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  1. 3481
    por Rossi, L
    Publicado 2002
    “…All together the LHC project will need more than 5000 km of fine filament superconducting cables capable of 14 kA @ 10 T, 1.9 K. (13 refs).…”
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    State-of-the-art superconducting accelerator magnets
  2. 3482
    por Lamont, M
    Publicado 1998
    “…Short bunch lengths excite higher order modes which can cause heating of the inter-cavity bellows a nd may be picked up by antennae cables causing burning. The bunch length is also important from a cryogenics viewpoint; HOM losses go up with shorter bunches and more cryogenics power is required. …”
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    Bunch length and the 102/90 degrees optics
  3. 3483
    por Kirby, Glyn
    Publicado 2019
    “…CERN has the first results of using a high current (10 kA) HTS, with REBCO cables, in an Accelerator type magnet development. …”
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    Next generation materials for future magnet development at CERN
  4. 3484
    por Adam, W., Bergauer, T., Dragicevic, M., Friedl, M., Frühwirth, R., Hänsel, S., Hrubec, J., Krammer, M., Oberegger, M., Pernicka, M., Schmid, S., Stark, R., Steininger, H., Uhl, D., Waltenberger, W., Widl, E., Van Mechelen, P., Cardaci, M., Beaumont, W., de Langhe, E., de Wolf, E.A., Delmeire, E., Bouhali, O., Charaf, O., Clerbaux, B., Dewulf, J.-P., Elgammal, S., Hammad, G., de Lentdecker, G., Marage, P., Vander Velde, C., Vanlaer, P., Wickens, J., Adler, V., Devroede, O., De Weirdt, S., D'Hondt, J., Goorens, R., Heyninck, J., Maes, J., Mozer, Matthias Ulrich, Tavernier, S., Van Lancker, L., Van Mulders, P., Villella, I., Wastiels, C., Bonnet, J.-L., Bruno, G., De Callatay, B., Florins, B., Giammanco, A., Gregoire, G., Keutgen, Th., Kcira, D., Lemaitre, V., Michotte, D., Militaru, O., Piotrzkowski, K., Quertermont, L., Roberfroid, V., Rouby, X., Teyssier, D., Vander Donckt, M., Daubie, E., Anttila, E., Czellar, S., Engstrom, P., Harkonen, J., Karimaki, V., Kostesmaa, J., Kuronen, A., Lampen, T., Linden, T., Luukka, P.-R., Maenpaa, T., Michal, S., Tuominen, E., Tuominiemi, J., Ageron, M., Baulieu, G., Bonnevaux, A., Boudoul, G., Chabanat, E., Chabert, E., Chierici, R., Contardo, D., Della Negra, R., Dupasquier, T., Gelin, G., Giraud, N., Guillot, G., Estre, N., Haroutunian, R., Lumb, N., Perries, S., Schirra, F., Trocme, B., Vanzetto, S., Agram, J.-L., Blaes, R., Drouhin, F., Ernenwein, J.-P., Fontaine, J.-C., Berst, J.-D., Brom, J.-M., Didierjean, F., Goerlach, U., Graehling, P., Gross, L., Hosselet, J., Juillot, P., Lounis, A., Maazouzi, C., Olivetto, C., Strub, R., Van Hove, P., Anagnostou, G., Brauer, R., Esser, H., Feld, L., Karpinski, W., Klein, K., Kukulies, C., Olzem, J., Ostapchuk, A., Pandoulas, D., Pierschel, G., Raupach, F., Schael, S., Schwering, G., Sprenger, D., Thomas, M., Weber, M., Wittmer, B., Wlochal, M., Beissel, F., Bock, E., Flugge, G., Gillissen, C., Hermanns, T., Heydhausen, D., Jahn, D., Kaussen, G., Linn, A., Perchalla, L., Poettgens, M., Pooth, O., Stahl, A., Zoeller, M.H., Buhmann, P., Butz, E., Flucke, G., Hamdorf, R., Hauk, J., Klanner, R., Pein, U., Schleper, P., Steinbruck, G., Blum, P., De Boer, W., Dierlamm, A., Dirkes, G., Fahrer, M., Frey, M., Furgeri, A., Hartmann, F., Heier, S., Hoffmann, K.-H., Kaminski, J., Ledermann, B., Liamsuwan, T., Muller, S., Muller, Th., Schilling, F.-P., Simonis, H.