黒河 賢二 Kurokawa Kenji
学位・学歴・職歴
学位
| 博士(理学) | Study on femtosecond optical soliton amplification and transmission in an erbium-doped optical fiber amplifier | 1997 |
職歴
| 1987.4-2013.9 | 日本電信電話株式会社アクセスサービスシステム研究所 |
| 1998.4-2003.3 | 茨城大学工学部 非常勤講師兼務 |
| 2005.4-2012.3 | 筑波大学大学院図書館情報メディア研究科 客員准教授兼務 |
| 2013.10 | 北見工業大学教授 |
担当科目・専門分野等
- 担当授業科目(学部)
- データ統計基礎 地域未来GH/短期履修, 情報デザイン・コミュニケーション工学概論 地域未来(2020年度以前入学), 電気磁気学 情報デザイン, 情報デザイン・コミュニケーション総合工学II 情報デザイン, 先端光通信工学 情報デザイン, 地域未来デザイン工学入門/短期履修
- 担当授業科目(大学院)
- 情報光学特論I 情報通信
- 専門分野
- 非線形光学、光通信
- 研究テーマ
- 高入力光下における光ファイバの信頼性に関する研究と超大容量光通信システム構成法への応用
- 研究内容キーワード
- 光ファイバ、ファイバヒューズ、超大容量光通信
- 所属学会
- 電子情報通信学会、応用物理学会、日本物理学会、IEEE(SM)、OSA(SM)
学術論文等
学術論文
| 論文名/掲載誌名等 | 掲載年月 | ||
|---|---|---|---|
Long-term reliability of pure silica core single-mode fiber when exposed to high-power laser light
IEEE Photon. Technol. Lett., 16, 4, 1110-1112
|
2004-04 | ||
Cutoff wavelength measurement in a fiber with improved bending loss
IEEE Photon. Technol. Lett., 16, 8, 1918-1920
|
2004-08 | ||
Novel optical loss design method for WDM systems
IEICE Trans. Commun., E87-B, 10, 2871-2876
|
2004-10 | ||
Ultrawide-band single-mode transmission performance in a low loss photonic crystal fiber
J. Lightwave Technol., 23, 1, 7-12
|
2005-01 | ||
Progress on low loss photonic crystal fibers
Opt. Fiber Technol., 11, 101-110
|
2005-02 | ||
PMD characteristics of twisted photonic crystal fibre
Electron. Lett., 41, 7, 403-405
|
2005-03 | ||
Optimum optical fiber design for a DRA-based DWDM transmission system
J. Lightwave Technol., 23, 3, 1232-1238
|
2005-03 | ||
Long-term reliability of single-mode fibers when exposed to high-power laser light
J. Lightwave Technol., 23, 9, 2713-2718
|
2005-09 | ||
Penalty-free dispersion-managed soliton transmission over a 100-km low-loss PCF
J. Lightwave Technol., 24, 1, 32-37
|
2006-01 | ||
Raman amplification characteristics at 850 nm in a silica-based photonic crystal fiber
IEEE Photon. Technol. Lett., 18, 3, 451-453
|
2006-02 | ||
Design and performance of low-loss submarine optical fiber cable for long-distance submarine repeaterless transmission system employing remotely pumped EDF and distributed Raman amplification
IEICE Trans. Commun., E89-B, 6, 1733-1737
|
2006-06 | ||
Application of a prechirp technique to 10-Gb/s transmission at 1064 nm through 24 km of photonic crystal fiber
IEEE Photon. Technol. Lett.,, 18, 19, 2026-2028
|
2006-10 | ||
10 GHz 0.5 ps pulse generation in 1000 nm band in PCF for high speed optical communication
J. Lightwave Technol., 25, 1, 75-78
|
2007-01 | ||
Visible high-speed optical transmission over photonic crystal fiber
Opt. Exp., 15, 2, 397-401
|
2007-01 | ||
Temperature-increase characteristics in bent hole-assisted fiber under high power
J. Lightwave Technol., 25, 5, 1231-1237
|
2007-05 | ||
Visible to infrared high-speed WDM transmission over PCF
IEICE Electronics Express, 4, 12, 375-379
|
2007-06 | ||
High-speed and wideband transmission using dispersion-compensating/managing photonic crystal fiber and dispersion-shifted fiber
J. Lightwave Technol., 25, 9, 2719-2726
|
2007-09 | ||
10 Gb/s WDM transmission at 1064 and 1550 nm over 24 km photonic crystal fiber with negative power penalties
IEICE Trans. Commun., E90-B, 10, 2803-2808
|
2007-10 | ||
WDM transmission in 1.0 um band over PCF using supercontinuum source
IEICE Electronics Express, 5, 11, 395-399
|
2008-06 | ||
Applicability of silica core photonic crystal fiber for distributed Raman amplification transmission
Opt. Fiber Technol., 14, 3, 196-202
|
2008-07 | ||
1.0 um band supercontinuum light as WDM pulse source generated by using photonic crystal fibers
IEICE Electronics Express, 5, 16, 592-596
|
2008-08 | ||
160 Gbit/s OTDM signal transmission over 26 km photonic crystal fibre
Electron. Lett., 44, 18, 1080-1081
|
2008-08 | ||
Ultra wideband WDM transmission over PCF
J. Lightwave Technol., 27, 11, 1653-1662
|
2009-06 | ||
DWDM transmission in O-band over 24 km PCF using optical frequency comb based multicarrier source
Electron. Lett., 45, 16, 850-851
