Abstract
We review different approaches to the variational assimilation of radio occultation (RO) observations into models of global atmospheric circulation. We derive the general equation for the bending angle that reduces to the Abel integral for a spherically layered atmosphere. We review the full 3-D observation operator for bending angles, which provides the strictest solution, but is also most computationally expensive. Commonly used is the 2-D approximation that allows treating rays as plane curve. We discuss a simple 1-D approach to the assimilation of bending angles. The observation operator based on the standard form of the Abel integral has a disadvantage, because it cannot account for waveguides. Alternative approaches use 1-D ray-tracing. The most straightforward way is to use the same framework as for the 3-D observation operator, with the refractivity field reduced to a single profile independent from the horizontal coordinates. An alternative 1-D ray-tracing approach uses the form of ray equation in a spherically layered medium that uses an invariant. The assimilation of refractivity has also 1-D and 3-D options. We derive a new simple form of the refractivity-mapping operator. We present the results of numerical tests of different 3-D and 1-D observation operators, based on Spire data.
Highlights
Radio occultation observations have always been looked at as an important source of data for numerical weather prediction (NWP) [1,2,3,4,5]
Because the application of data processing techniques based on Fourier Integral Operators, implementing canonical transforms in the wave optics, allows the retrieval of GO bending angles, the problem can be reduced to the geometrical optics
The basic equations for the bending angle can be directly derived from the wave equation, which can be solved under the GO approximation
Summary
Radio occultation observations have always been looked at as an important source of data for numerical weather prediction (NWP) [1,2,3,4,5]. A general approach to the use of observations in NWP is based on the variational data assimilation [6]. A way of the implementation of this approach for radio occultation (RO) observation was first discussed by Eyre [7], who applied the finite difference technique for the explicit derivation of the 3-D adjoint operator based on the ray-tracing. The bending angle was defined as the angle between the initial and final ray direction. This operator was successfully tested by Zou et al [10] and used by Liu et al [11] and enhanced by Liu and Zou [12]. This approach is referred to as 2-D approach, because it is a good approximation to consider rays as plane curves, i.e., to neglect the transverse displacement of a ray
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