Dive planning is the process of planning an underwater diving operation. The purpose of dive planning is to increase the probability that a dive will be completed safely and the goals achieved. [1] Some form of planning is done for most underwater dives, but the complexity and detail considered may vary enormously. [2]
Professional diving operations are usually formally planned and the plan documented as a legal record that due diligence has been done for health and safety purposes. [3] [4] Recreational dive planning may be less formal, but for complex technical dives, can be as formal, detailed and extensive as most professional dive plans. A professional diving contractor will be constrained by the code of practice, standing orders or regulatory legislation covering a project or specific operations within a project, and is responsible for ensuring that the scope of work to be done is within the scope of the rules relevant to that work. [3] A recreational (including technical) diver or dive group is generally less constrained, but nevertheless is almost always restricted by some legislation, and often also the rules of the organisations to which the divers are affiliated. [2]
The planning of a diving operation may be simple or complex. In some cases the processes may have to be repeated several times before a satisfactory plan is achieved, and even then the plan may have to be modified on site to suit changed circumstances. The final product of the planning process may be formally documented or, in the case of recreational divers, an agreement on how the dive will be conducted. A diving project may consist of a number of related diving operations.
A documented dive plan may contain elements from the following list: [1]
Commercial diving contractors will develop specifications for the operation in cooperation with the client, who will normally provide a specific objective. The client will generally specify what work is to be done, and the diving contractor will deal with the logistics of how to do it. [3]
Other professional divers will usually plan their diving operations around an objective related to their primary occupation. [5]
Recreational divers will generally choose an objective for entertainment value, or for training purposes.
It will generally be necessary to specify the following:
Detailed planning depends on the mode and techniques selected for the dive, and the choice of these depends to a large extent on the physical constraints of the dive, but also to the legal, financial and procedural constraints of the divers. The mode and techniques chosen must also allow the dive to be done at an acceptable level of risk. There is usually more than one mode which is physically feasible, and often a choice between modes which are otherwise acceptable. In some cases detailed planning may show that the initial choice was not appropriate, and the process has to be repeated for an alternative choice. [6] [5]
Freediving does not involve the use of external breathing devices, but relies on a diver's ability to hold his or her breath until resurfacing. Free diving is limited in depth and time, but for some purposes it may be suitable. [5]
Diving with a self-contained underwater breathing apparatus, which is completely independent of surface supply, provides the diver with the advantages of mobility and horizontal range far beyond what is possible when supplied from the surface by the umbilical hoses of surface-supplied diving equipment. Scuba has limitations of breathing gas supply, communications between diver and surface are problematic, the location of the diver may be difficult to monitor, and it is considered a higher-risk mode of diving in most circumstances. Scuba is specifically forbidden for some professional applications. Decompression is often avoided, and if necessary, is generally in-water, but may use a variety of gases. [6] [5]
Open-circuit scuba systems discharge the breathing gas into the environment as it is exhaled, and consist of one or more diving cylinders containing breathing gas at high pressure connected to a primary diving regulator, and may include additional cylinders for decompression gas or emergency breathing gas. [6]
Closed-circuit or semi-closed circuit rebreather systems allow recycling of exhaled gases. This reduces the volume of gas used, so that a smaller cylinder, or cylinders, than open-circuit scuba may be used for the equivalent dive duration, and giving the ability to spend far more time underwater compared to open circuit for the same gas consumption. Rebreathers also produce far less bubble volume and less noise than open circuit scuba, which makes them attractive to military, scientific and media divers. They also have a larger number of critical failure modes, are more expensive and require more maintenance and require more training to use at a reasonable level of safety. [6]
Breathing gases may be supplied from the surface through a diver's umbilical, or airline hose, which provides breathing gas, communications and a safety line, with options for a hot water hose for heating, a video cable and gas reclaim line. The diver's breathing gas supply is significantly more secure than for scuba; communications are simplified and the divers position is either known or can be traced reliably by following the umbilical. Several major risks are thereby mitigated, but the system also has serious disadvantages in some applications, as diver mobility is constrained by the length of the umbilical, and it may snag on obstructions.
