-Instrument Introduction

This innovative open experimental combination is different from previous experimental equipment with complete machine concepts. It adopts a portable, functional, and modular design, providing various components with unique functions. Students or teachers can freely design experimental plans, select, match, and assemble various components to complete the experimental plan. Intended to cultivate students' proactive thinking ability, hands-on ability, and divergent thinking; Provide a great platform for cultivating students' innovative and pioneering abilities; Provided convenient conditions for teachers' scientific research. In combination with the Internet plus experiment sharing platform, we can realize resource sharing, process sharing, and result comparison to make the boring student experiments "live". Product features: Modular and standardized design, free combination, portable and easy to store splicing guide rail, green light holographic, rich content from easy to difficult reservation and preview, micro lesson appreciation, experimental video viewing, virtual experiment operation, experimental result uploading and comparison, experimental video uploading, global comparison of experimental results, micro lesson uploading score viewing, click count statistics, making your experimental process a lightweight and small accessory for others' micro lessons, achieving the same experimental effect.

-Product Features

· 1. Modular and standardized design

· 2. Free to mix and match with any combination

· 3. Portable and easy to store

· 4. Modular and standardized design

· 5. Free to mix and match with any combination

· 6. Portable and easy to store

-Optical self-organizing innovation cloud platform

1. Measure the focal length of a thin lens using the self calibration method

2. Bessel method (two-stage imaging method) for measuring the focal length of thin lenses

3. Measure the focal length of the eyepiece based on the magnification of the object image

4. Measure the focal length of a concave lens using the object distance image distance method

5. Measurement of lens group nodes and focal length

6. Self assembling projector

7. Measure the magnification of the self assembling telescope

8. Self assembling telescope with positive prism

9. Measure the magnification of the self-assembled microscope

10. Yang's double slit experiment

11. Fresnel prism interference

12. Fresnel dual mirror interference

13. Lloyd's mirror interferometry

14. Newton's ring

15. Measure the refractive index of air using interferometry

16. Fraunhofer single slit diffraction

17. Fraunhofer circular hole diffraction

18. Fresnel single slit and circular hole diffraction

19. Straight edge Fresnel diffraction

20. Grating diffraction

21. Grating monochromator

22. Generation and inspection of polarized light

23. Holography

24. Making holographic gratings

25. Abbe imaging principle and spatial filtering

26. θ modulation

27. Observe the 6 aberrations of the lens

28. Build the Mach Zehnder interferometer optical path

29. Build the optical path of the Saniak interferometer

30. Addition and subtraction of light images

31. Experiment on Image Differentiation of Light

32. Convolution Theorem Experiment

33. Crystal birefringence experiment

34. Wave Plate Related Experiments

35. Laser interferometry is used to measure the refractive index and thickness of a medium.

This experiment adopts a functional modular design, including up to dozens of functional accessories, which can meet the needs of different experimental combinations from the platform to the guide rail.

Standardization and generalization of product accessories, uniform size, and easy replacement.

The arbitrary splicing of T-shaped and parallelogram angle guides facilitates different experimental combinations

-Holographic experiment