Doctor of Philosophy (Ph.D.) Major in Engineering Management (Entering with Bachelor's Degree) Online

Advance from an engineering bachelor’s degree directly to a Ph.D. Applicable in both business and academic settings, this online program will help you lead research, innovation, and technology-driven transformation.

Apply by: 7/22/26
Start class: 8/19/26
Apply Now

Program Overview

Explore the doctorate in engineering management online program

Streamline your path to a Ph.D. in Engineering Management. Designed for students with a bachelor’s degree in engineering, this flexible online program prepares you for senior roles in manufacturing, sustainability, systems design, product development, and university settings.

The online engineering management Ph.D. curriculum includes master’s- and doctoral-level online courses in research, experimentation, analytics, data-driven decision-making, AI, machine learning, data mining, and automation. Explore computational modeling, supply chain systems, operations improvement, and engineering technology. Tailor the program more closely to your professional goals by adding business management courses. Plus, benefit from flexible block scheduling and the support of dedicated faculty to guide you through dissertation completion.

Engineering management Ph.D. research areas

Doctoral students in engineering management engage in advanced, interdisciplinary research focused on optimizing systems, processes, and innovation across engineering-driven organizations. Areas of study include:

  • Data-Driven Decision-Making & Analytics: Apply data science and analytics to improve engineering and operational performance
  • Experimental Design & Engineering Research Methods: Develop rigorous research frameworks to test, validate, and optimize engineering systems
  • Computational Modeling & Simulation: Use simulation and computational tools to analyze complex systems and predict outcomes
  • Artificial Intelligence & Machine Learning in Engineering: Explore AI-driven approaches to automation, optimization, and intelligent systems
  • Data Mining & Forecasting: Extract insights from large datasets to support predictive decision-making and planning
  • Advanced Manufacturing & Automation: Study smart manufacturing, robotics, and automated production systems
  • Sustainable Engineering & Industrial Ecology: Design systems that balance performance with environmental and resource considerations
  • Lean Systems & Quality Improvement: Improve efficiency and reduce waste through lean methodologies and continuous improvement
  • Supply Chain & Operations Systems: Optimize logistics, supply networks, and operations in complex engineering environments
  • Product Design & Development: Advance processes for designing, testing, and launching innovative engineering solutions
  • Engineering Leadership & Innovation Management: Examine leadership strategies and innovation practices in technical organizations
  • Technology & Information Systems Management: Manage digital infrastructure, information systems, and technology integration in engineering contexts
Engineering management Ph.D. research areas
  • Data-Driven Decision-Making & Analytics: Apply data science and analytics to improve engineering and operational performance
  • Experimental Design & Engineering Research Methods: Develop rigorous research frameworks to test, validate, and optimize engineering systems
  • Computational Modeling & Simulation: Use simulation and computational tools to analyze complex systems and predict outcomes
  • Artificial Intelligence & Machine Learning in Engineering: Explore AI-driven approaches to automation, optimization, and intelligent systems
  • Data Mining & Forecasting: Extract insights from large datasets to support predictive decision-making and planning
  • Advanced Manufacturing & Automation: Study smart manufacturing, robotics, and automated production systems
  • Sustainable Engineering & Industrial Ecology: Design systems that balance performance with environmental and resource considerations
  • Lean Systems & Quality Improvement: Improve efficiency and reduce waste through lean methodologies and continuous improvement
  • Supply Chain & Operations Systems: Optimize logistics, supply networks, and operations in complex engineering environments
  • Product Design & Development: Advance processes for designing, testing, and launching innovative engineering solutions
  • Engineering Leadership & Innovation Management: Examine leadership strategies and innovation practices in technical organizations
  • Technology & Information Systems Management: Manage digital infrastructure, information systems, and technology integration in engineering contexts

As a student in this online Ph.D. in Engineering Management program, you will learn how to:

  • Apply advanced mathematical, analytical, and computational engineering methods to solve complex technical and organizational challenges
  • Design and conduct independent, data-driven engineering research that advances technology, process innovation, or applied industrial systems
  • Develop sustainable, efficient, and scalable engineering systems, integrating Lean principles, quality systems, and environmentally conscious design
  • Integrate leadership, ethics, communication, and engineering management principles into decision-making within technical organizations
  • Synthesize undergraduate, graduate, and doctoral-level learning into a cohesive research agenda that culminates in a defended dissertation
As a student in this online Ph.D. in Engineering Management program, you will learn how to:
  • Apply advanced mathematical, analytical, and computational engineering methods to solve complex technical and organizational challenges
  • Design and conduct independent, data-driven engineering research that advances technology, process innovation, or applied industrial systems
  • Develop sustainable, efficient, and scalable engineering systems, integrating Lean principles, quality systems, and environmentally conscious design
  • Integrate leadership, ethics, communication, and engineering management principles into decision-making within technical organizations
  • Synthesize undergraduate, graduate, and doctoral-level learning into a cohesive research agenda that culminates in a defended dissertation

Also available:

We offer a variety of student-centered online degrees that can help you advance. If you’re entering with a master’s degree, learn more about our Ph.D. in Engineering Management pathway designed for advanced standing. You can also explore other Ph.D. programs in construction and engineering management.

Total Tuition $42,039*
Duration As few as 4-5 years
Credit Hours 78
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Need More Information?

Call 833.690.1245 today!

Call 833.690.1245 today!

Tuition

Affordable tuition helps you invest in your future

Tuition for the online Ph.D. degree program in engineering management is affordable and paid by the course, so you can achieve your academic goals while remaining within your budget.

View full tuition

Program Per Credit Hour Per Course Per Program
Ph.D. Engineering Management $500 $1,501 $42,039*

*Students in Accelerated Online Programs are not eligible for payment plans or emergency loans. Tuition and fees are subject to change by legislative or Board of Regents action; changes become effective on the date of enactment. BookSmart fees are automatically added each semester but are not included in program costs; students may opt out by the start of each term. Registrations after the tuition deadline require full payment at registration. Cost of Attendance details are available through TXST One Stop.

Tuition breakdown

Total Tuition $42,039*
Per Credit Hour $500

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Calendar

Mark your calendar with these important dates

The Texas State Ph.D. in Engineering Management program is delivered in a convenient online learning format that offers maximum flexibility for working adults like you. Choose the start date that fits your goals.

View Full Calendar +

TermStart DateApp DeadlineDocument DeadlineRegistration DeadlineTuition DeadlineClass End DateTerm Length
Fall 1 20268/19/267/22/267/22/268/19/268/13/2610/7/268 weeks

Now Enrolling

Apply by 7/22/26
Start Class 8/19/26

Admissions

Review the application requirements for the engineering Ph.D. program

Apply to the Ph.D. in Engineering Management online program quickly and easily with our streamlined admission process. Review the admission requirements below and take the next step toward your professional goals.

View all admission requirements

To be eligible to earn your Ph.D. in Engineering Management degree online from Texas State University, you must have the following:

  • Completed online application
  • Nonrefundable application fee of $55 ($90 for international*)
  • Baccalaureate degree in engineering, computer science, physics, technology, or a closely related field from a regionally accredited university. (Non-U.S. degrees must be equivalent to a four-year U.S. bachelor’s degree. In most cases, three-year degrees are not considered. Visit our International FAQs for more information.)
  • A copy of an official transcript from each institution where course credit was granted.
  • Minimum 3.3 GPA on any graduate course work completed
  • Statement of purpose (two pages) conveying your research interests, plans for graduate study, and professional aspirations
  • Three letters of recommendation evaluating your skill and potential in this degree program, preferably from academic sources
  • Resume/CV outlining education, work experience, scholarships/grants, publications/presentations, and other accomplishments
  • Top-ranked applicants who meet the minimum preferred credentials may be interviewed by the Ph.D. program director and other committee members via online tools such as Zoom or Microsoft Teams
  • GRE not required

For applicants without a U.S. bachelor’s degree (or equivalent)**:
You must submit an approved English proficiency exam score that meets the minimum program requirements.

  • Official TOEFL iBT scores required with a 78 overall and minimum individual module scores of
    • 19 listening
    • 19 reading
    • 19 speaking
    • 18 writing
  • Official PTE scores required with a 52 overall
  • Official IELTS (academic) scores required with a 6.5 overall and minimum individual module scores of 6.0
  • Official Duolingo scores required with a 110 overall
  • Official TOEFL Essentials scores required with an 8.5 overall

**Exemption: Applicants who have earned a bachelor’s degree or higher from a regionally accredited U.S. institution or an equivalent degree from a country on our exempt countries list are not required to submit an English proficiency exam score.