-J., Steck, P., Zhukov, V., Cariola, P., De Robertis, G., Ferorelli, R., Fiore, L., Preda, M., Sala, G., Silvestris, L., Tempesta, P., Zito, G., Creanza, D., De Filippis, N., De Palma, M., Giordano, D., Maggi, G., Manna, N., My, S., Selvaggi, G., Albergo, S., Chiorboli, M., Costa, S., Galanti, M., Giudice, N., Guardone, N., Noto, F., Potenza, R., Saizu, M.A., Sparti, V., Sutera, C., Tricomi, A., Tuve, C., Brianzi, M., Civinini, C., Maletta, F., Manolescu, F., Meschini, M., Paoletti, S., Sguazzoni, G., Broccolo, B., Ciulli, V., D'Alessandro, R., Focardi, E., Frosali, S., Genta, C., Landi, G., Lenzi, P., Macchiolo, A., Magini, N., Parrini, G., Scarlini, E., Cerati, G., Azzi, P., Bacchetta, N., Candelori, A., Dorigo, T., Kaminsky, A., Karaevski, S., Khomenkov, V., Reznikov, S., Tessaro, M., Bisello, D., De Mattia, M., Giubilato, P., Loreti, M., Mattiazzo, S., Nigro, M., Paccagnella, A., Pantano, D., Pozzobon, N., Tosi, M., Bilei, G.M., Checcucci, B., Fano, L., Servoli, L., Ambroglini, F., Babucci, E., Benedetti, D., Biasini, M., Caponeri, B., Covarelli, R., Giorgi, M., Lariccia, P., Mantovani, G., Marcantonini, M., Postolache, V., Santocchia, A., Spiga, D., Bagliesi, G., Balestri, G., Berretta, L., Bianucci, S., Boccali, T., Bosi, F., Bracci, F., Castaldi, R., Ceccanti, M., Cecchi, R., Cerri, C., Cucoanes, A .S., Dell'Orso, R., Dobur, D ., Dutta, S ., Giassi, A., Giusti, S., Kartashov, D., Kraan, A., Lomtadze, T., Lungu, G.A., Magazzu, G., Mammini, P., Mariani, F., Martinelli, G., Moggi, A., Palla, F., Palmonari, F., Petragnani, G., Profeti, A., Raffaelli, F., Rizzi, D., Sanguinetti, G., Sarkar, S., Sentenac, D., Serban, A.T., Slav, A., Soldani, A., Spagnolo, P., Tenchini, R., Tolaini, S., Venturi, A., Verdini, P.G., Vos, M., Zaccarelli, L., Avanzini, C., Basti, A., Benucci, L., Bocci, A., Cazzola, U., Fiori, F., Linari, S., Massa, M., Messineo, A., Segneri, G., Tonelli, G., Azzurri, P., Bernardini, J., Borrello, L., Calzolari, F., Foa, L., Gennai, S., Ligabue, F., Petrucciani, G., Rizzi, A., Yang, Z., Benotto, F., Demaria, N., Dumitrache, F., Farano, R., Borgia, M.A., Castello, R., Costa, M., Migliore, E., Romero, A., Abbaneo, D., Abbas, M., Ahmed, I., Akhtar, I., Albert, E., Bloch, C., Breuker, H., Butt, S., Buchmuller, O., Cattai, A., Delaere, C., Delattre, M., Edera, L.M., Engstrom, P., Eppard, M., Gateau, M., Gill, K., Giolo-Nicollerat, A.-S., Grabit, R., Honma, A., Huhtinen, M., Kloukinas, K., Kortesmaa, J., Kottelat, L.J., Kuronen, A., Leonardo, N., Ljuslin, C., Mannelli, M., Masetti, L., Marchioro, A., Mersi, S., Michal, S., Mirabito, L., Muffat-Joly, J., Onnela, A., Paillard, C., Pal, I., Pernot, J.F., Petagna, P., Petit, P., Piccut, C., Pioppi, M., Postema, H., Ranieri, R., Ricci, D., Rolandi, G., Ronga, F., Sigaud, C., Syed, A., Siegrist, P., Tropea, P., Troska, J., Tsirou, A., Vander Donckt, M., Vasey, M., Alagoz, E., Amsler, Claude, Chiochia, V., Regenfus, Christian, Robmann, P., Rochet, J., Rommerskirchen, T., Schmidt, A., Steiner, S., Wilke, L., Church, I., Cole, J., Coughlan, J., Gay, A., Taghavi, S., Tomalin, I., Bainbridge, R., Cripps, N., Fulcher, J., Hall, G., Noy, M., Pesaresi, M., Radicci, V., Raymond, D.M., Sharp, P., Stoye, M., Wingham, M., Zorba, O., Goitom, I., Hobson, P.R., Reid, I., Teodorescu, L., Hanson, G., Jeng, G.-Y., Liu, H., Pasztor, G., Satpathy, A., Stringer, R., Mangano, B., Affolder, K., Affolder, T., Allen, A., Barge, D., Burke, Samuel P., Callahan, D., Campagnari, C., Crook, A., D'Alfonso, M., Dietch, J., Garberson, Jeffrey Ford, Hale, D., Incandela, H., Incandela, J., Jaditz, S., Kalavase, P., Kreyer, S., Kyre, S., Lamb, J., Mc Guinness, C., Mills, C., Nguyen, H., Nikolic, M., Lowette, S., Rebassoo, F., Ribnik, J., Richman, J., Rubinstein, N., Sanhueza, S., Shah, Y., Simms, L., Staszak, D., Stoner, J., Stuart, D., Swain, S., Vlimant, J.-R., White, D., Ulmer, K.A., Wagner, S.R., Bagby, L., Bhat, P.C., Burkett, K., Cihangir, S., Gutsche, O., Jensen, H., Johnson, M., Luzhetskiy, N., Mason, D., Miao, T., Moccia, S., Noeding, C., Ronzhin, A., Skup, E., Spalding, W.J., Spiegel, L., Tkaczyk, S., Yumiceva, F., Zatserklyaniy, A., Zerev, E., Anghel, I., Bazterra, V.E., Gerber, C.E., Khalatian, S., Shabalina, E., Baringer, Philip S., Bean, A., Chen, J., Hinchey, C., Martin, C., Moulik, T., Robinson, R., Gritsan, A.V., Lae, C.K., Tran, N.V., Everaerts, P., Hahn, K.A., Harris, P., Nahn, S., Rudolph, M., Sung, K., Betchart, B., Demina, R., Gotra, Y., Korjenevski, S., Miner, D., Orbaker, D., Christofek, L., Hooper, R., Landsberg, G., Nguyen, D., Narain, M., Speer, T., Tsang, K.V.
