http://ea.si-intl.com/Joint Space Operations Center (JSpOC) Weapon System
JWS
Air Force
Serco employs object-oriented techniques using the Unified Modeling Language (UML) to design required operational capabilities for joint space warfighters. JSMO is a large Air Force Space Command (AFSPC) Directorate of Requirements managed program to develop net-centric services for space situational awareness; identification and characterization of space threats; and, command and control of Space forces.
SSA & C2 Capability Area Architecture
SSA & C2
Air Force
Serco is partnered with Air Force Space Command (AFSPC/A5C) to perform enterprise architecture for Space Situation Awareness (SSA) and Space Command and Control (C2) – we’re successfully accomplishing the challenged of managing these program’s complex requirement needs using UML architectures. Top-down directed decisions necessitated an immediate need for AFSPC to transition the Combatant Commanders Integrated Command and Control System (CCIC2S) to sustainment and initiate new SSA and C2 major ACAT programs and potentially a new Air Warning and Defense program to fulfill remaining requirements not fully delivered by the CCIC2S ACAT I program. Working closely with the MITRE Corporation, Serco is delivering operational UML models in framework traceable to system development and software code. For the first time in Space Command’s history, DoDAF-compliant UML models representing the command’s user requirements are managing and driving system development.
Distributed Mission Operations for Space
DMO-S
Air Force
DMO-S is an evolving project providing training for space, ground, air, and sea forces through interface analysis from end-user training and exercises perspective. This is a main tenet of Training Transformation (T2), supporting the Joint Force Commander’s requirements for missile warning, positional navigation, battlespace awareness, and communications while training space force core competencies. Recently, Serco was placed on a five-year GSA contract focused on engineering support to assist in establishing technical analysis on integrating the system with the current Space assets and C2 Centers, and training simulation systems. This effort also includes using DoDAF artifacts to lead the Federation Development Process (FEDEP) for developing the Space Federated Object Model (S-FOM).
Architecture Integration and Management Directorate
AIMD/TRADOC
Army
Serco is performing DoD Architecture Framework (DoDAF)-compliant Unified Modeling Language 2.0 (UML) architecture modeling to fulfill life cycle engineering goals for all TRADOC Centers and Schools within the Continental United States (CONUS). Serco is using object-oriented analysis and design (OOAD) system engineering approach to deal with information technology (IT) architecture complexity, assist in business process reengineering (BPR), improve overall architecture program communications, and depict the blue print for current and future Service and Joint capabilities. Based on Joint Capabilities Integration and Development System (JCIDS), Serco is implementing an architectural capabilities analysis approach providing full traceability from policy and concept to the software and systems in a net-centric environment. Serco uses best commercial practices regarding software maintenance methods throughout the life of this contract. The primary purpose of the support is to consult with and facilitate AIMD with the necessary activities to migrate to a standardized, dynamic UML architectural capability.
North American Aerospace Defense Command C2
NORAD C2
NORAD
Serco employs object-oriented techniques using the Unified Modeling Language to design required operational capabilities for joint and combined warfighters. The NORAD C2 Enterprise Architecture models required operational capabilities to support sustainment of air and missile warning systems delivered by the Combatant Commanders Integrated Command and Control System (CCIC2S) program, and also captures required capabilities for NORAD’s new Maritime Warning mission.
Boeing Phantom Works UML Architecture Support
Architectures
Boeing
Beginning in late 2003, Serco was tasked to provide architectural support for Boeing’s Internal Research and Development (IRD) programs. Serco’s architecture team has provided Unified Modeling Language (UML) architecture support and architectural artifacts for several divisions within Boeing Phantom Works, Boeing Integrated Defense Systems, and Boeing Commercial Airplanes. The wide diversity of projects included Facility Protection and Battlefield Situational Awareness models for Phantom Works Homeland Defense, Mobile Targeting and Effects Based Operations doctrinal process models for Boeing ForceNet and Integrated Defense Systems, system development support and requirements gap analysis models for Boeing Commercial Airplanes, staff business and process analysis models for planning tool application development for Boeing’s Navy customer, architectural model and Concept of Operations (CONOPS) development support to Apache and Chinook program engineers, business development model support for a coalition team bid against an Army Logistics and Sustainment Support Request for Proposal (RFP), JCIDS and DoDAF compliant architectural artifacts and documentation for current and new platform development for Derivative Aircraft Platform within Advanced Platform Systems, and JCIDS and DoDAF compliant architectural artifacts and documentation as well as draft Concept of Operations/Concept of Employment (CONOPS/CONEMP) documents to help capture future requirements for Boeing Phantom Works Advanced Navy Strike platform development engineering teams.
