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Facilities
ECE Computer Operations and Services Center
The department's major computing facility houses two SunFire v880s, one for
undergraduate work, and one
for graduate and research work. Licenses are run off Sun v100’s in a redundant configuration to provide reliable services.The facility also houses several PC servers, including Dell PowerEdge models 4300, 2500, 2400 and 2200. Residing on the servers are:
- Licensing for different software packages
- Software installers for faculty and students
- Storage space for senior design teams
- A RAS Server: Remote Access Server for dialing into the Drexel network via a modem for faculty and staff
- Data-sharing space for faculty members to share data with one another
Various software packages
are available for graduate and undergraduate student use, including Cadence,
MATLAB, Maple, Mentor Graphics, and C and Fortran compilers. These applications
are also available to research labs in the ECE department. An X-terminal
facility is available for students to access these UNIX-controlled applications,
as well as several PC labs for access to the Windows versions of the software.
Public Computer
Labs
The department has both Windows NT and Macintosh computer facilities available for use by ECE students. These facilities can be accessed 24 hours a day, seven days a week, through the security system built into the student ID card. The computer systems have a broad assortment of applications used for class or lab work, as well as the common applications used for general computing projects.
Research and Teaching Laboratories
The Applied Communications
and Information Networking Center
The ACIN Camden Center, Camden, NJ; Dr. Moshe Kam,
ACIN Program General Manager; Dr. William Regli, Dr. Kapil Dandekar: Principal
Research Invesigators
The focus of the ACIN Camden Center is on the creation and demonstration
of
innovative telecommunications and information networking technologies; and
the demonstration of proofs-of-concept for: secure, reliable, user-centered,
wireless communication and networking platforms that leverage these
technologies.
These platforms will support network-based end user applications
that end
users can depend upon, in critical missions and operations... where these
networking platforms may be severely stressed or limited by environmental
factors; and where these networks may be under attack by adversaries,
including criminals and terrorists.
Current projects focus on wireless communication in non-line-of-sight
environments using various advanced technologies that employ relaying and
multipath diversity; and the creation of secure, wireless networks to
support teams of users conducting emergency operations.
Audio Processing Testbed
The Audio Processing testbed
is a NSF funded facility that consists of:
- B&K 4100 Binaural Dummy Head Microphone: used for high quality binaural measurement for testing human auditory perception.
- 24-bit stereo DAT Recorder: high quality 2-channel digital audio recorder/player.
- 8-channel out/2-channel in PC audio card: enables a PC to output multiple channels to multiple speakers for multi-speaker audio reproduction.
- 3 measurement quality microphones: individual omni-directional microphones for measuring sound at a particular location.
- 2 speakers: used for producing test signals for measurement.
- Mixer/pre-amplifier: low-noise professional analog mixer used to control and adjust gains and attenuation of signals from microphones to recording equipment and to speakers.
Center for Microwave/Lightwave Engineering
Director:
Dr.
Peter
Herczfeld,
215-895-2256
The
goal
of
this
newly established
Center
is
to
establish
a
premier
research
and education center for the advancement of microwave-lightwave engineering.
Microwaves and photonics are among the fastest growing disciplines
in
engineering.
The extensive national effort in monolithic microwave integrated circuits
(MMIC)
will have a profound effect on high-speed, high-frequency analog and digital
systems. The heart of this facility is the HP 8510 network analyzer,
a Tektronics Spectrum Analyzer, various power meters, high-sensitivity
microwave
bridges,
and a variety of active and passive components. There are facilities
to fabricate and test hybrid microwave and millimeter wave circuits.
The optical
equipment
includes five optical tables, an assortment of computer-controlled
positioners, high-precision positioners, dye laser, pulsed flag laser,
a number of
high-speed semiconductor lasers and detectors, CCD cameras, and an
image processing
facility. Several CAD programs such as Touchstone and
Supercompact are available
for research and teaching.
Cleanroom Microfabrication Facility
Room
6-334/334A
The
ECE
Department
Cleanroom
facility
is
used
to
develop
novel
microelectronic
materials, processes, and devices. It encompasses an area of 1,800
square
feet
with a rating of Class 10,000. The cleanroom contains a variety of
thin
film
manufacturing and diagnostic equipment, such as thin film evaporators,
a
diffusion
furnace, photoresist spinner, mask aligners, wafer scribing and dicing
equipment,
and an ellipsometer. Additional equipment suitable for the manufacture
and
packaging
of hybrid circuits is also available. Device characterization and testing
equipment
is also available and includes a computerized station with femto-Farad
and
pico-Amp
resolution. Faculty, graduate, and undergraduate students use the facility
in
their research and education programs.
Communications and Signal Processing Laboratory (CSPL)
Dr.
