| ²é¿´: 4147 | »Ø¸´: 33 | |||
beiyangxuezi½ð³æ (СÓÐÃûÆø)
|
[½»Á÷]
Ó¢¹ú»ªÍþ´óѧ(Warwick)½ÓÊÕ¹âͨÐźͻúÆ÷ѧϰ·½Ïò·ÃÎÊѧÕß1-2Ãû ÒÑÓÐ4È˲ÎÓë
|
|
Ó¢¹ú»ªÍþ´óѧ(University of Warwick) Assistant Professor Dr. Tianhua Xu¿ÎÌâ×é½ÓÊÕ¹âͨÐÅ¡¢¹âÍøÂç¡¢»úÆ÷ѧϰ·½Ïò·ÃÎÊѧÕß1-2Ãû Optical networks form an integral part of the world-wide communication infrastructure and nowadays over 95% of all digital data traffic is carried over fibres. Meeting the ever-growing information rate demands has become of utmost importance for optical communication networks. Optical fibre channel is nonlinear, that is, its refractive index, is dependent on signal intensity. At high power densities, the combination of fibre nonlinear effects, dispersion as well as laser phase fluctuation and transceiver noise will lead to nonlinear distortions, limiting both achievable capacities, spectral efficiencies and transmission distances. New research and development is critically required not only for finding new native nonlinear communication techniques but also transferring them into practical, error-resilient networks. Ñо¿·½Ïò£º 1. Machine learning and Digital signal processing in optical communication networks In optical communication, high performance computing and data center systems, as high-speed and high-order modulated signals are applied, system performance will be significantly degraded by transmission impairments, such as bandwidth limitation, dispersion, polarization dependent loss, channel fading, laser phase noise and nonlinear distortions from optical channels and components. In this project, reconfiguration of optical communication networks and data center systems will be investigated based on digital signal processing and machine learning techniques in conjunction with software-defined transceivers, to compensate for transmission impairments and to realize the optimum detection of optical signals. 2. Information rates and Channel estimation of optical networks In optical communication networks, signals of different users are often multiplexed at different wavelengths, and will interact with each other due to the linear and nonlinear effects in optical channels and devices. Thus it is of importance to develop accurate physical estimation for nonlinear channels and components to assess the achievable capacity and mutual information of optical communication networks. In this research, fundamental limits of optical transparent networks will be studied considering the linear and nonlinear physical impairments in the link, such as chromatic dispersion, polarization mode dispersion, laser phase noise, self-/cross-phase modulation, four-wave mixing, channel memory etc. 3. Optimization in elastic optical networks to maximize the throughputs Based on software-defined transceivers and elastic optical networks, the transmission parameters, e.g. forward error correction (FEC) schemes, modulation formats, frequency separation (in flex-grid networks), optical launch powers and symbol rates etc. will be adapted and tailored to physical channels and components in the transparent wavelength routed networks. In addition, probabilistic shaping and geometric shaping will be applied to optimize the signals to have better tolerance against the degradations. All these degrees of freedom will be jointly optimized in conjunction with the routing of lightpaths through the optical network to maximize the overall capacity and resources. »ªÍþ´óѧUniversity of Warwick has ranked 57th in QS World University Rankings 2018, and consistently ranks in the top 10 of all major rankings of British universities. For more details regarding the application, please contact Dr. Tianhua Xu Email: tianhua.xu@warwick.ac.uk Homepage: https://warwick.ac.uk/fac/sci/eng/staff/tx Studentship webpage: https://warwick.ac.uk/fac/sci/eng/study/pg/pgr/project/TX18 Ó¢¹ú»ªÍþ´óѧÔÚ×îз¢²¼µÄQS2019È«Çò´óѧÅÅÃûµÚ54Ãû https://www.topuniversities.com/ ... rsity-rankings/2019 [ Last edited by beiyangxuezi on 2018-6-7 at 23:59 ] |
»Ø¸´´ËÂ¥» ±¾ÌûÒÑ»ñµÃµÄºì»¨£¨×îÐÂ10¶ä£©
» ²ÂÄãϲ»¶
0703»¯Ñ§Çóµ÷¼Á
ÒѾÓÐ6È˻ظ´
-
Ò»Ö¾Ô¸ÖÐÄÏ´óѧ»¯Ñ§Ñ§Ë¶0703×Ü·Ö337Çóµ÷¼Á
ÒѾÓÐ6È˻ظ´
-
¿¼Ñл¯Ñ§308·ÖÇóµ÷¼Á
ÒѾÓÐ9È˻ظ´
-
Çóµ÷¼Á Ò»Ö¾Ô¸ ±¾¿Æ ±±¿Æ´ó »¯Ñ§ 343
ÒѾÓÐ4È˻ظ´
-
Ò»Ö¾Ô¸¼ªÁÖ´óѧ²ÄÁÏÓ뻯¹¤303·ÖÇóµ÷¼Á
ÒѾÓÐ3È˻ظ´
-
¸÷λÀÏʦÄúºÃ£º±¾È˳õÊÔ372·Ö
ÒѾÓÐ3È˻ظ´
-
BÇø¿¼Ñе÷¼Á
ÒѾÓÐ5È˻ظ´
-
284Çóµ÷¼Á
ÒѾÓÐ12È˻ظ´
-
Çóµ÷¼Á£¬Ò»Ö¾Ô¸:ÄϾ©º½¿Õº½Ìì´óѧ´óѧ £¬080500²ÄÁÏ¿ÆѧÓ빤³Ìѧ˶£¬×Ü·Ö289·Ö
ÒѾÓÐ6È˻ظ´
-
289²ÄÁÏÓ뻯¹¤£¨085600£©BÇøÇóµ÷¼Á
ÒѾÓÐ5È˻ظ´
beiyangxuezi
½ð³æ (СÓÐÃûÆø)
- Ó¦Öú: 0 (Ó׶ùÔ°)
- ½ð±Ò: 1377.7
- É¢½ð: 227
- ºì»¨: 1
- Ìû×Ó: 77
- ÔÚÏß: 207.7Сʱ
- ³æºÅ: 549463
- ×¢²á: 2008-04-21
- ÐÔ±ð: GG
- רҵ: ͨÐÅÀíÂÛÓëϵͳ
2Â¥2018-05-18 21:07:19
Ëͺ컨һ¶ä
 |
3Â¥2018-05-21 19:15:45
|
|
4Â¥2018-05-22 20:21:44
|
|
5Â¥2018-05-23 21:54:16
|
|
6Â¥2018-05-24 22:03:19
|
|
7Â¥2018-05-25 20:45:45
|
|
8Â¥2018-05-26 20:56:56
jingchawk
Òø³æ (ÖøÃûдÊÖ)
- Ó¦Öú: 76 (³õÖÐÉú)
- ½ð±Ò: 106
- É¢½ð: 2807
- ºì»¨: 15
- Ìû×Ó: 1146
- ÔÚÏß: 219.5Сʱ
- ³æºÅ: 1895819
- ×¢²á: 2012-07-16
- רҵ: ¼ÆËã»úÍøÂç
9Â¥2018-05-26 22:32:02
ÔÚ·ÉÏBen
гæ (ÕýʽдÊÖ)
- Ó¦Öú: 8 (Ó׶ùÔ°)
- ½ð±Ò: 42.6
- É¢½ð: 1258
- ºì»¨: 4
- Ìû×Ó: 545
- ÔÚÏß: 178.7Сʱ
- ³æºÅ: 3413238
- ×¢²á: 2014-09-13
- רҵ: ͨÐÅÀíÂÛÓëϵͳ
10Â¥2018-05-27 09:43:57
