iCON Pro Audio Dynamic Cardioid Microphone for Broadcast Podcast Singing

- PROFESSIONAL PODCASTING MICROPHONE: The iCON Pro Audio DynaMic is a top-tier dynamic microphone designed for exceptional clarity and quality in vocal applications, making it perfect for podcasts, broadcasting, live sound, and recording. - OPTIMAL BROADCASTING PERFORMANCE: With its supercardioid polar pattern, this microphone excels in isolating your voice while minimizing background noise and feedback, ensuring your radio, podcast, or streaming sessions sound pristine. - DURABLE CONSTRUCTION: Built to withstand years of use, the DynaMic features an ultra-rugged all-metal finish and a shock-mounted capsule for added durability, making it a reliable choice for demanding environments. - FLEXIBLE POSITIONING: The attached swing mount allows you to easily position the microphone to capture your voice at the perfect angle, enhancing your recording or broadcasting setup. - INTERNAL POP FILTER & SWITCHES: Equipped with an internal pop filter, you won't need external pop shields. Additionally, it offers a low-cut filter switch (400 Hz) and a high-boost switch (2KHz ? 6KHz) for further sound customization. - HIGH-QUALITY SPECIFICATIONS: With a frequency range of 50 Hz to 15 kHz, a sensitivity of ?54.5dBV/Pa, and an output impedance of 150 Ω, the DynaMic delivers outstanding audio quality. The 3-pin XLR male connector ensures a secure connection. - COMPACT AND PORTABLE: Measuring just 55mm x 55mm x 130mm and weighing only 0.563kg, this microphone is easy to transport and set up for various recording or live sound applications. - ENHANCE YOUR AUDIO SETUP: The iCON Pro Audio DynaMic is your go-to microphone for achieving professional sound quality, whether you're a podcaster, broadcaster, or musician. Invest in superior audio performance today!

Product description

DynaMic

The DynaMic is a dynamic microphone that offers performance for podcasting, broadcasting, live sound, and recording applications. Its supercardioid polar pattern provides off-axis rejection for minimizing noise and feedback.