Transcripts may be sent electronically to [email protected] or mailed to:

TXST One Stop
Texas State University – Graduate Admissions
601 University Dr.
San Marcos, TX 78666

*Texas State defines an on-campus international student as anyone with a nonimmigrant visa status, including H-1B visa holders, or those seeking a visa to enroll. If you are not a U.S. citizen, permanent resident, refugee, or asylee, you will be classified as an international applicant.

An online international student is someone who holds citizenship in another country, is not a U.S. permanent resident, and resides outside the U.S. while enrolling in an online program.

Students who are not on a visa but are graduating from a Texas high school after three years in residence are considered domestic applicants.

If you are a U.S. citizen, permanent resident, refugee, or asylee, you are considered a domestic applicant.

Admission Requirements

  • Minimum 3.3 GPA on any completed graduate course work
  • No GMAT/GRE required
  • All official transcripts

Courses

Preview the engineering management curriculum

To be admitted with a bachelor’s degree and graduate from the Ph.D. in Engineering Management online degree program, you must complete a total of 78 credit hours, including 24 credit hours of master’s level core courses, 21 credit hours of doctoral-level core courses, nine credit hours of electives, and 24 credit hours of dissertation courses.

Expand All
Duration: 8 Weeks weeks
Credit Hours: 3
This course provides an overview of the new product realization process, focusing on systematic product design, including problem identification, product planning, conceptual design, and embodiment design. Standard CAD tools are employed for product modeling.
Duration: 8 Weeks weeks
Credit Hours: 3
This course covers economic analytical techniques used in engineering decision-making. Topics include time-value of money, comparing alternatives, depreciation, replacement, and income tax considerations.
Duration: 8 Weeks weeks
Credit Hours: 3
Provides the student with in-depth knowledge of inferential statistics as applied to design of robust processes and products. Topics covered include probability distributions, ANOVA, fractional factorial design, response surface method, orthogonal arrays, and Taguchi method. Prior experience with introductory-level statistics is assumed. Prerequisite: TECH 5394 with a grade "C" or better.
Duration: 8 Weeks weeks
Credit Hours: 3
This course introduces students to industrial management system concepts and applications relating to management operations, system design, implementation and management, case studies of practices, and application of theory to practical problems.
Duration: 8 Weeks weeks
Credit Hours: 3
This course, in a case-based learning environment, integrates concepts and principles of information and communication technology (ICT) including mobile communication and Internet of Things (IoT). Analysis and evaluation of advanced ICT management examples demonstrate issues and strategies of modern ICT management.
Duration: 8 Weeks weeks
Credit Hours: 3
This course covers the principles of life cycle analysis (LCA) of engineered products and processes. Topics include industrial ecology, resource depletion, product design, process design, material selection, energy efficiency, product delivery, use, and end-of-life considerations.
Duration: 8 Weeks weeks
Credit Hours: 3
This course is an in-depth study of technical problems encountered in designing, equipping, arranging, and specifying facility requirements for industrial and technical training facilities.
Duration: 8 Weeks weeks
Credit Hours: 3
This course covers fundamentals of designing industrial experiments.
Duration: 8 Weeks weeks
Credit Hours: 3
This course will provide students with the essential knowledge and practical skills to conduct rigorous and systematic applied research in the field of engineering management. Through a combination of theoretical discussions and hands-on exercises, students will gain a comprehensive understanding of the systematic research process in the context of engineering management applications. Specific topics covered are problem formulation, literature search, research methods, data analysis, data management, data privacy, statistical approaches to analyze data, technical writing, academic integrity, presenting, and publishing.
Duration: 8 Weeks weeks
Credit Hours: 3
This course will provide the students with the necessary knowledge and skills to identify and understand various types of risks faced by organizations, manage and mitigate risk, and conduct resiliency analysis based on various quantitative methods. Specific topics covered includes risk identification, response, monitoring and control through the use of good data input, and systematic approach and quantitative risk and resilience evaluation.
Duration: 8 Weeks weeks
Credit Hours: 3
This course will provide students with the knowledge and skills needed to manage and grow a sustainable business by incorporating circular economy principles and strategies. The course will use systems thinking to understand the technological, economic and policy implications of circular economy transitions. The focus of the course will be on real-world applications of sustainable management with the objective of achieving zero waste and circular outcomes in various industries.
Duration: 8 Weeks weeks
Credit Hours: 3
This course will provide the students with the knowledge and practical skills required to leverage data analytics in decision-making and problem-solving processes. Emphasis will be placed on real-world applications and use cases across various engineering management areas. The topics include data preprocessing and cleaning, exploratory data analysis, descriptive statistics for decision making, predictive modeling techniques, and supervised and unsupervised machine learning.
Duration: 8 Weeks weeks
Credit Hours: 3
This course will provide students with the essential skills and knowledge to effectively handle and quantify uncertainty in engineering projects and decision-making processes. In addition to theoretical foundations for decision-making under uncertainty, practical techniques for uncertainty analysis will be extensively covered and industrial case studies will be discussed. Specific topics covered include sources and types of uncertainties in engineering systems, uncertainty propagation, robustness analysis, uncertainty reduction, reliability analysis, and design optimization with uncertainty.
Duration: 8 Weeks weeks
Credit Hours: 3
This course is the first of a two-course series to impart business and commercialization skills by producing a business plan. Key areas covered include intellectual property law, technology transfer and licensing strategies, business plan development, business finance strategies, management structures, project management methods, statistical quality and process control.
Duration: 8 Weeks weeks
Credit Hours: 3
This course is the second of a two-course series to impart business and commercialization skills by producing a business plan. Key areas covered include intellectual property law, technology transfer and licensing strategies, business plan development, business finance strategies, management structures, project management methods, statistical quality and process control. Prerequisite: MSEC 7301 with a grade of "B" or better.

