Academic Foundation & Technical Formation

From Physics to Computer Systems and Intelligent Infrastructure

My education combines a foundation in physics, mathematics, scientific modeling, computer science, cybersecurity, machine learning, and high-performance computing. That progression now supports my doctoral research and my deliberate path toward compiler, runtime, performance, and dependable systems engineering.

Physics Computer Science Machine Learning Cybersecurity High-Performance Computing Systems Engineering

Formal Education

Each stage strengthened a different layer of my technical development—from mathematical reasoning and scientific modeling to applied computing, doctoral research, and deeper systems work.

In Progress

Ph.D. in Computer Science

University of North Dakota

August 2025 – Present Grand Forks, North Dakota, United States

Doctoral research focused on probabilistic and generative modeling for cybersecurity, with emphasis on synthetic malware data, trustworthy evaluation, reproducible experimentation, and high-performance research workflows.

  • Developing GenCyberSynth, a framework for training, sampling, evaluating, comparing, and auditing synthetic cybersecurity-data generators.
  • Studying GANs, VAEs, diffusion models, autoregressive methods, and probabilistic baselines across controlled data-generation budgets.
  • Evaluating generated data through image-quality metrics, diversity measures, downstream classification utility, class-level performance, and reproducible experiment protocols.
  • Building artifact-backed workflows with fixed seeds, manifests, automated aggregation, reports, and high-performance computing infrastructure.
  • Connecting research rigor with systems-oriented concerns such as reproducibility, performance, reliability, automation, and dependable technical infrastructure.
Generative Models Cybersecurity ML Synthetic Data HPC Reproducibility Trustworthy Evaluation
Completed

M.S. in Computer Science

University of North Dakota

August 2023 – May 2025 Grand Forks, North Dakota, United States

Graduate study centered on machine learning, artificial intelligence, cybersecurity, data engineering, secure applications, predictive modeling, and the construction of end-to-end computing systems.

  • Developed practical experience in Python, SQL, APIs, machine-learning workflows, data pipelines, experiment design, and secure software concepts.
  • Studied machine learning, cloud security, application-layer security, ethical hacking, computer forensics, predictive modeling, and high-performance computing.
  • Built applied projects involving secure platforms, machine-learning services, educational technology, language-focused AI, and full-stack application design.
  • Established the computer-science foundation that enabled the transition into doctoral cybersecurity research and increasingly deep systems programming.
Machine Learning Artificial Intelligence Cybersecurity Data Engineering APIs Applied Software
Completed

B.S. in Physics

The University of Bamenda

October 2017 – August 2020 Bamenda, Cameroon

A quantitative scientific foundation in physics, mathematics, experimentation, modeling, and analytical problem solving that now supports my work in computer science, machine learning, research, and systems engineering.

  • Developed first-principles reasoning through physical modeling, mathematical analysis, laboratory work, and interpretation of experimental evidence.
  • Built a foundation in calculus, algebra, probability, statistics, quantitative reasoning, and scientific problem solving.
  • Learned to connect abstract models with observable behavior, test assumptions against evidence, and reason carefully about complex systems.
  • Established the analytical discipline that now supports machine-learning evaluation, performance reasoning, computer architecture, and low-level systems study.
Physics Mathematics Scientific Modeling Laboratory Analysis Quantitative Reasoning

Selected Graduate Coursework

Coursework most relevant to my doctoral research, systems foundation, security expertise, mathematical reasoning, and long-term compiler/runtime direction.

Machine Learning & Data

  • CSCI 543 Machine Learning
  • DATA 532 Applied Machine Learning
  • DATA 530 Artificial Intelligence
  • DATA 527 Predictive Modeling
  • DATA 540 Data Visualization

Cybersecurity

  • CSCI 587 Ethical Hacking
  • CSCI 551 Security for Cloud Computing
  • CSCI 589 Application Layer Security
  • CSCI 557 Computer Forensics

Computing & Research

  • CSCI 532 High Performance Computing & Paradigms
  • CSCI 999 Dissertation Research
  • EECS 500 Graduate Seminar

Mathematics Foundation

  • MATH 442 Linear Algebra
  • Mathematics Calculus
  • Mathematics Algebra
  • Mathematics Probability & Statistics

How My Education Supports My Direction

The degrees are not isolated credentials. Each contributes a specific layer to the engineer and researcher I am becoming.

01

Physics Built First-Principles Reasoning

Physics trained me to reason from models, identify assumptions, work quantitatively, interpret evidence, and connect abstract theory to observable system behavior.

Analytical foundation
02

Computer Science Built Implementation Capability

Graduate computer-science study added programming, algorithms, data, APIs, machine learning, software architecture, cybersecurity, and applied system construction.

Computing foundation
03

Doctoral Research Builds Technical Rigor

The Ph.D. strengthens experiment design, reproducibility, probabilistic reasoning, evaluation, research communication, infrastructure, and evidence-backed technical decision making.

Research depth
04

Systems Work Converts Theory into Machinery

My continuing C and C++ work translates mathematical and computational understanding into memory-aware, testable, performance-conscious software and future runtime systems.

Engineering direction

Current Academic Focus

My current work connects probabilistic modeling, cybersecurity, reproducible experimentation, high-performance computing, and systems-oriented implementation.

Doctoral Priorities

The research program is organized around both scientific questions and the infrastructure required to answer them reliably.

01

Generative Cybersecurity Models

Comparing probabilistic and deep generative approaches for synthetic malware-image generation.

02

Trustworthy Evaluation

Measuring quality, diversity, utility, class-level behavior, uncertainty, and failure modes.

03

Reproducible Infrastructure

Preserving seeds, manifests, configurations, artifacts, reports, environments, and experiment history.

04

Systems and Performance Depth

Strengthening C, C++, memory, operating systems, concurrency, architecture, and performance reasoning.

Research-to-Systems Progression

The long-term objective is to combine scientific rigor with increasingly deep systems implementation.

Scientific Question

Define hypotheses, controls, measurements, and evidence

Model & Experiment

Train, sample, evaluate, compare, and audit

Reliable Infrastructure

Automate pipelines, testing, artifacts, and reports

Compiler & Runtime Systems

Build execution, optimization, and dependable runtime machinery

Learning Philosophy

Formal education provides structure, but mastery requires implementation, testing, explanation, reflection, and sustained technical practice.

01

Learn from First Principles

Understand the underlying mathematical, computational, and machine-level mechanism before depending on abstractions.

02

Convert Theory into Implementations

Reinforce concepts through working programs, reusable modules, experiments, libraries, tools, and carefully designed systems.

03

Validate with Evidence

Use tests, measurements, controlled experiments, diagnostics, and reproducible workflows rather than intuition alone.

04

Build Mastery Progressively

Develop strong foundations in sequence and allow advanced specialization to emerge from demonstrated technical depth.

My compiler and runtime direction is a long-term specialization supported by ongoing systems study and implementation. It is presented as a deliberate trajectory rather than a claim that the specialization is already complete.

Building Reliable Systems from Scientific Foundations

Physics established the analytical foundation, computer science added implementation capability, doctoral research deepens experimental rigor, and systems programming is building the path toward compiler, runtime, and performance engineering.