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{{for|underwater navigation by divers|Underwater navigation}}
{{Short description|Skills and tech involved in submarine navigation}}
{{For|underwater navigation by divers|Underwater navigation}}
'''Submarine navigation''' underwater requires special skills and technologies not needed by [[surface ship]]s. The challenges of underwater [[navigation]] have become more important as [[submarines]] spend more time underwater, travelling greater distances and at higher speed. Military submarines travel underwater in an environment of total darkness with neither windows nor lights. Operating in stealth mode, they cannot use their [[Sonar#Active sonar|active sonar]] systems to [[Acoustic location|ping]] ahead for underwater hazards such as [[Seamount|undersea mountains]], [[drilling rig]]s or other submarines. Surfacing to obtain [[Fix (position)|navigational fixes]] is precluded by pervasive [[anti-submarine warfare]] [[Anti-submarine warfare#Technologies used|detection systems]] such as [[radar]] and [[Spy satellite|satellite]] surveillance. [[Antenna (radio)|Antenna masts]] and antenna-equipped [[periscope#Naval use|periscopes]] can be raised to obtain navigational signals but in areas of heavy surveillance, only for a few seconds or minutes;<ref>{{cite book | last = Bivens | first = Arthur Clarke | title = From Sailboats to Submarines |date=July 2004 | publisher = Infinity Publishing | isbn = 978-0-7414-2152-4 | pages = 184 }}</ref> current radar technology can detect even a slender periscope while submarine shadows may be plainly visible from the air.
'''Submarine navigation''' underwater requires special skills and technologies not needed by [[surface ship]]s. The challenges of underwater [[navigation]] have become more important as [[submarines]] spend more time underwater, travelling greater distances and at higher speed. Military submarines travel underwater in an environment of total darkness with neither windows nor lights. Operating in stealth mode, they cannot use their [[Sonar#Active sonar|active sonar]] systems to [[Acoustic location|ping]] ahead for underwater hazards such as [[Seamount|undersea mountains]], [[drilling rig]]s or other submarines. Surfacing to obtain [[Fix (position)|navigational fixes]] is precluded by pervasive [[anti-submarine warfare]] [[Anti-submarine warfare#Technologies used|detection systems]] such as [[radar]] and [[Spy satellite|satellite]] surveillance. [[Antenna (radio)|Antenna masts]] and antenna-equipped [[periscope#Naval use|periscopes]] can be raised to obtain navigational signals but in areas of heavy surveillance, only for a few seconds or minutes;<ref>{{cite book | last = Bivens | first = Arthur Clarke | title = From Sailboats to Submarines |date=July 2004 | publisher = Infinity Publishing | isbn = 978-0-7414-2152-4 | pages = 184 }}</ref> current radar technology can detect even a slender periscope while submarine shadows may be plainly visible from the air.


[[File:Damage to USS San FranciscoSSN-711 showing bow sonar.jpg|thumb|[[USS San Francisco (SSN-711)]] suffered substantial damage to its bow section and sonar array after colliding at high speed with an undersea mountain.]] [[File:USS Chicago (SSN 721) at periscope depth off Malaysia.jpg|thumb|A submarine at periscope depth risks visual or radar detection]] [[File:Annapolis masts.jpg|thumb|Submarines can raise various antenna masts, radar masts and periscopes to facilitate communications and navigation]]
[[File:USS Chicago (SSN 721) at periscope depth off Malaysia.jpg|thumb|A submarine at periscope depth risks visual or radar detection]] [[File:Annapolis masts.jpg|thumb|Submarines can raise various antenna masts, radar masts and periscopes to facilitate communications and navigation]]


==Navigational technologies==
==Navigational technologies==
Surfaced submarines entering and leaving port navigate similarly to traditional ships but with a few extra considerations because most of the ship rides below the waterline, making them hard for other ships to see and identify.
Surfaced submarines entering and leaving port navigate similarly to traditional ships but with a few extra considerations because most of the boat rides below the waterline, making them hard for other vessels to see and identify.
Submarines carry an inertial navigation system, which measures the boat’s motion and constantly updates position. Because it does not rely on radio signals or celestial sightings, it allows the boat to navigate while remaining hidden under the surface. To maintain accuracy, the submarine must periodically update its position using outside navigational radio signals. From the 1960s to the 1990s, Transit satellites and LORAN shore stations provided those signals. GPS has now replaced both.
Submarines carry an inertial navigation system, which measures the boat’s motion and constantly updates position. Because it does not rely on radio signals or celestial sightings, it allows the boat to navigate while remaining hidden under the surface. To maintain accuracy, the submarine must periodically update its position using outside navigational radio signals. From the 1960s to the 1990s, Transit satellites and LORAN shore stations provided those signals. GPS has now replaced both.