The collaboration process facilitated by Serco’s architectural team (as well as the architectural artifacts created) provided Boeing system engineers with a clear and unambiguous understanding of their own, or their customer’s, requirements. The Serco Boeing Architectural Team provided unparalleled technical acumen and consistent, professional support since work first began in 2003. This work also provides a self-supporting business development effort. As more internal Boeing units are introduced to object-oriented UML-based methods and Serco’s efforts and products, more work has been generated each year to satisfy their growing technical architecture needs that are not being met by older methods and approaches.
Serco (then SI International) was recognized as the Supplier of the Year in the category of Technology by The Boeing Company for our commitment to excellence and customer satisfaction. The Boeing Supplier of the Year award is the company’s premier supplier honor, presented annually to its top suppliers in recognition of their commitment to excellence and customer satisfaction. Serco was one of only 11 suppliers selected for top honors in various commodity categories for their performance in 2006. These awardees were selected from a pool of more than 27,000 suppliers to Boeing from nearly 100 countries around the world. This selection was based on stringent performance criteria for quality, on-time delivery, cost, and customer satisfaction.
Serco’s Boeing Architecture Team has also received formal Letters of Commendation in 2004, 2005 and 2007 specifically acknowledging the outstanding contributions that were consistently made to the Boeing Internal Research and Development effort.
NORTHCOM J8 Homeland Defense and Civil Support Capabilities Based Assessment
HD&CS CBA
NORTHCOM
Serco is employing object-oriented methodology using the Unified Modeling Language to develop DODAF products (currently 134 OV-5s and 13 OV-6Cs) to support DOD's Homeland Defense and Civil Support (HD&CS) Capabilities Based Assessment (CBA). The EA contains 6 domains (Air/Space, Cyber, Mission Assurance, Maritime, Defense Support to Civil Authorities, and Land - Homeland Defense). The resultant EA also contains the previously JROC validated NORAD Homeland Air and Cruise Missile Defense Joint Capabilities Document (JCD) and Functional Solutions Analysis, and NORTHCOM Maritime Homeland Defense JCD into a single integrated architecture (supporting 10 JCIDS documents). The architecture CD also contains 13 2D scenario animations, one of SI's industry unique capabilities.
RF Adaptive Persistent Intelligence, Surveillance and Reconnaissance Data Link
RAPID
Boeing
AFRL
Serco is employing object-oriented methodology using the Unified Modeling Language to develop DODAF-compliant products (including OV-5s, OV-6Cs, SV-4s and SV-10Cs) to support Boeing's development of a new high-speed ISR Data Link for the Air Force Research Laboratory. The RAPID Integrated Architecture (IA) serves as the framework for COTS hardware implementation and new software design supporting data link development, which will culminate in a final system demo to AFRL. The RAPID IA also serves as the framework for the Systems Concept Document (a document containing potential future applications of the RAPID Link) and the Systems Requirements Document (RAPID system requirements). The documents were "data-mined" directly from the RAPID IA, and the RAPID Architecture CD contains 2D visualizations of the Risk Reduction Demo and system component level process animations via SI's industry unique animation capability.
Transformational Satellite Communications System
TSAT
Air Force
Serco employs object-oriented techniques using the Unified Modeling Language (UML) to design required operational capabilities for the global warfighter. The TSAT architecture products focus on top-level operational services to be provided by the program, especially emphasizing how the TSAT system will enable net-centric services to Global Information Grid (GIG) users. The architecture is a statement of future capability objectives for developing the TSAT system. It is used to manage development, structure design, and support testing and training associated with fielding and operating the system, as it is incrementally deployed. To these ends, the TSAT Architecture provides an overarching picture of the functions, operational relationships, and the information exchanges required to accomplish assigned TSAT missions. The integrated architecture is meant to be a living representation of the TSAT system, allowing for the efficient integration of new missions, new functions, and new technology. The architecture is intended to support the acquisition and test community, the user community, and other communities who may need to interface into the TSAT system. The architecture is constantly evolving due to changes in the mission areas, evolution of doctrine, and maturation of the TSAT and related systems.