Surface-oriented, or bounce diving, is how commercial divers refer to diving operations where the diver starts and finishes the diving operation at atmospheric pressure. The alternative, while retaining surface supply, is saturation diving. For bounce dives, the diver may be deployed directly, often from a diving support vessel or indirectly via a diving bell. [7] Decompression procedures include in-water decompression or surface decompression in a deck chamber. Small closed bell systems which include a two-man bell, a launch and recovery frame and a chamber for decompression after transfer under pressure (TUP) are reasonably mobile, and suited to deep bounce dives. [7]
Saturation diving lets divers live and work at depth for days or weeks at a time. After working in the water, divers are transferred in a closed diving bell to rest and live in a dry pressurized underwater habitat on the bottom or a saturation life support system of pressure chambers at the surface. Decompression at the end of the dive may take many days, but since it is done only once for a long period of exposure, rather than after each of many shorter exposures, the overall risk of decompression injury to the diver and the total time spent decompressing are reduced. This type of diving allows greater economy of work and enhanced safety, but the capital and running costs are high and the systems are expensive to transport. Mobility of the diver is restricted because of the umbilical. [8]
Atmospheric diving suits can be used for very deep dives of up to 2,300 feet (700 m) for many hours, and eliminate several physiological dangers associated with deep diving: the occupant need not decompress; there is no need for special gas mixtures; and there is no danger of decompression sickness or nitrogen narcosis. Disadvantages include high cost, limited availability, bulk and limited diver dexterity.
The diving team personnel selection will depend largely on the diving mode selected and organisational requirements.
Professional dive team members will generally be selected on documented evidence of proven competence or qualification for the tasks allocated. The precise terminology may vary between organisations, but professional diving teams will usually include: [5] [9]
Technical teams will also generally base appointments on proven competence, certification or personal trust. Technical diving groups vary in complexity, but will generally comprise:
Recreational groupings may be based on personal experience and trust, but are frequently relatively arbitrary allocations by the service provider, based on certification. Recreational diving groups commonly comprise a buddy pair of divers, but may also be a solo diver or a group of divers who will be led by a divemaster. Selection may be by mutual agreement to dive together, or may simply be the result of booking on the same dive.
Depth is often one of the more straightforward parameters, as it is often fixed by the topography of the site.
Time is influenced by limitations of equipment and decompression constraints, as well as the actual time required to perform the intended task, which in turn is influenced by the underwater environment in general, and specific to the site.
The specific diving environment at the dive site will determine several factors which may require specific planning. The depth, water salinity and altitude affect decompression planning. An overhead environment affects navigation and gas planning. Water temperature and contaminants affect the choice of exposure and environmental protection. Site topography affects the choice of entry and exit points, and entry and exit procedures, which may require special equipment. The presence of entrapment or entanglement hazards, or dangerous animals, may require special precautions and additional equipment. [1]
Divers face specific physical and health risks when they go underwater with diving equipment, or use high pressure breathing gas.
A hazard is any biological, chemical, physical, mechanical or environmental agent or situation that poses a level of threat to life, health, property, or environment. The presence of a combination of several hazards simultaneously is common in diving, and the effect is generally increased risk to the diver, particularly where the occurrence of an incident due to one hazard triggers other hazards with a resulting cascade of incidents.
Diving hazards may be classified under several groups:
The assessed risk of a dive would generally be considered unacceptable if the diver is not expected to be able to cope with any single reasonably foreseeable incident with a significant probability of occurrence during that dive, or the dive team is not expected to be able to manage the probable consequences of such an event. [1] [9] Professional diving organisations tend to be less tolerant of risk than recreational, particularly technical divers, who are usually not constrained by occupational health and safety legislation.
Risk assessment is mandated in professional diving, where it is the specific responsibility of the diving supervisor, [6] [3] [1] and is expected in recreational diving, where it is generally the responsibility of the individual diver, though the expectations of the level of risk assessment are highly variable, and are associated with the level of training, certification and experience of the dive team, and the circumstances of the dive. A diving instructor is responsible for risk assessment during training, and a professional dive leader is responsible for some aspects of risk assessment when leading clients at an unfamiliar site.
