Dive computer Totally Explained

Everything about Dive Computer totally explained

A dive computer or decompression meter is a device used by a scuba diver to measure the time and depth of a dive so that a safe ascent rate can be calculated and displayed so that the diver can avoid decompression sickness.

Purpose

Dive computers address the same problem as decompression tables, but are able to perform a continuous calculation of the partial pressure of inert gases in the body based on the actual depth and time profile of the diver.
   In 1965, Stubbs and Kidd applied their decompression model to a pneumatic analogue decompression computer.
   The first recreational mechanical analogue dive computer, the decompression meter was marketed by Scubapro in 1972. It was very simple in principle: a waterproof bladder filled with gas inside a big casing bled into a smaller chamber through a calibrated porous ceramic cartridge (to simulate tissue in/out gassing), whose pressure was measured by a manometer whose graduation indicated decompression stops. The device was eventually nicknamed bend-O-meter.
   Several analogue decompression meters were subsequently, some with several bladders for illustrating the effect on various body tissues, but they were sidelined with the arrival on the scene of electronic computers.
   Early examples of recreational diving digital, electronic computers, from 1979, are the Hans Hass DecoBrain and Orca Edge.
   In 2001, the US Navy approved the use of Cochran NAVY decompression computer with the VVAL-18 for Special Warfare operations.

Display information

Dive computers provide a variety of visual dive information to the diver.
Modern dive computers display the following information on a LCD:

Current depth.
Maximum depth reached on this dive.
No stop time, the time remaining at the current depth without the need for decompression stops on ascent.
Dive time, often measured from the end of the last longer surface interval.

Many dive computers also display additional information:

Required decompression stop depth and time.

Water temperature.

Ascent rate.

Dive profile (often not displayed during the dive, but transmitted to a personal computer). Some computers are designed to display information from a diving cylinder pressure sensor, such as:

Gas pressure.

Estimated remaining time based on available gas and rate of gas consumption. Some information is only shown at the surface to avoid an information overload of the diver during the dive:

"Time to Fly" display showing when the diver can safely board an airplane.

A log of key information about previous dives.

Maximum non-decompression bottom times for subsequent dives based on the partial pressure of the gases in the tissue.

Audible information

Many dive computers have warning buzzers that warn the diver of events such as:

Excessive ascent rates.

Missed decompression stops.

Maximum operation depth exceeded.

Oxygen toxicity limits exceeded.

Operation

Modern dive computers are battery-powered computers within a watertight case. These computers track the dive profile by measuring time and pressure. All dive computers measure the surrounding pressure to estimate the partial pressure of gases in the human tissue. More advanced dive computers also include additional information into the calculations, for example, the water temperature or the diving cylinder pressure.
   The computer then uses the profile and a decompression algorithm to estimate the partial pressure of inert gases that has been dissolved in the diver's tissues. Based on these calculations, the computer estimates when a direct ascent is no longer possible, and what decompression stops would be needed.
   Examples of decompression algorithms are Bühlmann tables, the Multi-Tissue Model, the Varying Permeability Model, and the Reduced Gradient Bubble Model.
   Many dive computers are able to produce a safe decompression schedule for dives that take place at altitude, which requires a slower ascent than at sea level, because the computers measure the atmospheric pressure before the dive. When divers travel before or after diving and particularly when they fly, they should transport their dive computer with them in the same pressure regime so that the computer can measure the pressure profile that their body has undergone.

Algorithms

Algorithms vary by model from each manufacturer but only a few algorithms have been developed. An algorithm used may also be a modification of an existing algorithm. When considering a dive computer, the main feature to consider is the algorithm that the air decompression limit monitor uses. If you’re unaware which algorithm the model that you’re considering to purchase uses, don’t purchase it until that's known. The subcontractors and child companies that make the dive computers market these under an array of brand names.
The algorithm used prevents you from getting decompression sickness (DCS). Diving scientists use known data that's recorded and averaged from previous divers to form an algorithm. Interpreted data that the computer receives is used against the algorithm to determine deco and no-stop times. An algorithm tries to account for magnitude of pressure reduction, repetitive exposures, rate of ascent, and time at altitude. Scientists may not be able to account for age, previous injury, ambient temperature, body type, alcohol consumption/dehydration, and patent foramen ovale when determining how to form an algorithm.
The newest dive computers on the market use:

