Task loading

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In underwater diving, task load indicates the degree of difficulty experienced when performing a task, and task loading describes the accumulation of tasks that are necessary to perform an operation. A light task loading can be managed by the operator with capacity to spare in case of contingencies.

Contents

Task loads may be measured and compared. NASA uses six sub-scales in their task load rating procedure. Three of these relate to the demands on the subject and the other three to interactions between subject and task. Ratings contain a large personal component and may vary considerably between subjects, and over time as experience is gained. [1]

  1. Mental Demands: How much mental and perceptual effort is required;
  2. Physical Demands: How much physical effort is required;
  3. Temporal Demands: How much time pressure the subject feels;
  4. Own Performance: Rating of how successfully the task was performed;
  5. Effort: Rating of how much effort was put into the task; and
  6. Frustration: Rating of how frustrating or satisfying the task was to perform.

In underwater diving, task loading increases the risk of failure by the diver to undertake some key basic function which would normally be routine for safety underwater. [2] [3] A heavy task loading may overwhelm the diver if something does not go according to plan. [4] This is particularly a problem in scuba diving, where the breathing gas supply is limited and delays may cause decompression obligations. The same workload may be a light task loading to a skilled diver with considerable experience of all the component tasks, and heavy task loading for a diver with little experience of some of the tasks.

Excessive task loading is implicated in many diving accidents, and may be limited by adding tasks one at a time, and adequately developing the requisite skills for each before adding more.

Common examples in scuba diving

Task loading is generally increased by any unplanned demand on the diver's attention, such as an emergency, an adverse change in environmental conditions, or a deviation from the dive plan. If this is added to an already marginally manageable task load, the diver may no longer be able to cope.

Common examples of activities which can contribute to high task loading are:

Common examples of routine functions that can be neglected as a result of task loading are:

Management

Task loading is often identified as a key component in diving safety and diving accidents, although statistically it is difficult to monitor because divers with more experience can cope with a more complex array of tasks and equipment. [8] Simply controlling buoyancy while using a dry suit can call for great levels of attention in an inexperienced diver, but would be routine for an experienced cold water diver, and could be done safely while carrying a camera during a cave penetration or using a DPV.

Task loading represents an elevated risk when a new activity is undertaken by a diver. A diver learning how to use a dry suit, or starting underwater photography, or learning to operate a rebreather or manage multiple gas decompression will need to dedicate considerably more attention to the proper functioning of the new and unfamiliar piece of equipment which increases the risk of neglecting other critical responsibilities. Those risks will normally diminish with experience, provided that the experience is sufficiently concentrated and repeated to allow overlearning of skills and develop muscle memory.

See also

Footnotes

  1. This is identified in most training courses as a common failing of new underwater photographers and underwater videographers[ citation needed ]

Related Research Articles

<span class="mw-page-title-main">Scuba set</span> Self-contained underwater breathing apparatus

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<span class="mw-page-title-main">Technical diving</span> Extended scope recreational diving

Technical diving is scuba diving that exceeds the agency-specified limits of recreational diving for non-professional purposes. Technical diving may expose the diver to hazards beyond those normally associated with recreational diving, and to a greater risk of serious injury or death. The risk may be reduced by appropriate skills, knowledge and experience, and by using suitable equipment and procedures. The skills may be developed through appropriate specialised training and experience. The equipment often involves breathing gases other than air or standard nitrox mixtures, and multiple gas sources.

<span class="mw-page-title-main">Diver propulsion vehicle</span> Powered device for diver mobility and range extension

A diver propulsion vehicle (DPV), also known as an underwater propulsion vehicle, sea scooter, underwater scooter, or swimmer delivery vehicle (SDV) by armed forces, is an item of diving equipment used by scuba divers to increase range underwater. Range is restricted by the amount of breathing gas that can be carried, the rate at which that breathing gas is consumed, and the battery power of the DPV. Time limits imposed on the diver by decompression requirements may also limit safe range in practice. DPVs have recreational, scientific and military applications.

