Pilot fatigue

Flight operations often take place at night, which can disrupt the circadian rhythms responsible for monitoring sleep and wake cycles.

The International Civil Aviation Organization (ICAO) defines fatigue as "A physiological state of reduced mental or physical performance capability resulting from sleep loss or extended wakefulness, circadian phase, or workload."[1] The phenomenon places great risk on the crew and passengers of an airplane because it significantly increases the chance of pilot error.[2] Fatigue is particularly prevalent among pilots because of "unpredictable work hours, long duty periods, circadian disruption, and insufficient sleep".[3] These factors can occur together to produce a combination of sleep deprivation, circadian rhythm effects, and 'time-on task' fatigue.[3] Regulators attempt to mitigate fatigue by limiting the amount of hours pilots are allowed to fly over varying periods of time.

Effect on flight safety

It has been estimated that 4-7% of civil aviation incidents and accidents can be attributed to fatigued pilots.[4] "In the last 16 years, fatigue has been associated with 250 fatalities in air carrier accidents." Robert Sumwalt, NTSB vice chairman, said at an FAA symposium in July.[5]

Symptoms associated with fatigue include slower reaction times, difficulty concentrating on tasks resulting in procedural mistakes, lapses in attention, inability to anticipate events, higher toleration for risk, forgetfulness, and reduced decision-making ability.[6] The magnitude of these effects are correlated to the circadian rhythm and length of time awake. Performance is affected the most, when there is a combination of extended wakefulness and circadian influences.[7]

Studies on the effects of fatigue

A Federal Aviation Administration (FAA) study of 55 human-factor aviation accidents from 1978 to 1999, concluded accidents increased proportionally to the amount of time the captain had been on duty.[8] The accident proportion relative to exposure proportion rose from 0.79 (1–3 hours on duty) to 5.62 ( more than 13 hours on duty). This means that "5.62% of human factors accidents occurred to pilots who had been on duty for 13 or more hours, where only 1% of pilot duty hours occur during that time." [8]

In another study by Wilson,Caldwell and Russell,[9] participants were given three different tasks that simulated the pilot's environment. The tasks included reacting to warning lights, managing simulated cockpit scenarios, and conducting a simulated UAV mission. The subjects' performance was tested in a well-rested state and again after being sleep deprived. In the tasks that were not as complex, such as reacting to warning lights and responding to automated alerts, it was found that there was a significant decrease in performance during the sleep deprived stage. The reaction times to warning lights increased from 1.5 to 2.5 seconds, and the number of errors doubled in the cockpit. However, tasks that were engaging and required more concentration were found to not be significantly affected by sleep deprivation. The study concluded that "...fatigue effects can produce impaired performance. The degree of performance impairment seems to be a function of the numbers of hours awake and the 'engagement' value of the task." [9]

One United States Air Forces study found significant discrepancies regarding how fatigue affects different individuals. It tracked the performance of ten F-117 pilots on a high-fidelity flight simulator.[10] The subjects were sleep deprived for 38 hours and their performance was monitored over the final 24 hours. After baseline correction, the systematic individual differences varied by 50% and concluded that fatigue's effect on performance varied drastically among individuals.[10]

Accidents and incidents related to pilot fatigue

American Airlines Flight 1420 crash in Little Rock, Arkansas.

Prevalence of pilot fatigue

The first step to understanding the critical impact fatigue can have on flight safety is to quantify it within the airline environment. An airline's management often struggles to balance rest with duty periods because it strives for maximum crew productivity. However, fatigue comes as a limitation needing increasing consideration.[3]

A study by Reis et Al. investigated the prevalence of fatigue on a group of Portuguese airline pilots.[15] 1500 active airline pilots who had all flown within the past 6 months received a questionnaire. Out of the population, 456 reliable responses were received. A pretest was conducted to determine the viability of the fatigue scale adopted during the test, called Fatigue Severity Scale (FSS). The purpose of the validation survey was to set a benchmark (i.e. FSS=4) on an acceptable level of fatigue for the Portuguese culture. The scale ranged from 1 meaning no fatigue to 7 being high. Participants had one month and a half to respond to the inquiry. Results on physical fatigue found that 93% of short/medium haul pilots scored higher than 4 on the FSS while 84% of long-haul pilots scored greater than 4. Mental fatigue found short/medium haul at 96% and long haul at 92%. The Questionnaire also asked: "Do you feel so tired that you shouldn’t be at the controls?". 13% of pilots said that this never happened. 51% of all participants said it happened a few times. Limitations of the study were: fatigue levels are subjective and research didn’t attempt to control a number of time pilots had available to respond to the questionnaires. Overall the study establishes that pilots are subject to high levels of fatigue on the job. Levels of fatigue collected were also compared with a validation test conducted on multiple sclerosis patients in Switzerland. These patients showed average fatigue levels of 4.6 while pilots in the Portuguese study scored an average of 5.3.[15]

Electroencephalogram probes monitoring physiological activity during a pilot fatigue study.