Mares: Mares-Wienke Reduced Gradient Bubble Model

Pelagic: modified Haldanean / Diving Science and Technology Database

SEIKO: Buhlmann ZHL-12 + Randy Bohrer

Suunto: Suunto-Wienke Reduced Gradient Bubble Model

UWATEC: Buhlmann ZH-L8 /ADT (Adaptive), MB (Micro Bubble), PMG (Predictive Multigas)

Special purpose dive computers

Some dive computers are able to calculate decompression schedules for breathing gases other than air, such as nitrox, pure oxygen, trimix or heliox. The more basic nitrox dive computers only support one or two gas mixes for each dive. Others support many different mixes.
Most dive computers calculate decompression for 'open circuit' SCUBA where the proportions of the breathing gases are constant: these are "constant fraction" dive computers. Other dive computers are designed to model the gases in some 'closed circuit' SCUBA (rebreathers), which maintain constant partial pressures of gases by varying the proportions of gases in the mixture: these are "constant partial pressure" dive computers.

Precautions

The ease of use of dive computers, however, also exposes the diver to other dangers. Dive computers allow divers to perform complex dives with little planning. This may lead divers to exceed their competence and experience by relying too much on the computer rather than proper planning, discipline and monitoring.
   Many dive computers have menus, various selectable options and various display modes, which are controlled by a small number of buttons on the front of the computer. The diver should become familiar with the control of the computer on a series of shallow and undemanding dives before relying on it for more challenging dives.
   For safety reasons it's recommended that a dive plan should be established before the dive and then followed throughout the dive unless the dive is aborted. This dive plan should be within the limits of the decompression tables. This increases the margin of safety, and also provides a backup decompression schedule based on the dive tables in case the computer fails underwater. The main problem in establishing dive computer algorithms is that the gas absorption and release under pressure in the human body is still not completely understood. Furthermore, the risk of decompression sickness also depends on the physiology, fitness, condition and health of the individual diver.
   A diver wishing to reduce the risk of decompression sickness can take a number of precautionary measures such as:

Use dive computers with a conservative decompression model

Use safety factors with dive computers (for example using a high altitude dive mode for a dive at sea level)

Add additional deep safety stops during a deep dive

Make a slow ascent

Add additional shallow safety stops

Have a long surface interval between dives Many computers go into a "lockout" mode for 24 hours if the diver violates the computer's safety limits, to discourage continued diving after an unsafe dive. While in lockout mode, these computers won't function until the lockout period has ended. Other computers, for example Delta P's VR3, will continue to function, providing 'best guess' functionality whilst warning the diver that a stop has been missed, or stop depth exceeded.

Manufacturers

There are only a few dive computers manufacturers:

Benemec(External Link

)

Citizen

Cochran Undersea Technology(External Link

)

Delta P Technology(External Link

)

HeinrichsWeikamp(External Link

) (Open source)

HTM Sports: Mares(External Link

) and Dacor(External Link

)

HydroSpace Engineering(External Link

)

Liquivision(External Link

)

Pelagic Pressure Systems: Aeris(External Link

) and Oceanic(External Link

)

UWATEC(External Link

) child company of Johnson Outdoors

Underwater Technology Center(External Link

)

Seiko

Suunto

Inspired Others are selling computers clones made by Seiko(Apeks, Cressi, Dive Rite, ScubaPro, Tusa, Zeagle) or Pelagic Pressure Systems(Beuchat, Genesis, Seemann, Sherwood) or Benemec Oy(A.P.Valves).

Market Share

Pelagic is currently the global market leader in dive computers. Suunto announced in December 2005 that they'd manufactured a million dive computers.
Statistics of dive computer manufacturers by market share are welcome to be posted and updated here.
Dive computer market share worldwide estimates by brand as of May 2008:

Suunto 31.6%

Oceanic 27.0%

Aeris 11.9%

Uwatec 6.6%

Mares 5.3%

Cressi-Sub 3.8%

Sherwood 3.5%

Scubapro 3.1%

Genesis 2.8%

Tusa 2.0%

Aqua Lung America 1.3%

Seaquest 0.8%

Zeagle 0.2%Further Information

Get more info on 'Dive Computer'.

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