The EO Tech Vudu 3-9X32mm MR-5 MRAD Precision Rifle Scope Kit offers versatility and precision for medium to long-range shooting. Featuring a sleek black finish, this scope is designed for durability and optimal performance in various conditions. Its 3X to 9X magnification allows shooters to quickly adapt to different target distances, making it suitable for hunting, tactical, or precision shooting applications. The 32mm objective lens provides a bright and clear image, while the 1/4 MOA adjustments enable precise zeroing and reticle calibration for consistent accuracy. The illuminated MR-5 MRAD reticle enhances target acquisition in low-light environments, ensuring clarity and visibility when it matters most. The scope's second focal plane design maintains reticle size regardless of magnification, providing consistent point of aim throughout your zoom range. Weighing approximately 16 ounces and measuring about 6.8 inches in length, this scope balances portability with stability for a comfortable shooting experience. The EO Tech Vudu includes an EFLX ring mount, facilitating quick attachment and secure fit on compatible firearms, and its robust construction withstands recoil and harsh conditions. Whether you're a professional marksman or an avid hunter, this scope is engineered to deliver precise, reliable performance for demanding shooting scenarios. Its straightforward adjustments and illuminated reticle make it an excellent addition to your rifle setup, enhancing accuracy and confidence at the range or in the field.

Features:

• EFLX and Ring Mount: Quick attachment and secure fit on rifles

• Second Focal Plane: Maintains reticle size across magnifications

• 10 Brightness Settings: Customizable illumination for various lighting conditions

• Optic Magnification: 3X to 9X for versatile targeting

• Objective Size: 32mm for bright, clear images

• Optic Adjustments: 1/4 MOA for precise zeroing

• Reticle: MR-5 MRAD designed for accurate range estimation and holdovers

• Illuminated Reticle: Yes for enhanced visibility in low-light scenarios