    Publicado 2008
    “…Nearly 15% of the detector was instrumented using cables, fiber optics, power supplies, and electronics intended for the operation at the LHC. …”
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    Performance studies of the CMS Strip Tracker before installation
  5. 3485
    “…The sensitivity of linear variable differential transformer (LVDT) position sensors to external slowly varying magnetic fields represents a critical issue when these sensors are installed close to high-current cables or electrical motors with significant fringe fields. …”
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    Design of a Linear Variable Differential Transformer With High Rejection to External Interfering Magnetic Field
  6. 3486
    “…Then we focus on the analysis and tests performed to determine the most suitable shapes of end turns and spacers, minimizing the mechanical stress on the cables. We conclude with a detailed description of the baseline end design for the first series of the short model coils.…”
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    Coil End Optimization of the Nb$_3$Sn Quadrupole for the High Luminosity LHC
  7. 3487
    por Taylor, Jonathan Thomas
    Publicado 2018
    “…A serial power scheme will be used for the pixel layers to reduce the radiation length and power consumption in cables. New elements are required to operate and monitor a serially powered detector including a detector control system, constant current sources and front-end electronics with shunt regulators. …”
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    Development and evaluation of prototypes for the Phase-II upgrade of the pixel detector of the ATLAS experiment
  8. 3488
    “…All magnets feature a four-layer coil wound from two 8.2 mm wide graded NbTi cables and a four-way split yoke supporting structure. …”
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    Performance of the 1-meter models of the 70 mm aperture quadrupole for the LHC low-beta insertions
  9. 3489
    “…A double-sided strip detector using prototype cables has been installed in the NA57 experiment in 1998.…”
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    Very low mass microcables for the ALICE silicon strip detector
  10. 3490
    “…The first type of disturbance comes from non-uniform current distribution in superconducting cables whereas the second one usually originates from conductor motions or micro-fractures of insulating materials under the action of Lorentz forces. …”
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    Statistical Diagnosis Method of Conductor Motions in Superconducting Magnets to Predict their Quench Performance
  11. 3491
    “…All main magnets are superconducting and employ NbTi/Cu Rutherford type cables operated at 1.9 K. The dipole production has reached the equivalent of almost three octants of cold masses and nearly four octants of collared coils. …”
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    Status Report on the LHC Main Magnet Production
  12. 3492
    “…Because of current redistribution on the superconducting cables, the harmonic components of the magnetic fields of the superconducting magnets in the Large Hadron Collider (LHC) show decay during the low field injection plateau. …”
