• Source: Navigational algorithms

The navigational algorithms are the quintessence of the executable software on portable calculators or smartphones as an aid to the art of navigation, this attempt article describe both algorithms and software for smartphones implementing different calculation procedures for navigation. The calculation power obtained by the languages—Basic, C, Java, etc.—from portable calculators or smartphones, has made it possible to develop programs that allow calculating the position without the need for tables, in fact they have some basic tables with the correction factors for each year and calculate the values "on the fly" at runtime.




Comparison between manual calculation methods and the use of calculators



The traditional methods require bulky and expensive nautical tables (which must be uSmartphoneted), pencil and paper, and calculation time, following the working algorithms.
Calculators (and the like) do not need books (they have tables and ephemeris integrated) and, with their own algorithms, allow quick and error-free calculation of navigation problems.




Types of algorithms


Celestial navigation: Sight reduction, circle of equal altitude, Line Of Position, Fix...
Positional astronomy: RA, GHA, Dec
Coastal navigation: Range, Bearing, Horizontal angles, IALA...
Sailings: Rhumbs, Loxodromic, Orthodromic, Meridional parts...
Weather, tides
Software PC- Smartphone: Nautical Almanac, Sailings, Variation, Sextant corrections




Programs for general navigation


Programs on the nautical chart, directions, coastal navigation and beacons, nautical publications. The astronomical navigation section includes the resolution of the position triangle, the usefulness of a height line, the recognition of stars and the determinant of the height line, in addition to other topics of interest in nautical: tides, naval kinematics, meteorology and hurricanes, and oceanography. All heading measurements made with a magnetic compass or compass must be corrected for magnetic declination or local variation.




= Coordinate conversion subroutine

=
sub Rectang2Polar (a () as double, b () as double) static
'----- Subprograma para convertir un vector de estado coord.cartesianas
'----- En vector de estado en coord.polars.
'----- De entrada: vector de estado en coord.cartesianes
'----- De salida: vector de estado en coord.polars.
'----- NOTA: El vector de velocidad polar es el de la velocidad total,
'----- Corregido por el efecto de la latitud.
'------------------------------------------------- ------------------------
mar x as double
mar y as double
mar z as double
mar x_dot as double
mar y_dot as double
mar z_dot as double
mar rho as double
mar r as double
mar lambda as double
mar beta as double
mar lambda_dot as double
mar beta_dot as double
mar r_dot as double
x = a (1)
y = a (2)
z = a (3)
x_dot = a (4)
y_dot = a (5)
z_dot = a (6)
rho = sqr (x * x+y * y)
r = sqr (rho * rho+z * z)
lambda = atan2 (y, x)
beta = atan2 (z, rho)
if (z <0 #) then beta = beta - TWOPI
yf rho = 0 # then
lambda_dot = 0 #
beta_dot = 0 #
else
lambda_dot = (x * y_dot - y * x_dot)/(rho * rho)
beta_dot = (z_dot * rho * rho - z * (x * x_dot+_
y * y_dot))/(r * r * rho)
end if
r_dot = (x * x_dot+y * y_dot+z * z_dot)/r
'----- Componentes del vector de posición
b (1) = lambda
if b (1)> = TWOPI then b (1) = b (1) - TWOPI
b (2) = beta
b (3) = r
'----- Componentes del vector velocidad total
b (4) = r * lambda_dot * cuerpo (beta)
b (5) = r * beta_dot
b (6) = r_dot
end sub




Programs for astronomical navigation


Advanced navigation algorithms include piloting and astronomical navigation: loxodromia and orthodromia. Height correction of the sextant . Astronomical position with calculator, template and blank mercantile chart. Position by 2 Lines of Height. Position from n Height Lines. Vector equation of the Height Circle. Position for vector solution from two observations. Position by Height Circles: matrix solution. And articles related to ancient procedures such as obtaining latitude by the pole star, the meridian, the method of lunar distances , etc.




= Programs for the "Nautical Almanac"

=
Ephemerides of the celestial bodies used in navigation.
GHA - Greenwich Hour Angle
Dec - Declination
SD - Semidiameter
HP - Horizontal Parallax
s the solution for course and SOG.




= CelestialFix

=
They solve the problem of calculating the position from observations of the stars made with the sextant in Astronomical Navigation.
Algorithm implementation:
For n = 2 observations

An analytical solution of the two star sight problem of celestial navigation, James A. Van Allen.
Vector Solution for the Intersection of two Circles of Equal Altitude. Andrés Ruiz.
For n ≥ 2 observations

DeWit/USNO Nautical Almanac/Compac Data, Least squares algorithm for n LOPs
Kaplan algorithm, USNO. For n ≥ 8 observations, gives the solution for course and SOG.




= Magnetic declination

=
Any measure of course made with a magnetic compass must be corrected because of the magnetic declination or local variation.




See also


American Practical Navigator
Celestial navigation
Institute of Navigation (NAVIGATION journal)
Lunar distance (navigation)
Nautical almanac
Navigation
Rhumbline network
Royal Institute of Navigation (Journal of Navigation)
Sextant
Shortest path problem and automotive navigation, for navigational algorithms in other domains




References






External links


González, Andrés Ruiz (2008-03-25). "Vector Solution for the Intersection of Two Circles of Equal Altitude". Journal of Navigation. 61 (2). Cambridge University Press (CUP): 355–365. doi:10.1017/s0373463307004602. ISSN 0373-4633. S2CID 130293359.
Journal of Navigation (en inglés)
The Institute of Navigation (en inglés)
Navigational Algorithms

Kata Kunci Pencarian:

• Graph database
• Navigational algorithms
• Rhumb line
• Longitude by chronometer
• Lunar distance (navigation)
• Sight reduction
• Tide table
• A* search algorithm
• Pathfinding
• Isoazimuth
• D*