===Surface and near-surface navigation===
===Surface and near-surface navigation===
On the surface or at [[periscope depth]], submarines have used these methods to fix their position:
On the surface or at [[periscope depth]], submarines have used these methods to fix their position:
*Satellite navigation:
*Satellite navigation:
**[[Global positioning system]] (GPS) — by entering waypoints internally, able to navigate at a more precise level.
**[[Global positioning system]] (GPS)—by entering waypoints internally, able to navigate at a more precise level.
**[[Transit (satellite)|NAVSAT]]
**[[Transit (satellite)|NAVSAT]]
*Terrestrial [[Radio navigation|radio-based navigation]] systems; largely superseded by satellite systems
*Terrestrial [[Radio navigation|radio-based navigation]] systems; largely superseded by satellite systems
**[[LORAN]]—Low frequency radio [[hyperbolic navigation]] system, no longer in use
**[[LORAN]]—seldom if rarely used anymore.
**[[CHAYKA]], the Russian counterpart of LORAN
**[[CHAYKA]], the Russian counterpart of LORAN
**[[Omega (navigation system)|OMEGA]], the Western counterpart of the Alpha Navigation System, no longer in use
**[[Omega (navigation system)|OMEGA]], Western very low frequency global-range radio hyperbolic navigation system, no longer in use
**[[Alpha (navigation)|Alpha]], the Russian counterpart of the Omega Navigation System
**[[Alpha (navigation)|Alpha]], the Russian counterpart of the Omega Navigation System
*[[Celestial navigation]] using the periscope, or sextant—seldom used anymore due to advancement in technology
*[[Celestial navigation]] using the periscope, or sextant—seldom used anymore due to advancement in technology
*[[Radar navigation]]; radar signals are easily detected so radar is normally only used in friendly waters entering and exiting ports. With the implementation of a more advanced radar system, many new techniques have been implemented in this process.
*[[Radar navigation]]; radar signals are easily detected so radar is normally only used in friendly waters entering and exiting ports. With the implementation of a more advanced radar system, many new techniques have been implemented in this process.
*[[Active sonar]]; like radar, active sonar systems are readily detected, so active sonar is usually used only entering and exiting ports.
*[[Active sonar]]; like radar, active sonar systems are readily detected, so active sonar is usually used only entering and exiting ports.
*[[Pilotage]] — in coastal and [[internal waters]], surfaced submarines rely on the standard system of navigational aids (buoys, navigational markers, lighthouses, etc.), utilizing the periscopes for obtaining lines of position to plot a triangulation fix.
*[[Pilotage]]—in coastal and [[internal waters]], surfaced submarines rely on the standard system of navigational aids (buoys, navigational markers, lighthouses, etc.), utilizing the periscopes for obtaining lines of position to plot a triangulation fix.
*[[Voyage Management System]]—referred to as the VMS, utilizes digital charts with other external sources fed in, to establish the ship's position. Other information may also be entered in manually in establishing a high quality fix or position.
*[[Voyage Management System]]—referred to as the VMS, utilizes digital charts with other external sources fed in, to establish the ship's position. Other information may also be entered in manually in establishing a high quality fix or position.


