Engineering: Career and Education Opportunities in St. Paul, Minnesota
Engineering: Engineers design and often construct new devices and technologies. Working is a variety of areas, including aerospace, automotive and biomedical, they are the drivers of new inventions and innovations.
St. Paul is located in Ramsey County, Minnesota. It has a population of over 279,590, which has shrunk by 2.6% in the past ten years. The cost of living index in St. Paul, 99, is near the national average. New single-family homes in St. Paul are valued at $213,300 on average, which is well below the state average. In 2008, thirty new homes were built in St. Paul, down from seventy-four the previous year.
The three most popular industries for women in St. Paul are educational services, health care, and finance and insurance. For men, it is educational services, professional, scientific, and technical services, and construction. The average commute to work is about 21 minutes. More than 32.0% of St. Paul residents have a bachelor's degree, which is higher than the state average. The percentage of residents with a graduate degree, 12.0%, is higher than the state average.
The unemployment rate in St. Paul is 7.4%, which is greater than Minnesota's average of 7.0%.
The percentage of St. Paul residents that are affiliated with a religious congregation, 61.3%, is more than both the national and state average. Zion Church, Convent of the Visitation and Saint Paul Cathedral are some of the churches located in St. Paul. The most prominent religious groups are the Catholic Church, the Evangelical Lutheran Church in America and the Baptist General Conference.
St. Paul is home to the Saint Paul Orphange and the Wilder Center as well as Terrace Park and East View Playground.
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CAREERS WITHIN: Engineering
Aerodynamics Engineers perform a variety of engineering work in designing, constructing, and testing aircraft, missiles, and spacecraft. Aerodynamics Engineers need to evaluate the effectiveness of systems in order to improve their performance. They also need to evaluate and judge the efficacy of solutions.
Agricultural Engineers apply knowledge of engineering technology and biological science to agricultural problems concerned with power and machinery, electrification, structures, soil and water conservation, and processing of agricultural products. Agricultural Engineers need to use core mathematical skills in problem solving. They also need to read and understand what has been read.
Biomedical Engineers apply knowledge of engineering, biology, and biomechanical principles to the design, development, and evaluation of biological and health systems and products, such as artificial organs, prostheses, instrumentation, medical information systems, and health management and care delivery systems. Biomedical Engineers need to read and understand what has been read. They also need to use core mathematical skills in problem solving.
Chemical Engineers design chemical plant equipment and devise processes for manufacturing chemicals and products, such as gasoline, synthetic rubber, and pulp, by applying principles and technology of chemistry, physics, and engineering. Chemical Engineers need to understand and use core scientific concepts. They also need to read and understand what has been read.
Civil Engineers perform engineering duties in planning, designing, and overseeing construction and maintenance of building structures, and facilities, such as roads, railroads, airports, bridges, harbors, channels, dams, irrigation projects, pipelines, power plants, water and sewage systems, and waste disposal units. Civil Engineers need to read and understand what has been read. They also need to use core mathematical skills in problem solving.
Computer Engineers research, design, and test computer or computer-related equipment for commercial, industrial, or scientific use. Computer Engineers need to read and understand what has been read. They also need to evaluate and judge the efficacy of solutions.
Electrical Engineers design, develop, or supervise the manufacturing and installation of electrical equipment, components, or systems for commercial, industrial, or scientific use. Electrical Engineers need to diagnose equipment problems and failures. They also need to read and understand what has been read.
Electronics Engineers research, design, and test electronic components and systems for commercial, industrial, or scientific use utilizing knowledge of electronic theory and materials properties. Electronics Engineers need to read and understand what has been read. They also need to diagnose equipment problems and failures.
Industrial Engineers design, develop, and evaluate integrated systems for managing industrial production processes including human work factors, quality control, inventory control, logistics and material flow, cost analysis, and production coordination. Industrial Engineers need to determine which tools and techniques should be applied to solve a problem or deal with a situation. They also need to read and understand what has been read.
Manufacturing Engineers apply knowledge of materials and engineering theory and methods to design, integrate, and improve manufacturing systems or related processes.
Materials Engineers evaluate materials and develop machinery and processes to manufacture materials for use in products that must meet specialized design and performance specifications. Materials Engineers need to read and understand what has been read. They also need to understand and use core scientific concepts.
Mechanical Engineers perform engineering duties in planning and designing tools, engines, and other mechanically functioning equipment. Mechanical Engineers need to identify when problems are more complex then expected and deal with them appropriately. They also need to respond to the actions of other and coordinate activities with them.