stress response to the complex SART.

Conclusion

Increasing the behavioral response requirement during a response inhibition task can decrease errors of commission; however, it comes at the cost of slower response times to target stimuli. Heart-rate variability may provide better insight into objective workload relative to subjective measures.

Application

The use of complex behavioral responses may provide a viable option to reduce potential “friendly fire” or collateral damage by Soldiers remotely engaging a target-rich environment.

Keywords

response inhibition motor control

Get full access to this article

View all access options for this article.

References

Ashley

E. A.

Niebauer

(2004). Cardiology explained. London, England: Remedica.

Ballinger

G. A.

(2004). Using generalized estimating equations for longitudinal data analysis. Organizational Research Methods, 7, 127–150.

Bender

A. D.

Filmer

H. L.

Garner

Naughtin

C. K.

Dux

P. E.

(2016). On the relationship between response selection and response inhibition: An individual differences approach. Attention, Perception, & Psychophysics, 78, 2420–2432.

Biggs

A. T.

(2017). How many bullets do you need? Contrasting and comparing behavioral outcomes and cognitive abilities when using a semiautomatic versus automatic firearm. American Journal of Psychology, 130, 439–453.

Biggs

A. T.

Cain

M. S.

Mitroff

S. R.

(2015). Cognitive training can reduce civilian casualties in a simulated shooting environment. Psychological Science, 26, 1164–1176.

Bray-Miners

Ste-Croix

Morton

(2012). Human-robot interaction literature review. Retrieved from http://www.dtic.mil/dtic/tr/fulltext/u2/a592508.pdf

Cheyne

J. A.

Carriere

J. S.

Smilek

(2009). Absent minds and absent agents: Attention-lapse induced alienation of agency. Consciousness and Cognition, 18, 481–493.

Clark

Blackwell

A. D.

Aron

A. R.

Turner

D. C.

Dowson

Robbins

T. W.

Sahakian

B. J.

(2007). Association between response inhibition and working memory in adult ADHD: A link to right frontal cortex pathology? Biological Psychiatry, 61, 1395–1401.

Dang

J. S.

Figueroa

I. J.

Helton

W. S.

(2018). You are measuring the decision to be fast, not inattention: The sustained attention to response task does not measure sustained attention. Experimental Brain Research, 236, 2255–2262.

10.

Feickert

(2005). The Army’s future combat system (FCS): Background and issues for Congress. Retrieved from https://digital.library.unt.edu/ark:/67531/metadc700916/m1/1/high_res_d/RL32888_2009Mar13.pdf

11.

Fitts

P. M.

(1954). The information capacity of the human motor system in controlling the amplitude of movement. Journal of Experimental Psychology, 47, 381–391.

12.

Friedman

N. P.

Miyake

(2004). The relations among inhibition and interference control functions: A latent-variable analysis. Journal of Experimental Psychology: General, 133, 101–135.

13.

Goldberger

J. J.

Challapalli

Waligora

Kadish

A. H.

Johnson

D. A.

Ahmed

M. W.

Inbar

(2000). Uncertainty principle of signal-averaged electrocardiography. Circulation, 101, 2909–2915.

14.

Gunn

D. V.

Warm

J. S.

Nelson

W. T.

Bolia

R. S.

Schumsky

D. A.

Corcoran

K. J.

(2005). Target acquisition with UAVs: Vigilance displays and advanced cuing interfaces. Human Factors: The Journal of the Human Factors and Ergonomics Society, 47, 488–497.

15.

Haas

G. A.

David

Haug

B. T.

(1996). Target acquisition and engagement from an unmanned ground vehicle: The robotics test bed of demo 1. Retrieved from http://www.dtic.mil/docs/citations/ADA308459

16.

Halekoh

Højsgaard

Yan

(2006). The R package geepack for generalized estimating equations. Journal of Statistical Software, 15(2), 1–11.

17.

Hart

S. G.

Staveland

L. E.

(1988). Development of NASA-TLX (task load index): Results of empirical and theoretical research. Advances in Psychology, 52, 139–183.

