- Test or perform failure analysis for optomechanical or optoelectrical products, according to test plans.
Occupations with related tasks Save Table: XLSX CSV
- Conduct post-service or failure analyses, using electromechanical diagnostic principles or procedures.
- Analyze fuel cell or related test data, using statistical software.
- Plan or conduct experiments to validate new materials, optimize startup protocols, reduce conditioning time, or examine contaminant tolerance.
- Provide technical consultation or direction related to the development or production of fuel cell systems.
- Characterize component or fuel cell performances by generating operating maps, defining operating conditions, identifying design refinements, or executing durability assessments.
- Plan or implement fuel cell cost reduction or product improvement projects in collaboration with other engineers, suppliers, support personnel, or customers.
- Conduct fuel cell testing projects, using fuel cell test stations, analytical instruments, or electrochemical diagnostics, such as cyclic voltammetry or impedance spectroscopy.
- Define specifications for fuel cell materials.
- Recommend or implement changes to fuel cell system designs.
- Validate design of fuel cells, fuel cell components, or fuel cell systems.
- Read current literature, attend meetings or conferences, or talk with colleagues to stay abreast of new technology or competitive products.
- Prepare test stations, instrumentation, or data acquisition systems for use in specific tests of fuel cell components or systems.
- Develop fuel cell materials or fuel cell test equipment.
- Fabricate prototypes of fuel cell components, assemblies, stacks, or systems.
- Manage fuel cell battery hybrid system architecture, including sizing of components, such as fuel cells, energy storage units, or electric drives.
- Design or implement fuel cell testing or development programs.
- Write technical reports or proposals related to engineering projects.
- Simulate or model fuel cell, motor, or other system information, using simulation software programs.
- Design fuel cell systems, subsystems, stacks, assemblies, or components, such as electric traction motors or power electronics.
- Identify or define vehicle and system integration challenges for fuel cell vehicles.
- Calculate the efficiency or power output of a fuel cell system or process.
- Coordinate fuel cell engineering or test schedules with departments outside engineering, such as manufacturing.
- Authorize release of fuel cell parts, components, or subsystems for production.
- Evaluate the power output, system cost, or environmental impact of new hydrogen or non-hydrogen fuel cell system designs.
- Integrate electric drive subsystems with other vehicle systems to optimize performance or mitigate faults.
- Develop or evaluate systems or methods of hydrogen storage for fuel cell applications.
- Conduct post-service or failure analyses, using electromechanical diagnostic principles or procedures.
- Analyze fuel cell or related test data, using statistical software.
- Conduct failure analyses, document results, and recommend corrective actions.
- Analyze test results in relation to design or rated specifications and test objectives, and modify or adjust equipment to meet specifications.
- Assemble or disassemble complex mechanical systems.
- Interpret engineering sketches, specifications, or drawings.
- Calculate required capacities for equipment of proposed system to obtain specified performance and submit data to engineering personnel for approval.
- Review project instructions and blueprints to ascertain test specifications, procedures, and objectives, and test nature of technical problems such as redesign.
- Provide technical support to other employees regarding mechanical design, fabrication, testing, or documentation.
- Test machines, components, materials, or products to determine characteristics such as performance, strength, or response to stress.
- Draft detail drawing or sketch for drafting room completion or to request parts fabrication by machine, sheet or wood shops.
- Record test procedures and results, numerical and graphical data, and recommendations for changes in product or test methods.
- Prepare specifications, designs, or sketches for machines, components, or systems related to the generation, transmission, or use of mechanical or fluid energy.
- Read dials and meters to determine amperage, voltage, electrical output and input at specific operating temperature to analyze parts performance.
- Design molds, tools, dies, jigs, or fixtures for use in manufacturing processes.
- Review project instructions and specifications to identify, modify and plan requirements fabrication, assembly and testing.
- Design specialized or customized equipment, machines, or structures.
- Set up and conduct tests of complete units and components under operational conditions to investigate proposals for improving equipment performance.
