After completing this course, students will be able to understand and apply the concept of Total Quality Management in both service and product organizations.

Upon completion of this course, students will be able to oganize the set of activities that integrate the concept of quality assurance to provide the necessary evidence that establishes an adequate level of confidence, related to the fulfillment of the objectives and the functions assigned to quality, considering ISO 14000 as well as FMEA, MSA, PPAP, APQP, and the Control Plan, all of the foregoing with an ISO TS 16949 approach.

Upon conclusion of this course, students will be able to design basic electronic circuits with op amps and apply concepts such as feedback, analogical frequency compensation, filters, and frequency response analysis. Additionally, they will become acquainted with the operation of comparators as well as with the main ASICs. They will also use computer-aided simulation for the analysis of circuits using these devices.

The aim of this course is for students to operate the basic principles and applications for the design of control systems: open loop and closed loop, optimal, discreet, adaptable bow, PID. Also, they will be able to analyze the stability of these systems by applying different techniques.

The aim of this course is for students to: (1) Schematize the evolution and impact of IT on the operation of the supply chain. (2) Analyze relevant technology platforms to enable electronic logistic processes. (3) Understand technologies to share information across the chain supply and support its integration and decision-making.

Upon completion of this course, students will be able to operate technical, technological and economic evaluations of projects in the engineering area, especially in the environment of the company, using the concepts and conventional methods applied to examples and real cases including new products or expansion of the production, risk factors, taxes, and inflation.
 

By the end of this course, students will be able to solve problems to calculate the stress and strain in mechanical elements and basic structural members, typically found in the daily practice of Engineering.

The aim of this course is for students to schematize the biomaterials used in different artificial organs, implants, and medical devices on the market, understanding their mechanical properties and tests, as well as their effects and degradation in their applications in the human body.

Upon completion of this course, students will understand the basic concepts of biomedical instrumentation and describe the principal diagnostic, monitoring, and therapeutic medical equipment.

Students will become aquainted with leading applications and successful approaches in the area of quality, as used by high-performance companies which are highly renowned for their competitiveness.