The planned dive profile is an important input parameter for gas planning and decompression planning, and is generally based on the time required to perform the task of each specific dive, and the depth at which the task will be performed, in combination with environmental considerations and the breathing gas mixtures chosen. Limits are often due to exposure to cold, work load, decompression time, safety constraints and logistics of breathing gas supply. [2] [5]
For some dives the route to be followed and navigation procedures to follow the planned route may be important, either for achieving the objective, for safety, or for both. There may be known hazards that can be avoided by following a specific route or constraining the possible extent of diver excursion. [10]
In all penetration dives the route may be critical for safety. The diver must be assured of getting out from the overhead zone before running out of gas. The standard method is to follow a guideline into and out of the overhead environment, and laying the line or laying and recovering the line may be part of the dive plan. In explorations and surveys the route may be unknown or uncertain, and contingency plans must be known to the divers so that the dive plan can be altered to suit the situation as it unfolds. [11] [2]
Professional divers may follow a planned route to the worksite which prevents the diver from close approach to known hazards. This may involve limiting umbilical length and manned or unmanned underwater tending points, downlines and jackstays. [10] [9]
Equipment will be chosen based on several constraints, including: [11] [5] [9]
Equipment and supplies selection would normally include: [5]
A recreational diver may expect many of these items to be arranged by the service provider (the dive boat operator, shop, or school providing thansport to the dive site and organising the dive). Technical diving is less constrained by legislation than professional diving, but risk analysis may indicate similar equipment to be necessary or desirable for a specific dive. [12]
Decompression is planned based on the intended dive profile, the chosen gas mixtures, and the chosen decompression tables or algorithms. [11] [5]
There are two basic approaches to decompression for surface oriented dives, and one for saturation diving.
The procedures chosen will to a large extent depend on the mode of diving and equipment available. [6]
Gas planning for diving operations where divers use open circuit equipment with breathing gas mixtures is more complex than operations where atmospheric air is supplied via low pressure compressor from the surface, or the breathing gas is reclaimed, processed and re-used. [10] [9] [5]
Scuba gas planning is the aspect of dive planning which deals with the calculation or estimation of the amounts and mixtures of gases to be used for a planned dive profile, and can be critical to the safety of the dive. The scuba diver by definition is independent of surface supply and, in general, must carry all gas needed for the dive, though in limited circumstances depots of drop cylinders may be placed along the route of the dive for use on the return. This requires the route to be marked and the divers to return along the marked route, and is particularly suited to penetration dives, such as wreck and cave dives. [11]
Deep dives with open water ascents can also occasionally make use of surface standby divers who can provide contingency gas to ascending divers whose position is marked by a shotline or decompression buoys. [2]
The calculations assume that the dive profile, including decompression, is known, but the process may be iterative, involving changes to the dive profile as a consequence of the gas requirement calculation, or changes to the gas mixtures chosen. [11] [5]
Scuba gas planning includes the following aspects: [11] [5]
Open circuit surface supplied diving mostly uses air as the breathing gas, though mixed gases may also be used. [9]
Surface supplied air is generally supplied by low pressure compressor, and the continuous supply is limited only by the compressor continuing to run effectively, and to provide air of suitable quality. There is also a reserve air supply, either from a second compressor, or from fairly large high pressure cylinders. Each diver also carries a scuba bailout cylinder, which should carry sufficient gas to safely surface from any point in the planned dive. [9] [5]
