Will “Aerospace Stress Engineer” be Replaced By Robots? 🤔

1.7% Chance of Automation

“Aerospace Stress Engineer” will not be replaced by robots.

This job is ranked #79 out of #702. A higher ranking (i.e., a lower number) means the job is less likely to be replaced.

Care to share? Click for Facebook, Twitter, LinkedIn, or XING. 👍

Job Description

Perform engineering duties in designing, constructing, and testing aircraft, missiles, and spacecraft. May conduct basic and applied research to evaluate adaptability of materials and equipment to aircraft design and manufacture. May recommend improvements in testing equipment and techniques.

Job Details

The SOC (Standard Occupational Classification) code is 17-2011.00
The Mean Annual Wage in the U.S. is $ 112,010.00
The Mean Hourly Wage is $ 53.00
Currently, there are 68,510 people on this job

☝️ Information based on the reference occupation “Aerospace Engineers”.

Also Known As…

Tasks for “Aerospace Stress Engineer”

Maintain records of performance reports for future reference.
Plan or conduct experimental, environmental, operational, or stress tests on models or prototypes of aircraft or aerospace systems or equipment.
Formulate conceptual design of aeronautical or aerospace products or systems to meet customer requirements or conform to environmental regulations.
Direct or coordinate activities of engineering or technical personnel involved in designing, fabricating, modifying, or testing of aircraft or aerospace products.
Plan or coordinate activities concerned with investigating and resolving customers' reports of technical problems with aircraft or aerospace vehicles.
Research new materials to determine quality or conformance to environmental standards.
Write technical reports or other documentation, such as handbooks or bulletins, for use by engineering staff, management, or customers.
Analyze project requests, proposals, or engineering data to determine feasibility, productibility, cost, or production time of aerospace or aeronautical products.
Evaluate product data or design from inspections or reports for conformance to engineering principles, customer requirements, environmental regulations, or quality standards.
Design or engineer filtration systems that reduce harmful emissions.
Review aerospace engineering designs to determine how to reduce negative environmental impacts.
Design new or modify existing aerospace systems to reduce polluting emissions, such as nitrogen oxide, carbon monoxide, or smoke emissions.
Formulate mathematical models or other methods of computer analysis to develop, evaluate, or modify design, according to customer engineering requirements.
Evaluate and approve selection of vendors by studying past performance or new advertisements.
Develop design criteria for aeronautical or aerospace products or systems, including testing methods, production costs, quality standards, environmental standards, or completion dates.
Direct aerospace research and development programs.
Diagnose performance problems by reviewing performance reports or documentation from customers or field engineers or inspecting malfunctioning or damaged products.
Evaluate biofuel performance specifications to determine feasibility for aerospace applications.

Related Technology & Tools

Digital oscilloscopes
Fatigue testing machines
Acoustic emissions systems
Load frames
Plotters
Force transducers
Spectrometers
Terminal computers
Surface grinding machines
Mainframe computers
Vibration isolation tables
Multi-axis mills
Axial flow research fans
Impinging jet apparatus
Profilometers
Computer numerical controlled CNC milling machines
Digital pressure gauges
Laboratory centrifugal pumps
Fiber optic interferometers
Electronic pressure scanners
Propellant combustion chambers
Electronic flight instrument systems EFIS
Strain gauge balances
Flight simulators
Anechoic chambers
Parallel computers
Cluster computers
Reflection polariscopes
Axial flow compressor facilities
Power microwave generators
Vacuum facilities
Viscometers
Axial flow turbines
UNIX work stations
Ultrasonic inspection equipment
Laser velocimeters
Flight management systems FMS
Impact guns
Lathes
Welders
Signal generators
Lasers
Atomic force microscopes
Centerless grinders
Laser Doppler velocimeters LDV
Digital voltmeters DVM
Push/pull dynamometers
Flow meters
Personal computers
Argon-ion lasers
Wave analyzers

Linux
Computer-aided engineering CAE software
C
Mathsoft Mathcad
Dassault Systemes CATIA
Thermal design software
TEAM Engineering FEMAP
Extensible markup language XML
Microsoft Access
IBM Rational Requisite Pro
PTC Pro/INTRALINK
Phoenix Integration ModelCenter
Wolfram Research Mathematica
Thermal Radiation Analysis System TRASYS
Microsoft Visual C++
Cullimore & Ring Technologies Thermal Desktop
Ada
ANSYS
Thermal analysis software
Alstom ESATAN
The MathWorks MATLAB
Maplesoft Maple
Microsoft PowerPoint
Computer aided manufacturing CAM software
Sun Microsystems Java
Microsoft Office
Altera Quartus II
Dassault Systemes SolidWorks
K&K Associates Thermal Analysis Kit TAK
Digital Equipment Corporation DIGITAL Fortran 90
Microsoft Excel
National Instruments LabVIEW
Network Analysis SINDA-G
Hewlett-Packard HP OpenVMS
UNIX
IBM Rational DOORS
UGS Solid Edge
Analytical Graphics STK Expert Edition
MSC Software Fatigue
Thermal Synthesizer System TSS
Universal Technical Systems TK Solver
Data acquisition systems
IBM Rational ClearCase
Collier Research HyperSizer
The MathWorks Simulink
MSC Software Patran
Xilinx TMRTool
IBM Rational ClearQuest
Practical extraction and reporting language Perl
MSC Software Nastran
Alstom ESARAD
Fatigue analysis software
Cullimore & Ring Technologies SINDA/FLUINT
Image processing systems
Flexible dynamics modeling software
Microsoft Visual Basic
PTC Creo Parametric
Computational fluid dynamics CFD software
Stress analysis software
Autodesk AutoCAD
Microsoft Project
Grid generation software
Microsoft Word
Python
Finite element method FEM software
Southwest Research Institute NASGRO
Verilog
Harvard Thermal TAS
ESI Group AutoSEA2
Tecplot Focus