Data Center Engineering Certificate

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The curriculum required for the Undergraduate Data Center Engineering Certificate prepares students to deal with the specific needs and challenges of the complex environments of modern data centers in government, industry, and academia. In particular, the program provides students with skills associated with facility planning, decision making supporting operations management, infrastructure design, and resource management for (large scale) data centers.

To earn a certificate students take 27 credit hours involving areas such as Computer Science, Electrical Engineering, and Mechanical Engineering. Students will choose two classes from each area plus management and capstone class on best practices in data center operations (new class). This program is designed to provide students with the broad foundational preparation needed for managing operations in modern data centers. This interdisciplinary combination of classes addresses the specific needs of this industry sector for a skilled workforce with knowledge in power and thermal engineering, computer science, general management, and best practices for managing large scale facilities.

Following the course outline, participating students will continue to connect with other students and professionals in this field, which will require students to develop individually and in small groups, understand and identify engineering knowledge leading them to a thorough understanding of the principles of large-scale data center management.

In addition to the capstone course, the program requires students to develop and deliver skills in the Computer Science, Electrical Engineering, Mechanical Engineering and Management fields. These are courses designed to promote this new knowledge at the proper beginning level needed for this certificate.

 

Program Curriculum

The central component of the Data Center Engineering program is a certificate that involves 8 classes in Computer Science, Electrical Engineering, Mechanical Engineering, and Management (two in each area). These classes are organized as follows:


General requirements:

OIS 5670 – Managing Service Operations (prerequisites waved):

3 credits
Service companies constitute the largest and fastest-growing segment of the economies of the United States and many other countries. To successfully compete in this emerging service economy, it is critical for business managers to understand the managerial issues and problems unique to designing, producing, marketing and delivering services. This course aims to develop a better understanding of best practices in the service sector through analysis of leading-edge firms and the strategies they have employed to create and maintain competitive advantage. Topics include the design and delivery of breakthrough services, managing the service encounter, and the role of technology, in particular information technology, in changing the nature of the service delivered and/or the way in which the service is delivered. The course relies on the analysis of a number of case studies, and includes a project where the principles developed in the course are applied to a real service organization

CS 5030 – Current Data Center Operational Practices (capstone class):

3 credits
This course will focus on the evolving design elements and the latest operational practices employed in modern, large-scale data centers for efficient management of electric power, computational and data load, and cooling. The course will include both seminars by professionals from design firms and local data centers and reports by students who have completed internships at these facilities. We will also tour several local data centers during the term and expose students to the latest green technologies adopted in Utah data centers. Enrollment is limited to those enrolled in the Data Center Engineering program with either senior or masters student standing.

 

Two classes in Mechanical Engineering (Thermal Systems and Design) (7 credits):

ME EN 3650 - Heat Transfer for non-majors (prerequisites waved)

Credits 4
Basic mechanisms of heat transfer, law of conservation of energy, conduction, convection, radiation, heat transfer with change of phase, heat exchangers.

One class chosen among the following three:

ME EN 5800 - Sustainable Energy Engineering:

Credits 3
Engineering of energy collection and production systems that satisfy long-term energy needs while minimizing damage to the earth's ecosystem. Conversion of chemical and nuclear fuels to produce work or electrical energy. Solar, wind, biomass, geothermal, co-generation and direct energy conversion. Conservation, seasonal underground energy storage, and hydrogen production technologies.

ME EN 5810 - Thermal System Design:

Credits 3
Design of steam-power plants, feed-water heater systems, pumping systems, compressor blades, turbine blades, and heat exchangers. Equation fitting and economic analysis as basis of design decisions. Optimization of thermal systems using Lagrange multipliers, search methods, dynamic programming, geometric programming, and linear programming. Probabilistic approaches to design.

ME EN 5820 - Thermal Environmental Engineering:

Credits 3
Principles of design of systems for heating and cooling of buildings. Heat-load calculations, psychometrics, thermodynamic systems, and solar-energy concepts.

 

Two classes in Computer Science (8 credits):

CS 3810 - Computer Organization:

Credit hours 4
An in-depth study of computer architecture and design, including topics such as RISC and CISC instruction set architectures, CPU organizations, pipelining, memory systems, input/output, and parallel machines. Emphasis is placed on performance measures and compilation issues

CS 4400 - Computer Systems:

Credit hours 4
Introduction to computer systems from a programmer's point of view. Machine level representations of programs, optimizing program performance, memory hierarchy, linking, exceptional control flow, measuring program performance, virtual memory, concurrent programming with threads, network programming

 

Two classes in Electrical and Computer Engineering for Power Engineering (6 credits):

ECE 2210 - Electrical and Computer Engineering for Non-majors:

3 credits
Fundamentals of electrical and computer engineering topics for non-electrical and computer engineers. Covers fundamentals of dc and ac circuit theory, active semiconductor devices (diodes, transistors, amplifiers), 60 Hz-power circuits and equipment (2 and 3 phase circuits, transformers, motors), transducers and actuators, safety considerations.

ECE 3600 - Introduction to Electric Power Engineering:

3 credits
Introduction to AC power generation, distribution, and use. Topics will include single-phase and 3-phase power, power factors and corrections, transformers, power distribution and the grid, generation plants, and some wiring and AC motors