- Assist engineers to design, develop, test, or manufacture industrial machinery, consumer products, or other equipment.
- Prepare layouts of machinery, tools, plants, or equipment.
- Prepare equipment inspection schedules, reliability schedules, work plans, or other records.
- Set up prototype and test apparatus and operate test controlling equipment to observe and record prototype test results.
- Evaluate tool drawing designs by measuring drawing dimensions and comparing with original specifications for form and function using engineering skills.
- Analyze energy requirements and distribution systems to maximize the use of intermittent or inflexible renewable energy sources, such as wind or nuclear.
- Prepare parts sketches and write work orders and purchase requests to be furnished by outside contractors.
- Estimate cost factors including labor and material for purchased and fabricated parts and costs for assembly, testing, or installing.
- Assist mechanical engineers in product testing through activities such as setting up instrumentation for automobile crash tests.
- Conduct statistical studies to analyze or compare production costs for sustainable and nonsustainable designs.
- Analyze or estimate production costs, such as labor, equipment, and plant space.
- Devise, fabricate, or assemble new or modified mechanical components for products such as industrial machinery or equipment, and measuring instruments.
- Discuss changes in design, method of manufacture and assembly, or drafting techniques and procedures with staff and coordinate corrections.
- Monitor, inspect, or test mechanical equipment.
- Conduct failure analyses, document results, and recommend corrective actions.
- Analyze test results in relation to design or rated specifications and test objectives, and modify or adjust equipment to meet specifications.
- Perform root cause analysis on wind turbine tower component failures.
- Create or maintain wind farm layouts, schematics, or other visual documentation for wind farms.
- Recommend process or infrastructure changes to improve wind turbine performance, reduce operational costs, or comply with regulations.
- Create models to optimize the layout of wind farm access roads, crane pads, crane paths, collection systems, substations, switchyards, or transmission lines.
- Provide engineering technical support to designers of prototype wind turbines.
- Investigate experimental wind turbines or wind turbine technologies for properties such as aerodynamics, production, noise, and load.
- Develop active control algorithms, electronics, software, electromechanical, or electrohydraulic systems for wind turbines.
- Develop specifications for wind technology components, such as gearboxes, blades, generators, frequency converters, or pad transformers.
- Test wind turbine components, using mechanical or electronic testing equipment.
- Oversee the work activities of wind farm consultants or subcontractors.
- Test wind turbine equipment to determine effects of stress or fatigue.
- Monitor wind farm construction to ensure compliance with regulatory standards or environmental requirements.
- Direct balance of plant (BOP) construction, generator installation, testing, commissioning, or supervisory control and data acquisition (SCADA) to ensure compliance with specifications.
- Analyze operation of wind farms or wind farm components to determine reliability, performance, and compliance with specifications.
- Design underground or overhead wind farm collector systems.
- Write reports to document wind farm collector system test results.
- Perform root cause analysis on wind turbine tower component failures.
- Analyze product failure data and laboratory test results to determine causes of problems and develop solutions.
- Design and direct the testing or control of processing procedures.
- Monitor material performance, and evaluate its deterioration.
- Conduct or supervise tests on raw materials or finished products to ensure their quality.
- Evaluate technical specifications and economic factors relating to process or product design objectives.
- Modify properties of metal alloys, using thermal and mechanical treatments.
- Determine appropriate methods for fabricating and joining materials.
- Guide technical staff in developing materials for specific uses in projected products or devices.
- Review new product plans, and make recommendations for material selection, based on design objectives such as strength, weight, heat resistance, electrical conductivity, and cost.
- Supervise the work of technologists, technicians, and other engineers and scientists.
- Plan and implement laboratory operations to develop material and fabrication procedures that meet cost, product specification, and performance standards.
- Plan and evaluate new projects, consulting with other engineers and corporate executives, as necessary.
- Supervise production and testing processes in industrial settings, such as metal refining facilities, smelting or foundry operations, or nonmetallic materials production operations.
- Solve problems in a number of engineering fields, such as mechanical, chemical, electrical, civil, nuclear, and aerospace.
