Bühlmann decompression algorithm

The Bühlmann decompression algorithm is a mathematical model (algorithm) of the way in which inert gases enter and leave the human body as the ambient pressure changes.[1] Versions are used to create Bühlmann decompression tables and in personal dive computers to compute no-decompression limits and decompression schedules for dives in real-time. These decompression tables allow divers to plan the depth and duration for dives and the required decompression stops.

The algorithm was developed by Swiss physician Dr. Albert A. Bühlmann, who did research into decompression theory at the Laboratory of Hyperbaric Physiology at the University Hospital in Zürich, Switzerland.[2][3] The results of Bühlmann's research that began in 1959 were published in a 1983 German book whose English translation was entitled Decompression-Decompression Sickness.[1] The book was regarded as the most complete public reference on decompression calculations and was used soon after in dive computer algorithms.

The model assumes perfusion limited gas exchange and multiple parallel tissue compartments and uses an inverse exponential model for in-gassing and out-gassing, both of which are assumed to occur in the dissolved phase (without bubble formation).

Principles

Building on the previous work of John Scott Haldane and Robert Workman,[4][5] and working off funding from Shell Oil Company,[6] Bühlmann designed studies to establish the longest half-times of nitrogen and helium in human tissues.[1] These studies were confirmed by the Capshell experiments in the Mediterranean Sea in 1966.[6][7]

Table of ZH-L16A Half-times with “a” and “b” values for nitrogen and helium.[8]
Compartment Half-time N2
(minutes)
N2 'a' value N2 'b' value Half-time He
(minutes)
He 'a' value He 'b' value
1 4 1.2599 0.5050 1.5 1.7435 0.1911
2 8 1.0000 0.6514 3.0 1.3838 0.4295
3 12.5 0.8618 0.7222 4.7 1.1925 0.5446
4 18.5 0.7562 0.7725 7.0 1.0465 0.6265
5 27 0.6667 0.8125 10.2 0.9226 0.6917
6 38.3 0.5933 0.8434 14.5 0.8211 0.7420
7 54.3 0.5282 0.8693 20.5 0.7309 0.7841
8 77 0.4701 0.8910 29.1 0.6506 0.8195
9 109 0.4187 0.9092 41.1 0.5794 0.8491
10 146 0.3798 0.9222 55.1 0.5256 0.8703
11 187 0.3497 0.9319 70.6 0.4840 0.8860
12 239 0.3223 0.9403 90.2 0.4460 0.8997
13 305 0.2971 0.9477 115.1 0.4112 0.9118
14 390 0.2737 0.9544 147.2 0.3788 0.9226
15 498 0.2523 0.9602 187.9 0.3492 0.9321
16 635 0.2327 0.9653 239.6 0.3220 0.9404

Versions

Several versions of the Bühlmann algorithm have been developed, both by Bühlmann and by later workers. The naming convention used to identify the algorithms is a code starting ZH-L, from Zürich (ZH), limits (L) followed by the number of tissue compartments, and other unique identifiers. For example:

  • ZHL-16 or ZH-L16A: The original 16 compartment algorithm (no conservatism at all).
  • ZHL-16B: The 16 compartment algorithm modified for dive table production, using slightly more conservative “a” values, mainly in the middle compartments.[8] Recently used in dive computers with high performance processor units, is it more flexible (especially in tech dives) compared to the ZHL16C
  • ZHL-16C:The 16 compartment algorithm with further modification to the middle and faster “a” values, intended for use in dive computers as a "package". It can be used with almost all low-level processor units but it is less flexible compared to the ZHL16B.
  • ZHL-8: A version using a reduced number of tissue compartments to reduce the computational load for personal dive computers.
  • ZHL-8 ADT: 8-compartment adaptive model used by Uwatec. This model may reduce the no-stop limit or require the diver to complete a compensatory decompression stop after an ascent rate violation, high work level during the dive, or low water temperature. This algorithm is used in computers which can accurately monitor air consumption and instantaneous rate of air consumption to model work load (exertion) via changes in the rate of gas consumption, which allows plausible modelling of additional decompression obligation based on exertion at depth. It also monitors ambient temperature and selects the choice of risk tissue accordingly. This results in earlier and longer decompression requirements in colder water.[9][10]
  • ZHL-8 ADT MB: A version of the ZHL-8 ADT claimed to suppress microbubble formation.[9]
  • ZHL–8 ADT MB PDIS: Profile-Determined Intermediate Stops.[11]
  • ZHL-8 ADT MB PMG: Predictive Multi-Gas.
  • ZHL-16 ADT DD: 16-compartment adaptive model used by Uwatec for their trimix-enabled computers. Modified in the middle compartments from the original ZHL-C, is adaptive to diver workload and includes Profile-Determined Intermediate Stops. Profile modification is by means of "MB Levels", personal option conservatism settings, which are not defined in the manual.[12]
  • ZHL-12

Tables

Max Hahn first used Bühlmann's algorithm to develop dive tables for the Swiss Underwater Sport Association. In 1987, the SAA Bühlmann System was developed by Bob Cole. This system used the dive tables and a set of rules so that people could dive safely and stay below their no-decompression limit.[13] The tables are still used today and are very popular; many dive computers still use the ZHL-8 algorithm and many tables are based on the ZHL-16 algorithm or derivatives. These calculations also include considerations for repetitive and altitude diving.[1][14][15][16][17][18]

gollark: microG, I mean.
gollark: I got it working without that.
gollark: Compiled it? Why?
gollark: Basically, it uses Bucklescript (OCaml -> JS) and Rollup (JS -> slightly different JS) and getting them to cooperate is horrible, and also everything else is aargh.
gollark: I've been configuring a project which relies on JS build systems.