Athina
P.
Petropulu,
215-895-2358
The
lab
equipment
has
been
purchased
through
funding
from
the
National
Science
Foundation, the US Army, The Whitaker Foundation, the National Institute
of
Health
and support from Drexel University. It includes:
- SUN Ultra ENTERPRISE 2, Dual-200 MHz processors, 8.6 GB Hard Disk, 256 MB RAM, Exabyte 8505/XL Tape Drive (6-14 GB), CD-ROM (internal), Floppy Disk (1.4 MB internal), color monitor, Solaris 2.5.1.
- SUN Ultra 1, 147 MHz Processor, 2 GB Hard Disk Space, 64 MB RAM, color monitor, Solaris 2.5.1.
- SUN SparcStation 5, 110 MHz processor, 64 MB RAM, 1.2 GB Hard Disk, CD-ROM (external), color monitor, Solaris 2.5.
- Dell Dimension XT550, 550MHz Pentium III processor, 364MB RAM, 64MB Video Memory, 18 GB SCSI Hard Driver, 19' Trinitron monitor, 2X4 CDRW, soundblaster with 32MB on board memory, Windows NT OS.
- SUN Ultra 10 workstation (300 MHz processor, 256 MB RAM, 8.6 GB hard disk, 21'' color monitor, Creator 3D video card, Solaris 2.5.1).
- HP LaserJet 4000 TN printer.
- Three (3) HDS @work Supra-66 17CH X-terminals, color monitor, 16 MB RAM.
- APPLE LaserWriter 16/600 PS.
Computer Communications Laboratory
Dr. Harish Sethu, 215-895-5876
The Computer Communications Laboratory, founded in 1999, conducts
both fundamental and applied research in the design and analysis of protocols,
architectures, and algorithms in computer networks. Research efforts in
this laboratory have primarily focused on performance and quality of
service with applications to computer networks at all scales, from
interconnection networks of parallel computer systems and web servers to
large-scale distributed networks such as the Internet. Specific areas of
research include fair traffic management strategies for best-effort as
well as real-time applications, switch and router architectures, and
quality of service in mobile ad hoc networks. Some recent efforts have
also focused on other areas of research such as sensor networks, practical
pricing strategies for the Internet, network security issues beyond
cryptography, and large-scale dynamics of the Internet. Housed in Room 502
of the Commonwealth Hall, the laboratory is equipped with several high-end
workstations and continues to expand its computational facilities. Primary
sponsors of the research in this laboratory include NSF, DARPA, Department
of Defense, Lockheed Martin, and Northrop Grumman Corporation.
Data Fusion Laboratory
Dr.
Moshe
Kam,
215-895-6920,
Dr.
Paul
Kalata,
215-895-2251, Dr. Leonid Hrebein 215-895-6755
The Data Fusion Laboratory investigates problems in multisensor detection and
estimation with applications in digital communications, radar, and target tracking.
Among the projects in progress: computationally efficient parallel distributed
detection, modulation recognition in digital communications over fading channels,
neural network synthesis for pattern recognition, and hardware realization
of a data fusion center for binary detection and target tracking. The laboratory
also participates in joint efforts with the Power Systems Laboratory to develop
automatic contingency selection algorithms using combined neural network/expert
system architectures.
Electric Power Engineering Center
Room
2-048,
Dr.
Karen
Miu,
215-895-6207,
Dr.
Dagmar
Niebur,
215-895-6749,
Dr.
Chika
Nwankpa,
215-895-2218
This newly established facility makes possible state-of-the-art research in a
wide variety of areas, ranging from detailed theoretical model study to experimental
investigation in its high voltage laboratories. The mission is to advance and
apply scientific and engineering knowledge associated with the generation, transmission,
distribution, use, and conservation of electric power. In pursuing these goals,
this center works with electric utilities, state and federal agencies, private
industries, nonprofit organizations and other universities on a wide spectrum
of projects. Research efforts, both theoretical and experimental, focus on the
solution of those problems currently faced by the electric power industry. Advanced
concepts for electric power generation are also under investigation to ensure
that electric power needs will be met at the present and in the future.
Microwave-Photonics Device Laboratories
Dr.
