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The method yields a [[line of position]] (LOP) on which the observer is situated. The intersection of two or more such lines will define the observer's position, called a "fix". Sights may be taken at short intervals, usually during hours of twilight, or they may be taken at an interval of an hour or more (as in observing the Sun during the day). In either case, the lines of position, if taken at different times, must be advanced or retired to correct for the movement of the ship during the interval between observations. If observations are taken at short intervals, a few minutes at most, the corrected lines of position by convention yield a "fix". If the lines of position must be advanced or retired by an hour or more, convention dictates that the result is referred to as a "running fix".
== Summary ==
The intercept method is based on the following principle.
The actual distance from the observer
[[Image:Diagram showing GP distance = ZD.jpg|thumb|right|500px
The diagram on the right shows why the zenith distance of a celestial body is equal to the angular distance of its GP from the observer's position.
The rays of light from a celestial body are assumed to be parallel (unless the observer is looking at the moon, which is too close for such a simplification). The angle at the centre of the
Taking a sight using the intercept method consists of the following process:
* Observe the altitude above the horizon '''Ho''' of a celestial body and note the time of the observation.
* Assume a certain geographical position (lat., lon.), it does not matter which one so long as it is within, say, 50 NM of the actual position (or even 100 NM would not introduce too much error). Compute the altitude '''Hc''' and azimuth '''Zn''' with which an observer situated at that assumed position would observe the body.
* If the actual observed altitude Ho is smaller than the computed altitude Hc this means the observer is farther away from the body than the observer at the assumed position, and
* On the chart he marks the assumed position '''AP''' and draws a line in the direction of the azimuth Zn. He then measures the intercept distance along this azimuth line, towards the body if Ho>Hc and away from it if Ho<Hc. At this new point he draws a perpendicular to the azimuth line and that is the line of position '''LOP''' at the moment of the observation.
* The reason that the chosen AP is not important (within limits) is that if a position closer to the body is chosen then Hc will be greater but the distance will be measured from the new AP which is closer to the body and the end resulting LOP will be the same.
==Methodology==
[[Image:
Suitable bodies for celestial sights are selected, often using a Rude Star Finder. Using a [[sextant]], an altitude is obtained of the
The first step in sight reduction is to correct the sextant altitude for various errors and corrections. The instrument may have an error, IC or index correction (
Next, using an accurate clock, the observed celestial object's geographic position (''GP'') is looked up in an almanac. That's the point on the Earth's surface directly below it (where the object is in the [[zenith]]). The latitude of the geographic position is called declination, and the longitude is usually called the [[hour angle]].
Next, the altitude and azimuth of the celestial body are computed for a selected position (assumed position or AP). This involves resolving a spherical triangle. Given the three magnitudes local hour angle, LHA, observed body's declination, dec., and assumed latitude, lat, the altitude Hc and azimuth Zn must be computed.▼
▲Next, the altitude and azimuth of the celestial body are computed for a selected position (assumed position or AP). This involves resolving a spherical triangle. Given the three magnitudes: local hour angle
The relevant formulas are ▼
The relevant formulas (derived using the [[spherical trigonometric identities]]) are:
Sin(Hc) = Sin(lat) * Sin(dec) + Cos(lat) * Cos(dec) Cos(LHA)▼
▲:
: <math>\begin{align}
\tan(Zn) = \tan(Zn \pm 180) &= \frac{\sin(LHA)}{\sin(lat) \cdot \cos(LHA) - \cos(lat) \cdot \tan(dec)} \triangleq tanZ \\
Z &= arctan(tanZ) \text{ } \in [-90,+90] \\
Zn &= \begin{cases}
Z+180 & \text{if }LHA \in [90,270]\\
Z+360 & \text{if }LHA \in [270,360] && \equiv \text{ mod 360}\\
\end{cases} \\
\end{align}</math>
:The adjustment from Z to Zn (which is in <math>[0,360]</math>, and measured from North) has two reasons:
::(1)The angles in [0,360] with the same <math>\tan</math> is not unique (since <math>\tan(X) = tan (X \pm 180)</math>), but <math>\arctan</math> is defined only in <math>[-90,90]</math>.
::(2)The negative angle must be adjusted to positive angle.
or, alternatively,
▲ cos(lat) * cos(Hc)
: <math>\begin{align}
\cos(\pm Zn) &= \frac{\sin(dec) - \sin(lat) \cdot \sin(Hc)}{\cos(lat) \cdot \cos(Hc)} \triangleq cosZ \\
Z & = \arccos(cosZ) \text { } \in [0,180] \\
Zn &= \begin{cases}
+Z & \text{if }LHA \in [180,360] \\
-Z+360 & \text{if }LHA \in [0,180] \\
\end{cases} \\
\end{align}</math>
:The adjustment for disambiguating <math>\cos</math> values has similar reasons.