High Prevalence of fatigue was also revealed in a study by Jackson and Earl investigating prevalence among short haul pilots.[16] The study consisted of a questionnaire that was posted on a website, Professional Pilot’s Rumour network (PPRUNE) and was able to obtain 162 respondents. Of the 162, all being short haul pilots, 75% were classified to have experienced severe fatigue. Based on questionnaire results, the study also demonstrated that pilots who were highly concerned about their level of fatigue during the flight often scored higher on the fatigue scale and thus were likely to experience more fatigue. Not only this, operational factors example change in flights or flight into discretion time often cause the pilot to experience greater fatigue.[16]

On the other hand, research by Samen, Wegmann, and Vejvoda investigated the variation of fatigue among long-haul pilots.[17] 50 pilots all from German airlines participated in the research. As participants, pilots were subject to physiological measures pre-departure and during flight and filled out routine logs recording their times of sleep and awakening. Pilots also completed two questionnaires. The first reflecting feelings of fatigue before and after the flight, recorded before departure, 1-hour intervals during the flight and then immediately after landing. The second questionnaire was the NASA task load index.

The second questionnaire also administered during flight, assessed different dimensions including mental, physical and temporal demand as well as performance. Key findings from the study conveyed that: outgoing flights from the home base were rated as less stressful and night flights were rated as the most stressful. The physiological measures found that micro-sleeps recorded by the EEGs increased progressively with flight duty. Micro-sleeps are recordings of alpha wave activity and they occur during wakeful relaxation often resulting in loss of attention. They are considered macro-sleeps if they last less than thirty seconds. Micro-sleep cases for pilots on outgoing flights were half compared the amount on incoming flights back to the home base showing that fatigue is more prevalent on flights returning home. Pilots are more prone to microsleeps during the cruise phase of the flight while they are more alert and less likely to experience microsleeps during the take-off, approach and landing phases of the flight. Findings also show that fatigue was greater during night flights because pilots had already been awake for more than 12 hours and would begin duty, by the time they were going to sleep.[17]

Countermeasures to fatigue

Since the 1930s, airlines have been aware of the impact of fatigue on pilot's cognitive abilities and decision making. Nowadays prevalence of fatigue draws greater attention because of boom in air travel and because the problem can be addressed with new solutions and countermeasures.[7]

In-flight strategies

Alternative strategies

Cockpit design

Further considerations

Aircraft are becoming increasingly automated, often resulting in the flight crew becoming complacent because of less direct involvement especially during the cruise phases of a long haul flight. Long legs in cruise may cause pilots to become bored, thus incrementing the prevalence of risk because it will take a pilot a longer time to resume full alertness in case of emergency. Airlines schedule two crews or a junior first officer as a strategy to combat boredom during the cruise phases of flight. "Keep Awake" routines are another countermeasure. They consist of small events in flight designed to start a false problem that has previously been inputted by a flight engineer. "Keep awake" routines do not affect flight safety and their purpose reattain pilot's full alertness and undivided attention [23]

Regulations

National aviation regulators typically use the hours-of-service approach to prevent fatigue.[19] The hours-of-service is usually measured by flight duty period which is defined as "a period which commences when a flight crew member is required to report for duty... and which finishes when the aircraft is parked with no intention of [further movement]".[24] Limits are generally set on flight duty time across daily, weekly, and monthly time periods. These limits differ based on: what type of operation is being conducted, the time of day, and whether the flight is single-pilot or multi-pilot. There are also requirements for time free from duty after consecutive days on duty.[25]

All ICAO member states place some kind of operational limit, but there are differences in how this is done across nations. A survey of ten nations found that a total of twelve different operational factors were regulated, with each country regulating six factors on average. However, these factors are often measured in different ways and vary significantly in limit.[26]

Many experts in aviation safety find that the current regulations are inadequate in combating fatigue. They point to high prevalence rates and laboratory studies as evidence for the current systems failure. While the current system helps prevent extended sleep deprivation, it does not take into account circadian rhythm disruptions, time of day, or accumulated sleep debt. One study found that the findings show "a need to raise the level of knowledge within the industry regarding the causes and consequences of fatigue and of processes for its management".[27]

