AP® Physics C: Mechanics Score Calculator 2026

Last Updated: September 29, 2025 | By the LearnQ.ai Team

Estimate Your AP® Physics C - Mechanics Scores Instantly with LearnQ.ai

Are you curious about how your AP® Physics C: Mechanics score is determined? Utilize our interactive AP® Physics C: Mechanics Score Calculator to get an instant estimate of your score! Simply input your scores or adjust the sliders for each section, and receive your predicted AP® score ranging from 1 to 5 immediately.

How Are You Projecting the Scoring Curve? Currently, the College Board has not released an official scoring worksheet that incorporates the latest updates to AP® Physics C: Mechanics. To develop our projected curve, we have analyzed the relative percentages of the Multiple-Choice Questions (MCQs) and Free-Response Questions (FRQs), along with the point values of each question based on the 2019-2020 scoring guidelines.

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Understanding AP® Physics C: Mechanics

AP® Physics C: Mechanics is a rigorous, calculus-based course offered by the College Board as part of the Advanced Placement (AP) program. This course is designed for students with a strong foundation in physics and calculus, providing an in-depth understanding of mechanics principles. It is ideal for those pursuing careers in engineering, physics, and other STEM fields.

AP® Physics C: Mechanics Curriculum Overview

The AP® Physics C: Mechanics curriculum is divided into several key topics, each focusing on both theoretical knowledge and practical application:

1. Kinematics

Motion in One and Two Dimensions: Understanding displacement, velocity, acceleration, and the graphical representation of motion.
Projectile Motion: Analyzing the motion of objects under the influence of gravity.

Motion in One and Two Dimensions: Understanding displacement, velocity, acceleration, and the graphical representation of motion.
Projectile Motion: Analyzing the motion of objects under the influence of gravity.

2. Newton’s Laws of Motion

First Law (Inertia): Exploring the relationship between force and motion.
Second Law (F=ma): Understanding the connection between force, mass, and acceleration.
Third Law (Action and Reaction): Analyzing the interactions between objects.

First Law (Inertia): Exploring the relationship between force and motion.
Second Law (F=ma): Understanding the connection between force, mass, and acceleration.
Third Law (Action and Reaction): Analyzing the interactions between objects.

3. Work, Energy, and Power

Work and Kinetic Energy: Calculating work done by forces and the conversion between work and kinetic energy.
Potential Energy and Conservation of Energy: Understanding potential energy in various systems and applying energy conservation principles.
Power: Analyzing the rate at which work is done.

Work and Kinetic Energy: Calculating work done by forces and the conversion between work and kinetic energy.
Potential Energy and Conservation of Energy: Understanding potential energy in various systems and applying energy conservation principles.
Power: Analyzing the rate at which work is done.

4. Systems of Particles and Linear Momentum

Momentum and Impulse: Understanding the concepts of momentum and impulse in collisions.
Conservation of Momentum: Applying momentum conservation in various scenarios.

Momentum and Impulse: Understanding the concepts of momentum and impulse in collisions.
Conservation of Momentum: Applying momentum conservation in various scenarios.

5. Circular Motion and Rotation

Uniform Circular Motion: Examining the forces involved in objects moving in circular paths.
Rotational Dynamics: Understanding torque, angular acceleration, and rotational inertia.

Uniform Circular Motion: Examining the forces involved in objects moving in circular paths.
Rotational Dynamics: Understanding torque, angular acceleration, and rotational inertia.

6. Oscillations and Gravitation

Simple Harmonic Motion: Studying the motion of oscillatory systems.
Gravitational Forces: Analyzing the gravitational interactions between masses.

Simple Harmonic Motion: Studying the motion of oscillatory systems.
Gravitational Forces: Analyzing the gravitational interactions between masses.

Exam Structure and Scoring

Multiple-Choice Section (35 questions)

Duration: 45 minutes
Content: Tests students’ comprehension of fundamental concepts and their ability to apply these concepts to various scenarios.

Free-Response Section (3 questions)

Duration: 45 minutes
Content: Requires detailed, written responses that demonstrate problem-solving and analytical skills. The free-response questions cover experimental design, quantitative analysis, and real-world applications of mechanics principles.

Scoring Breakdown:

Multiple-Choice: 35 points
Free-Response: 55 points
Total Composite Score: 90 points
Predicted AP® Score: Based on the composite score and the College Board’s scoring guidelines.

Disclaimer:

AP® and Advanced Placement® are registered trademarks of the College Board, which was not involved in the production of, and does not endorse, this product.