Excelitas Technologies is a global technology leader focused on delivering innovative, high-performance photonic solutions to a wide range of industries. With a comprehensive portfolio of products and expertise in photonics technology, Excelitas serves customers in the biomedical, scientific, industrial, and defense markets. The company's offerings include advanced optoelectronics, sensors, light sources, and customized photonic systems that enable applications such as medical diagnostics, DNA sequencing, and precision measurement. Excelitas is committed to driving technological advancements and has a strong track record of developing cutting-edge solutions to address complex challenges across various industries. As a trusted partner for photonics solutions, Excelitas continues to play a pivotal role in advancing critical technologies and empowering customers to achieve their goals through the use of light-based technologies.
Optical polarizers are critical components used to transform unpolarized light into polarized light, enabling precise control over the light's polarization state. These polarizers come in various types and configurations, each optimized for specific applications and wavelength ranges. The primary function of optical polarizers is to transmit only that predefined polarization while blocking all others, enabling the elimination of unwanted polarization states. Common types of optical polarizers include linear polarizers, circular polarizers, and wire-grid polarizers, each with its unique characteristics and advantages. When selecting an optical polarizer, several parameters need to be considered. Wavelength compatibility ensures that the polarizer operates optimally within the desired wavelength range. Optic diameter determines the size of the polarizer, influencing the amount of light transmitted and the maximum beam diameter that can be accommodated by the polarizer without significant light loss or distortion. Polarization efficiency refers to the ability of the polarizer to eliminate unwanted polarization states, determining the quality of the polarized light output. Other factors that impact polarization efficiency include the angle of incidence, beam size, and the polarization state of the incident light. Other factors to consider may include environmental robustness, temperature stability, and surface quality. Environmental robustness ensures that the polarizer can withstand variations in temperature, humidity, and other conditions. Temperature stability measures the polarizer's ability to maintain its polarization properties under varying temperature conditions. Surface quality measures how smooth and flat the polarizer's surface is, impacting the quality of the polarized light output. In summary, optical polarizers are indispensable devices used to transform unpolarized light into polarized light for various applications. They can be selected based on parameters such as polarizer type, wavelength compatibility, optic diameter, polarization efficiency, environmental robustness, temperature stability, and surface quality. Their wide range of applications includes microscopy, imaging systems, and more.