Sudip Shekhar received the B.Tech. from the Indian Institute of Technology, Kharagpur, in 2003 and the M.S. and Ph.D. degrees from the University of Washington, in 2005 and 2008, respectively. From 2008 to 2013, he worked as a Research Scientist in the Circuits Research Laboratory at Intel Corporation, Hillsboro, Oregon. He joined the department of ECE at University of British Columbia as an Assistant Professor in 2013.
Dr. Shekhar is the recipient of the IEEE Solid-State Circuits Society Predoctoral Fellowship, the Intel Foundation Ph.D. Fellowship, the Analog Devices Outstanding Student Designer Award, and the Darlington Best Paper Award of the IEEE Circuits and Systems Society. His research interests include circuits for high-speed I/O interfaces, Silicon Photonics, RF transceivers and sensor interfaces.
EECE 571H |
Integrated Circuits for High-Speed Data Links Introduction to high-speed links, Noise and Jitter, Characterizing data channels in frequency and time domain, Equalization, Link modeling and simulation, Signaling schemes, Design of different transmitter and receiver circuits, Clock and data recovery.. Prerequisites: One of (EECE457, EECE488, EECE571F Section 202 [2014W], EECE588) |
ELEC 404 |
RF Integrated Circuits Introduction to radio-frequency (RF) communication systems; Matching Networks, Transceiver architectures, Low Noise Amplifiers, Mixers, Oscillators, etc. [3-0-1] Prerequisite ELEC 221 - Signals and Systems Corequisite ELEC 401 - Analog CMOS Integrated Circuit Design |
EECE 571Z |
CMOS Design for Optoelectronics Applications Course Structure/Operation This is a one semester course involving lectures, projects and exams. In the previous years, this used to be only a project-based course (since September 2013). Learning Objectives By the end of the course, it is expected that students will be able to: |
ELEC 402 |
Introduction to VLSI Systems The chip design process using VLSI design styles in CMOS technology. Data path, control and register file design and layout. Clocking schemes, flip-flop and latch-based design. VHDL/Verilog design project using CAD tools. [3-0-2] |
ELEC 403 |
Digital Integrated Circuit Design Overview of deep submicron custom ic design. Advanced MOS models. IC fabrication. Timing and power calculations. Interconnect modeling and analysis techniques. Circuit-level design issues. SPICE circuit simulation. High-speed circuit design project. |
ELEC 506 |
CMOS Design for Optoelectronics Applications Course Structure/Operation This is a one semester course involving lectures, projects and exams. Pre-requisites: Basic core undergraduate courses in electronics, i.e, familiarity with CMOS and circuit analysis, and computer-aided design tools for circuit design such as Cadence. Learning Objectives By the end of the course, it is expected that students will be able to: |
EECE 571F |
Electrical Engineering Seminar and Special Problems - RF INTGRTD CIRCT Introduction to radio-fr |
EECE 571H |
Integrated Circuits |