Running out of air is a relatively low risk with these facilities, and gas planning centres on ensuring that the primary and, if present, backup compressors are correctly sized to provide the necessary pressure and flow rates. These are specified by the breathing equipment manufacturer based on depth and workload, and by the compressor manufacturer for the standard running speed of the machine. [9]
Reserve surface supply cylinder contents are based on the gas requirement for safe ascent from any part of the dive, allowing for reasonably foreseeable delays, and for a rescue by the standby diver. [10]
The diver's bailout cylinder should contain adequate gas in case of an emergency at the planned depth. Critical pressure should be calculated based on the planned profile and must allow change-over, ascent and all planned decompression. [9]
In some jurisdictions the stand-by diver must be supplied from an air source which is independent of that supplying the working divers, as the cause of an emergency may be failure or contamination of the main air supply to the working diver. [9]
Compressors are rated according to the volume of air taken in each minute. This is also the free gas volume that will be supplied to the divers. The volume of air used by the divers will depend on work rate and depth. Short term variations are compensated by the air receiver on the compressor. The delivery volume at maximum ambient pressure for the planned dive must be sufficient for all the divers to be supplied from the compressor. [10]
The supply pressure must be in excess of minimum functional pressure for the regulator to be enough to get air to the diver. In practice a delivery pressure of about 20 bar is commonly used. The manufacturer of the helmet or full-face mask will specify a pressure range which will deliver sufficient air for a given dive depth, which is usually from 6 to 10 bar more than the ambient pressure due to depth. [10]
Free flow helmets generally require a considerably higher compressor delivery than demand helmets, as the flow is continuous, and should never drop below peak inhalation rate of the diver. Flow rates up to 1500 litres per minute surface equivalent are quoted for the Divex AH-5 helmet at 50 metres sea water for heavy work. Delivery pressure at the AH-5 helmet is recommended at 3.5 bar above ambient. [13]
Saturation systems frequently use gas reclaim equipment to minimize the loss of expensive helium, and this makes the gas usage relatively independent of dive duration and depth, however reserves must be available in case of loss or leakage. [8] [10]
Scrubber systems are used to remove carbon dioxide from the breathing gas, and other filters to remove odours and other contaminants. Booster pump systems are used to return gas to high pressure storage. [8]
Contingency planning covers what to do if something happenes that is not according to the planned operation. The hazard identification and risk assessment will suggest the range of foreseeable contingencies, and the specifics of how much to organise to deal with them will depend on the consequences. [11]
In general, contingencies that have serious health and safety consequences should have plans in place to deal with them, while those which are merely an inconvenience may be accepted if they occur. [9] [5]
Some contingency classes are listed here:
One contingency that must always be considered is an out-of-gas emergency, as there are several ways it can happen, it is known to have happened by most of these ways on more than one occasion, and the consequences can be fatal. The diver must be able to safely reach a reliable alternative source of breathing gas at all times during the planned dive. Plans for technical contingencies may include arrangements for alternative equipment, spares, alternative boat etc. The level of contingency planning will depend on the project, and the importance of the task. Plans for adverse conditions may include arrangements for alternative dates, or in some cases alternative venues. [9] [5]
In general, there should be plans to deal with reasonably foreseeable emergencies that pose a risk to health and safety wherever there is a duty of care, these may include where relevant: [9] [5]
Some of the action generally taken to prepare for possible medical emergencies will include: [9] [5]
It may be necessary to arrange for clearance to dive. Permits or permission for access or to dive at the site may be required, and making the arrangements can be considered part of dive planning. [9] [5]
This may include, but is not limited to: [9] [5]
Estimating the cost of a diving operation is an important component of the planning process, [11] and is dependent on almost all the factors described above.
