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Computational Modeling Simulation Multiphysics Jobs in Rochester, NY

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Computational Modeling Simulation Multiphysics information

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$38.5K

$99.9K

$142.1K

How much do computational modeling simulation multiphysics jobs pay per year?

As of May 30, 2026, the average yearly pay for computational modeling simulation multiphysics in Rochester, NY is $99,905.00, according to ZipRecruiter salary data. Most workers in this role earn between $77,500.00 and $127,800.00 per year, depending on experience, location, and employer.

What are the key skills and qualifications needed to thrive as a Computational Modeling Simulation Multiphysics Engineer, and why are they important?

A strong background in physics, engineering, mathematics, and computational science—typically with an advanced degree—is essential for a Computational Modeling Simulation Multiphysics Engineer. Proficiency in simulation software such as ANSYS, COMSOL Multiphysics, MATLAB, and programming languages like Python or C++ is commonly required, along with familiarity with high-performance computing environments. Analytical thinking, problem-solving skills, and effective communication set standout professionals apart in this field. These capabilities enable accurate modeling of complex physical phenomena, efficient collaboration, and successful project outcomes in research and industry settings.

What are some common challenges faced by professionals in Computational Modeling Simulation Multiphysics roles, and how can they be addressed?

One of the main challenges in Computational Modeling Simulation Multiphysics roles is managing the complexity of integrating multiple physical phenomena, such as thermal, structural, and fluid dynamics, into a single simulation. This often requires a deep understanding of both the underlying physics and the numerical methods used by simulation software. Collaborating closely with domain experts and maintaining clear communication within multidisciplinary teams can help address these challenges. Additionally, staying updated with advances in simulation tools and best practices through continuous learning is key to overcoming technical hurdles and ensuring accurate results.

What is computational modeling simulation multiphysics?

Computational modeling simulation multiphysics refers to the use of computer-based models to simulate and analyze systems that involve multiple interacting physical phenomena—such as fluid dynamics, heat transfer, electromagnetics, and structural mechanics—all at once. This approach allows researchers and engineers to predict complex real-world behavior, optimize designs, and reduce the need for expensive prototypes. Multiphysics simulations are widely used in industries like aerospace, automotive, energy, and biomedical engineering, where accurate modeling of coupled physical processes is critical.

What is the difference between Computational Modeling Simulation Multiphysics vs Computational Engineer?

AspectComputational Modeling Simulation MultiphysicsComputational Engineer
CredentialsTypically requires degrees in engineering, physics, or related fields; certifications in simulation software are commonSimilar educational background; often holds engineering degrees and software certifications
Work EnvironmentPrimarily in R&D labs, engineering firms, or manufacturing settings focusing on complex simulationsInvolved in product development, software development, or systems design in various industries
Industry UsageUsed in aerospace, automotive, energy, and manufacturing for advanced simulationsApplied across industries for designing, analyzing, and optimizing systems and products

While both roles involve computational skills and engineering principles, Computational Modeling Simulation Multiphysics specializes in complex, multi-physics simulations, whereas Computational Engineer focuses on designing and implementing computational solutions across various engineering projects.

What are popular job titles related to Computational Modeling Simulation Multiphysics jobs in Rochester, NY? For Computational Modeling Simulation Multiphysics jobs in Rochester, NY, the most frequently searched job titles are:
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What cities near Rochester, NY are hiring for Computational Modeling Simulation Multiphysics jobs? Cities near Rochester, NY with the most Computational Modeling Simulation Multiphysics job openings:
Computational Modeling Simulation Multiphysics jobs near you

Specialist, Mechanical Engineer - Dynamics Analyst (Space Optical Systems)

L3HHCM20

Rochester, NY • On-site

$75.50K - $142.50K/yr

Other

Medical, Retirement, PTO

Posted 14 days ago

Job description

Job Title: Specialist, Mechanical Engineer - Dynamics Analyst (Space Optical Systems)

Job Code: 37544

Job Location: Rochester NY

Job Schedule: 9/80 (Every other Friday off!)

