Shure HA-8089: The Ultimate Helical Antenna for Enhanced Connectivity
Upgrade your wireless experience with the Shure HA-8089 Helical Antenna! This remarkable antenna offers greater bandwidth and longer range gain for receivers, transmitters, and distribution systems. Ideal for wireless microphone systems and in-ear monitor systems, it revolutionizes RF performance by distributing signal multi-dimensionally between 480 to 900MHz. Enjoy longer range without interference, high gain, and freedom of movement, no matter where you are on the stage.
Key Features:
- • Covers a wide bandwidth from 480 to 900MHz, ensuring seamless connectivity across various devices.
- • Rotates RF energy through 360 degrees of polarization for crystal clear reception, no matter how you move.
- • Delivers crystal clear reception wherever the artist moves on the stage, providing an unparalleled audio experience.
Specifications:
- Frequency Range: 460 - 900 MHz
- Impedance: 50 Ohms
- Beamwidth: 57°
- Antenna Gain: 14 dBi (on axis)
- Power Source: Not Required
- RF Connector: BNC female, right angle
- Operating Temperature: -30°F to 180°F (-34°C to 80°C)
- Construction: Clear Polycarbonate plastic
- Dimensions: 14' x 14' x 14' (36 x 36 x 36 cm) shipping
- Weight: 3lbs 11oz (1.7 kg)
- Packaging Info: Package Weight: 5.74 lbs., Box Dimensions (LxWxH): 15 x 15 x 15'
The Shure HA-8089 Helical Antenna is a must-have for anyone using wireless microphone or in-ear monitor systems. It works great with receivers, transmitters, and distribution systems. With dimensions of 14' x 14' x 14' (36 x 36 x 36 cm) and weighing 3lbs 11oz (1.7 kg), it's easy to handle. The frequency range is 460 - 900 MHz, and it has an impedance of 50 Ohms. It's made of clear polycarbonate plastic and has a BNC female, right angle RF connector. It can operate in temperatures from -30°F to 180°F (-34°C to 80°C). The antenna provides great bandwidth and longer range gain, ensuring clear connections without interference. It's perfect for artists on stage who need freedom of movement while maintaining a strong signal.