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*[[Dead reckoning#Marine navigation|Dead reckoning]] [[Course (navigation)|course information]] obtained from the ship's [[gyrocompass]], [[Pit sword|measured speed]] and estimates of local ocean currents, this could also be considered an estimated position as long as the ocean current is computed in.
*[[Dead reckoning#Marine navigation|Dead reckoning]] [[Course (navigation)|course information]] obtained from the ship's [[gyrocompass]], [[Pit sword|measured speed]] and estimates of local ocean currents, this could also be considered an estimated position as long as the ocean current is computed in.
*[[Inertial navigation system]] is an estimated position source, utilizing acceleration, deceleration, and pitch and roll for computing.
*[[Inertial navigation system]] is an estimated position source, utilizing acceleration, deceleration, and pitch and roll for computing.
*Bottom contour navigation may be used in areas where detailed [[Hydrography|hydrographic]] data has been charted and there is adequate variation in sea floor topography.<ref>{{cite web|url=http://www2.ku.edu/~kunrotc/academics/300/Lesson14%20Electronic%20Navigation.ppt |title=Lesson 14: Electronic Navigation |accessdate=2007-11-14 |format=[[Microsoft PowerPoint]] |work=Navigation and Operations I |publisher=[[University of Kansas]], [[Naval Reserve Officer Training Corps]] |pages=Slides 19 to 21 |deadurl=yes |archiveurl=https://web.archive.org/web/20060911053132/http://www2.ku.edu/~kunrotc/academics/300/Lesson14%20Electronic%20Navigation.ppt |archivedate=September 11, 2006 }}</ref><ref>{{cite web
*Bottom contour navigation may be used in areas where detailed [[Hydrography|hydrographic]] data has been charted and there is adequate variation in sea floor topography.<ref>{{cite web|url=http://www2.ku.edu/~kunrotc/academics/300/Lesson14%20Electronic%20Navigation.ppt |title=Lesson 14: Electronic Navigation |access-date=2007-11-14 |format=[[Microsoft PowerPoint]] |work=Navigation and Operations I |publisher=[[University of Kansas]], [[Naval Reserve Officer Training Corps]] |pages=Slides 19 to 21 |url-status=dead |archive-url=https://web.archive.org/web/20060911053132/http://www2.ku.edu/~kunrotc/academics/300/Lesson14%20Electronic%20Navigation.ppt |archive-date=September 11, 2006 }}</ref><ref>{{cite web
|url=https://www.navigator.navy.mil/navigator/ECDIS/Policy_Standards/CJCSI_6130_01C_MasterPNT.pdf
|url=https://www.navigator.navy.mil/navigator/ECDIS/Policy_Standards/CJCSI_6130_01C_MasterPNT.pdf
|title=2003 CJCS Master Positioning, Navigation, And Timing Plan
|title=2003 CJCS Master Positioning, Navigation, And Timing Plan
|accessdate=2007-11-14
|access-date=2007-11-14
|format=PDF
|publisher=[[Joint Chiefs of Staff]]
|publisher=[[Joint Chiefs of Staff]]
|page=F-12
|page=F-12
|deadurl=yes
|url-status=dead
|archiveurl=https://web.archive.org/web/20070705104016/https://www.navigator.navy.mil/navigator/ECDIS/Policy_Standards/CJCSI_6130_01C_MasterPNT.pdf
|archive-url=https://web.archive.org/web/20070705104016/https://www.navigator.navy.mil/navigator/ECDIS/Policy_Standards/CJCSI_6130_01C_MasterPNT.pdf
|archivedate=2007-07-05
|archive-date=2007-07-05
}}</ref><ref>{{cite news | first = Hamn | last = S. E.| title = Coastal piloting: bottom contour navigation.(Seamanship) | url = http://findarticles.com/p/articles/mi_hb5263/is_199508/ai_n20411943| publisher = Trailer Boats | date = August 1995 | access-date = 2007-11-14}} {{Dead link|date=October 2010|bot=H3llBot}}</ref> [[Echo sounding|Fathometer]] depth measurements are compared to [[Nautical chart|charted depth]] patterns.
|df=
}}</ref><ref>{{cite news | first = Hamn | last = S. E.| title = Coastal piloting: bottom contour navigation.(Seamanship) | url = http://findarticles.com/p/articles/mi_hb5263/is_199508/ai_n20411943| publisher = Trailer Boats | date = August 1995 | accessdate = 2007-11-14}} {{Dead link|date=October 2010|bot=H3llBot}}</ref> [[Echo sounding|Fathometer]] depth measurements are compared to [[Nautical chart|charted depth]] patterns.


==See also==
==See also==
*[[Bearing (navigation)]]
*{{annotated link|Bearing (angle)}}
*[[Sonar#Passive sonar|Passive sonar]]
*{{annotated link|Sonar#Passive sonar|Passive sonar}}
*[[Underwater navigation|Underwater navigation by divers]]
*{{annotated link|Diver navigation}}
*{{annotated link|Underwater acoustic positioning system}}


==Footnotes==
==Footnotes==
Line 52: Line 50:


