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Defence & Mobility | Lead Systems Engineer Defense| Defence Architecture | Verteidigung

Marburg (Weimar), Deutschland
Weltweit
Diplom-Ingenieur (Diploma in Precision Engineering)
Marburg (Weimar), Deutschland
Weltweit
Diplom-Ingenieur (Diploma in Precision Engineering)

Profilanlagen

Frontline Testing.pdf
Vitae Dipl.-Ing. Stefan Peil v12.pdf

Über mich

Defense systems leader commanding end-to-end lifecycles of mission/safety-critical capabilities. I translate strategy into phased roadmaps, drive NATO-interoperable MBSE development, and lead V&V in Ukrainian theatres to deliver battle-ready systems. Ensure coalition integration & mission assurance.

Skills

DefenceVerification and ValidationSystemarchitektEA SparxMBSESystems Engineering NAFV&VBattlefieldProduct Owner
  1. Command the end-to-end lifecycle of mission- and safety-critical defence systems, ensuring operational readiness and survivability.
  2. Translate strategic objectives and mission-level operational imperatives into actionable, phased product roadmaps aligned with coalition priorities.
  3. Orchestrate agile, cyber-secure, and NATO-interoperable systems development in strict accordance with multinational defence frameworks.
  4. Define, validate, and control system-level requirements and architectures to ensure combat effectiveness and coalition integration.
  5. Execute a rigorously standardized, internationally aligned Model-Based Systems Engineering (MBSE) methodology.
  6. Direct frontline system verification, validation, and evaluation for Ukrainian operational theatres, ensuring combat-proven performance and mission assurance under fire.
  7. Provide technical command and leadership to multi-disciplinary development teams to deliver high-assurance, battle-ready systems on accelerated timelines.

Website

Sprachen

DeutschMutterspracheEnglischverhandlungssicher

Projekthistorie

Development of an urban C-UAV Detection System

CONFIDENTIAL Marburg/Kyiv

Internet und Informationstechnologie

50-250 Mitarbeiter

Challenge
Design and operationalization of a rapid-response Urban Counter-UAV (C-UAV) protection system, tailored for First-Person View (FPV) and multicopper threat vectors within a 4CISR battlespace. The system is intended to enable urban force protection and crowd defence in high-density civilian-military domains under NATO operational conditions.

Contribution
Systems Engineering approach under NATO doctrine for European deployment

Operational Concept (CONOPS) Development
  1. Developed codified decision logic to prioritise target interdiction, safeguard crowd movements, and ensure corridor shielding during high-risk events.
Tactical Dimensioning & Resource Management
  1. Established terrain-informed sensor placement rules and density heuristics, based on reconnaissance surveys and threat modelling.
NATO-Compliant Service Architecture
  1. Delivered full-stack NAF artefacts, including Service Viewpoints (NSOV), Logical and Physical Architectures, Resource Specifications, and Architecture Foundation.
Legal & Safety Compliance Envelope
  1. Performed regulatory alignment checks against host-nation legal frameworks, privacy constraints, and civilian safety mandates.
Technical Baseline Verification & Validation
  1. Conducted performance validation for detection bands, sensor modes, detection rates, and operational form factors (e.g., soldier-wearable).
Delivery
Zoned threat defence plans, device & power distribution, SOPs for tactical response, Functional verification, Incident log, forensic analytics toolkit

Impementaion of Systems Engineering (MBSE) for defence drone development

ABALY Technologies

Internet und Informationstechnologie

10-50 Mitarbeiter

Challenge
Concept for the creation of an MBSE model of a reconnaissance drone

Contribution
Model-Based Systems Engineering and Simulation of a UAV
  • Development of a scalable MBSE demonstrator for a high-performance tactical reconnaissance drone optimized for ISR (Intelligence, Surveillance, Reconnaissance) in a military context.
  • Definition of the Framework Basis: DoDAF 2.0 and STANAG, SysML
     
    • Defence Architecture Framework:
      • Systems Architecture DoDAF (CV-1 – CV-6)
      • Stakeholder Requirements and Mission Requirements
      • Systems Architecture DoDAF (OV-1 – OV-6)
      • Systems Viewpoints DoDAF (SV1 – SV10)
      • Certification View STANAG-4671, MIL-STD-882 E
       
  • Definition of Verification and Validation approach
  • Elaboration of a digital twin for Life-Cycle-Management
     
    • Model area
      • Requirements model
      • Architecture model
      • Functions model
      • Behavior model
      • Communication model
      • Safety model
      • Airworthiness model
       
  • Safety System and HAZOP Analysis
  • Physical Simulation with Simulink UAV toolbox (optional)
  • Tools: SPARX EA, MATLAB Simulink
Delivery 
SysML Model of the reconnaissance drone as a template for further development and retrofit of drones

Technology and methods stack
ISO/IEC 19514 System Modelling Language (SysML)
MIL-STD-882E Defence System Safety
MIL-STD-881 Work breakdown structure for defense material items and SOW
MIL-STD-881 Integrated Master Plan and Master Schedule
STANAG 4671
FRAMEWORKS DoDAF, NAF

Software Product and Project Management, Development Life Cycle Management

MEDIVATIONZ

Pharma und Medizintechnik

< 10 Mitarbeiter

Challenge
As product manager, creating a SaMD development project plan for an APP (DiGA) to operate in the European market, ensuring compliance with MDR, GDPR, and other relevant regulatory requirements based on a further scientific study

Contribution
Creation of a MBSE model-based comprehensive project plan and describing the steps necessary for a successful European Medical Device certification according to MDR
  • Define the project scope, the ConOps operating concept, the intended use, and the clinical relevance.
  • Establish a framework for research and clinical evaluation collaboration.
  • Determine regulatory pathways and market needs.
  • Develop a preliminary risk plan for the overall project.
  • Develop a roadmap and agile development work plan that considers development partners such as app developers, AI/ML developers, clinical physicians, and cloud hosts.
  • Design the logical architecture of the software and network.
  • Determine the regulatory strategy considering MDR regulations.
  • Determine a cost breakdown and revenue generation strategy.
  • Create an interim development and milestone plan for the specific development.
    Determine system requirements stemming from the intended use.
Delivery
Presenting the Work products to clinical partners and potential investors

Zertifikate

Masterclass Prozessvalidierung

blaurock und philippeit

2023

Innovations Manager

WBS AG

2019

SCRUM Master

WBS AG

2019

PRINCE 2.0

WBS AG

2019

Bewertungen

"Stefan's expertise in system architecture, development, and requirements engineering was significant to our work. We could confidently rely on his knowledge and skills."

Lotus Tech Innovation Centre GmbH

Head of Chassis Mechatronic Systems

"Herr Walczyk, Volkswagen AG, Entwicklung Elektronischer Lenksysteme: "Die Zusammenarbeit mit Herrn Peil war sehr erfolgreich. Er hat uns im Bereich des Anforderungsmanagements unterstütz und mit seiner Hilfe sind wir gut vorangekommen. Ich kann Herrn Peil auf jeden Fall weiterempfehlen.""

Volkswagen AG

Projektmanager (Jörg Walczyk)

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