- Conduct training sessions on new material products, applications, or manufacturing methods for customers and their employees.
- Perform managerial functions, such as preparing proposals and budgets, analyzing labor costs, and writing reports.
- Present technical information at conferences.
- Replicate the characteristics of materials and their components, using computers.
- Design processing plants and equipment.
- Write for technical magazines, journals, and trade association publications.
- Teach in colleges and universities.
- Analyze product failure data and laboratory test results to determine causes of problems and develop solutions.
- Perform failure, variation, or root cause analyses.
- Conduct or direct system-level automotive testing.
- Provide technical direction to other engineers or engineering support personnel.
- Calibrate vehicle systems, including control algorithms or other software systems.
- Design or analyze automobile systems in areas such as aerodynamics, alternate fuels, ergonomics, hybrid power, brakes, transmissions, steering, calibration, safety, or diagnostics.
- Prepare or present technical or project status reports.
- Conduct research studies to develop new concepts in the field of automotive engineering.
- Establish production or quality control standards.
- Alter or modify designs to obtain specified functional or operational performance.
- Research or implement green automotive technologies involving alternative fuels, electric or hybrid cars, or lighter or more fuel-efficient vehicles.
- Develop calibration methodologies, test methodologies, or tools.
- Create design alternatives for vehicle components, such as camless or dual-clutch engines or alternative air-conditioning systems, to increase fuel efficiency.
- Develop or implement operating methods or procedures.
- Develop engineering specifications or cost estimates for automotive design concepts.
- Conduct automotive design reviews.
- Design vehicles that use lighter materials, such as aluminum, magnesium alloy, or plastic, to improve fuel efficiency.
- Write, review, or maintain engineering documentation.
- Develop specifications for vehicles powered by alternative fuels or alternative power methods.
- Build models for algorithm or control feature verification testing.
- Coordinate production activities with other functional units, such as procurement, maintenance, or quality control.
- Design control systems or algorithms for purposes such as automotive energy management, emissions management, or increased operational safety or performance.
- Develop or integrate control feature requirements.
- Research computerized automotive applications, such as telemetrics, intelligent transportation systems, artificial intelligence, or automatic control.
- Read current literature, attend meetings or conferences, or talk with colleagues to stay abreast of new automotive technology or competitive products.
- Design vehicles for increased recyclability or use of natural, renewable, or recycled materials in vehicle construction.
- Perform failure, variation, or root cause analyses.
- Participate in out-of-specification and failure investigations and recommend corrective actions.
- Conduct routine and non-routine analyses of in-process materials, raw materials, environmental samples, finished goods, or stability samples.
- Interpret test results, compare them to established specifications and control limits, and make recommendations on appropriateness of data for release.
- Calibrate, validate, or maintain laboratory equipment.
- Ensure that lab cleanliness and safety standards are maintained.
- Perform visual inspections of finished products.
- Complete documentation needed to support testing procedures, including data capture forms, equipment logbooks, or inventory forms.
- Compile laboratory test data and perform appropriate analyses.
- Identify and troubleshoot equipment problems.
- Write technical reports or documentation, such as deviation reports, testing protocols, and trend analyses.
- Investigate or report questionable test results.
- Monitor testing procedures to ensure that all tests are performed according to established item specifications, standard test methods, or protocols.
- Identify quality problems and recommend solutions.
- Receive and inspect raw materials.
- Train other analysts to perform laboratory procedures and assays.
- Supply quality control data necessary for regulatory submissions.
- Serve as a technical liaison between quality control and other departments, vendors, or contractors.
- Write or revise standard quality control operating procedures.
- Participate in internal assessments and audits as required.
- Perform validations or transfers of analytical methods in accordance with applicable policies or guidelines.
- Evaluate analytical methods and procedures to determine how they might be improved.
- Prepare or review required method transfer documentation including technical transfer protocols or reports.
- Review data from contract laboratories to ensure accuracy and regulatory compliance.
- Develop and qualify new testing methods.
- Coordinate testing with contract laboratories and vendors.