Select three courses from the following list:

Duration: 8 Weeks weeks
Credit Hours: 3
This course teaches students to plan, design and conduct experiments efficiently and effectively, and to analyze the resulting data for obtaining valid conclusions. Students use computer experiments and software tools to optimize manufacturing, energy and service operations based on both deterministic and stochastic models. Topics include full and fractional factorial designs, blocking and confounding design, regression model, response surface method and design, and robust parameter design or Taguchi method. Through the course project, students apply the optimal design methodology to improve a real manufacturing or service process.
Duration: 8 Weeks weeks
Credit Hours: 3
This course covers machine learning tools. Topics include supervised algorithms, techniques for improving model performance, evaluation techniques, and software packages for implementation. Emphasis will be placed on real-world applications across various domains particularly relevant to mechanical, manufacturing or industrial engineering (MMIE) and engineering management (EM) fields. Prerequisite: MMIE 7305 with a grade of "B" or better.
Duration: 8 Weeks weeks
Credit Hours: 3
This course focuses on concepts and techniques in unsupervised machine learning. Students will explore various algorithms and methodologies for extracting meaningful information from unlabeled data. The course covers dimensionality reduction, clustering methods, generative models, and deep unsupervised learning. Emphasis will be placed on understanding and implementation of unsupervised learning models across various domains particularly relevant to mechanical, manufacturing and industrial engineering (MMIE) and engineering management (EM) fields. Prerequisite: MMIE 7317 with a grade of "B" or better.
Duration: 8 Weeks weeks
Credit Hours: 3
This course gives students an in-depth understanding of the intersection between data science techniques and multi-objective optimization. It equips students with the knowledge and skills required to address real-world problems that involve multiple conflicting objectives by leveraging data-driven approaches and optimization techniques. This course assumes a prerequisite solid understanding of data analysis, programming, and optimization concepts. Prerequisite: MMIE 7317 with a grade of "B"or better.
Duration: 8 Weeks weeks
Credit Hours: 3
This course is designed to take a broad look at Sustainability from both Ecological and Organizational perspective.
Duration: 8 Weeks weeks
Credit Hours: 3
This course teaches students to design and operate carbon neutral and zero-energy manufacturing, transportation, and service infrastructure through the integration of renewable energy. Students use statistics and probability theory, design of experiments, discrete event and agent-based simulation, and stochastic optimization to solve large scale, multi-layer manufacturing supply chain design and operation problems. Through the semester-long team project, students make both strategic and operational decisions on production, warehousing, transportation, and microgrid generation in the nexus of manufacturing, energy and climate.
Duration: 8 Weeks weeks
Credit Hours: 3
This course focuses on organizational behavior and structure as influenced by environmental variables and system relationships. Topics include personality, motivation, teams, and leadership. These key concepts and others such as perception, emotions, and culture act interdependently, are influenced by, and in turn influence the environment in which the system operates.
Duration: 8 Weeks weeks
Credit Hours: 3
This course includes planning, budgeting, identification of risks and risk mitigation approaches, resource allocation, review of milestones and schedules, and evaluating projects to measure success. Responsibilities of project managers in the areas of problem solving, motivating and managing creative technical staff in project and matrix organizations will be included.
Duration: 8 Weeks weeks
Credit Hours: 3
This course covers the basic principles of life cycle analysis (LCA) of engineered products, materials, and processes. Topics covered include: biological ecology, industrial ecology, resource depletion, product design, process design, material selection, energy efficiency, product delivery, use, end of life and LCA.
Duration: 8 Weeks weeks
Credit Hours: 3
