This system is designed to observe the polarization rotation of an optical beam going through a magneto-optic material. Through this system, students can understand the fundamental parameters of a magneto-optic device with related measurement techniques.
This system is designed to study the acousto-optic effect of a crystal sample. Through this system, students can get a better understanding of the fundamental parameters of an acousto-optic device with related measurement techniques.
The experimental apparatus of ultrasonic grating is constructed by placing individual components on an optical rail with liquid as the ultrasonic medium. It allows students to adjust each component independently, and thus strengthens their hands-on ability.
This unit is designed to help students understand the theory of the electro-optic modulation in a crystal material. Through this system, students can acknowledge the fundamental parameters of a LiNbO3 crystal with related measurement techniques.
This apparatus is designed to help students understand the principle and application of liquid crystal electro-optic effect. Through this system, students can measure LC response curve, threshold & saturation voltages, and transmittance.
This unit is designed to measure the fundamental characteristics and parameters of a silicon photocell. By designing and constructing experimental configuration, students can enhance their understanding of the fundamental principles of silicon photocells.
This experiment studies the V-I characteristics and light illumination characteristics of the four photosensitive sensors: photosensitive resistance, silicon photocell, photosensitive diode and photosensitive transistor.
This experimental system is designed for nonlinear optical experiments at universities and colleges. It can help students understand the theory of a diode-pumped solid-state (DPSS) laser with frequency doubling technique.
LEOI-53 allows students to monitor the change in frequency distribution pattern of laser modes by adjusting the laser cavity configuration. The use of a confocal scanning interferometer further enables quantitative analysis of the frequency spacing between laser modes.
This apparatus is designed to measure these characteristics of a semiconductor laser: far-field distribution and divergent angles, voltage-current relationship, power-current relationship, temperature characteristic, and polarization ratio.
This system is designed to measure the output power of a semiconductor laser as well as the driving voltage and injection current of the laser. It can help students understand the working characteristics of a semiconductor laser under CW output mode.
This kit is designed to meet the increasing demand for the support of laboratory based experiments in fiber optics. This kit provides the essential basic knowledge & skills with seven experiment examples.
This Fiber Optic Experimental kit is a sister kit to LEOK-20, which has been revised and rewritten to include ten experiment examples.
This kit will provide an overview of fiber optic technology and basic skills needed to work with fiber optics. It provides fourteen experiment examples.