Family of Advanced Beyond Line-of-Sight Terminals
FAB-T
Air Force
Serco is performing DoD Architecture Framework (DoDAF) compliant Unified Modeling Language (UML) to model an Enterprise Architecture (EA) for Headquarters Air Force Space Command (HQ AFSPC). The primary purposes of the EA is to communicate the usage and technical details of the FAB-T to other appropriate interested organizations and to support the certification of the Net Ready Key Performance Parameter (NR-KPP) of the FAB-T program. The EA supports an evolutionary acquisition approach to system architecture and design. The EA will evolve over the life of the program and serve additional purposes after program key decision points. Future uses include support to the Planning, Programming, Budgeting and Execution (PPBE) process, training development, operational planning and analysis, and testing.
Command and Control System – Consolidated
CCS-C
Air Force
Serco is performing DoD Architecture Framework (DoDAF) compliant Unified Modeling Language (UML) to model an Enterprise Architecture (EA) for The MILSATCOM Command and Control Squadron (MCCS). The EA documents the physical and virtual functionalities of the CCS-C. It identifies CCS-C impacts on the operational organizations, identifies system interfaces and data transfer requirements, and serves as a tool to evaluate the CCS-C operational concepts against the actual system design. The EA supports system design teams responsible for developing interfaces, hardware and software used in the CCS-C. It also supports the acquisition of future C2 systems by leveraging what CCS-C can already provide determining development required to realize additional functionality. Additionally, this EA supports budgetary decisions with respect to system design and operational and sustainment cost data. The EA will also serve as the reference that addresses the areas concerned with system design, system maintenance and system operation.
Global Positioning System
GPS
Air Force
Serco employs object-oriented techniques using the Unified Modeling Language (UML) to model required systems to provide precise position, velocity and time (PVT) to the GPS User Segment. The GPS Architecture gives an overarching picture of the functions and the information exchanges required to accomplish assigned GPS missions. The OA is meant to be a living representation of the GPS system, allowing for the efficient integration of new missions, new functions, and new technology. The integrated views of the GPS architecture are intended to trace requirements generation and integration, evolutionary acquisition support (system design, development and test) and operational training.
Ground Multi-band Terminal
GMT
Air Force
Serco employs object-oriented techniques using the Unified Modeling Language (UML) to model an Integrated Architecture, for Air Force Space Command (AFSPC) supporting acquisition of non-development item (NDI) deployable quad-band SATCOM terminals. The primary purposes of the Integrated Architecture is to communicate the usage and technical details of the GMT to other appropriate interested organizations and to support the certification of the Net-Ready Key Performance Parameter (NR-KPP) of the GMT program. The Integrated Architecture supports an evolutionary acquisition approach to system architecture and design. The Integrated Architecture will evolve over the life of the program and serve additional purposes after program Key Decision Points. Future uses may include support to the Planning, Programming, Budgeting and Execution (PPBE) process, training development, operational planning and analysis, and testing.
Enhanced Polar Satellite Communications System
EPS
Air Force
Serco is performing DoD Architecture Framework (DoDAF) compliant Unified Modeling Language (UML) to model an Enterprise Architecture (EA) for Air Force Space Command (AFSPC) reflecting current knowledge and projections of how EPS will be developed. The primary purposes of the EA is to communicate the usage and technical details of the EPS to other appropriate interested organizations and to support the certification of the Net Ready Key Performance Parameter (NR-KPP) of the EPS program. The EA supports an evolutionary acquisition approach to system architecture and design. The Integrated Architecture will evolve over the life of the program and serve additional purposes after program key decision points. Future uses include support to the Planning, Programming, Budgeting and Execution (PPBE) process, training development, operational planning and analysis, and testing.
European Midcourse Radar System
EMR
Air Force
Serco employs object-oriented techniques using the Unified Modeling Language (UML) to model desired EMR operational capabilities for providing track, discrimination, and hit-assessment data for the Ballistic Missile Defense European Capability to provide a defense of Europe against a limited intermediate and long range ballistic missile attack from the Middle East, and provide additional capability to the current missile defense system located in Alaska and California to defend the United States. The EA is meant to be a living representation of the EMR system throughout the development and production process, allowing for the efficient integration of new functions and new technology. The integrated views of the architecture are intended to trace requirements generation and integration, evolutionary acquisition support (system design, development and test) and operational training.