References

  1. Bühlmann, Albert A (1984). Decompression-Decompression Sickness. Berlin New York: Springer-Verlag. ISBN 0-387-13308-9.
  2. Bühlmann, Albert A (1982). "[Experimental principles of risk-free decompression following hyperbaric exposure. 20 years of applied decompression research in Zurich]". Schweizerische Medizinische Wochenschrift (in German). 112 (2): 48–59. PMID 7071573.
  3. Wendling, J; Nussberger, P; Schenk, B (1999). "Milestones of the deep diving research laboratory Zurich". South Pacific Underwater Medicine Society Journal. 29 (2). ISSN 0813-1988. OCLC 16986801. Archived from the original on 2012-02-03. Retrieved 2009-04-02.
  4. Boycott, AE; Damant, GCC; Haldane, John Scott (1908). "Prevention of compressed air illness". Journal of Hygiene. Cambridge University Press. 8 (3): 342–443. doi:10.1017/S0022172400003399. PMC 2167126. PMID 20474365. Archived from the original on 2011-03-24. Retrieved 2009-06-12.
  5. Workman, Robert D (1957). "Calculation of air saturation decompression tables". Navy Experimental Diving Unit Technical Report. NEDU-RR-11-57. Archived from the original on 2011-09-18. Retrieved 2009-06-12.
  6. Völlm, Ernst B; Götte, Georg (1994). "Leading diving researcher dies unexpectedly: Albert A Bühlmann, 1923 - 1994". Pressure, Newsletter of the Undersea and Hyperbaric Medical Society. 23 (3): 1–3. ISSN 0889-0242.
  7. Bühlmann, Albert A; Frei, P; Keller, Hannes (October 1967). "Saturation and desaturation with N2 and He at 4 atm". Journal of Applied Physiology. 23 (4): 458–62. doi:10.1152/jappl.1967.23.4.458. PMID 6053671.
  8. Chapman, Paul. "An explanation Professor A A Buhlmann's ZH-L16 Algorithm" (PDF). Retrieved 12 March 2016.
  9. Staff. "Smart microbubble management" (PDF). In Depth. Uwatec. Retrieved 12 March 2016.
  10. Marroni, A; Cali Corleo, R; Balestra, C; Longobardi, P; Voellm, E; Pieri, M; Pepoli, R (2000). "Effects of the variation of Ascent Speed and Profile on the production of Circulating Venous Gas Emboli and the Incidence of DCI in Compressed Air Diving. Phase 1. Introduction of extra deep stops in the ascent profile without changing the original ascent rates. DSL Special Project 01/2000" (PDF). Divers Alert Network. Retrieved 12 March 2016.
  11. Staff. "Diving with PDIS (Profile-Dependent Intermediate Stop)" (PDF). Dykkercentret website. Frederiksberg: Dykkercentret ApS. Archived from the original (PDF) on 17 October 2016. Retrieved 5 March 2016.
  12. Technical diving software for Galilio: User manual (PDF). Scubapro. Retrieved 18 September 2019.
  13. Powell, Mark (2008). Deco for Divers. Southend-on-Sea: Aquapress. p. 18. ISBN 978-1-905492-07-7.
  14. Bühlmann, Albert A (1987). "Decompression after repeated dives". Undersea Biomedical Research. 14 (1): 59–66. ISSN 0093-5387. OCLC 2068005. PMID 3810993. Retrieved 2008-04-25.
  15. Böni, M; Schibli, R; Nussberger, P; Bühlmann, Albert A (1976). "Diving at diminished atmospheric pressure: air decompression tables for different altitudes". Undersea Biomedical Research. 3 (3): 189–204. ISSN 0093-5387. OCLC 2068005. PMID 969023. Retrieved 2008-04-24.
  16. Bühlmann, Albert A; Schibli, R; Gehring, H (March 1973). "[Experimental studies on decompression following diving in mountain lakes at reduced air pressure]". Schweizerische Medizinische Wochenschrift (in German). 103 (10): 378–83. PMID 4144210.
  17. Bühlmann, Albert A (1989). "[Decompression problems in diving in mountain lakes]". Schweizerische Zeitschrift fur Sportmedizin (in French). 37 (2): 80–3, discussion 99–102. PMID 2799365.
  18. Bühlmann, Albert A (1984). "[Decompression during lowered air pressure]". Schweizerische Medizinische Wochenschrift (in German). 114 (26): 942–7. PMID 6087447.

Further reading

  • Keller, Hannes; Bühlmann, Albert A (November 1965). "Deep diving and short decompression by breathing mixed gases". Journal of Applied Physiology. 20 (6): 1267–70. doi:10.1152/jappl.1965.20.6.1267.
  • Bühlmann, Albert A (1992). Tauchmedizin: Barotrauma Gasembolie Dekompression Dekompressionskrankheit (in German). Berlin: Springer-Verlag. ISBN 3-540-55581-1.
  • Bühlmann, Albert A (1995). Tauchmedizin (in German). Berlin: Springer-Verlag. ISBN 3-540-55581-1.

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