==References==
==References==
*{{cite book | last = Clancy | first = Tom | authorlink = Tom Clancy |author2=John Gresham | title = Submarine: A Guided Tour Inside a Nuclear Warship | origyear = 1993 | edition = Revised | date = 2002-01-08 | publisher = Berkley Books | location = | isbn = 978-0-425-18300-7 }}
*{{cite book | last = Clancy | first = Tom | author-link = Tom Clancy | author2 = John Gresham | title = Submarine: A Guided Tour Inside a Nuclear Warship | orig-year = 1993 | edition = Revised | date = 2002-01-08 | publisher = [[Berkley Books]] | isbn = 978-0-425-18300-7 | url = https://archive.org/details/submarineguidedt00clan }}
*{{cite book | last = Craven | first = John Piña | authorlink = John Piña Craven | title = The Silent War: The Cold War Battle Beneath the Sea | publisher = Simon & Schuster | location = New York, New York | isbn = 978-0-684-87213-1 }}
*{{cite book | last = Craven | first = John Piña | author-link = John Piña Craven | title = The Silent War: The Cold War Battle Beneath the Sea | year = 2001 | publisher = Simon & Schuster | location = New York, New York | isbn = 978-0-684-87213-1 | url = https://archive.org/details/silentwarcoldwar00crav }}
*{{cite book | last = DiMercurio | first = Michael |author2=Michael Benson | title = Complete Idiot's Guide to Submarines | publisher = Alpha Books | location = Indianapolis, Indiana | isbn = 978-0-02-864471-4 }}
*{{cite book | last = DiMercurio | first = Michael |author2=Michael Benson | title = Complete Idiot's Guide to Submarines | date = 23 December 2002 | publisher = Alpha Books | location = Indianapolis, Indiana | isbn = 978-0-02-864471-4 }}
*{{cite book | last = Harris | first = Brayton | title = Navy Times Book of Submarines | edition = 1st | publisher = Berkley Hardcover | location = New York, New York | isbn = 978-0-425-15777-0 }}
*{{cite book | last = Harris | first = Brayton | title = Navy Times Book of Submarines | year = 1997 | edition = 1st | publisher = Berkley Hardcover | location = New York, New York | isbn = 978-0-425-15777-0 }}
*{{cite book | last = Hutchinson | first = Robert | title = Jane's Submarines: War Beneath the Waves from 1776 to the Present Day | publisher = HarperCollins Publishers | location = | isbn = 978-0-06-081900-2 }}
*{{cite book | last = Hutchinson | first = Robert | title = Jane's Submarines: War Beneath the Waves from 1776 to the Present Day | year = 2001 | url = https://archive.org/details/janessubmarinesw0000hutc | url-access = registration | publisher = HarperCollins Publishers | isbn = 978-0-06-081900-2 }}
*{{cite book | last = Leary | first = William M. |author-link=William M. Leary | title = Under Ice: Waldo Lyon and the Development of the Arctic Submarine | year = 1999 | edition = 1st | publisher = Texas A&M University Press | location = College Station, Texas | isbn = 978-0-89096-845-1 }}
*{{cite book | last = Leary | first = William M. |author-link=William M. Leary | title = Under Ice: Waldo Lyon and the Development of the Arctic Submarine | year = 1999 | edition = 1st | publisher = Texas A&M University Press | location = College Station, Texas | isbn = 978-0-89096-845-1 }}
*{{cite book | last = Miller | first = David | title = Modern Submarine Warfare | edition = 1st | publisher = Crescent | isbn = 978-0-517-64647-2 }}
*{{cite book | last = Miller | first = David | title = Modern Submarine Warfare | year = 1987 | edition = 1st | publisher = Crescent | isbn = 978-0-517-64647-2 | url = https://archive.org/details/modernsubmarinew00mill }}
*{{cite book | last = Parrish | first = Tom | title = The Submarine: A History | publisher = Viking Penguin | location = New York, New York | language = | isbn = 978-0-670-03313-3 }}
*{{cite book | last = Parrish | first = Tom | title = The Submarine: A History | year = 2004 | publisher = Viking Penguin | location = New York, New York | isbn = 978-0-670-03313-3 | url = https://archive.org/details/submarinehistory00parr }}
*{{cite book | last = Preston | first = Antony | authorlink = Antony Preston (naval historian) | title = Submarine Warfare: An Illustrated History | origdate = | year = 1999 | publisher = Thunder Bay Press | location = San Diego, California | isbn = 978-1-57145-172-9 }}
*{{cite book | last = Preston | first = Antony | author-link = Antony Preston (naval historian) | title = Submarine Warfare: An Illustrated History | year = 1999 | publisher = Thunder Bay Press | location = San Diego, California | isbn = 978-1-57145-172-9 }}
*{{cite book | last = van der Vat | first = Dan | authorlink = Dan van der Vat | title = Stealth at Sea: The History of the Submarine | publisher = Houghton Mifflin | location = | isbn = 978-0-395-65242-8 }}
*{{cite book | last = van der Vat | first = Dan | author-link = Dan van der Vat | title = Stealth at Sea: The History of the Submarine | year = 1995 | publisher = Houghton Mifflin | isbn = 978-0-395-65242-8 | url-access = registration | url = https://archive.org/details/stealthatseahist0000vand }}
*{{cite book | last = Waller | first = Douglas C. | authorlink = Douglas C. Waller | title = Big Red: Three Months on Board a Trident Nuclear Submarine | publisher = HarperCollins Publishers | location = | isbn = 978-0-06-019484-0 }}
*{{cite book | last = Waller | first = Douglas C. | author-link = Douglas C. Waller | title = Big Red: Three Months on Board a Trident Nuclear Submarine | date = March 2001 | publisher = HarperCollins Publishers | isbn = 978-0-06-019484-0 | url = https://archive.org/details/bigredthreemonth00wall }}


