Observation of Continuum radiations from the CLUSTER fleet: first results from direction finding P. M. E. Decreau (1), C. Ducoin (1), G. Le Rouzic (1), O. Randriamboarison (1), J.-L. Rauch (1), J.-G. Trotignon (1), X. Vallieres (1), P. Canu (2), F. Darrouzet (3), M. P. Gough (4), A. M. Buckley (4), and T. D. Carozzi (4) (1) LPCE, CNRS et Universite d'Orleans, Orleans, France (2) CETP, CNRS et Universite Versailles St Quentin, Velizy, France (3) Belgian Institute for Space Aeronomy, (IASB-BIRA), Brussels, Belgium (4) Space Science Centre, the University of Sussex, Falmer, Brighton, U.K. The Cluster fleet offers the first possibility of comparing non-thermal terrestrial continuum radiation from similarly equipped nearby observation points. A very rich data set has already been acquired on the Cluster polar orbit, i.e. between 4 and 19 Earth radii geocentric distances, and preliminary analysis have been carried out on these emissions. We focus in this paper on direction finding performed from all four spacecraft as means to locate the position of the sources of this continuum radiation. Directions are derived from spin modulation properties, under the usual analysis assumptions of the wave vector of the radiation lying in the plane containing the spin axis and the antenna position at electric field minimum. All the spin axes of the four Cluster spacecraft are aligned perpendicular to the ecliptic, thus the aligned spacecraft antenna spin planes provide redundant 2D views of propagation path of the radiation and source location. Convincing 2D triangulation results have been obtained in the vicinity of the source region. In addition, the out of spin plane component of the wave vector reveals itself to a certain extent through directivity characteristics compared at different distances of spin plane to the ecliptic. The four case events studied (two of them taken near apogee, two others near perigee) have confirmed general properties derived from previous observations: trapping in the lower frequency range, radiation escaping into the magnetosheath region in the higher frequency range. All propagation directions are compatible with source positions in the plasmapause region, however at a significant distance from the equator in one case. Our observations have also revealed new properties, like the importance of small scale density irregularities in the local amplification of continuum radiation. We conclude that more detailed generation and propagation models are needed to fit the observations.