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 SIN 871-3 System Design, Engineering and IntegrationHere’s a GSA description of this SIN#. Following is a list of Projects we have worked on relating to this SIN # Services required under this SIN involve the translation of a system (or subsystem, program, project, activity) concept into a preliminary and detailed design (engineering plans and specifications), performing risk identification/analysis/mitigation, traceability, and then integrating the various components to produce a working prototype or model of the system. Typical associated tasks include, but are not limited to computer-aided design, design studies and analysis, high level detailed specification preparation, configuration management and document control, fabrication, assembly and simulation, modeling, training, privatization and outsourcing. Example: The navigation satellite concept produced in the preceding stage will be converted to a detailed engineering design package, performance will be computer simulated and a working model will be built for testing and design verification. Architect-Engineering (A/E) Services as that term is defined in FAR 36.601-3 are excluded from the PES Schedule. If the agency’s statement of work, substantially or to a dominant extent, specifies performance or approval by a registered of licensed architect or engineer for services related to real property, the Brooks Architect-Engineers Act applies and such services must be procured in accordance with FAR Part 36. Use of this schedule for Brooks Act architectural or engineering services is not authorized. Inappropriate use of this SIN is providing professional engineering services not specifically related to System Design, Engineering and Integration and associated disciplines. To see additional information about these projects, click on the project #. Project 1: Innovative Rotorcraft Flight Control Systems Options to Enhance Shipboard Operations. Develop a flight control design environment to facilitate the design of control systems for shipboard operations. Project 2: Real-Time Modeling of Rotor Induced Flow with Shipboard Interaction. Develop a viscous vortex wake model that can properly capture the effects of the rotor/ship interaction Project 3: Design and Analysis of a Compound Helicopter for High Speed Flight Use ART modeling and analysis tools RCAS and FLIGHTLAB to design and simulate a compound helicopter that uses a variable speed rotor for efficient autorotative lift in high speed forward flight Project 4: HeliFlight-R - Develop a reconfigurable simulator to support engineering applications Project 5: Aeroelastic Modeling of a Long Endurance Fixed Wing UAV - Use ART modeling and analysis tool RCAS to design and simulate a Long Endurance Fixed Wing UAV Advanced Rotorcraft Technology, Inc. Project 6: HI-ARMS - Coupling of Comprehensive Structural Analysis Codes to Computational Fluid Dynamics Codes for advanced Modeling and Simulation Project 7: H-60M helicopter Upgrade Program - Use ART modeling and analysis tool FLIGHTLAB to design and simulate upgrades to the H-60M helicopter Project 8: Waypoint Following - Design and testing of a trajectory following autonomous control system for a UAV Project 9: Sensor Visualization - Develop visualization tool for Apache helicopter electrooptical sensor blind spots Project 10: CH-53 Aeroelastic Simulation Model Project 11: Ducted Fan Model - Develop a ducted fan model in FLIGHTLAB that includes blade element modeling of the rotor, panel method modeling of the duct, and mutual interaction between the rotor and duct. Project 12: OH-58D Model for Flight School XXI – Integration and Testing of OH-58D flight dynamics model with Rockwell simulator for U.S. Army Flight School XXI Project 13: Sling Load Modeling for Handling Qualities Analysis - Modeling and validation of sling loads for handling qualities analysis Project 14: HeliQuiet - Couple RCAS with CFD codes to provide a design environment for quieter rotor blades Project 15: Advanced Multi-Aircraft Shipboard Landing Model - Model aerodynamic interaction of multiple aircraft in a shipboard environment Project 16: OH-58D Simulator for Advanced Rotorcraft Training Services - Designed, developed and certified to FAA Level D standards a simulator of the OH-58D helicopter. Project 17: Lift Simulation for Helicopters Improvement Program (LSHIP) Integration and testing of FLIGHTLAB UH-60 flight dynamics model with shipboard landing on a U.S. Army Operational Flight Trainer Project 18: CHSSI - HPC RCAS - Integration of RCAS with Overflow CFD program and testing with CH-47 model Advanced Rotorcraft Technology, Inc. Project 19: DASH SIM - Integration and testing of FLIGHTLAB UH-60 flight dynamics model with Army research simulators. Integration with tactical environment and visual display using HLA. Project 20: Ship Dynamics/Ship Air Wake Interface - Enhanced ship airwake integration with ship model and flight dynamics model Project 21: Generation of Consistent Rotorcraft Dynamic Models for Life Cycle Simulation Support - Utilize simulation models traceable to a common comprehensive simulation model for all stages of flight vehicle life cycle; Conceptual design to pilot training. |
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Contact Information
SIN 871-3 System Design, Engineering and Integration
Project 1