[[Category:Navigation]]
[[Category:Navigation]]

Latest revision as of 10:34, 8 July 2023

Submarine navigation underwater requires special skills and technologies not needed by surface ships. The challenges of underwater navigation have become more important as submarines spend more time underwater, travelling greater distances and at higher speed. Military submarines travel underwater in an environment of total darkness with neither windows nor lights. Operating in stealth mode, they cannot use their active sonar systems to ping ahead for underwater hazards such as undersea mountains, drilling rigs or other submarines. Surfacing to obtain navigational fixes is precluded by pervasive anti-submarine warfare detection systems such as radar and satellite surveillance. Antenna masts and antenna-equipped periscopes can be raised to obtain navigational signals but in areas of heavy surveillance, only for a few seconds or minutes;[1] current radar technology can detect even a slender periscope while submarine shadows may be plainly visible from the air.

A submarine at periscope depth risks visual or radar detection
Submarines can raise various antenna masts, radar masts and periscopes to facilitate communications and navigation
[edit]

Surfaced submarines entering and leaving port navigate similarly to traditional ships but with a few extra considerations because most of the boat rides below the waterline, making them hard for other vessels to see and identify. Submarines carry an inertial navigation system, which measures the boat’s motion and constantly updates position. Because it does not rely on radio signals or celestial sightings, it allows the boat to navigate while remaining hidden under the surface. To maintain accuracy, the submarine must periodically update its position using outside navigational radio signals. From the 1960s to the 1990s, Transit satellites and LORAN shore stations provided those signals. GPS has now replaced both.

Surface and near-surface navigation

[edit]

On the surface or at periscope depth, submarines have used these methods to fix their position:

  • Satellite navigation:
  • Terrestrial radio-based navigation systems; largely superseded by satellite systems
    • LORAN—Low frequency radio hyperbolic navigation system, no longer in use
    • CHAYKA, the Russian counterpart of LORAN
    • OMEGA, Western very low frequency global-range radio hyperbolic navigation system, no longer in use
    • Alpha, the Russian counterpart of the Omega Navigation System
  • Celestial navigation using the periscope, or sextant—seldom used anymore due to advancement in technology
  • Radar navigation; radar signals are easily detected so radar is normally only used in friendly waters entering and exiting ports. With the implementation of a more advanced radar system, many new techniques have been implemented in this process.
  • Active sonar; like radar, active sonar systems are readily detected, so active sonar is usually used only entering and exiting ports.
  • Pilotage—in coastal and internal waters, surfaced submarines rely on the standard system of navigational aids (buoys, navigational markers, lighthouses, etc.), utilizing the periscopes for obtaining lines of position to plot a triangulation fix.
  • Voyage Management System—referred to as the VMS, utilizes digital charts with other external sources fed in, to establish the ship's position. Other information may also be entered in manually in establishing a high quality fix or position.

Deep water navigation

[edit]

At depths below periscope depth submarines determine their position using:

See also

[edit]

Footnotes

[edit]
  1. ^ Bivens, Arthur Clarke (July 2004). From Sailboats to Submarines. Infinity Publishing. p. 184. ISBN 978-0-7414-2152-4.
  2. ^ "Lesson 14: Electronic Navigation". Navigation and Operations I. University of Kansas, Naval Reserve Officer Training Corps. pp. Slides 19 to 21. Archived from the original (Microsoft PowerPoint) on September 11, 2006. Retrieved 2007-11-14.
  3. ^ "2003 CJCS Master Positioning, Navigation, And Timing Plan" (PDF). Joint Chiefs of Staff. p. F-12. Archived from the original (PDF) on 2007-07-05. Retrieved 2007-11-14.
  4. ^ S. E., Hamn (August 1995). "Coastal piloting: bottom contour navigation.(Seamanship)". Trailer Boats. Retrieved 2007-11-14. [dead link]

References

[edit]