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Physics Software Engineer Jobs in Spring, TX (NOW HIRING)

Collaborate with electrical, mechanical, and software engineers on equipment design, manufacturing ... Bachelor's degree or higher in Physics, Engineering, Mathematics (with specialization in ultrasound ...

Collaborate with electrical, mechanical, and software engineers on equipment design, manufacturing ... Bachelor's degree or higher in Physics, Engineering, Mathematics (with specialization in ultrasound ...

Collaborate with electrical, mechanical, and software engineers on equipment design, manufacturing ... Bachelor's degree or higher in Physics, Engineering, Mathematics (with specialization in ultrasound ...

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Physics Software Engineer information

See Spring, TX salary details

$56.5K

$131.3K

$182.9K

How much do physics software engineer jobs pay per year?

As of Jul 9, 2026, the average yearly pay for physics software engineer in Spring, TX is $131,280.00, according to ZipRecruiter salary data. Most workers in this role earn between $106,800.00 and $154,000.00 per year, depending on experience, location, and employer.

What is the difference between Physics Software Engineer vs Data Scientist?

AspectPhysics Software EngineerData Scientist
Required CredentialsBachelor's or Master's in Physics, Computer Science, or related fieldBachelor's or Master's in Data Science, Statistics, Computer Science, or related field
Work EnvironmentResearch labs, tech companies, aerospace, or defense industriesTech firms, finance, healthcare, or consulting companies
Industry UsagePhysics research, simulation, modeling, and software developmentData analysis, machine learning, predictive modeling, and data visualization

Physics Software Engineers focus on developing software for physics applications, simulations, and research, often working in research or engineering environments. Data Scientists analyze large datasets to extract insights and build predictive models. While both roles require strong programming skills, Physics Software Engineers emphasize physics principles, whereas Data Scientists focus on data analysis and statistical methods.

What are the key skills and qualifications needed to thrive as a Physics Software Engineer, and why are they important?

To thrive as a Physics Software Engineer, you need a strong background in physics, mathematics, and computer science, typically supported by a degree in physics, engineering, or a related field. Proficiency in programming languages such as C++, Python, or MATLAB, and experience with simulation software or scientific computing libraries are essential. Analytical thinking, problem-solving, and effective communication are crucial soft skills for collaborating with multidisciplinary teams and interpreting complex data. These skills are vital for developing accurate, efficient software solutions that model physical systems and drive innovation in scientific and engineering projects.

What is a Physics Software Engineer?

A Physics Software Engineer is a professional who develops, maintains, and optimizes software that simulates or models physical systems and phenomena. They often work at the intersection of physics, computer science, and engineering, creating tools for scientific research, simulations, or real-time physics engines used in industries like gaming, aerospace, or research institutions. These engineers typically have a strong background in both physics and programming, enabling them to translate complex physical formulas and concepts into efficient and accurate code. Their work is crucial for advancing technology in areas such as computational physics, virtual reality, and engineering design.

How does a Physics Software Engineer typically collaborate with scientists and other engineering teams during a project?

Physics Software Engineers often work closely with physicists, data scientists, and hardware engineers to translate complex physical models into reliable software solutions. Collaboration usually involves regular meetings to clarify requirements, iterative development cycles to test and validate simulation accuracy, and ongoing feedback to refine algorithms. Effective communication and teamwork are essential, as engineers must bridge the gap between theoretical concepts and practical implementation while ensuring that software integrates smoothly with other systems. This collaborative environment fosters continuous learning and problem-solving, making the role both challenging and rewarding.
What are popular job titles related to Physics Software Engineer jobs in Spring, TX? For Physics Software Engineer jobs in Spring, TX, the most frequently searched job titles are:
What job categories do people searching Physics Software Engineer jobs in Spring, TX look for? The top searched job categories for Physics Software Engineer jobs in Spring, TX are:
What cities near Spring, TX are hiring for Physics Software Engineer jobs? Cities near Spring, TX with the most Physics Software Engineer job openings:
Assistant Professor, Clinical Faculty, Imaging Physics

