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Company Information:

Company Name: Advanced Numerical Solutio
City: Hilliard
State: OH
Zip+4: 43026 0572
Woman-Owned: No
Minority-Owned: No
HUBZone-Owned: No
Website URL: N/A
Phone: (614) 771-4861

Award Totals:

Program/Phase Award Amount ($) Number of Awards
SBIR Phase I $219,291.00 2
SBIR Phase II $1,226,353.00 2

Award List:

Multi-Body Dynamic Two Dimensional Contact Analysis Tool for Transmission Design

Award Year / Program / Phase: 1999 / SBIR / Phase I
Agency / Branch: DOD / ARMY
Principal Investigator: Sandeep Vijayakar
Award Amount: $120,000.00
Abstract:
Not Available IFOS proposes to develop novel photonic signal-processing subsystems to replace certain electronic signal-processing functions presently limiting many sophisticated systems such as radar. Using photonics for signal processing and computing holds promise for ultra-high bandwidth and… More

Multi-Body Dynamic Two Dimensional Contact Analysis Tool for Transmission Design

Award Year / Program / Phase: 2000 / SBIR / Phase II
Agency / Branch: DOD / ARMY
Principal Investigator: Sandeep Vijayakar
Award Amount: $726,647.00

SBIR Phase I: A Multilevel Method for Rapid Evaluation of Sound Fields

Award Year / Program / Phase: 2005 / SBIR / Phase I
Agency: NSF
Principal Investigator: Rajendra Gunda, Dr
Award Amount: $99,291.00
Abstract:
This Small Business Innovation Research (SBIR) Phase I project aims to obtain rapid solutions to the acoustic wave equation for periodic built-up structures through development of advanced computational tools. The proposed novel modification exploits the structural symmetry to dramatically speedup… More

SBIR Phase II: A Multilevel Method for Rapid Evaluation of Sound Fields

Award Year / Program / Phase: 2006 / SBIR / Phase II
Agency: NSF
Principal Investigator: Rajendra Gunda, Dr
Award Amount: $499,706.00
Abstract:
This Small Business Innovation Research (SBIR) Phase II project aims to extend the current high frequency limit of acoustic analysis by two orders of magnitude and facilitate numerical simulation of extremely large sound structure interaction problems. The proposed method will advance the state of… More