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[[File:VANDAL.png|right|super|200px]]
[[File:VANDAL.png|right|super|200px]]


== Drexel VLSI and Architecture Laboratory ('''VANDAL''') for '''IoT Systems'''  ==
== Drexel VLSI and Architecture Laboratory (VANDAL)   ==


Drexel VANDAL group consists of a research group of computer engineers and electrical engineers tackling high impact engineering problems with the objective of building sophisticated systems.  <!--Grand research goals are:


Drexel VLSI and Architecture Laboratory consists of a research group of computer engineers and electrical engineers tackling big engineering problems of building sophisticated systems.  Particular goals are in Internet-of-Things (IoT) systems targeting CPS, Energy and Health Monitoring with existing projects in:


* Exa-scale computing systems
# ''Design of Smart Cities and Homes''
* Smart energy/smart home/smart city systems
# ''Architectures for Security and Energy Efficiency of Cyber Physical Systems and IoT devices''
* IoT processor design
# ''Architectures and Efficient Design Methods for Future Healthcare''
* Bio-implantable and wearable systems
 
* 5G communication systems
-->
* Nano-electronic systems
* Algorithms and software for IoT hardware and software design, including machine learning






VANDAL is home to researchers involved closely with the design, analysis, implementation of integrated circuits and chip architectures with a focused goal of implementing sophisticated systems. Suited with industrial design tools for integrated circuits, simulation tools and measurement beds, the VLSI and Architecture group can design and test digital and mixed-signal circuitry to verify the functionality of the discovered novel circuit and physical design principles. The group also develops new tools and methodologies to improve application performance and efficiency through optimization of both software and hardware architectures. The VLSI and Architecture group explores a gamut of workloads including High-Performance Computing, Data Center, GPU, Machine Learning, and Cryptocurrencies. Some of the most exciting projects currently ongoing involve:
VANDAL has been home to researchers involved closely with the design, analysis, implementation of integrated circuits, chip architectures and software with a focused goal of implementing sophisticated systems. Suited with industrial design tools for integrated circuits, simulation tools and measurement beds, the VANDAL team can design and test digital and mixed-signal circuitry to verify the functionality of the discovered novel circuit and physical design principles. The group also develops new tools and methodologies to improve application performance and efficiency through optimization of both software and hardware architectures. The VANDAL team explores a gamut of workloads including High-Performance Computing, Data Center, GPU, Machine Learning, and Cryptocurrencies. Some of the most exciting projects currently ongoing involve:


