EGK PhysicsLab AR
iOS Universel / Education
EGK PhysicsLab AR is a premier interactive educational software platform designed specifically to bridge the gap between complex theoretical physics and tangible reality.
By utilizing state-of-the-art Augmented Reality (AR) spatial anchoring, students, educators, and science enthusiasts no longer need to rely purely on flat textbook illustrations or rigid 2D diagrams to grasp fundamental natural laws. Instead, users can anchor mathematically rigorous, fully animated 3D physics models directly onto any physical surface in their immediate environment—whether it is a classroom table, a study desk, or a laboratory workbench.
Key Technological Features & Innovations
Zero-Latency Spatial Mapping: Leveraging cutting-edge real-time plane detection, the app maps local physical spaces dynamically, enabling users to drop and reposition intricate structural models with a single tap.
Programmatic Vector Overlays: Beyond displaying high-quality asset models, the rendering pipeline dynamically draws functional visual indicators—such as changing velocity arrows, force decomposition lines, and wave field matrices—directly within the 3D space.
Seamless Formative Assessment: Every single experiment module contains dedicated, contextual evaluation features. Students can immediately transition from interacting with a 3D model to a tailored interactive quiz, reinforcing core competencies right when retention is highest.
Complete Core Experiment Manifest
The platform is organized into core physics tracks, providing a wide breadth of academic coverage across high-priority syllabus topics:
1. Advanced Mechanics
Projectile Motion: Visualize kinematics by launching virtual masses. Students can study the independence of horizontal (vx) and vertical (vy) velocities, tracking parabolic curves while real-time vector components adjust dynamically along the flight path.
Simple Pendulum: Investigate the relationship between pendulum string length and its oscillation period (T=2πl/g). Isolate variables in real time to prove that changing the bob's mass has no effect on timing.
Inclined Plane: Decompose gravitational forces (W=mg) into components parallel (mgsinθ) and perpendicular (mgcosθ) to the slope. Students can manipulate angles to calculate friction coefficients and tipping points effortlessly.
2. Wave Phenomena
Wave Interference: Simulates an advanced ripple tank environment. Watch constructive and destructive interference patterns take shape as waves cross paths, clearly illustrating phase changes, nodes, and antinodes.
Young's Double Slit: Experience wave optics first-hand. Observe how a monochromatic light source diffracts through dual apertures to create alternating bright and dark fringes on an adjusted measurement screen.
3. Electricity & Circuit Design
Series Circuits: Build a direct-current electrical pathway to master voltage dividers. See how electric current remains uniform while voltage drops across individual resistive nodes.
Parallel Circuits: Explore current dividers by routing parallel current paths. Test how individual branches draw current inversely proportional to their specific resistances while sharing a uniform voltage drop.
4. Geometrical Optics
Convex Lenses: Interact with an optical bench to track converging light rays. Move virtual object points back and forth relative to the focal length (f) to observe the exact mathematical transformation between real, inverted images and virtual, upright images.
Concave Mirrors: Explore reflective properties by focusing parallel incoming rays to a crisp focal point. Discover practical applications, from car headlights to satellite receivers, through ray tracing.
5. Thermodynamics
Boyle's Law: Manipulate a closed piston compression apparatus to study gas behaviors at a constant temperature. Compress the volume to witness gas molecules colliding more frequently, proving that pressure and volume share a strict, inverse relationship (PV=k).
