• Designed specifically for musical instruments
• Accurate response, even in high sound pressure level (SPL) applications
• Flexible mechanical design for optimum positioning
• Supercardioid pattern for exceptional acoustic isolation and feedback rejection
• Dynamic N/DYM¬ Magnet Structure: Yes
• Frequency Response: Close 30-22,000 Hz, Far 60-22,000 Hz
• Polar Pattern: Supercardioid
• Input Impedance: Low-Z balanced (150 ohms)
• Sensitivity: Open-Circuit Voltage 3.1 mV/Pascal at 1 kHz
• Power Level*: -51.0 dB
• Accessories (included with product): Stand clamp (black) and soft, zippered gig bag

Characteristic of all N/DYM® microphones is the outstanding neodymium-iron-boron magnetic structure. This structure provides greater sensitivity for exceptional signal-to-noise ratio and improved recording quality. Combining the N/DYM® magnetic structure with a large, reinforced diaphragm results in a transducer manifesting a warm, open and transparent sound quality normally found in studio-quality microphones. The N/D468 also includes a highly effective humbucking coil that reduces hum interference from lighting and other electrical power sources.

N/DYM ® microphones feature EV's AcoustiDYM™ shock-mount system. This unique vibration isolating system works as a multistage device. At low frequencies, a rear sound wave cancels the diaphragm motion while, at high frequencies, the specially designed rubber shock mount isolates the transducer from motion. Combined with the windscreen bumper, the shock mount forms an advanced technology, vibration isolating system that dramatically reduces all forms of handling noise for the most demanding situations.

To ensure superior gain-before-feedback in live performance and acoustic isolation in recording studio environments, the N/D468 is constructed with a supercardioid polar pattern. The supercardioid pattern yields greater rejection and acoustic isolation to off-axis sounds than the typical heart-shaped cardioid pattern. For enhanced clarity, the polar response is also unusually uniform with frequency. The impact of the supercardioid polar design is to reduce the likelihood of feedback in live performance conditions, particularly with typical monitor speaker placements.

The N/D468 pop filter's unique design utilizes a specially processed Acoustifoam TM filter to minimize wind noise and vocal P-pops. This design makes the pop filter an integral part of the microphone's removable front grille assembly, allowing easy cleaning for continued top performance.

OPERATION
The N/D468's low-frequency response varies with the distance of the sound source to the microphone. This is known as "proximity effect." Maximum bass response is produced in "close-up" use with the microphone 1/4 inch from the sound source. Minimal bass response is experienced at distances greater than 24 inches. By working closer to the microphone, the instrument will sound more robust. The pivoting yoke designed for the N/D468 allows this type of versatile microphone placement.

"Close miking" will also reduce the potential for feedback from a PA sound system.This benefit is in addition to the feedback-reducing supercardioid polar pattern. When close-talked, the substantial bass boost provides an increase in overall microphone output level. The mixer gain may be proportionately reduced, resulting in a reduction of the system's sensitivity to feedback caused by sound entering the microphone from the loudspeakers.

The dynamic element of the N/D468 will provide reliable operation in extreme temperature, humidity and other adverse conditions that would render typical condenser microphones useless. These N/D468 features will provide years of trouble-free operation.

EV is famous throughout the industry for high quality and robust microphones as used in studios, on stage, TV and broadcasting. Cardiline®, RE-Series, Variable-D® are all well-known industry terms. Most of EV´s microphones are low-impedance enabling long cable runs without RFI problems. By the way, it was an EV mic which amplified Neil Armstrong's famous words on his arrival on the moon's surface in 1969.