Afshin
Daryoush, 215-895-2362
The laboratory is equipped with fiber-optic and optical equipment such
as high-speed semiconductor laser diodes up to 20 GHz, traveling wave
MZ modulators with bandwidth of 18Ghz, and high-speed pin photodiode
up to
25 GHz in 680 nm, 780nm, 820nm, 1300nm, and 1500nm range. A fiber etching
platform and fusion splice is also available to make lenses on single-mode
and multimode fibers. Additional passive components such as translation
micropositioners, single-mode and multi-mode 3dB optical couplers,
optical switches, fiber-optic polishing and connectorizing equipment,
optical
spectrum analyzer, scanning F-P and optical power meters. Microwave
test equipment
such as Agilent network analyzer, HP synthesized sources, Rohde-Schwartz
signal generators, Tektronix and HP spectrum analyzers, power meters,
and assortment of passive and active microwave components up to 40
GHz. Intercontinental
test fixtures are used for testing of MMIC circuits
and solid-state transistors. Furthermore, a specialized test fixture
is developed for testing of ASIC
circuits up to 10 GB/s. Our computer facilities are based on x-terminals
connected to servers that support state-of-the-art microwave and
electromagnetic CAD packages such as ADS, Ansoft HFSS, and Cadence.
Millimeterwave/Lightwave Engineering Laboratory
Dr.
Peter
Herczfeld,
215-895-2256,
Dr.
Afshin
Daryoush,
215-895-2362
This
laboratory
is
equipped with state-of-the-art
test
equipment
for
the
characterization
of electrical and optical passive and active circuits. Facilities include
HP8510
automated vector network analyzer (45MHZ–26.5GHZ), Tektronix 7854 computer
controlled
TDR/sampler scope with 25ps resolution, Tektronix 2756P GPIB controllable
spectrum
analyzer with external mixers up to 60 GHz, Tektronix 7L18 spectrum analyzer
and associated external mixers up to 60 GHz, synthesized sweeper HP8340B
and
sweep
oscillator
HP8350
(10 KHz–26.5
GHz),
synthesized
attenuators,
and passive
microwave and millimeter wave components. There are a GPIB-controlled optical
spectrum analyzer covering 600–1750nm with resolution of 0.1nm from Ando,
focusing aspherical lenses, laser diode collimating lenses, and assortments
of interference
filters and neutral density filters, and a scanning Fabry-Perot. The laboratory
is also equipped with a tunable dye laser diode (500–960nm) and a pulsed
Nd-YAG laser from Spectra Physics
for semiconductor device
characterizations.
Power Electronics Research Laboratory
Room
2-048,
Dr.
Chika
Nwankpa, 215-895-2218
The
Power
Electronics
Research Laboratory (PERL)
is
involved
in
circuit
and
design
simulation, device modeling and simulation, and experimental testing and fabrication
of power electronic circuits. The research and development activities include
electrical terminations, power quality, solar photovoltaic systems, GTO modeling,
protection and relay coordination, and solid-state circuit breakers. The analysis
tools include EMPT, SPICE, and others, which have been modified to incorporate
models of such controllable solid-state switches as SCRs, GTOs, and MOSFETs.
These programs have a wide variety and range of modeling capabilities used
to model electromagnetics and electromechanical transients ranging from
microseconds
to seconds in duration. The PERL is a fully equipped laboratory with 42 kVA
AC
and 70 kVA DC power sources and data acquisition systems, which have the
ability to display and store data for detailed analysis. Some of the equipment
available
is a distribution and HV transformer
and three phase rectifiers
for power sources and digital oscilloscopes for data measuring and experimental
analysis. Some of the recent studies performed by
the PERL include static VAR compensators, power quality of motor controllers, solid-state circuit breakers, and power device modeling which have been supported
by PECO, GE, Gould, and EPRI.
Supervisory Control Laboratory
Dr.
Moshe
Kam,
215-895-6920
The Supervisory Control Laboratory investigates large-scale dynamic systems and
robotic plants, using techniques that are imported from the disciplines of control
theory and computer science. Special emphasis is given to control via the formulation
of discrete event systems with applications in power system and complex manufacturing
processes. Several physical plants are used for concept demonstration and algorithm
verification, among them a hopping robotic leg and a mobile autonomous robot.
Major funding for the laboratory’s activities comes from the NSF and from EPRI.
Ultrasound Transducer Research Facility
Dr.
Peter
Lewin,
215-895-2361
This 600-square-foot facility has water, work benches for electronic construction
and testing, computer controlled scanning tanks, and a broad range of modern
test high speed digitizers, ultrasound pulsers and receivers, digital oscilloscopes,
and micro/minicomputers. Moreover, there is distilled water supply equipment,
experimental shock wave generator, and several calibrated miniature PVDF receivers
together with standard pulse-echo imaging transducers. The piezoelectric receivers
include both wideband needle-type hydrophone probe and a spot poled membrane
hydrophone developed for both calibration and testing, and the shock wave measurements.
Comprehensive acoustic characterization of the transducers and materials can be carried out using Time Delay Spectrometry (TDS) measurement set-up. Small workshop facilities are established in the laboratory allowing prototype transducer assembly. In addition, there is a high-voltage poling facility.
VLSI Design Facility
Dr.