Release Date : 2025
Version : 1.0.5
Developer : CRQL
Developer’s Website : crql.works
Format : STANDALONE, VST3, AU, CLAP
Bit depth : 64bit
Tablet : not required
System requirements : Windows, MacOS, Linux
- 27.7Β MB
Description : 8192 notch
It works using spectral filtering. Simple idea, extraordinary results.
UZU is a so-called frequency-domain filter, the shape of which is directly inspired by Harmor’s Phaser effect. Since it’s spectral, you’ll hear signal smearing and delay.
Features:
1: Distance between each spectral notch
2: Main phase-offset of the filter shape
3: Add sharpness and depth to each notch
4: Automatic offset-control speed
5: Overall mix of the plugin
6: Rounds spectral bins for rhythmic “pulses”
7: Weighs the filter to either Hz or Log
8: Speed ββand offset 5x multiplier
9: Preserves low-end frequencies under 250hz
10: Change the spectral-engine’s blocksize
1: Distance between each spectral notch
2: Main phase-offset of the filter shape
3: Add sharpness and depth to each notch
4: Automatic offset-control speed
5: Overall mix of the plugin
6: Rounds spectral bins for rhythmic “pulses”
7: Weighs the filter to either Hz or Log
8: Speed ββand offset 5x multiplier
9: Preserves low-end frequencies under 250hz
10: Change the spectral-engine’s blocksize
Re-thinking the “phaser”
Conventional phasers work in the time domain, using phase shifts and tiny delays to create a handful of notches (usually 12 or 24 at most)…
UZU flips the table
It operates in the frequency domain using an FFT (Fast Fourier Transform), allowing up to 8192 notches, a scale traditional phasers simply can’t reach. This way, notches are sharp, bubbly and are just how we think phasers should sound!
Conventional phasers work in the time domain, using phase shifts and tiny delays to create a handful of notches (usually 12 or 24 at most)…
UZU flips the table
It operates in the frequency domain using an FFT (Fast Fourier Transform), allowing up to 8192 notches, a scale traditional phasers simply can’t reach. This way, notches are sharp, bubbly and are just how we think phasers should sound!