<span class="mw-page-title-main">Scuba diving</span> Swimming underwater, breathing gas carried by the diver

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<span class="mw-page-title-main">Diver rescue</span> Rescue of a distressed or incapacitated diver

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Underwater breathing apparatus is equipment which allows the user to breathe underwater. The three major categories of ambient pressure underwater breathing apparatus are:

<span class="mw-page-title-main">Emergency ascent</span> An ascent to the surface by a diver in an emergency

An emergency ascent is an ascent to the surface by a diver in an emergency. More specifically, it refers to any of several procedures for reaching the surface in the event of an out-of-air emergency, generally while scuba diving.

<span class="mw-page-title-main">Scuba gas management</span> Logistical aspects of scuba breathing gas

Scuba gas management is the aspect of scuba diving which includes the gas planning, blending, filling, analysing, marking, storage, and transportation of gas cylinders for a dive, the monitoring and switching of breathing gases during a dive, efficient and correct use of the gas, and the provision of emergency gas to another member of the dive team. The primary aim is to ensure that everyone has enough to breathe of a gas suitable for the current depth at all times, and is aware of the gas mixture in use and its effect on decompression obligations, nitrogen narcosis, and oxygen toxicity risk. Some of these functions may be delegated to others, such as the filling of cylinders, or transportation to the dive site, but others are the direct responsibility of the diver using the gas.

<span class="mw-page-title-main">Rebreather diving</span> Underwater diving using self contained breathing gas recycling apparatus

Rebreather diving is underwater diving using diving rebreathers, a class of underwater breathing apparatus which recirculate the breathing gas exhaled by the diver after replacing the oxygen used and removing the carbon dioxide metabolic product. Rebreather diving is practiced by recreational, military and scientific divers in applications where it has advantages over open circuit scuba, and surface supply of breathing gas is impracticable. The main advantages of rebreather diving are extended gas endurance, low noise levels, and lack of bubbles.

<span class="mw-page-title-main">Scuba skills</span> The skills required to dive safely using a self-contained underwater breathing apparatus

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Diving safety is the aspect of underwater diving operations and activities concerned with the safety of the participants. The safety of underwater diving depends on four factors: the environment, the equipment, behaviour of the individual diver and performance of the dive team. The underwater environment can impose severe physical and psychological stress on a diver, and is mostly beyond the diver's control. Equipment is used to operate underwater for anything beyond very short periods, and the reliable function of some of the equipment is critical to even short-term survival. Other equipment allows the diver to operate in relative comfort and efficiency, or to remain healthy over the longer term. The performance of the individual diver depends on learned skills, many of which are not intuitive, and the performance of the team depends on competence, communication, attention and common goals.

<span class="mw-page-title-main">History of scuba diving</span> History of diving using self-contained underwater breathing apparatus

The history of scuba diving is closely linked with the history of the equipment. By the turn of the twentieth century, two basic architectures for underwater breathing apparatus had been pioneered; open-circuit surface supplied equipment where the diver's exhaled gas is vented directly into the water, and closed-circuit breathing apparatus where the diver's carbon dioxide is filtered from the exhaled breathing gas, which is then recirculated, and more gas added to replenish the oxygen content. Closed circuit equipment was more easily adapted to scuba in the absence of reliable, portable, and economical high pressure gas storage vessels. By the mid-twentieth century, high pressure cylinders were available and two systems for scuba had emerged: open-circuit scuba where the diver's exhaled breath is vented directly into the water, and closed-circuit scuba where the carbon dioxide is removed from the diver's exhaled breath which has oxygen added and is recirculated. Oxygen rebreathers are severely depth limited due to oxygen toxicity risk, which increases with depth, and the available systems for mixed gas rebreathers were fairly bulky and designed for use with diving helmets. The first commercially practical scuba rebreather was designed and built by the diving engineer Henry Fleuss in 1878, while working for Siebe Gorman in London. His self contained breathing apparatus consisted of a rubber mask connected to a breathing bag, with an estimated 50–60% oxygen supplied from a copper tank and carbon dioxide scrubbed by passing it through a bundle of rope yarn soaked in a solution of caustic potash. During the 1930s and all through World War II, the British, Italians and Germans developed and extensively used oxygen rebreathers to equip the first frogmen. In the U.S. Major Christian J. Lambertsen invented a free-swimming oxygen rebreather. In 1952 he patented a modification of his apparatus, this time named SCUBA, an acronym for "self-contained underwater breathing apparatus," which became the generic English word for autonomous breathing equipment for diving, and later for the activity using the equipment. After World War II, military frogmen continued to use rebreathers since they do not make bubbles which would give away the presence of the divers. The high percentage of oxygen used by these early rebreather systems limited the depth at which they could be used due to the risk of convulsions caused by acute oxygen toxicity.