# '''Charge Recovering Systems''': Charge recycling logic typically aims at recycling, or recovering, charge that is usually wasted in normal circuits. Since this charge is recycled, Charge Recovery Circuits consume less energy than standard circuits, allowing, for example, a longer battery life.
# ''Charge Recovering Systems for IoT, Bio-Implants and Energy Harvesting'': Charge recycling logic typically aims at recycling, or recovering, charge that is usually wasted in normal circuits. Since this charge is recycled, Charge Recovery Circuits consume less energy than standard circuits, allowing, for example, a longer battery life.
# '''Aging-Resilient Hardware for IoT Applications''': The VLSI group develops automated mitigation techniques that ensure device operation in the toughest environments. Electronics degrade over time and lead to slower operation including failure to operate. By using predictive models with targeted mitigation techniques, electronic devices maintain their operation for longer periods of time.
# ''Aging-Resilient IoT Hardware'': The VLSI group develops automated mitigation techniques that ensure device operation in the toughest environments. Electronics degrade over time and lead to slower operation including failure to operate. By using predictive models with targeted mitigation techniques, electronic devices maintain their operation for longer periods of time.
# '''Energy-Efficient Clock Synchronization for Computing Systems''': The design of clock networks is integral to ensuring fast performance of integrated circuits. The VLSI lab creates automated tools and design methodologies for the synthesis of exa-scale clock networks that require advanced techniques such as Deep Neural Networks. These tools and design methodologies aid in developing novel clocking techniques such as resonant clocking and wireless interconnects.
# ''Energy-Efficient Clock Synchronization for Computing Systems'': The design of clock networks is integral to ensuring fast performance of integrated circuits. The VLSI lab creates automated tools and design methodologies for the synthesis of exa-scale clock networks that require advanced techniques such as Deep Neural Networks. These tools and design methodologies aid in developing novel clocking techniques such as resonant clocking and wireless interconnects.
# '''Hardware and Software Co-Design for Exascale Computing Systems''': With the growth in the number of cores in chip multi-processors (CMP), it is essential to design for scalable communication interconnects. We explore the modeling and design of networks-on-chips (NoCs) as a fabric interconnecting cores in future high-performance chip multi-processors (CMPs).
# ''Hardware and Software Co-Design for Exascale Computing Systems'': With the growth in the number of cores in chip multi-processors (CMP), it is essential to design for scalable communication interconnects. We explore the modeling and design of networks-on-chips (NoCs) as a fabric interconnecting cores in future high-performance chip multi-processors (CMPs).
# '''Communication Infrastructure for On-chip Chp-Multi-Processors and Off-Chip 5G systems''': Wireless communication on-chip are investigated to replace the resource-demanding, conventional, wire-based interconnect networks within integrated circuits. Wireless communication will provide a solution that is highly scalable into the future for the IC communication challenge, as increases in technology scaling and die size dimensions are forecast by the semiconductor industry.
# ''Communication Infrastructure for Chip-Multi-Processors and 5G IoT systems within Smart Office Spaces'': Wireless communication on-chip are investigated to replace the resource-demanding, conventional, wire-based interconnect networks within integrated circuits. Wireless communication will provide a solution that is highly scalable into the future for the IC communication challenge, as increases in technology scaling and die size dimensions are forecast by the semiconductor industry.
#'''Energy-Efficient Clock Synchronization for Computing systems''': Design automation of resonant traveling wave oscillators (RTWOs) operating at frequencies ranging from MHz to GHz in nano-scale CMOS technology nodes. Enhance reliability of RTWOs by accounting for PVT and aging at the design stage.  
<!--#''Energy-Efficient Clock Synchronization'': Design automation of resonant traveling wave oscillators (RTWOs) operating at frequencies ranging from MHz to GHz in nano-scale CMOS technology nodes. Enhance reliability of RTWOs by accounting for PVT and aging at the design stage. -->
# '''Cyber Physical Design Automation of Smart Homes/Smart Cities''':  Through managing energy efficiency and cost-effectiveness.  Building an embedded-system based smart CPS platform for power systems.  A modern approach in meeting today’s technological need is to use Internet of Things (IoT). Through adaptive exchange of data, hardware equipments are designed to operate autonomously without human supervision. In assistance of our increasing need in electric power, we design this intelligent agent to manage the operation of electric power distribution. In advancement of our understanding in Cyber-Physical System (CPS), we study the physical limit such systems can be designed to delegate.
# ''Cyber Physical Design Automation of Smart Homes/Smart Cities'':  Through managing energy efficiency and cost-effectiveness.  Building an embedded-system based smart CPS platform for power systems.  A modern approach in meeting today’s technological need is to use Internet of Things (IoT). Through adaptive exchange of data, hardware equipments are designed to operate autonomously without human supervision. In assistance of our increasing need in electric power, we design this intelligent agent to manage the operation of electric power distribution. In advancement of our understanding in Cyber-Physical System (CPS), we study the physical limit such systems can be designed to delegate.




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Philadelphia, PA 19104
Philadelphia, PA 19104


<!--
<!-- Comments out
 
= ''' PhD student Research Assistantship positions are available ''' =  
= ''' PhD student Research Assistantship positions are available ''' =  


Open position to be filled in Fall 2015.  Seeking interest in some (not all) of the following areas:
Multiple open positions to be filled in Winter/Spring/Fall 2022.  Seeking interest in some (not all) of the following areas:


* VLSI
* VLSI
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* integrated circuits
* integrated circuits


Apply through the Drexel University website: [http://drexel.edu/grad/ | Drexel Admissions]
Apply through the Drexel University website: [http://drexel.edu/grad/ Drexel Admissions]
----
 


-->
-->
----


== [[People]] ==
== [[People]] ==
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=== Ph.D. students ===
=== Ph.D. students ===


[[Sief Atari]]


[[Leo Filippini]]
[[Yilmaz Gonul]]


[[Ragh Kuttappa]]
[[Ceyhun Kayan]]


[[Scott Lerner]]
[[Scott Lerner]]
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[[Michael Lui]]
[[Michael Lui]]


