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PhysicalConstants.jl provides common physical constants. They are defined as
instances of the new Constant type, which is subtype of AbstractQuantity
(from Unitful.jl package) and can
also be turned into Measurement objects (from
Measurements.jl package) at
request.
Constants are grouped into different submodules, so that the user can choose different datasets as needed. Currently, 2014 and 2018 editions of CODATA recommended values of the fundamental physical constants are provided.
The latest version of PhysicalConstants.jl is available for Julia 1.0 and
later versions, and can be installed with Julia built-in package
manager. After entering the
package manager mode by pressing ], run the command
pkg> add PhysicalConstantsYou can load the package as usual with using PhysicalConstants but this module
does not provide anything useful for the end-users. You most probably want to
directly load the submodule with the dataset you are interested in. For
example, for CODATA 2018 load PhysicalConstants.CODATA2018:
julia> using PhysicalConstants.CODATA2018
julia> SpeedOfLightInVacuum
Speed of light in vacuum (c_0)
Value = 2.99792458e8 m s^-1
Standard uncertainty = (exact)
Relative standard uncertainty = (exact)
Reference = CODATA 2018
julia> NewtonianConstantOfGravitation
Newtonian constant of gravitation (G)
Value = 6.6743e-11 m^3 kg^-1 s^-2
Standard uncertainty = 1.5e-15 m^3 kg^-1 s^-2
Relative standard uncertainty = 2.2e-5
Reference = CODATA 2018SpeedOfLightInVacuum and NewtonianConstantOfGravitation are two of the
PhysicalConstants defined in the PhysicalConstants.CODATA2018 module, the
full list of available constants is given below.
PhysicalConstants can be readily used in mathematical operations, using by
default their Float64 value:
julia> import PhysicalConstants.CODATA2018: c_0, ε_0, μ_0
julia> 2 * ε_0
1.77083756256e-11 F m^-1
julia> ε_0 - 1 / (μ_0 * c_0 ^ 2)
-3.8450973786644646e-25 A^2 s^4 kg^-1 m^-3If you want to use a different precision for the value of the constant, use the
function float(float_type, constant), for example:
julia> float(Float32, ε_0)
8.854188f-12 F m^-1
julia> float(BigFloat, ε_0)
8.854187812799999999999999999999999999999999999999999999999999999999999999999973e-12 F m^-1
julia> big(ε_0)
8.854187812799999999999999999999999999999999999999999999999999999999999999999973e-12 F m^-1
julia> big(ε_0) - inv(big(μ_0) * big(c_0)^2)
-3.849883307464075736533920296598236938395867709081184624499315166190408485179288e-25 A^2 s^4 kg^-1 m^-3Note that big(constant) is an alias for float(BigFloat, constant).
If in addition to units you also want the standard uncertainty associated with
the constant, use measurement(x):
julia> using Measurements
julia> import PhysicalConstants.CODATA2018: h, ħ
julia> measurement(ħ)
1.0545718176461565e-34 ± 0.0 J s
julia> measurement(Float32, ħ)
1.0545718e-34 ± 0.0 J s
julia> measurement(BigFloat, ħ)
1.054571817646156391262428003302280744722826330020413122421923470598435912734741e-34 ± 0.0 J s
julia> measurement(BigFloat, ħ) / (measurement(BigFloat, h) / (2 * big(pi)))
1.0 ± 0.0For more information read the documentation, which includes the full list of constants defined by the package.
The PhysicalConstants.jl package is licensed under the MIT "Expat" License.
The original author is Mosè Giordano.