<span class="mw-page-title-main">Outline of underwater diving</span> Hierarchical outline list of articles related to underwater diving

The following outline is provided as an overview of and topical guide to underwater diving:

Investigation of diving accidents includes investigations into the causes of reportable incidents in professional diving and recreational diving accidents, usually when there is a fatality or litigation for gross negligence.

Diving procedures are standardised methods of doing things that are commonly useful while diving that are known to work effectively and acceptably safely. Due to the inherent risks of the environment and the necessity to operate the equipment correctly, both under normal conditions and during incidents where failure to respond appropriately and quickly can have fatal consequences, a set of standard procedures are used in preparation of the equipment, preparation to dive, during the dive if all goes according to plan, after the dive, and in the event of a reasonably foreseeable contingency. Standard procedures are not necessarily the only courses of action that produce a satisfactory outcome, but they are generally those procedures that experiment and experience show to work well and reliably in response to given circumstances. All formal diver training is based on the learning of standard skills and procedures, and in many cases the over-learning of the skills until the procedures can be performed without hesitation even when distracting circumstances exist. Where reasonably practicable, checklists may be used to ensure that preparatory and maintenance procedures are carried out in the correct sequence and that no steps are inadvertently omitted.

<span class="mw-page-title-main">Human factors in diving equipment design</span> Influence of the interaction between the user and the equipment on design

Human factors in diving equipment design are the influence of the interaction between the diver and the equipment on the design of the equipment. The underwater diver relies on various items of diving and support equipment to stay alive and in reasonable comfort and to perform the planned tasks during a dive. The design of the equipment can strongly influence its effectiveness in performing the desired functions.

References

  1. Human Performance Research Group (January 1986). Task Load Index (NASA-TLX) v. 1.0 (PDF). Moffett Field. California: NASA Ames Research Center. Retrieved 2017-12-30.
  2. Blumenberg, MA (1996). "Human Factors in Diving". California Univ Berkeley (ADA322423). Archived from the original on July 26, 2012. Retrieved 2008-07-05.{{cite journal}}: CS1 maint: unfit URL (link)
  3. Lorenz J, Lorenz B, Heineke M (July 1992). "Effect of mental task load on fronto-central theta activity in a deep saturation dive to 450 msw". Undersea Biomedical Research. 19 (4): 243–62. PMID   1353926. Archived from the original on July 7, 2012. Retrieved 2008-07-05.{{cite journal}}: CS1 maint: unfit URL (link)
  4. Zimmerman, M.E. (2011). Kreutzer, J.S.; DeLuca, J.; Caplan, B. (eds.). Task Load. Encyclopedia of Clinical Neuropsychology. New York, NY: Springer.
  5. Kagan, Becky (2009-05-16). "Task Loading Tips For Underwater Photographers & Videographers". DivePhotoGuide.com. Retrieved 2009-05-16.
  6. Vaughan WS (June 1977). "Distraction effect of cold water on performance of higher-order tasks". Undersea Biomedical Research. 4 (2): 103–16. PMID   878066. Archived from the original on July 15, 2012. Retrieved 2008-07-05.{{cite journal}}: CS1 maint: unfit URL (link)
  7. Biersner, RJ & Cameron, BJ (1970). "Cognitive Performance during a 1000-Foot Helium Dive". United States Navy Experimental Diving Unit Technical Report (NEDU-RR-10-70). Archived from the original on July 7, 2012. Retrieved 2008-07-05.{{cite journal}}: CS1 maint: unfit URL (link)
  8. O'Connor PE (2007). "The nontechnical causes of diving accidents: can U.S. Navy divers learn from other industries?". Undersea and Hyperbaric Medicine. 34 (1): 51–9. PMID   17393939. Archived from the original on July 8, 2012. Retrieved 2008-07-05.{{cite journal}}: CS1 maint: unfit URL (link)


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