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    Tune and Chromaticity Control During Snapback and Ramp in 2015 LHC Operation
  13. 3493
    “…The detectors are connected to the readout electronics (situated in a rack room with radiation levels comparable to the natural background radiation) by 80 m long cables. The technical design was tested for distances up to 120 m. …”
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    Timepix3 detector network at ATLAS experiment
  14. 3494
    “…Due to this specific cycled operation, innovative design and development approaches is required to cope with the AC losses in the superconducting cables and iron yoke. The research joins experience accumulated at CERN and JINR in the design and operation of large systems operated at 1.9 K and in fast ramped and cycled magnets respectively. …”
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    Design of a fast cycled low loss 6 T model dipole cooling at 1.9 K
  15. 3495
    “…By avoiding disconnecting or moving the cables, the proposed method eliminates errors related to the repeatability of connectors, resulting in improved broadband traceability to SI units.…”
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    Online Artículo Texto
    Propagation Constant Measurement Based on a Single Transmission Line Standard Using a Two-Port VNA
  16. 3496
    “…The amplifier was integrated in the close vicinity of the nanowire inside the cryostat to minimize cabling load and interference. The function of the circuit was impedance conversion for current flow measurements in NEMSs with a high internal resistance. …”
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    Online Artículo Texto
    Characterization of Mechanical Oscillations in Bismuth Selenide Nanowires at Low Temperatures
  17. 3497
    “…Critical information regarding their acoustic signatures and activity level is collected and analyzed using standard outdoor-grade telecommunication fiber cables. We believe these results have the potential to be a quantitative baseline for regional Brood X activity and pave the way for more detailed monitoring of insect populations to combat global insect decline. …”
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    Online Artículo Texto
    Long-term monitoring and analysis of Brood X cicada activity by distributed fiber optic sensing technology
  18. 3498
    Publicado 1980
    “…Immunocytochemical studies with human fibroblasts and L6 myoblasts revealed intense staining of typical cytoplasmic cables. Myofibrils were not stained after treatment of human and frog skeletal muscle with the antibody, although the distribution of immunofluorescence suggested that cytoplasmic actin is associated with membrane systems in the muscle fiber. …”
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    Texto
    An antiactin antibody that distinguishes between cytoplasmic and skeletal muscle actins
  19. 3499
    “…Although the presented methodology is completely general, we restrict ourselves to the analysis of a model robot made of hyperelastic materials and actuated by cables or tendons. To comply with the stringent real-time constraints imposed by control algorithms, a reduced-order modeling strategy is proposed that allows to minimize the amount of online CPU cost. …”
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    Online Artículo Texto
    Reduced-order modeling of soft robots
  20. 3500
    “…In recent years, cabled ocean observation technology has been increasingly used for deep sea in situ research. …”
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    Online Artículo Texto
    Analysis and Modeling Methodologies for Heat Exchanges of Deep-Sea In Situ Spectroscopy Detection System Based on ROV
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