1,731,746 research outputs found
NEMO-Nordic 3.3.1 for RCA4-NEMO
No full text<p>NEMO 3.3.1 based ice-ocean component of the coupled atmosphere-ice-ocean model RCA4-NEMO. This ocean model setup has been know as BaltiX and was renamed NEMO-Nordic later on. It uses NEMO 3.3.1 with some changes and is set up for the North Sea and Baltic Sea. The horizontal resolution is 2 nautical miles and 56 levels with 3 m near the surface increasing to 10 m at 100 m. This setup uses LIM 3 with 5 ice classes as an ice model.</p>
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NEMO Reference configurations inputs
No full text<p>Input archives for running the configurations included in NEMO 3.4: AMM12, AMM12_PISCES, ORCA2_LIM, ORCA2_LIM_PISCES and ORCA2_OFF_PISCES</p>
NEMO Reference configurations inputs
No full text<p>Input archives for running the configurations included in NEMO 3.6: AMM12, C1D_PAPA, ORCA2_LIM[3], ORCA2_LIM_PISCES, ORCA2_OFF_PISCES and ORCA2_SAS_LIM</p>INPUTS_PISCES_v3.6.tar archive is outdated, see 'Versions' to find the right uploa
Limits on different majoron decay modes of 100Mo and 82Se for neutrinoless double beta decays in the NEMO-3 experiment
No full textThe NEMO-3 tracking detector is located in the Fréjus Underground Laboratory. It was designed to study double beta decay in a number of different isotopes. Presented here are the experimental half-life limits on the double beta decay process for the isotopes 100Mo and 82Se for different majoron emission modes and limits on the effective neutrino–majoron coupling constants. In particular, new limits on “ordinary” majoron (spectral index 1) decay of 100Mo (T1/2>2.7×1022 yr) and 82Se (T1/2>1.5×1022 yr) have been obtained. Corresponding bounds on the majoron–neutrino coupling constant are gee<(0.4–1.8)×10−4 and <(0.66–1.9)×10−4
Efficient NEMO Security Management Via CAPKI.
Full text linkNetwork Mobility (NEMO) has gained much momentum ever since being introduced. The concept of NEMO, is actually building on top of the MIPv6 and using MIh6 as its backbone. The differences are much align at the capability of the
Router being able to roam freely, hence the term Mobile Router
(MR)
Securing route optimisation in NEMO
Full text linkThird International Symposium on Modeling and Optimization in Mobile, Ad Hoc,and Wireless Networks. 4-6 April 2005. Riva del Garda, Trentino, ItalyThe network mobility (NEMO) basic support protocol enables mobile networks to change their point of attachment to the Internet, while preserving established sessions of the nodes within the mobile network. When only a nonnested mobile network is considered, the so-called triangle routing is the main problem that should be faced. In mobile IPv6, the route optimisation mechanism solves this problem, and the return routability mechanism aims to limit the security concerns originated because of the route optimisation. Nowadays return routability is considered a weak solution (i.e., based on strong assumptions). In this article we explore different approaches to route optimisation in NEMO and we devise how to adapt some of the terminal mobility solutions to a NEMO environment, where, as we propose, a delegation of signalling rights from the mobile network node to the mobile router is necessary.Publicad
NEMO Reference configurations inputs
No full text<p>Input archives for running the configurations included in NEMO 4.0 |</p>
<ul>
<li>AGRIF_DEMO: <em>AGRIF_DEMO_v4.0.tar, ORCA2_ICE_v4.0.tar</em></li>
<li>AMM12: <em>AMM12_v4.0.tar</em></li>
<li>C1D_PAPA: <em>INPUTS_C1D_PAPA_v4.0.tar</em></li>
<li>ORCA2_ICE_PISCES: <em>ORCA2_ICE_v4.0.tar, INPUTS_PISCES_v4.0.tar</em></li>
<li>ORCA2_OFF_PISCES: <em>ORCA2_OFF_v4.0.tar, INPUTS_PISCES_v4.0.tar</em></li>
<li>ORCA2_OFF_TRC: <em>ORCA2_OFF_v4.0.tar</em></li>
<li>ORCA2_SAS_ICE: <em>ORCA2_ICE_v4.0.tar, INPUTS_SAS_v4.0.tar</em></li>
<li>SPITZ12: <em>SPITZ12_v4.0.tar</em></li>
</ul>In NEMO-PISCES v4.0 and v3.6 we assume that the units of Nitrogen deposition data in the inputs file are in kgN/m2/s. In the previous version, the units was supposed to be in mg/m2/yr. And so the data in the input nitrogen deposition file - ndeposition.orca.nc need to be changed. We keep the old units ( mg/m2/yr ) by renaming the variable ndep to ndep2 and we add a variable ndep in the new units ( kg/m2/s ) : ndep = ndep2/(86400*365*1e6
Status of the NEMO project
No full textActivities leading to the realization of a km3 Cherenkov neutrino detector, carried out by the NEMO collaboration, are described. Long term exploration of a 3500 m deep site in the Mediterranean close to the Sicilian coast has shown that it is optimal for the installation of the detector. A complete feasibility study, which has considered all the components of the detector, as well as its deployment, has been carried out demonstrating that technological solutions exist for the realization of the km3 detector. The realization of a technological demonstrator (the NEMO Phase 1 project) is under way
Status of NEMO: results from the NEMO Phase-1 detector
No full textThe NEMO Collaboration installed art underwater detector including most of the critical elements of a possible km(3) neutrino telescope: a four-floor tower (called Mini-Tower) and a Junction Box, including the data transmission, the power distribution, the timing calibration and the acoustic positioning systems. These technical Solutions will be evaluated, among others proposed for the construction of the km(3) detector, within the KM3NeT Consortium. The main test of this test experiment was the validation of the proposed design solutions mentioned above. We present results of the analysis of data collected with the NEMO Mini-Tower. The position of PMTs is determined through the acoustic position system; signals detected with PMTs are used to reconstruct the tracks of atmospheric muons. The angular distribution of atmospheric muons was measured and results were compared with Monte Carlo simulations
Design and Experimental Evaluation of a Route Optimisation Solution for NEMO
Full text linkAn important requirement for Internet protocol (IP)
networks to achieve the aim of ubiquitous connectivity is network
mobility (NEMO). With NEMO support we can provide Internet
access from mobile platforms, such as public transportation vehicles,
to normal nodes that do not need to implement any special
mobility protocol. The NEMO basic support protocol has been
proposed in the IETF as a first solution to this problem, but this
solution has severe performance limitations. This paper presents
MIRON: Mobile IPv6 route optimization for NEMO, an approach
to the problem of NEMO support that overcomes the limitations
of the basic solution by combining two different modes of operation:
a Proxy-MR and an address delegation with built-in routing
mechanisms. This paper describes the design and rationale of the
solution, with an experimental validation and performance evaluation
based on an implementation.Publicad
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