Dive planning for technical diving can berelatively complex, particularly the aspects of decompression and gas planning, which are the components of dive planning most amenable to automation. Software for decompression planning on personal dive computers, smartphones and other personal computers has become easily available and reliable, and has made manual calculations largely obsolescent, though they are still common during training, so that the diver can develop a feel for the correct order of magnitude of the computed values, as a sanity check in case of input errors. [14]
The original system of technical dive planning involved either looking up the commercial or military tables for a depth and time profile, or contacting a researcher for experimental tables if they wanted to use trimix. Later, pregenerated trimix tables became available within the community. The schedule of depths and run times for the planned profile would be written on a dive slate, along with contingency schedules for extended exposure, usually for deeper depth, longer bottom time and/or both. A bailout schedule could also be carried, for a shorter bottom time and/or shallower depth. CNS and OTU exposure values would be manually calculated for these schedules, and gas requirements calculated for each phase of the profiles, including contingency gas, using the rule of thirds, rock bottom calculations, or other rule of thumb, and used to select appropriate cylinders. Contingency plans for loss of decompression gas would usually also be carried. The dive would be done following the dive plan and monitored using a watch and depth gauge or a bottom timer. [14]
Later, dive computers that were programmed with algorithms for mixed gas diving and constant oxygen partial pressure for rebreather diving became available These were built to be used to greater depths, but they were expensive and sometimes unreliable, so some diver and training agencies did not trust them and insisted on using a written plan and schedule, using a computer as a backup in case of an emergency, which was a waste of the flexibility provided by real-time monitoring of decompression status by the computer, similar to the situation when dive computers were first accepted for scientific diving. [14]
As technical diving computers became more reliable and more affordable, more divers started accepting them as the primary tool for dive and decompression monitoring, using the written schedule as a backup, but still planning the dive beforehand based on a specified maximum depth and bottom time, so that gas planning based on the planned profile would be reliable. When the diver has a backup computer, the flexibility of the real-time monitoring can be fully utilised. [14]
A consequence of using a decompression computer to monitor gas loading during a dive is that it becomes possible to adapt the dive plan during the dive, but it remains necessary to ensure that there is sufficient gas remaining to make the return to the surface with all necessary decompression while providing emergency gas for a buddy. [14]
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Nitrox refers to any gas mixture composed of nitrogen and oxygen. This includes atmospheric air, which is approximately 78% nitrogen, 21% oxygen, and 1% other gases, primarily argon. In the usual application, underwater diving, nitrox is normally distinguished from air and handled differently. The most common use of nitrox mixtures containing oxygen in higher proportions than atmospheric air is in scuba diving, where the reduced partial pressure of nitrogen is advantageous in reducing nitrogen uptake in the body's tissues, thereby extending the practicable underwater dive time by reducing the decompression requirement, or reducing the risk of decompression sickness.
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. Risk may be reduced via appropriate skills, knowledge, and experience. Risk can also be managed by using suitable equipment and procedures. The skills may be developed through specialized training and experience. The equipment involves breathing gases other than air or standard nitrox mixtures, and multiple gas sources.
Surface-supplied diving is a mode of underwater diving using equipment supplied with breathing gas through a diver's umbilical from the surface, either from the shore or from a diving support vessel, sometimes indirectly via a diving bell. This is different from scuba diving, where the diver's breathing equipment is completely self-contained and there is no essential link to the surface. The primary advantages of conventional surface supplied diving are lower risk of drowning and considerably larger breathing gas supply than scuba, allowing longer working periods and safer decompression. Disadvantages are the absolute limitation on diver mobility imposed by the length of the umbilical, encumbrance by the umbilical, and high logistical and equipment costs compared with scuba. The disadvantages restrict use of this mode of diving to applications where the diver operates within a small area, which is common in commercial diving work.
The buddy check is a procedure carried out by scuba divers using the buddy system where each diver checks that the other's diving equipment is configured and functioning correctly just before the start of the dive. A study of pre-dive equipment checks done by individual divers showed that divers often fail to recognize common equipment faults. By checking each other's equipment as well as their own, it is thought to be more likely that these faults will be identified prior to the start of the dive.
Scuba diving is a mode of underwater diving whereby divers use breathing equipment that is completely independent of a surface breathing gas supply, and therefore has a limited but variable endurance. The name scuba is an anacronym for "Self-Contained Underwater Breathing Apparatus" and was coined by Christian J. Lambertsen in a patent submitted in 1952. Scuba divers carry their own source of breathing gas, usually compressed air, affording them greater independence and movement than surface-supplied divers, and more time underwater than free divers. Although the use of compressed air is common, a gas blend with a higher oxygen content, known as enriched air or nitrox, has become popular due to the reduced nitrogen intake during long or repetitive dives. Also, breathing gas diluted with helium may be used to reduce the effects of nitrogen narcosis during deeper dives.
