- Instrument Introduction
Unlike traditional experimental equipment, which typically consists of complete, integrated systems, this innovative open-experiment kit features a portable, functional, and modular design. It provides individual components, each with unique functions, allowing students or instructors to freely design experimental protocols by selecting, combining, and assembling these components to complete their experiments. It aims to cultivate students’ critical thinking, hands-on skills, and divergent thinking; provides an excellent platform for fostering students’ innovation and exploratory abilities; and offers convenient conditions for teachers’ research. Integrated with an “Internet+” experimental sharing platform, it enables resource sharing, process collaboration, and result comparison, bringing “life” to otherwise tedious student experiments. Product Features: Modular and standardized design; freely mix and match components; portable and easy to store; interlocking guide rails; green-light holographic display; rich content ranging from easy to difficult; scheduling and previewing; micro-lecture viewing; experimental video viewing; virtual experiment operation; uploading and comparing experimental results; uploading experimental videos; global comparison of experimental results; uploading micro-lectures; viewing grades; click-through statistics—turn your experimental process into a micro-lecture for others; achieve the same experimental results with lightweight and minimal accessories.
- Product Features
· 1. Modular, standardized design
· 2. Flexible configuration and customization
· 3. Portable and easy to store
· 4. Modular, standardized design
· 5. Flexible configuration and customization
· 6. Portable and easy to store
- Optical DIY Innovation Cloud Platform
1. Measuring the focal length of a thin lens using the self-collimation method
2. Measuring the focal length of a thin lens using the Bessel method (double-image method)
3. Determining the focal length of an eyepiece from the object-image magnification
4. Measuring the focal length of a concave lens using the object-image distance method
5. Determining the nodal point and focal length of a lens system
6. DIY Projector
7. Measuring the Magnification of a DIY Telescope
8. DIY Telescope with a Real-Image Prism
9. Measuring the Magnification of a DIY Microscope
10. Young’s Double-Slit Experiment
11. Fresnel Double-Prism Interference
12. Fresnel Double-Mirror Interference
13. Lloyd Mirror Interference
14. Newton’s Rings
15. Determining the Refractive Index of Air Using Interference
16. Fraunhofer Single-Slit Diffraction
17. Fraunhofer Circular Aperture Diffraction
18. Fresnel Single-Slit and Circular Aperture Diffraction
19. Straight-edge Fresnel diffraction
20. Grating diffraction
21. Grating monochromator
22. Generation and detection of polarized light
23. Holography
24. Fabrication of holographic gratings
25. Abbe imaging principle and spatial filtering
26. θ Modulation
27. Observation of the Six Types of Lens Aberrations
28. Setting Up the Optical Path for a Mach-Zehnder Interferometer
29. Setting Up the Optical Path for a Sagnac Interferometer
30. Addition and Subtraction of Light Images
31. Differentiation of Light Images Experiment
32. Convolution Theorem Experiment
33. Crystal Birefringence Experiment
34. Waveplate Correlation Experiment
35. Laser Interferometry Measurement of the Refractive Index and Thickness of Media.
This experimental kit features a modular design and includes dozens of functional components, capable of meeting various experimental configuration needs ranging from platforms to guide rails.
Product components are standardized and universal, with uniform dimensions, allowing for easy replacement.
The ability to freely assemble T-shaped and parallelogram-shaped guide rails with angles facilitates different experimental configurations.
- 全息实验
