@article{bhanja2006stimulus,
title={{A stimulus-free graphical probabilistic switching model for sequential circuits using dynamic bayesian networks}},
author={Bhanja, S. and Lingasubramanian, K. and Ranganathan, N.},
journal={ACM Transactions on Design Automation of Electronic Systems (TODAES)},
volume={11},
number={3},
pages={773--796},
year={2006},
publisher={ACM New York, NY, USA}
}
Monday, August 21, 2006
A Stimulus-free Graphical Probabilistic Switching Model for Sequential Circuits using Dynamic Bayesian Networks
S. Bhanja, K. Lingasubramanian and N. Ranganathan
Wednesday, August 16, 2006
WIP- Dominant Sensory Mode based Groups in VLSI Classes
S. Bhanja, “WIP- Dominant Sensory Mode based Groups in VLSI Classes”, accepted for publication in 36th ASEE/IEEE Frontiers in Education (FIE), 2006.
This work in progress reports an effort of introducing knowledge module regarding novel nano-devices and novel logic primitives in undergraduate logic design class. Our motivation is to make our students aware of fundamental abstracted logical behaviors of future nano-devices, their functionality. This effort would also help the students use their existing knowledge of K-map based logical synthesis into constructing logic blocks for novel devices that uses majority logic as basic construct. Moreover, additional to stimulating our students' interests, we are also augmenting their learning by challenging them to use their existing knowledge to analyze, synthesize and comprehend novel nano-logic issues through the worksheets and lecture modules. Whereas many efforts are focusing on developing new courses on nanofabrication and even nano-computing, we intend to augment the existing standard EE and CS courses by inserting knowledge modules on nano-logic structure for stimulating their interest without significant diversion from the course framework.
@conference{bhanja2006work,
title={{Work in Progress: Dominant Sensory Mode based Groups in VLSI Classes}},
author={Bhanja, S.},
booktitle={Frontiers in Education Conference, 36th Annual},
pages={14--15},
year={2006}
}
Abstract:This work in progress reports an effort of introducing knowledge module regarding novel nano-devices and novel logic primitives in undergraduate logic design class. Our motivation is to make our students aware of fundamental abstracted logical behaviors of future nano-devices, their functionality. This effort would also help the students use their existing knowledge of K-map based logical synthesis into constructing logic blocks for novel devices that uses majority logic as basic construct. Moreover, additional to stimulating our students' interests, we are also augmenting their learning by challenging them to use their existing knowledge to analyze, synthesize and comprehend novel nano-logic issues through the worksheets and lecture modules. Whereas many efforts are focusing on developing new courses on nanofabrication and even nano-computing, we intend to augment the existing standard EE and CS courses by inserting knowledge modules on nano-logic structure for stimulating their interest without significant diversion from the course framework.
Tuesday, January 3, 2006
VLSI DESIGN Honorable Mention Award
Probabilistic model on soft error paper (Thara Rejimon, Sanjukta Bhanja) was nominated for "Best Paper award" and received "Honorable Mention" award in IEEE Conference on Vlsi Design 2006.
Saturday, September 3, 2005
Javier Pulecio receives BD Scholarship
Javier Pulecio receives National Science Foundation Bridge to Doctorate scholarship.
Thursday, September 1, 2005
A Highly Reconfigurable Computing Array: DSP Plane of a 3-D Heterogeneous SoC
V. K. Jain, S. Bhanja, G. H. Chapman, L. Doddannagari and N. Nguyen, “A Highly Reconfigurable Computing Array: DSP Plane of a 3-D Heterogeneous SoC”, Accepted for publication for IEEE SOC conference, pp. 243-246, 2005.
@INPROCEEDINGS{1554503,
title={A highly reconfigurable computing array: DSP plane of a 3D heterogeneous SoC},
author={Jain, V.K. and Bhanja, S. and Chapman, G.H. and Doddannagari, L.},
booktitle={SOC Conference, 2005. Proceedings. IEEE International},
year={2005},
month={Sept.},
volume={},
number={},
pages={ 243-246},
abstract={A 3D heterogeneous system on a chip using a stack of planes has recently been proposed. While the sensors are located on the top plane, the other planes provide for analog processing, digital signal processing, and wireless communication. This paper focuses on a reconfigurable computing array for its DSP plane. The advantages of such an approach are high performance, small area and low power compared to FPGAs, and greater flexibility over ASICs. The authors presented the reconfigurable J-platform, which employs coarse-grain VLSI cells with high functionality, performance, and reconfigurability. These include a universal nonlinear (UNL) cell, an extended multiply accumulate (MA_PLUS) cell, and a data-fabric (DF) cell. The coarse-grain approach has the benefits of reduced external interconnect, much reduced design time, and manageable testability. The paper discusses these cells, including a new concept, namely multi-granularity. The methodology for mapping algorithms is illustrated by two important examples, FIR filtering of signals and images and the independent component analysis (ICA) algorithm. Finally, the paper discusses the issue of defect tolerance, which is critical in attaining reasonable yields making chip manufacture feasible.},
keywords={ VLSI, digital signal processing chips, reconfigurable architectures, system-on-chip 3D heterogeneous system-on-chip, DSP plane, coarse grain VLSI cells, data fabric cell, defect tolerance, extended multiply accumulate cell, independent component analysis, reconfigurable J-platform, reconfigurable computing array, universal nonlinear cell},
doi={10.1109/SOCC.2005.1554503},
ISSN={}, }
@INPROCEEDINGS{1554503,
title={A highly reconfigurable computing array: DSP plane of a 3D heterogeneous SoC},
author={Jain, V.K. and Bhanja, S. and Chapman, G.H. and Doddannagari, L.},
booktitle={SOC Conference, 2005. Proceedings. IEEE International},
year={2005},
month={Sept.},
volume={},
number={},
pages={ 243-246},
abstract={A 3D heterogeneous system on a chip using a stack of planes has recently been proposed. While the sensors are located on the top plane, the other planes provide for analog processing, digital signal processing, and wireless communication. This paper focuses on a reconfigurable computing array for its DSP plane. The advantages of such an approach are high performance, small area and low power compared to FPGAs, and greater flexibility over ASICs. The authors presented the reconfigurable J-platform, which employs coarse-grain VLSI cells with high functionality, performance, and reconfigurability. These include a universal nonlinear (UNL) cell, an extended multiply accumulate (MA_PLUS) cell, and a data-fabric (DF) cell. The coarse-grain approach has the benefits of reduced external interconnect, much reduced design time, and manageable testability. The paper discusses these cells, including a new concept, namely multi-granularity. The methodology for mapping algorithms is illustrated by two important examples, FIR filtering of signals and images and the independent component analysis (ICA) algorithm. Finally, the paper discusses the issue of defect tolerance, which is critical in attaining reasonable yields making chip manufacture feasible.},
keywords={ VLSI, digital signal processing chips, reconfigurable architectures, system-on-chip 3D heterogeneous system-on-chip, DSP plane, coarse grain VLSI cells, data fabric cell, defect tolerance, extended multiply accumulate cell, independent component analysis, reconfigurable J-platform, reconfigurable computing array, universal nonlinear cell},
doi={10.1109/SOCC.2005.1554503},
ISSN={}, }
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