Diver rescue, usually following an accident, is the process of avoiding or limiting further exposure to diving hazards and bringing a diver to a place of safety. A safe place generally means a place where the diver cannot drown, such as a boat or dry land, where first aid can be administered and from which professional medical treatment can be sought. In the context of surface supplied diving, the place of safety for a diver with a decompression obligation is often the diving bell.
Buddy breathing is a rescue technique used in scuba diving "out-of-gas" emergencies, when two divers share one demand valve, alternately breathing from it. Techniques have been developed for buddy breathing from both twin-hose and single hose regulators, but to a large extent it has been superseded by safer and more reliable techniques using additional equipment, such as the use of a bailout cylinder or breathing through a secondary demand valve on the rescuer's regulator.
A pony bottle or pony cylinder is a small diving cylinder which is fitted with an independent regulator, and is usually carried by a scuba diver as an auxiliary scuba set. In an emergency, such as depletion of the diver's main air supply, it can be used as an alternative air source or bailout bottle to allow a normal ascent in place of a controlled emergency swimming ascent. The key attribute of a pony bottle is that it is a totally independent source of breathing gas for the diver.
In underwater diving, an alternative air source, or more generally alternative breathing gas source, is a secondary supply of air or other breathing gas for use by the diver in an emergency. Examples include an auxiliary demand valve, a pony bottle and bailout bottle.
Diving equipment, or underwater diving equipment, is equipment used by underwater divers to make diving activities possible, easier, safer and/or more comfortable. This may be equipment primarily intended for this purpose, or equipment intended for other purposes which is found to be suitable for diving use.
A bailout bottle (BoB) or, more formally, bailout cylinder is a scuba cylinder carried by an underwater diver for use as an emergency supply of breathing gas in the event of a primary gas supply failure. A bailout cylinder may be carried by a scuba diver in addition to the primary scuba set, or by a surface supplied diver using either free-flow or demand systems. The bailout gas is not intended for use during the dive except in an emergency, and would be considered a fully redundant breathing gas supply if used correctly. The term may refer to just the cylinder, or the bailout set or emergency gas supply (EGS), which is the cylinder with the gas delivery system attached. The bailout set or bailout system is the combination of the emergency gas cylinder with the gas delivery system to the diver, which includes a diving regulator with either a demand valve, a bailout block, or a bailout valve (BOV).
Scuba gas planning is the aspect of dive planning and of gas management which deals with the calculation or estimation of the amounts and mixtures of gases to be used for a planned dive. It may assume that the dive profile, including decompression, is known, but the process may be iterative, involving changes to the dive profile as a consequence of the gas requirement calculation, or changes to the gas mixtures chosen. Use of calculated reserves based on planned dive profile and estimated gas consumption rates rather than an arbitrary pressure is sometimes referred to as rock bottom gas management. The purpose of gas planning is to ensure that for all reasonably foreseeable contingencies, the divers of a team have sufficient breathing gas to safely return to a place where more breathing gas is available. In almost all cases this will be the surface.
Diver training is the set of processes through which a person learns the necessary and desirable skills to safely dive underwater within the scope of the diver training standard relevant to the specific training programme. Most diver training follows procedures and schedules laid down in the associated training standard, in a formal training programme, and includes relevant foundational knowledge of the underlying theory, including some basic physics, physiology and environmental information, practical skills training in the selection and safe use of the associated equipment in the specified underwater environment, and assessment of the required skills and knowledge deemed necessary by the certification agency to allow the newly certified diver to dive within the specified range of conditions at an acceptable level of risk. Recognition of prior learning is allowed in some training standards.
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.
Scuba skills are skills required to dive safely using self-contained underwater breathing apparatus, known as a scuba set. Most of these skills are relevant to both open-circuit scuba and rebreather scuba, and many also apply to surface-supplied diving. Some scuba skills, which are critical to divers' safety, may require more practice than standard recreational training provides to achieve reliable competence.
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.
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.
The following index is provided as an overview of and topical guide to underwater diving:
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.