See also

References

  1. "Operation of Aircraft" (PDF). International Standards and Recommended Practices. February 25, 2013.
  2. Caldwell, John; Mallis, Melissa (January 2009). "Fatigue Countermeasures in Aviation". Aviation, Space, and Environmental Medicine. 80 (1): 29–59. doi:10.3357/asem.2435.2009.
  3. 1 2 3 Caldwell, John A.; Mallis, Melissa M.; Caldwell, J. Lynn (January 2009). "Fatigue Countermeasures in Aviation". Aviation, Space, and Environmental Medicine. 80 (1): 29–59. doi:10.3357/asem.2435.2009.
  4. Caldwell, John. A (July 21, 2004). "Fatigue in aviation". Travel Medicine and Infectious Disease. 3 (2): 85–96. doi:10.1016/j.tmaid.2004.07.008. PMID 17292011.
  5. "Pilot Fatigue". CNN. Retrieved May 2, 2016.
  6. 1 2 3 Caldwell, John A. (2012). "Crew Schedules, Sleep Deprivation and Aviation Performance". Current Directions in Psychological Science. 21 (2): 85–89. doi:10.1177/0963721411435842.
  7. 1 2 3 Williamson, Ann; Friswell, Rena (May 2011). "Investigating the relative effects of sleep deprivation and time of day on fatigue and performance". Accident Analysis and Prevention. 43 (3): 690–697. doi:10.1016/j.aap.2010.10.013. PMID 21376856.
  8. 1 2 Goode, Jeffrey H. (March 27, 2003). "Are pilots at risk of accidents due to fatigue?". Journal of Safety Research. 34 (3): 309–313. doi:10.1016/s0022-4375(03)00033-1. PMID 12963077.
  9. 1 2 Wilson, Glen F.; Caldwell, John A.; Russel, Christopher A. (April 2007). "Performance and Psychological Measures of Fatigue Effects on Aviation Related Tasks of Varying Difficulty". The International Journal of Aviation Psychology. 17 (2): 219–247. doi:10.1080/10508410701328839.
  10. 1 2 Van Dongen, Hans P.A; Caldwell, John A.; Caldwell, J. Lynn (2006). "Investigating systematic individual differences in sleep-deprived performance on a high-fidelity flight simulator". Behavior Research methods. 38 (2): 333–343. doi:10.3758/bf03192785. PMID 16956110.
  11. (PDF) NTSB Aircraft Accident Safety Report%5d http://www.ntsb.gov/doclib/reports/1998/NTSB/AAR-00/01_body.pdf NTSB Aircraft Accident Safety Report] Check |url= value (help). Missing or empty |title= (help)
  12. Caldwell, John A. (September 12, 2004). "Fatigue in Aviation". Travel Medicine and Infectious Disease.
  13. (PDF) NTSB Aircraft Accident Safety Report%5d http://www.ntsb.gov/doclib/reports/2006/NTSB/AAR-06/01_body.pdf NTSB Aircraft Accident Safety Report] Check |url= value (help). Missing or empty |title= (help)
  14. "NTSB confirms pilots fell asleep". August 4, 2009.
  15. 1 2 Reis, Cátia; Mestre, Catarina; Canhão, Helena (August 2013). "Prevalence of Fatigue in a group of Airline Pilots". Aviation, Space, and Environmental Medicine. Aerospace Medical Association: 828–833.
  16. 1 2 Jackson; Earl (June 2006). "Prevalence of Fatigue Among Commercial Pilots". Occupational Medicine. 56 (4): 263. doi:10.1093/occmed/kql021. PMID 16733255.
  17. 1 2 Samel,Wegmann, Vejvoda (July 1997). "Aircrew Fatigue in long haul operations". Pergamon: Accident Analysis Prevention.
  18. Rosekind MR, Graeber RC, Dinges DF, Connell LJ, Rountree MS, Spinweber CL (1994). "Effects of planned cockpit rest on crew performance and alertness in long-haul operations.". Crew Factors in Flight Operations IX.
  19. 1 2 3 4 5 Caldwell, John A.; Mallis, Melissa M.; Caldwell, J. Lynn; Paul, Michel A.; Miller, James C.; Neri, David F. (January 2009). "Fatigue Countermeasures in Aviation". Aviation, Space, and Environmental Medicine.
  20. Dijkman M, Sachs N, Levine E, Mallis M, Carlin MM, Gillen KA (1997). "Effects of reduced stimulation on neurobehavioral alertness depend on circadian phase during human sleep deprivation.". Sleep Res: 265.
  21. Cajochen C, Zeitzer JM, Czeisler CA, Dijk DJ (2000). "Dose response relationship for light intensity and ocular and electroencephalographic correlates of human alertness". Behav Brain Res. 115 (1): 75–83. doi:10.1016/s0166-4328(00)00236-9. PMID 10996410.
  22. Millar, Michelle (2012). "Measuring Fatigue" (PDF). ICAO.int. ICAO/IATA/IFALPA. p. 8.
  23. 1 2 Novacheck, Paul. "How Can Avionics Help Reduce Pilot Fatigue?" (PDF). Aea.net. Aircraft Electronics Association.
  24. Foltz, Joshua. "How maximum Flight Duty Periods and maximum Flight Times will affect Airlines – FAR 121 subpart Q versus FAR 117 – un-augmented". Understanding FAR Part 117.
  25. Aviation, Government of Canada; Transport Canada; Safety and Security Group, Civil. "Table of Contents - Canadian Aviation Regulations - Part VII". www.tc.gc.ca. Retrieved 2015-10-27.
  26. Missoni, Eduard; Missoni, Ivan (February 2009). "Civil Aviation Rules on Crew Flight Time, Flight Duty, And Rest: Comparison of 10 ICAO Member States". Aviation, Space, and Environmental Medicine. 80.
  27. Signal, T. Leigh; Ratieta, Denise; Gander, Philippa H. (2008-01-01). "Flight Crew Fatigue Management in a More Flexible Regulatory Environment: An Overview of the New Zealand Aviation Industry". Chronobiology International. 25 (2–3): 373–388. doi:10.1080/07420520802118202. ISSN 0742-0528.
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