18.

Head

Helton

W. S.

(2012). Natural scene stimuli and lapses of sustained attention. Consciousness and Cognition, 21, 1617–1625. doi:10.1016/j.concog.2012.08.009

19.

Head

Helton

W. S.

(2013). Perceptual decoupling or motor decoupling? Consciousness and Cognition, 22, 913–919. doi:10.1016/j.concog.2013.06.003

20.

Head

Russell

P. N.

Dorahy

M. J.

Neumann

Helton

W. S.

(2012). Text-speak processing and the sustained attention to response task. Experimental Brain Research, 216, 103–111. doi:10.1007/s00221-011-2914-6

21.

Head

Tenan

M. S.

Tweedell

A. J.

LaFiandra

M. E.

Morelli

Wilson

K. M.

Helton

W. S.

(2017). Prior mental fatigue impairs marksmanship decision performance. Frontiers in Physiology, 8, 680. doi:10.3389/fphys.2017.00680

22.

Head

Tenan

M. S.

Tweedell

A. J.

Price

T. F.

LaFiandra

M. E.

Helton

W. S.

(2016). Cognitive fatigue influences time-on-task during bodyweight resistance training exercise. Frontiers in Physiology, 7, 373.

23.

Helton

W. S.

(2009). Impulsive responding and the sustained attention to response task. Journal of Clinical and Experimental Neuropsychology, 31, 39–47.

24.

Helton

W. S.

Head

(2012). Earthquakes on the mind: Implications of disasters for human performance. Human Factors: The Journal of the Human Factors and Ergonomics Society, 54, 189–194.

25.

Helton

W. S.

Head

Russell

P. N.

(2011). Reliable- and unreliable-warning cues in the sustained attention to response task. Experimental Brain Research, 209, 401–407. doi:10.1007/s00221-011-2563-9

26.

Helton

W. S.

Kemp

(2011). What basic–applied issue? Theoretical Issues in Ergonomics Science, 12, 397–407.

27.

Helton

W. S.

Kern

R. P.

Walker

D. R.

(2009). Conscious thought and the sustained attention to response task. Consciousness and Cognition, 18, 600–607.

28.

Helton

W. S.

Weil

Middlemiss

Sawers

(2010). Global interference and spatial uncertainty in the sustained attention to response task (SART). Consciousness and Cognition, 19, 77–85.

29.

Hjortskov

Rissén

Blangsted

A. K.

Fallentin

Lundberg

Søgaard

(2004). The effect of mental stress on heart rate variability and blood pressure during computer work. European Journal of Applied Physiology, 92(1–2), 84–89.

30.

Ishimatsu

Meland

Hansen

T. A. S.

Kåsin

J. I.

Wagstaff

A. S.

(2016). Action slips during whole-body vibration. Applied Ergonomics, 55, 241–247.

31.

Kainda

Flechais

Roscoe

(2010, February 15–18). Security and usability: Analysis and evaluation. Paper presented at the 2010 International Conference on Availability, Reliability, and Security, Krakow, Poland. Retrieved from https://ieeexplore.ieee.org/stamp/ stamp.jsp?tp=&arnumber=5438081

32.

Lara

Madrid

J. A.

Correa

. (2014). The vigilance decrement in executive function is attenuated when individual chronotypes perform at their optimal time of day. PLoS ONE, 9(2), e88820.

33.

Lockett

(2017, June 15). US military will have more combat robots than human soldiers by 2025. The Sun. Retrieved from https://nypost.com/2017/06/15/us-military-will-have-more-combat-robots-than-human-soldiers-by-2025/

34.

Logan

G. D.

(1994). On the ability to inhibit thought and action: A users’ guide to the stop signal paradigm. In Dagenbach

Carr

T. H.

(Eds.), Inhibitory processes in attention, memory and language (pp. 189–239), San Diego, CA: Academic Press.

35.

Luque-Casado

Perales

J. C.

Cárdenas

Sanabria

(2016). Heart rate variability and cognitive processing: The autonomic response to task demands. Biological Psychology, 113, 83–90.

