calins: Caloric insolation
In mcrucifix/palinsol: Insolation for Palaeoclimate Studies
calins R Documentation
Caloric insolation
Description
Computes caloric summer insolation for a given astronomical configuration
and latitude.
Usage
calins(orbit, lat = 65 * pi/180, ...)
Arguments
orbit
Output from a solution, such as ber78, ber90 or
la04
lat
latitude
...
Other arguments passed to Insol
Details
The caloric summer is a notion introduced by M. Milankovitch. It is defined
as the halve of the tropical year during for which daily mean insolation are
greater than all days of the other halves. The algorithm is an original
algorithm by M. Crucifix, but consistent with earlier definitions and
algorithms by A. Berger (see examples). Do not confuse this Berger (1978)
reference with the Berger (1978), J. Atm. Sci. of the astronomical solution.
Value
Time-integrated insolation in kJ/m2 during the caloric summer.
Author(s)
Michel Crucifix, U. catholique de Louvain, Belgium.
References
Berger (1978) Long-term variations of caloric insolation
resulting from the earth's orbital elements, Quaternary Research, 9, 139 -
167.
Examples
## reproduces Table 2 of Berger 1978
lat <- seq(90, 0, -10) * pi/180. ## angles in radians.
orbit_1 = ber78(0)
orbit_2 = orbit_1
orbit_2 ['eps'] = orbit_2['eps'] + 1*pi/180.
T <- sapply(lat, function(x) c(lat = x * 180/pi,
calins(orbit_2, lat=x, S0=1365) / (4.18 * 1e1)
- calins(orbit_1, lat=x, S0=1365) / (4.18 * 1e1) ) )
data.frame(t(T))
# there are still some differences, of the order of 0.3 %, that are probably related to
# the slightly different methods.
# 41.8 is the factor from cal/cm2 to kJ/m2
mcrucifix/palinsol documentation built on Oct. 24, 2023, 1:35 a.m.
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| calins | R Documentation |
Caloric insolation
Description
Computes caloric summer insolation for a given astronomical configuration and latitude.
Usage
calins(orbit, lat = 65 * pi/180, ...)
Arguments
orbit |
Output from a solution, such as |
lat |
latitude |
... |
Other arguments passed to Insol |
Details
The caloric summer is a notion introduced by M. Milankovitch. It is defined as the halve of the tropical year during for which daily mean insolation are greater than all days of the other halves. The algorithm is an original algorithm by M. Crucifix, but consistent with earlier definitions and algorithms by A. Berger (see examples). Do not confuse this Berger (1978) reference with the Berger (1978), J. Atm. Sci. of the astronomical solution.
Value
Time-integrated insolation in kJ/m2 during the caloric summer.
Author(s)
Michel Crucifix, U. catholique de Louvain, Belgium.
References
Berger (1978) Long-term variations of caloric insolation resulting from the earth's orbital elements, Quaternary Research, 9, 139 - 167.
Examples
## reproduces Table 2 of Berger 1978
lat <- seq(90, 0, -10) * pi/180. ## angles in radians.
orbit_1 = ber78(0)
orbit_2 = orbit_1
orbit_2 ['eps'] = orbit_2['eps'] + 1*pi/180.
T <- sapply(lat, function(x) c(lat = x * 180/pi,
calins(orbit_2, lat=x, S0=1365) / (4.18 * 1e1)
- calins(orbit_1, lat=x, S0=1365) / (4.18 * 1e1) ) )
data.frame(t(T))
# there are still some differences, of the order of 0.3 %, that are probably related to
# the slightly different methods.
# 41.8 is the factor from cal/cm2 to kJ/m2
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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