This course is a small group seminar that focuses on analytic strategies specific to the doctoral student’s dissertation topic. Examples include structural equation modeling, hierarchical linear modeling, log linear modeling, non-parametric analyses, factor analysis, factorial analysis of variance, and other multivariate statistical methods. Prerequisites: ED 7351 and ED 7353, all with a grade of "B" or better.
Duration: 8 Weeks weeks
Credit Hours: 3
This course examines the measurement and analysis of corporate operations through an integrated strategic lens. Students apply advanced systems theory, organizational design, and financial and operational frameworks to evaluate and optimize corporate policies. Emphasis is placed on quantitative analysis, risk management, ESG integration, and governance structures. Through engagement with academic and practitioner research, students assess policy impacts on firm value, behavior, and performance, and ultimately develop data-driven, innovative strategies and original research proposals for sustainable growth.
Duration: 8 Weeks weeks
Credit Hours: 3
This course focuses on the methods and applications of survey, quasi-experimental, and experimental research by designing and testing models as appropriate. Topics include construct development, latent variables (formative and reflective), non-latent variables, hypotheses development, different types of research design (e.g. completely randomized design, Latin square design, factorial design), design with covariates, confounding, blocking, power analysis, random effects/mixed effects models, statistical techniques for analyzing data, interpreting results and ethical considerations including the role of IRB approval on different types of research.
Duration: 8 Weeks weeks
Credit Hours: 3
This course provides a rigorous foundation for managing an enterprise that operates in a global economy. It integrates global economic issues and global strategic issues to provide a comprehensive understanding of macroeconomic concepts and models for analyzing the global environment in which managers of the multi-national enterprises need to make business decisions and develop strategies for diversification, vertical integration, global expansions, etc. The role of technology, supply chain, and government policies in affecting the economic and business conditions will be assessed.
Duration: 8 Weeks weeks
Credit Hours: 1
Original research and writing in Materials Science, Engineering, and Commercialization, is to be accomplished under direct supervision of the PhD Research Advisor. While conducting dissertation research and writing, students must be continuously enrolled each long semester. Repeatable for credit.
Duration: 8 Weeks weeks
Credit Hours: 2
Original research and writing in Materials Science, Engineering, and Commercialization, is to be accomplished under direct supervision of the PhD Research Advisor. While conducting dissertation research and writing, students must be continuously enrolled each long semester. Repeatable for credit.
Duration: 8 Weeks weeks
Credit Hours: 3
Original research and writing in Materials Science, Engineering, and Commercialization, is to be accomplished under direct supervision of the PhD Research Advisor. While conducting dissertation research and writing, students must be continuously enrolled each long semester. Repeatable for credit.
Duration: 8 Weeks weeks
Credit Hours: 5
Original research and writing in Materials Science, Engineering, and Commercialization, is to be accomplished under direct supervision of the PhD Research Advisor. While conducting dissertation research and writing, students must be continuously enrolled each long semester. Repeatable for credit.
Duration: 8 Weeks weeks
Credit Hours: 8
Original research and writing in Materials Science, Engineering, and Commercialization, is to be accomplished under direct supervision of the PhD Research Advisor. While conducting dissertation research and writing, students must be continuously enrolled each long semester.
Duration: 8 Weeks weeks
Credit Hours: 9
Original research and writing in Materials Science, Engineering, and Commercialization, is to be accomplished under direct supervision of the PhD Research Advisor. While conducting dissertation research and writing, students must be continuously enrolled each long semester. Repeatable for credit.

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