kw.\*:("DEPOT AXIAL PHASE VAPEUR")
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FABRICATION OF THE VAD SINGLE-MODE FIBRESTOMARU S; KAWACHI M; YASU M et al.1982; TRANSACTIONS OF THE INSTITUTE OF ELECTRONICS AND COMMUNICATION ENGINEERS OF JAPAN. SECTION E; ISSN 0387-236X; JPN; DA. 1982; VOL. 65; NO 12; PP. 717-722; BIBL. 13 REF.Article
DECREASED LOSSES IN GERMANIUM-OXIDE GLASS OPTICAL FIBER PREPARED BY VAD METHODTAKAHASHI H; SUGIMOTO I.1983; JAPANESE JOURNAL OF APPLIED PHYSICS; ISSN 0021-4922; JPN; DA. 1983; VOL. 22; NO 3; PART. 2; PP. L139-L140; BIBL. 2 REF.Article
DISPERSION-FREE VAD SINGLE-MODE FIBERS IN THE 1.5 MU M WAVELENGTH REGIONMIYA T; HANAWA F; CHIDA K et al.1983; APPLIED OPTICS; ISSN 0003-6935; USA; DA. 1983; VOL. 22; NO 3; PP. 372-373; BIBL. 11 REF.Article
FABRICATION OF OH-FREE MULTIMODE FIBER BY VAPOR PHASE AXIAL DEPOSITIONCHIDA K; HANAWA F; NAKAHARA M et al.1982; IEEE JOURNAL OF QUANTUM ELECTRONICS; ISSN 0018-9197; USA; DA. 1982; VOL. 18; NO 11; PP. 1883-1889; BIBL. 23 REF.Article
TRANSMISSION CHARACTERISTICS OF VAD FIBERS USING A MULTIPLE BURNER WITH SINGLE SOURCE GAS NOZZLEISHIDA K; IMOTO K; SUGANUMA T et al.1982; FIBER AND INTEGRATED OPTICS; ISSN 0146-8030; USA; DA. 1982; VOL. 4; NO 2; PP. 191-202; BIBL. 10 REF.Article
High-rate fabrication of wholly synthesised fibre preforms by the multiflame VAD method using SiHCl3 raw materialsSUDA, H; SHIBATA, S; NAKAHARA, M et al.Electronics Letters. 1985, Vol 21, Num 24, pp 1123-1124, issn 0013-5194Article
Improvement in VAD optical fiber preform fabrication systemCHIDA, K; NAKAHARA, M; INAGAKI, N et al.Review of the electrical communication laboratories. 1984, Vol 32, Num 3, pp 395-403, issn 0029-067XArticle
Characterization of soot from multimode vapor-phase axial deposition (VAD) optical fiber preformsPOTKAY, E; CLARK, H. R; SMYTH, I. P et al.Journal of lightwave technology. 1988, Vol 6, Num 8, pp 1338-1347, issn 0733-8724Article
Fine glass particle-deposition mechanism in the VAD processSUDA, H; SUDO, S; NAKAHARA, M et al.Fiber and integrated optics. 1983, Vol 4, Num 4, pp 427-437, issn 0146-8030Article
High rate fabrication technique for VAD optical fiber preformsSUDA, H; CHIDA, K; SUDO, S et al.Review of the electrical communication laboratories. 1984, Vol 32, Num 3, pp 418-424, issn 0029-067XArticle
Direct observation of sintering of VAD soot particles by hot stage scanning electron microscopyBISWAS, D. R; NATH, D. K.Journal of materials science letters. 1983, Vol 2, Num 6, pp 245-248, issn 0261-8028Article
Optimierung des Brechzahlverlaufs an aussenbeschichteten Lichtwellenleitern (VAD-Profile) = Optimalisation du profil d'indice de fibres optiques fabriquées par un procédé extérieurs (profils obtenus par dépôt axial en phase vapeur) = Optimisation of the refractive index profile of outside coated optical fibers (VAD profiles)HANSSKE, A.Nachrichtentechnik. Elektronik. 1986, Vol 36, Num 4, issn 0323-4657, 143Article
Transmission characteristics of a single-mode fiber in the 1.3.-μm wavelength regionISHIDA, Y; OHASHI, M; UESUGI, N et al.Journal of lightwave technology. 1984, Vol 2, Num 3, pp 322-327, issn 0733-8724Article
VAD graded-index optical fiber fabricationCHIDA, K; HANAWA, F; NAKAHARA, M et al.Review of the electrical communication laboratories. 1984, Vol 32, Num 3, pp 404-410, issn 0029-067XArticle
Collection and characterization of soot from an optical fiber preform torchCLARK, H. R; STAWICKI, R. P; SMYTH, I. P et al.Journal of the American Ceramic Society. 1990, Vol 73, Num 10, pp 2987-2991, issn 0002-7820Article
Temperature measurement system for optical-fiber preform fabricationBODEEP, G. E.Review of scientific instruments. 1985, Vol 55, Num 12, pp 1957-1959, issn 0034-6748Article
Realization of intentionally introduced mode-coupling in optical fibers by Downward Axial Vapor DepositionPRESBY, H. M.Journal of lightwave technology. 1985, Vol 3, Num 2, pp 219-224, issn 0733-8724Article
A germanium-oxide glass optical fiber prepared by a VAD methodTAKAHASHI, H; SUGIMOTO, I.Journal of lightwave technology. 1984, Vol 2, Num 5, pp 613-616, issn 0733-8724Article
Multi-flame VAD process for high-rate fabrication of optical fiber preformsSUDA, H; SHIBATA, S; NAKAHARA, M et al.Transactions of the Institute of Electronics and Communication Engineers of Japan. Section E. 1986, Vol 69, Num 11, pp 1206-1212, issn 0387-236XArticle
The VAD preform stretching process: a numerical model for evaluation of internal distortionCLARK, H. R; MONTRI VIRIYAYUTHAKORN.Journal of lightwave technology. 1986, Vol 4, Num 8, pp 1039-1047, issn 0733-8724Article
Germanate glass optical fibers for 2 to 3μm band fabricated by vapor-phase axial deposition methodTAKAHASHI, H; SUGIMOTO, I; SATO, T et al.Optical engineering (Bellingham. Print). 1984, Vol 23, Num 4, pp 465-469, issn 0091-3286Article
Properties of alumina doped VAD fibersOMORI, Y; NAKAHARA, M; HORIGUCHI, M et al.Review of the electrical communication laboratories. 1984, Vol 32, Num 3, pp 432-443, issn 0029-067XArticle
VAD Single-mode fiber fabrication techniques-1.5 μm dispersion-free single-mode fibersMIYA, T; NAKAHARA, M; INAGAKI, N et al.Review of the electrical communication laboratories. 1984, Vol 32, Num 3, pp 411-417, issn 0029-067XArticle
Impurity influence in raw materials on transmission loss for the VAD fibersSUDA, H; CHIDA, K; NAKAHARA, M et al.Transactions of the Institute of Electronics and Communication Engineers of Japan. Section E. 1983, Vol 66, Num 10, pp 591-595, issn 0387-236XArticle
Recent developments in vapor phase axial depositionMURATA, H.Journal of lightwave technology. 1986, Vol 4, Num 8, pp 1026-1033, issn 0733-8724Article