C. Cooper scite author profile

An ensemble of twenty four coupled oceanatmosphere models has been compared with respect to their performance in the tropical Paci®c. The coupled models span a large portion of the parameter space and dier in many respects. The intercomparison includes TOGA (Tropical Ocean Global Atmosphere)-type models consisting of high-resolution tropical ocean models and coarse-resolution global atmosphere models, coarse-resolution global coupled models, and a few global coupled models with high resolution in the equatorial region in their ocean components. The performance of the annual mean state, the seasonal cycle and the interannual variability are investigated. The primary quantity analysed is sea surface temperature (SST). Additionally, the evolution of interannual heat content variations in the tropical Paci®c and the relationship between the interannual SST variations in the equatorial Paci®c to¯uctuations in the strength of the Indian summer monsoon are investigated. The results can be summarised as follows: almost all models (even those employing¯ux corrections) still have problems in simulating the SST climatology, although some

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STOIC: a study of coupled model climatology and variability in tropical ocean regions

Davey

et al. 2002

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North Atlantic Oceanic Decadal Variability in the Hadley Centre Coupled Model

Cooper

Gordon

2002

J. Climate

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Measurement of Ionospheric Total Electron Content Using Single‐Frequency Geostationary Satellite Observations

et al. 2019

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The ionized upper portion of the atmosphere, the ionosphere, affects radio signals traveling between satellites and the ground. This degrades the performance of satellite navigation, surveillance, and communication systems. Techniques to measure and mitigate ionospheric effects and in particular to measure the total electron content (TEC) are therefore required. TEC is usually determined by analyzing the differential delay experienced by dual‐frequency signals. Here we demonstrate a technique which enables TEC to be derived using single‐frequency signals passing between geostationary satellites and terrestrial Global Positioning System (GPS) receivers. Geostationary satellites offer the key advantage that the raypaths are not moving and hence are easier to interpret than standard GPS TEC. Daily TEC time series are derived for three ground receivers from Europe over the year 2015. The technique is validated by correlation analysis both between pairs of ground receiver observations and between ground receivers and independent ionosonde observations. The correlation between pairs of receivers over a year shows good agreement. Good agreement was also seen between the TEC time series and ionosonde data, suggesting the technique is reliable and routinely produces realistic ionospheric information. The technique is not suitable for use on every GPS receiver type because drift in derived TEC values was observed for profiles calculated using receivers without links to highly stable clocks. The demonstrated technique has the potential to become a routine method to derive TEC, helping to map the ionosphere in real time and to mitigate ionospheric effects on radio systems.

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The Origin of Flux Adjustments in a Coupled Model

1997

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Improving ionospheric imaging via the incorporation of direct ionosonde observations into GPS tomography

Cooper

Chartier

Mitchell

et al. 2014

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C. Cooper

The simulation of SST, sea ice extents and ocean heat transports in a version of the Hadley Centre coupled model without flux adjustments

The internal climate variability of HadCM3, a version of the Hadley Centre coupled model without flux adjustments

ENSIP: the El Niño simulation intercomparison project

STOIC: a study of coupled model climatology and variability in tropical ocean regions

North Atlantic Oceanic Decadal Variability in the Hadley Centre Coupled Model

Measurement of Ionospheric Total Electron Content Using Single‐Frequency Geostationary Satellite Observations

The Origin of Flux Adjustments in a Coupled Model

Improving ionospheric imaging via the incorporation of direct ionosonde observations into GPS tomography

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