[[Vasil Pano]]
[[Nicholas Sica]]
 
[[Karthik Sangaiah]]
 


=== Other researchers ===
=== Other researchers ===
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[[Research#Resonant Clocking Technologies|Resonant Clocking Technologies]]
[[Research#Resonant Clocking Technologies|Resonant Clocking Technologies]]


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[[Research#Energy Efficient Computing with OptoElectronics|Energy Efficient Computing with OptoElectronics]]
[[Research#Energy Efficient Computing with OptoElectronics|Energy Efficient Computing with OptoElectronics]]
-->


== [[Publications]] ==
== [[Publications]] ==

Latest revision as of 12:38, 7 February 2023


VANDAL.png

Drexel VLSI and Architecture Laboratory (VANDAL)

Drexel VANDAL group consists of a research group of computer engineers and electrical engineers tackling high impact engineering problems with the objective of building sophisticated systems.


VANDAL has been home to researchers involved closely with the design, analysis, implementation of integrated circuits, chip architectures and software with a focused goal of implementing sophisticated systems. Suited with industrial design tools for integrated circuits, simulation tools and measurement beds, the VANDAL team can design and test digital and mixed-signal circuitry to verify the functionality of the discovered novel circuit and physical design principles. The group also develops new tools and methodologies to improve application performance and efficiency through optimization of both software and hardware architectures. The VANDAL team explores a gamut of workloads including High-Performance Computing, Data Center, GPU, Machine Learning, and Cryptocurrencies. Some of the most exciting projects currently ongoing involve:

  1. Charge Recovering Systems for IoT, Bio-Implants and Energy Harvesting: Charge recycling logic typically aims at recycling, or recovering, charge that is usually wasted in normal circuits. Since this charge is recycled, Charge Recovery Circuits consume less energy than standard circuits, allowing, for example, a longer battery life.
  2. Aging-Resilient IoT Hardware: The VLSI group develops automated mitigation techniques that ensure device operation in the toughest environments. Electronics degrade over time and lead to slower operation including failure to operate. By using predictive models with targeted mitigation techniques, electronic devices maintain their operation for longer periods of time.
  3. Energy-Efficient Clock Synchronization for Computing Systems: The design of clock networks is integral to ensuring fast performance of integrated circuits. The VLSI lab creates automated tools and design methodologies for the synthesis of exa-scale clock networks that require advanced techniques such as Deep Neural Networks. These tools and design methodologies aid in developing novel clocking techniques such as resonant clocking and wireless interconnects.
  4. Hardware and Software Co-Design for Exascale Computing Systems: With the growth in the number of cores in chip multi-processors (CMP), it is essential to design for scalable communication interconnects. We explore the modeling and design of networks-on-chips (NoCs) as a fabric interconnecting cores in future high-performance chip multi-processors (CMPs).
  5. Communication Infrastructure for Chip-Multi-Processors and 5G IoT systems within Smart Office Spaces: Wireless communication on-chip are investigated to replace the resource-demanding, conventional, wire-based interconnect networks within integrated circuits. Wireless communication will provide a solution that is highly scalable into the future for the IC communication challenge, as increases in technology scaling and die size dimensions are forecast by the semiconductor industry.
  6. Cyber Physical Design Automation of Smart Homes/Smart Cities: Through managing energy efficiency and cost-effectiveness. Building an embedded-system based smart CPS platform for power systems. A modern approach in meeting today’s technological need is to use Internet of Things (IoT). Through adaptive exchange of data, hardware equipments are designed to operate autonomously without human supervision. In assistance of our increasing need in electric power, we design this intelligent agent to manage the operation of electric power distribution. In advancement of our understanding in Cyber-Physical System (CPS), we study the physical limit such systems can be designed to delegate.


Drexel University

Department of Electrical and Computer Engineering

3141 Chestnut Street (map)

324 Bossone Research Center

Philadelphia, PA 19104



People

Faculty

Baris Taskin (Biography, CV, Contact)

Ph.D. students

Sief Atari

Yilmaz Gonul

Ceyhun Kayan

Scott Lerner

Michael Lui

Nicholas Sica

Other researchers

See People

Research

Publications

Software

Github

SynchroTrace

Seminars

Tutorials

Teaching

News/Events