2. Web-Based Modeling and Simulation Understanding and Dealing With Complexity in... Mr. Dana Paterson AIR4.0X C4ISR Systems Architecture Development and Analysis Engineer

3. CNO’s Transformation Roadmap

4. FORCEnet Command & Control Grid Sensor Grid(s) Weapon Grid(s) For the purposes of this presentation … is the operational construct and architectural framework for Naval Warfare in the Information Age which integrates warriors, sensors, networks, command and control, platforms and weapons into a networked, distributed combat system, scalable across the spectrum of conflict from seabed to space and sea to land.

5. Concept Development Experiments Requirements Generation LIVE CONSTRUCTIVE VIRTUAL M&S ISTF RANGE HITL LABS ANALYSIS Iterative Process Naval Aviation Experimentation Framework Iterative, Step-wise Refinement Exploiting M&S in a DoD 5000 Framework The Concept Maturation Engine

6. Concept Definition Strategy Development Planning & Management Requirements Management Concept Development Knowledge Management Functions Define Assess Strategize Validate Iterative Function The Concept Maturation Process is comprised of four components which are Closely integrated through an iterative and continuous concept assessment Approach (DEFINE-ASSESS-STRATEGIZE-VALIDATE). LIVE CONSTRUCTIVE VIRTUAL ISTF RANGE HITL LABS Spiral Process Naval Aviation Experimentation Framework Concept Development Experiments Requirements Generation M&S ANALYSIS The Inner Workings of Concept Maturation

7. SYSTEM ANALYSIS SYSTEM DESIGN SYSTEM INTEGRATION SYSTEM VERIFICATION ARCHITECTURE Digital Models Integrated Product Teams Stakeholders System Verification Working Groups Contractors Trades & Analysis System Design & Implementation Requirements Definition An Architecturally-Governed, Iterative Systems Engineering Process The Systems Engineering Engine

8. The System Engineering Context External Factors Provide the “Rotational Force”

9. Collaborative Engineering for a Single System System Engineering Over Time

10. Weapons Grid (For Example) Synchronized System Engineering Required to Deploy System of Systems Many Concepts, Much Engineering, Timely Deployments Synchronized, Over Time

11. Synchronous Engineering Scientific Method Analytic Rigor COLLABORATIVE ENGINEERING ENVIRONMENT Simultaneous Engineering in the Large …sensors, networks, decision aids, weapons, warriors and supporting systems integrated…

12. METRICS DESIGN ANALYSIS EXPERIMENT SENSORS COMMAND & CONTROL WEAPONS VALIDATION & CERTIFICATION FORCEnet Backplane Architecture for a System of Systems of Systems (an Architecture of Architectures)

13. Typical Infrared Hardware-In-the- Loop Test Lash-up Atmosphere Scenario (movements) Obscurants Targets Terrain Scene Rendering Scene IR IR Scene Projector IR Scene Sensor DATABASES Sensor Platform State Vector

14. Signals Instrumentation Nav JIMM In Development Untested Nearly Ready or Ready EA-6B ICAP-III Multi-Sensor Test Lash-Up As of December 12, 2001 IOC: February 18, 2002 FOC: April 1, 2002

15. HARDWARE-IN-THE-LOOP ANECHOIC CHAMBERS FLIGHT TEST SQUADRONS SIMULATIONS TARGETS PATUXENT RIVER POINT MUGU CHINA LAKE LAKEHURST ORLANDO TEST AND EVALUATION ENGINEERING T&E EXPERTISE OPEN AIR RANGES Simultaneous FORCEnet Concept Evaluation A NAVAIR Example

16. Futurespective

17. FORCEnet Command & Control Grid Sensor Grid(s) Weapon Grid(s) Backplane

18. QUESTIONS