Sullivan, D., Rosenfeld, L., Smith, S., & Murphree, T. (2010). Oceanographic instrumentation technician, Knowledge and Skill Guidelines for Marine Science and Technology. Monterey, CA: Marine Advanced Technology Education Center.
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Sun, J., & Wu, Z. (2019). Isolating spatiotemporally local mixed Rossby-gravity waves using multi-dimensional ensemble empirical mode decomposition. Clim Dyn, (3-4), 1383–1405.
Abstract: Tropical waves have relatively large amplitudes in and near convective systems, attenuating as they propagate away from the area where they are generated due to the dissipative nature of the atmosphere. Traditionally, nonlocal analysis methods, such as those based on the Fourier transform, are applied to identify tropical waves. However, these methods have the potential to lead to the misidentification of local wavenumbers and spatial locations of local wave activities. To address this problem, we propose a new method for analyzing tropical waves, with particular focus placed on equatorial mixed Rossby-gravity (MRG) waves. The new tropical wave analysis method is based on the multi-dimensional ensemble empirical mode decomposition and a novel spectral representation based on spatiotemporally local wavenumber, frequency, and amplitude of waves. We first apply this new method to synthetic data to demonstrate the advantages of the method in revealing characteristics of MRG waves. We further apply the method to reanalysis data (1) to identify and isolate the spatiotemporally heterogeneous MRG waves event by event, and (2) to quantify the spatial inhomogeneity of these waves in a wavenumber-frequency-energy diagram. In this way, we reveal the climatology of spatiotemporal inhomogeneity of MRG waves and summarize it in wavenumber-frequency domain: The Indian Ocean is dominated by MRG waves in the period range of 8–12 days; the western Pacific Ocean consists of almost equal energy distribution of MRG waves in the period ranges of 3–6 and 8–12 days, respectively; and the eastern tropical Pacific Ocean and the tropical Atlantic Ocean are dominated by MRG waves in the period range of 3–6 days. The zonal wavenumbers mostly fall within the band of 4–15, with Indian Ocean has larger portion of higher wavenumber (smaller wavelength components) MRG waves.
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Sun, S. (2017). Dynamics-based analysis of tropical waves. Ph.D. thesis, Florida State University, Tallahassee, FL.
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Sweeny, S. R. (1996). Impact of ENSO on weather conditions at continental U.S military bases. Master's thesis, Florida State University, Tallahassee, FL.
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Tartaglione, C. A. (2002). Regional effects of ENSO on US hurricane landfalls. Master's thesis, Florida State University, Tallahassee, FL.
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Tartaglione, C. S., Hanley, D. E., O'Brien, J. J., & Smith, S. R. (2002). Regional Effects of ENSO on U.S Hurricane Landfalls. COAPS Technical Report 02-5. Tallahassee, FL: Center for Ocean-Atmospheric Prediction Studies, Florida State University.
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Tartaglione, C. A., Smith, S. R., & O'Brien, J. J. (2003). ENSO Impact on Hurricane Landfall Probabilities for the Caribbean. J. Climate, 16(17), 2925–2931.
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Taylor, J. P. (2006). Comparison of ECMWF and Quikscat-Derived Surface Pressure Gradients. Master's thesis, Florida State University, Tallahassee, FL.
Abstract: A technique based solely on QuikSCAT data is developed for determining suspect differences between QSCAT and ECMWF pressure gradients. Pressure fields are computed from scatterometer winds using a variational method that applies a gradient wind conversion. Kinematic analysis of the satellite wind field is performed in order to determine which parameters are physically related to the suspect pressure gradients. It is discovered that the likelihood of these suspect occurrences has the greatest dependence on relative vorticity, total deformation, and the curvature Rossby number. A broad range of these values is tested and a single assessment criterion is derived based upon the value of several skill scores. Overall, the assessment criterion is able to correctly identify the majority of suspect pressure gradients; yet considerable over-flagging does occur in many instances. However, the over-flagging is not random: the false alarms are tightly clustered around the suspect areas, resulting in flagged regions that are too large. Identification of the location of suspect areas in pressure products should be useful to forecasters.
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Tilburg, C. E. (2000). Ocean dynamics around New Zealand. Ph.D. thesis, Florida State University, Tallahassee, FL.
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Tilburg, C. E., Hurlburt, H. E., & O'Brien, J. J. (1999). The role of New Zealand in the separation of the East Australian Current (Vol. 28). CAS/JSC Working Group on the Numerical Experimentation, Research Activities in Atmospheric and Oceanic Modelling Number.
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