|
2009-07 | ||
Observation of new propagation mode of fiber fuse with a long-period damage track in hole-assisted fiber
Opt. Lett., 35, 12, 2004-2006
|
2010-06 | ||
Suppression of fiber fuse propagation in hole assisted fiber and photonic crystal fiber
J. Lightwave Technol., 28, 15, 2115-2120
|
2010-08 | ||
Group velocity dispersion measurement method using sinusoidally phase-modulated continuous wave light based on cyclic nature of waveform change by group velocity dispersion
Appl. Opt., 49, 27, 5148-5156
|
2010-09 | ||
1.0 um band supercontinuum generation using photonic crystal fiber and its application as multi-wavelength pulse source
IEICE Electronics Express, 7, 19, 1504-1508
|
2010-10 | ||
Fiber fuse propagation and its suppression in hole-assisted fibers
IEICE Trans. Commun., E94-B, 2, 384-391
|
2011-02 | ||
Power dependence of fiber fuse propagation with a long-period damage track in hole-assisted fiber
IEICE Electronics Express, 8, 11, 802-807
|
2011-06 | ||
Optical Fiber for high-power optical communication
Crystals, 2, 1382-1392
|
 |
2012-09 | |
光ファイバ通信の高入力化に向けた光ファイバの検討
電子情報通信学会論文誌, J96-B, 3, 348-355
|
|
2013-03 | |
Holey fibers for low bend loss
J. Nanophotonics, 2, 341-353
|
2013-12 | ||
空孔アシストファイバにおける特異なファイバヒューズ伝搬特性
電子情報通信学会論文誌, J96-B, 12, 1369-1377
|
|
2013-12 | |
Fiber fuse propagation characteristics of LP01 and LP11 modes in few-mode fiber
J. Lightwave Technol., 34, 15, 3628-3632
|
 |
2016-08 | |
Hole-assisted fiber based fiber fuse terminator supporting 22 W input
Optical Fiber Technology, 42, 24-28
|
|
2018-05 | |
異種ファイバ接続点近傍におけるファイバヒューズによる気泡間隔ゆらぎの観測
電子情報通信学会和文論文誌B, J101-B, 10, 833-840
|
2018-10 | ||
Fiber fuse terminator consisting of a step-index multimode fiber spliced with SMFs
IEICE Communications Express (ComEX), 9, 9, 400-404
|
2020-06 | ||
空孔アシストファイバを用いたファイバヒューズ停止部品の設計方法
電子情報通信学会論文誌 B, J103-B, 10, 440-451
|
2020-10 | ||
WDMシステムにおける入力光強度変調によるファイバヒューズ発生抑圧
電子情報通信学会論文誌, J105-B, 3, 307-309
|
2022-03 | ||
波長1 µmパルス光を用いたSMFにおけるファイバヒューズ伝搬抑圧
電子情報通信学会論文誌B, J107–B, 3, 226–229
|
|
2024-03 |
国際会議発表論文
| 発表題名 | 発行年月 |
|---|---|
Fiber fuse propagation in LP11 mode in few-mode fiber
Optical Fiber Communications Conference, OFC2015, OSA, IEEE, Los Angeles
|
2015-03 |
Design of Hole-assisted Fiber Based Fiber Fuse Terminator Considering Area of Melted Region
OECC/PSC 2019, IEICE Communications Society, 福岡
|
2019-07 |
Dopant dependence of fiber fuse propagation threshold
24th Microoptics Conference (MOC2019), The Japan Society of Applied Physics (JSAP) , 富山
|
2019-11 |
Fiber fuse terminator consisting of a step-index multimode fiber spliced with SMFs
24th Microoptics Conference (MOC2019), The Japan Society of Applied Physics (JSAP) , 富山
|
2019-11 |
Suppression of fiber fuse initiation by amplitude modulation of input light
24th Microoptics Conference (MOC2019), The Japan Society of Applied Physics (JSAP), 富山
|
2019-11 |
Fiber fuse suppression dependence on input power of amplitude-modulated light
2020 International Conference on Emerging Technologies for Communications (ICETC2020), IEICE, オンライン
|
2020-12 |
Termination of fiber fuse propagation using optical pulses
the 26th Microoptics Conference (MOC2021), The Japan Society of Applied Physics (JSAP), オンライン
|
2021-09 |
Stimulated Raman Scattering and Power-over-Fiber Property of Multi-core Fiber
Optical Fiber Communications Conference, OFC2022, OPTICA(OSA), San Diego, CA, USA
|
2022-03 |
High-Efficiency and Long-Distance Power-over-Fibre Transmission using a 125-μm Cladding Diameter 4-Core Fibre
European Conference on Optical Communications (ECOC2023), IEEE, Glasgow
|
2023-10 |
Optical power delivery with suppressed fiber fuse in SMF at a wavelength of 1 μm
ICETC2023, IEICE, Sapporo
|
2023-11 |
科学研究費
| 研究課題・他 | 取得年月 |
|---|---|
ファイバヒューズの発生伝搬を抑圧する方法の検討
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ファイバヒューズの発生伝搬を抑圧する方法の検討
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ファイバヒューズの発生伝搬を抑圧する方法の検討
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受賞
| 2005 | 日経BP技術賞 「ホーリーファイバ」 |