36.

Manly

Owen

A. M.

McAvinue

Datta

Lewis

G. H.

Scott

S. K.

Robertson

I. H.

(2003). Enhancing the sensitivity of a sustained attention task to frontal damage: Convergent clinical and functional imaging evidence. Neurocase, 9, 340–349.

37.

Manly

Robertson

I. H.

Galloway

Hawkins

(1999). The absent mind: Further investigations of sustained attention to response. Neuropsychologia, 37, 661–670.

38.

Parasuraman

Barnes

Cosenzo

(2007). Adaptive automation for human-robot teaming in future command and control systems. The International C2 Journal, 21(2), 43–68. Retrieved from http://www.dtic.mil/dtic/tr/fulltext/u2/a503770.pdf

39.

Peebles

Bothell

(2004). Modelling performance in the sustained attention to response task. In Proceedings of the sixth international conference on cognitive modeling (pp. 231–236). Pittsburgh, PA: University of Pittsburgh. Retrieved from http://act-r.psy.cmu.edu/wordpress/wp-content/uploads/2012/12/542Pebbles.pdf

40.

Pegasus-Eagle Rock Entertainment (2004). The American Orient Express [DVD]. Longdon: Eagle Rock/Pegasus.

41.

R Development Core Team. (2015). R: A language and environment for statistical computing. Vienna, Austria: R Foundation for Statistical Computing. Retrieved from http://www.R-project.org

42.

Robertson

I. H.

Manly

Andrade

Baddeley

B. T.

Yiend

(1997). “Oops!”: Performance correlates of everyday attentional failures in traumatic brain injured and normal subjects. Neuropsychologia, 35, 747–758.

43.

Rodríguez-Liñares

Vila

Méndez

A. J.

Lado

M. J.

Olivieri

(2008, June). R-HRV: An R-based software package for heart rate variability analysis of ECG recordings. Paper presented at the 3rd Iberian Conference in Systems and Information Technologies (CISTI 2008), Ourense, Spain.

44.

Seli

Cheyne

J. A.

Smilek

(2012). Attention failures versus misplaced diligence: Separating attention lapses from speed–accuracy trade-offs. Consciousness and Cognition, 21, 277–291.

45.

Thayer

J. F.

Ahs

Fredrikson

Sollers

I. I. I. J. J.

Wager

T. D.

(2012). A meta-analysis of heart rate variability and neuroimaging studies: Implications for heart rate variability as a marker of stress and health. Neuroscience & Biobehavioral Reviews, 36, 747–756.

46.

Verbruggen

Logan

G. D.

(2008). Response inhibition in the stop-signal paradigm. Trends in Cognitive Sciences, 12, 418–424.

47.

Wilson

K. M.

de Joux

N. R.

Finkbeiner

K. M.

Russell

P. N.

Retzler

J. R.

Helton

W. S.

(2018). Prolonging the response movement inhibits the feed-forward motor program in the sustained attention to response task. Acta Psychologica, 183, 75–84.

48.

Wilson

K. M.

Head

de Joux

N. R.

Finkbeiner

K. M.

Helton

W. S.

(2015). Friendly fire and the sustained attention to response task. Human Factors: The Journal of the Human Factors and Ergonomics Society, 57, 1219–1234.

49.

Wilson

K. M.

Head

Helton

W. S.

(2013). Friendly fire in a simulated firearms task. Proceedings of the Human Factors and Ergonomics Society Annual Meeting, 57, 1244–1248. doi:10.1177/1541931213571276

50.

Yan

Fine

(2004). Estimating equations for association structures. Statistics in Medicine, 23, 859–874.

51.

Zeger

S. L.

Liang

K.-Y.

Albert

P. S.

(1988). Models for longitudinal data: A generalized estimating equation approach. Biometrics, 44, 1049–1060.

Response Complexity Reduces Errors on a Response Inhibition Task

Abstract

Objective

Background

Method

Results

Conclusion

Application

Keywords

Get full access to this article

References