The Eyeball fits most vocal recording microphones and shock-mounts. Mics which are side address with long/short-bodies having a diameter of (38mm to 70mm / 1.5” to 2.75”)



Record Anywhere

 In your closet or a cave

Flame Retardant

 No tears! Smoke and choke around the Eyeball freely

No Stand, No Shock Mount, No Hassel

 Works with what you have: a microphone

 Won’t tip over or knock you out

Works with most Vocal Microphones

 Bring out the best in your mic


 Don’t throw your back out! It weighs less than your microphone


 Dent resistant, won’t rust, Never needs Duct-Tape

A Practical Sound booth solution

 Eat eggs cuz you want to, not just for the tray

 Stop stealing your grandma’s precious quilts

Integrated pop filter

 Spit all you want, only your voice reaches the microphone


The Kaotica Eyeball is an acoustic treatment device that isolates your microphone and creates a sound channel directly to your mic.By isolating and channeling sound, the Eyeball is able to accurately capture the pure vocal tone while greatly reducing room reflections and ambient noise. Designed for all vocal/voice-over applications either as standalone, mobile, or in conjunction with treated spaces. Includes an integrated pop-filter and fits most large diaphragm condenser microphones 38mm to 70mm / 1.5” to 2.75”


Frequency response 0Hz - 30KHz +/-1.4dB
THD: 6.789%
Max Peak: 140 dB
TL: 3.73 dB (average)
Polar Patterns: Cardioid is recommended, but all types of polar patterns can be used with the Eyeball


The frequency response chart was generated using a frequency sweep from 0 Hz - 30 KHz. All frequencies are captured equally, producing a flat frequency response. The Eyeball captures an accurate representation of sound, as the the low & high end frequencies of a signal can be lost in the recording process due to sound's tendency to disperse through air.

3D Spectrograph results on how the Kaotica Eyeball reduces ambient noise


In respect to the comparative spectrograph below, on the left is a 3D representation of a vocalist singing without The Eyeball, on the right is a representation of the vocals inside of The Eyeball. The large spikes you are seeing are being produced by ambient noise & room tone. This includes things like structure born vibration, bleed & generally most other unwanted sounds. You can very clearly see on the right that the sound has been ‘evened out’, and the ambient noise and bleed is gone, leaving only the pure vocal tone to be captured by your microphone.

Frequency Spectrum


The THD comparison portrays sound traveling through air and sound in the Eyeball. The THD reading is dramatically decreased inside of the Eyeball, producing a more accurate representation of the sound source.

No Eyeball  20.8553%
Eyeball 6.7996%


The Eyeball reduces the external environment and only leaves the pure tone to be channeled into the microphone. By reducing the external environment, phase anomalies and cancellation are diminished within an untreated space.


Based upon the volume levels indicated by the RMS and DBSPL readings above, sound is louder inside of the Eyeball. The louder volume level has many distinct advantages. An increase in the Signal to Noise ratio is apparent as the clean signal is increased while the noise ratio is substantially decreased. The reason for these amplitude increases is because sound is not being allowed to disperse through air, but is being channeled directly into your microphone without coloration.


No Eyeball 74.5
Eyeball 80.55
No Eyeball -35.4
Eyeball -18.3

Envelope graph portraying the smoother decay within the Kaotica Eyeball

The graph above portrays the envelope of a sound within the Eyeball (represented in red) and without the Eyeball (represented in purple). By comparing the Envelope (Attack, Sustain, Decay, Release) readings, we determined several key characteristics about sound within the Eyeball. Note the difference in Decay time (the drop of the waveform after the initial attack (rise). Within the Eyeball we see a smoother, slower, and more linear decay pattern, while the envelope of the sound without the Eyeball decays much quicker. This shows us how quickly sound is dispersed through air, and how much longer the sound is maintained inside of The Eyeball.