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High performance optical transmitter for next generation supercomputing and data communication.

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Format:
Book
Thesis/Dissertation
Author/Creator:
Wu, Xiaotie.
Contributor:
Shastri, Kal, committee member.
Nelson, Dale, committee member.
Laker, Kenneth R., 1946- committee member.
Engheta, N. (Nader), committee member.
Spiegel, Jan Van Der, advisor.
University of Pennsylvania. Electrical and Systems Engineering.
Language:
English
Subjects (All):
Electrical engineering.
Oral communication.
Communication.
0459.
0544.
Penn dissertations--Electrical and systems engineering.
Electrical and systems engineering--Penn dissertations.
Local Subjects:
Penn dissertations--Electrical and systems engineering.
Electrical and systems engineering--Penn dissertations.
0459.
0544.
Physical Description:
184 pages
Contained In:
Dissertation Abstracts International 75-01B(E).
System Details:
Mode of access: World Wide Web.
text file
Summary:
High speed optical interconnects consuming low power at affordable prices are always a major area of research focus. For the backbone network infrastructure, the need for more bandwidth driven by streaming video and other data intensive applications such as cloud computing has been steadily pushing the link speed to the 40Gb/s and 100Gb/s domain. However, high power consumption, low link density and high cost seriously prevent traditional optical transceiver from being the next generation of optical link technology. For short reach communications, such as interconnects in supercomputers, the issues related to the existing electrical links become a major bottleneck for the next generation of High Performance Computing (HPC). Both applications are seeking for an innovative solution of optical links to tackle those current issues.
In order to target the next generation of supercomputers and data communication, we propose to develop a high performance optical transmitter by utilizing CISCO SystemsRTM's proprietary CMOS photonic technology. The research seeks to achieve the following outcomes: 1. Reduction of power consumption due to optical interconnects to less than 5pJ/bit without the need for Ring Resonators or DWDM and less than 300 fJ/bit for short distance data bus applications. 2. Enable the increase in performance (computing speed) from Peta-Flop to Exa-Flops without the proportional increase in cost or power consumption that would be prohibitive to next generation system architectures by means of increasing the maximum data transmission rate over a single fiber. 3. Explore advanced modulation schemes such as PAM-16 (Pulse-Amplitude-Modulation with 16 levels) to increase the spectrum efficiency while keeping the same or less power figure.
This research will focus on the improvement of both the electrical IC and optical IC for the optical transmitter. An accurate circuit model of the optical device is created to speed up the performance optimization and enable co-simulation of electrical driver. Circuit architectures are chosen to minimize the power consumption without sacrificing the speed and noise immunity.
As a result, a silicon photonic based optical transmitter employing 1V supply, featuring 20Gb/s data rate is fabricated. The system consists of an electrical driver in 40nm CMOS and an optical MZI modulator with an RF length of less than 0.5mm in 0.13mu m SOI CMOS. Two modulation schemes are successfully demonstrated: On-Off Keying (OOK) and Pulse-Amplitude-Modulation-N (PAM-N N=4, 16). Both versions demonstrate signal integrity, interface density, and scalability that fit into the next generation data communication and exa-scale computing. Modulation power at 20Gb/s data rate for OOK and PAM-16 of 4pJ/bit and 0.25pJ/bit are achieved for the first time of an MZI type optical modulator, respectively.
Notes:
Thesis (Ph.D. in Electrical and Systems Engineering) -- University of Pennsylvania, 2013.
Source: Dissertation Abstracts International, Volume: 75-01(E), Section: B.
Adviser: Jan Van der Spiegel.
Local Notes:
School code: 0175.
ISBN:
9781303397004
Access Restriction:
Restricted for use by site license.

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