Where
:''Hc'' = Computed altitude
:''Zn'' = Computed azimuth (Zn=0 at North)
:''Z'' = preliminary result for Zn (in some nautical almanacs)<ref name="Training_Movie_CelNav">{{cite web
| title = Celestial Navigation
| website = youtube.com
| date = 11 January 2015
| url = https://www.youtube.com/watch?v=fn9xMkNUMmY&t=1592s
| at = about 26m32s (1h33m31s)
| language=en
| access-date=July 1, 2022
}}</ref>
:''lat'' = Latitude
:''dec'' = Declination
:''LHA'' = Local Hour Angle
: <math>\
Where CompHc is the zenith distance or complement of Hc. CompHc = 90º - Hc▼
''{{overline|Hc}}'' = 90° - ''Hc''.
: <math> \operatorname{hav}(Zn) = \frac{ \cos(lat - Hc) - \sin(dec)}{2 \cdot \cos(lat) \cdot \cos(Hc)}</math>
When using such tables or a computer or scientific calculator, the navigation triangle is solved directly, so any assumed position can be used. Often the dead reckoning DR position is used. This simplifies plotting and also reduces any slight error caused by plotting a segment of a circle as a straight line.
With the use of
Professional navigators are
The precise ___location of the assumed position has no great impact on the result, as long as it is reasonably close to the observer's actual position. An assumed position within 1 degree of arc of the observer's actual position is usually considered acceptable.
The calculated altitude (''Hc'') is compared to the observed altitude (''Ho'', sextant altitude
Navigators use the memory aid "computed greater away" to determine whether the observer is farther from the body's geographic position (measure intercept from ''Hc'' away from the azimuth). If the ''Hc'' is less than ''Ho'', then the observer is closer to the body's geographic position, and intercept is measured from the AP toward the azimuth direction.
The last step in the process is to plot the lines of position ''LOP'' and determine the vessel's ___location. Each assumed position is plotted first. Best practise is to then advance or retire the assumed positions to correct for vessel motion during the interval between sights. Each LOP is then constructed from its associated AP by striking off the azimuth to the body, measuring intercept toward or away from the azimuth, and constructing the perpendicular line of position.
To obtain a fix (a position) this ''LOP'' must be crossed with another ''LOP'' either from another sight or from elsewhere e.g. a bearing of a point of land or crossing a depth contour such as the 200 metre depth line on a chart.
==Sights==
Until the age of satellite navigation ships usually took sights at dawn, during the forenoon, at noon (meridian transit of the Sun) and dusk. The morning and evening sights were taken during twilight while the [[horizon]] was visible and the stars, planets and/or
==Running fix==
A fix is called a ''running fix'' when one or more of the LOPs used to obtain it is an LOP advanced or retrieved over time.
Any sight can be advanced and used to obtain a ''running fix''. It may be that the navigator due to weather conditions could only obtain a single sight at dawn. The resulting LOP can then be advanced when, later in the morning, a Sun observation becomes possible. The precision of a running fix depends on the error in distance and course so, naturally, a running fix tends to be less precise than an unqualified fix and the navigator must take into account his confidence in the exactitude of distance and course to estimate the resulting error in the running fix.
Determining a fix by crossing LOPs and advancing LOPs to get running fixes are not specific to the intercept method and can be used with any sight reduction method or with LOPs obtained by any other method (bearings, etc.).
== See also ==
* [[
* [[Circle of equal altitude]]
* [[navigation]]▼
* [[
▲* [[Intersection (air navigation)]]
* [[Intersection (land navigation)]]
* [[Navigation]]
* [[Latitude]]
* [[Longitude]]
* [[Haversine formula]]
* [[Longitude by chronometer]]
==References==
{{Reflist}}
*''Nicholls's Concise Guide, Volume 1'', by Charles H. Brown F.R.S.G.S. Extra Master
*''Norie's Nautical Tables'', edited by Capt. A.G. Blance
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==External links==
* ''Navigational Algorithms'' http://sites.google.com/site/navigationalalgorithms/
*[https://web.archive.org/web/20080430060810/http://www.smartcomsoftware.com/winastro.html WinAstro sight reduction software]▼
▲*[http://www.smartcomsoftware.com/winastro.html WinAstro sight reduction software]
*[http://www.navigation-spreadsheets.com/navigation_triangles.html Navigation Spreadsheets: Navigation Triangles]
[[Category:Navigation]]
[[Category:Celestial navigation]]
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