Relocation: Relocation assistance is available for qualified applicants

 

Job Description: Dynamics Analyst (GN&C/ACS/Controls/LOS/Jitter)

L3Harris is seeking a highly skilled Dynamics Analyst to perform design, analysis, modeling, and testing of high-performance controls for electro-mechanical and optical-mechanical systems with focus on Attitude Control Systems, Controls, LOS/Jitter, and/or dynamic testing.  The analyst will use their experience to model, analyze and simulate dynamic systems, utilizing methodologies for a variety of dynamic systems, but with a primary focus on system-level interdisciplinary electro-mechanical optical systems. This includes, but is not limited to, actuated optical systems, high bandwidth steering mirror control, multidisciplinary system modeling and characterization, image stabilization, and closed loop state estimation.

Job responsibilities include:

  • Control Theory: Applying classical and modern control theory concepts such as stability, feedback control, and robustness. Utilizing analysis tools like Bode, Nyquist, Nichols, pole-zero plots, root-locus, and frequency-response analysis.
  • Control Systems: Conducting analysis, synthesis, development, and implementation of feedback control systems. This includes developing models as state-variable equations, transfer functions, and/or block diagrams to determine dynamic systems characteristics, and analyzing both time and frequency responses.
  • Structural Dynamics and Vibration Analysis: Performing structural dynamics and vibration analysis, including random vibration and acoustic analysis, design, measurement, and computation of multi-degree-of-freedom systems.
  • Computational Methods: Employing finite-element-based computational methods, dynamic testing methods, and modal analysis (both analytical and experimental).
  • Optical Performance Analysis: Evaluating system-level optical performance related to pointing, smear, and jitter.
  • Digital Signal Processing: Applying fundamental concepts and techniques of digital signal processing theory and its applications, including discrete-time signals, systems, and modern digital processing algorithms for both time-domain and frequency-domain methods.

Essential Functions:

  • Model control systems as part of larger system simulations for electro-mechanical and opto-mechanical hardware
  • Line-of-sight (LOS) control, attitude control, servo control, Kalman filtering
  • Algorithm development, implementation, flight software development, mission simulation, verification and validation
  • Multidisciplinary (hardware, electronics, and software) integrated system development and operation
  • Dynamic stabilization\isolation, passive vibration control, active vibration control
  • Model characterization and performance predictions\evaluations
  • Modal\Random Vibration\Acoustic\Shock model predictions, testing and correlation
  • Definition and documentation of system specifications

Qualifications:

  • Bachelor's Degree in Mechanical Engineering or other related engineering or science degree and minimum 4 years of prior relevant experience. Graduate Degree and a minimum of 2 years of prior related experience. In lieu of a degree, minimum of 8 years of prior related experience.
  • Professional experience with dynamic stabilization\isolation, passive vibration control, active vibration control.
  • 2+ years of experience using MATLAB and Simulink.
  • Professional experience with algorithm development and implementation for aerospace applications
  • Ability to obtain a U.S. TS/SCI Security Clearance

Preferred Additional Skills:

  • Active TS/SCI Clearance is preferred but not required
  • Proficient in FE modeling and analysis tools, MATLAB, Simulink, C/C++
  • Knowledge of astrodynamics principles relevant to remote sensing. Familiarity with space mission analysis and design impacts on remote sensing.
  • Familiarity with key elements of modeling the end-to-end imaging chain of remote sensing systems, with particular focus on the LOS impacts on image quality.
  • Preferred experience with real-time control implementation, and embedded C/C++ programming.

In compliance with pay transparency requirements, the salary range for this role in Colorado state, Hawaii, Illinois, Maryland, Minnesota, New York state, and Vermont is $75,500.00 - $142,500.00. This is not a guarantee of compensation or salary, as final offer amount may vary based on factors including but not limited to experience and geographic location. L3Harris also offers a variety of benefits, including health and disability insurance, 401(k) match, flexible spending accounts, EAP, education assistance, parental leave, paid time off, and company-paid holidays. The specific programs and options available to an employee may vary depending on date of hire, schedule type, and the applicability of collective bargaining agreements.

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