- Evaluate new technologies and methods to make recommendations regarding their use.
- Participate in out-of-specification and failure investigations and recommend corrective actions.
- Conduct analyses addressing issues such as failure, reliability, or yield improvement.
- Create schematics and physical layouts of integrated microelectromechanical systems (MEMS) components or packaged assemblies consistent with process, functional, or package constraints.
- Investigate characteristics such as cost, performance, or process capability of potential microelectromechanical systems (MEMS) device designs, using simulation or modeling software.
- Create or maintain formal engineering documents, such as schematics, bills of materials, components or materials specifications, or packaging requirements.
- Plan or schedule engineering research or development projects involving microelectromechanical systems (MEMS) technology.
- Propose product designs involving microelectromechanical systems (MEMS) technology, considering market data or customer requirements.
- Develop formal documentation for microelectromechanical systems (MEMS) devices, including quality assurance guidance, quality control protocols, process control checklists, data collection, or reporting.
- Communicate operating characteristics or performance experience to other engineers or designers for training or new product development purposes.
- Evaluate materials, fabrication methods, joining methods, surface treatments, or packaging to ensure acceptable processing, performance, cost, sustainability, or availability.
- Refine final microelectromechanical systems (MEMS) design to optimize design for target dimensions, physical tolerances, or processing constraints.
- Conduct harsh environmental testing, accelerated aging, device characterization, or field trials to validate devices, using inspection tools, testing protocols, peripheral instrumentation, or modeling and simulation software.
- Develop or file intellectual property and patent disclosure or application documents related to microelectromechanical systems (MEMS) devices, products, or systems.
- Conduct or oversee the conduct of prototype development or microfabrication activities to ensure compliance to specifications and promote effective production processes.
- Conduct experimental or virtual studies to investigate characteristics and processing principles of potential microelectromechanical systems (MEMS) technology.
- Devise microelectromechanical systems (MEMS) production methods, such as integrated circuit fabrication, lithographic electroform modeling, or micromachining.
- Develop or validate specialized materials characterization procedures, such as thermal withstand, fatigue, notch sensitivity, abrasion, or hardness tests.
- Validate fabrication processes for microelectromechanical systems (MEMS), using statistical process control implementation, virtual process simulations, data mining, or life testing.
- Demonstrate miniaturized systems that contain components, such as microsensors, microactuators, or integrated electronic circuits, fabricated on silicon or silicon carbide wafers.
- Manage new product introduction projects to ensure effective deployment of microelectromechanical systems (MEMS) devices or applications.
- Conduct acceptance tests, vendor-qualification protocols, surveys, audits, corrective-action reviews, or performance monitoring of incoming materials or components to ensure conformance to specifications.
- Develop or implement microelectromechanical systems (MEMS) processing tools, fixtures, gages, dies, molds, or trays.
- Develop customer documentation, such as performance specifications, training manuals, or operating instructions.
- Identify, procure, or develop test equipment, instrumentation, or facilities for characterization of microelectromechanical systems (MEMS) applications.
- Develop or validate product-specific test protocols, acceptance thresholds, or inspection tools for quality control testing or performance measurement.
- Oversee operation of microelectromechanical systems (MEMS) fabrication or assembly equipment, such as handling, singulation, assembly, wire-bonding, soldering, or package sealing.
- Consider environmental issues when proposing product designs involving microelectromechanical systems (MEMS) technology.
- Design or develop energy products using nanomaterials or nanoprocesses, such as micro-nano machining.
- Design or develop industrial air quality microsystems, such as carbon dioxide fixing devices.
- Design or develop sensors to reduce the energy or resource requirements to operate appliances, such as washing machines or dishwashing machines.
- Design sensors or switches that require little or no power to operate for environmental monitoring or industrial metering applications.
- Research or develop emerging microelectromechanical (MEMS) systems to convert nontraditional energy sources into power, such as ambient energy harvesters that convert environmental vibrations into usable energy.
- Conduct analyses addressing issues such as failure, reliability, or yield improvement.