Assistant Professor, Clinical Faculty, Imaging Physics

MD Anderson Center

Houston, TX • On-site

Full-time

Medical, Dental, Retirement, PTO

Posted 8 days ago


MD Anderson Cancer Center rating

8.4

Company rating: 8.4 out of 10

Based on 168 frontline employees who took The Breakroom Quiz

29th of 880 rated healthcare providers


Job description

Summary
This is a clinical faculty appointment at the level of Assistant Professor for a Qualified Medical Physicist (QMP) in the Department of Imaging Physics, Division of Diagnostic Imaging to provide service and expertise at Houston Area Locations (HALs). The department provides imaging physics support to the primary campus of UT MD Anderson, as well as nearby HALs, and national remote affiliate sites (Cancer Network). This position requires independent clinical and scientific effort in the physics of diagnostic imaging and nuclear medicine therapy. Technical emphasis of the position is directed towards participation in development and management of programs at HALs focused on imaging physics and nuclear medicine therapy quality assurance (including patient procedures, acquisition and post-processing protocols) as well as safety considerations for patients and staff. These activities will involve expertise in the evaluation and integration of imaging systems, continuous quality improvement and consultation in imaging protocols for diagnosis, intervention and therapy, consultations regarding patient safety, site and equipment acceptance testing, and ongoing quality control, including annual system testing. Research efforts are expected to align closely with discovery and innovation in these patient care activities. Participation in institutional and departmental graduate and post-graduate educational and training programs is also expected.
Qualifications & EXPERIENCE
  1. Ph.D. or equivalent degree in Medical Physics from a CAMPEP accredited program with either completion of a CAMPEP accredited residency or 2 year experience in clinical Diagnostic or Nuclear Medical Physics, or
  2. Ph.D. or an equivalent degree in a related field and 3 years relevant experience in clinical Diagnostic or Nuclear Medical Physics, and
  3. American Board of Radiology certification in Diagnostic or Nuclear Medical Physics or American Board of Science in Nuclear Medicine certification in Physics and Instrumentation (or eligible), and
  4. Able to obtain a Texas License in Diagnostic Medical Physics or Medical Nuclear Physics, and
  5. Eligible for Institutional Class I medical privileges.

SPECIFIC Skills
  1. Knowledge of, and clinical experience in, all aspects of imaging physics and instrumentation (radiography, fluoroscopy, mammography, DXA, interventional radiology, computed tomography, MRI, ultrasound, single-photon and PET imaging and non-imaging instruments, radionuclides and radiopharmaceuticals, internal dosimetry, radiation protection) as well as standard radiation detection/monitoring and electronic test equipment.
  2. Aptitude and experience in imaging physics research and development commensurate with the academic title sought with evidence from peer-reviewed scientific publications.
  3. Experience and programming aptitude for image processing and data analysis software tools (e.g., MATLAB, IDL, R, Python, etc.)
  4. Strong interpersonal and communication skills, both oral and written, as well as ability to work in a clinical environment independently.
    The University of Texas MD Anderson Cancer Center offers excellent benefits, including medical, dental, paid time off, retirement, tuition benefits, educational opportunities, and individual and team recognition.
    This position may be responsible for maintaining the security and integrity of critical infrastructure, as defined in Section 113.001(2) of the Texas Business and Commerce Code and therefore may require routine reviews and screening. The ability to satisfy and maintain all requirements necessary to ensure the continued security and integrity of such infrastructure is a condition of hire and continued employment.
    It is the policy of The University of Texas MD Anderson Cancer Center to provide equal employment opportunity without regard to race, color, religion, age, national origin, sex, gender, sexual orientation, gender identity/expression, disability, protected veteran status, genetic information, or any other basis protected by institutional policy or by federal, state, or local laws unless such distinction is required by law.http://www.mdanderson.org/about-us/legal-and-policy/legal-statements/eeo-affirmative-action.html

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