Physics AI
Extension Actions
Get step-by-step solutions for any physics problem using our Physics AI solver with detailed explanations.
Physics AI operates as an automated problem solver that processes physics questions through photo upload or text input. The system applies computer vision technology to recognize handwritten or printed physics problems, then generates solutions across mechanics, thermodynamics, electromagnetism, optics, and quantum physics. The tool delivers results with claimed 99.7% accuracy.
Learn Why, Not Just What
Most AI homework solvers output answers. Physics AI structures its responses differently. Each solution begins with identification of the relevant physical principles—conservation laws, field equations, thermodynamic cycles. The system then displays mathematical derivations step-by-step, showing how equations transform from initial conditions to final results.
Contextual explanations accompany each transformation (the reasoning behind choosing specific formulas, the physical meaning of intermediate steps, the conditions under which approximations hold).
This methodology-first architecture separates it from answer-delivery platforms. Students receive the logical framework. Not just numerical outputs.
Core Features
The OCR engine processes both typed equations and handwritten notation, converting images into solvable physics problems. Solutions break down into discrete steps—force diagrams for mechanics problems, circuit analysis for electromagnetism, thermodynamic process paths.
Formula explanations link mathematical expressions to their physical interpretations, covering topics from basic kinematics through advanced quantum mechanics and relativistic dynamics.
From Answer-Chaser to Problem-Solver
The platform repositions AI assistance from completion tool to learning instrument. Students initially seeking homework solutions encounter systematic problem-solving frameworks instead—the approach trains pattern recognition for physics methodology rather than answer memorization.
Repeated exposure to derivation logic and principle application theoretically builds independent analytical capability.
Use Cases
The system functions across homework verification, exam preparation, and concept reinforcement scenarios. High school students working through introductory mechanics can trace solution paths; university students tackling upper-level thermodynamics or electromagnetic theory receive detailed derivations.
Self-learners use it for guided practice without instructor access.