Directivity
Let’s talk some about directivity, which is a huge topic in itself. The goal was a uniform horizontal and vertical dispersion over a wide area. A general weakness with many speakers today is that they only have a constant directivity in the higher frequencies. For example above 1 KHz and below this the directivity control is lost and we then have what was called a collapsing polar in acoustical circles. This leads to a difference in the reflective energy, and IMO such speakers don’t sound tonality correct without acoustics treatment.
With Coherence 12 we wanted therefore a speaker that could maintain the directivity much lower in frequency. The horizontal dispersion is 180°, meaning 90° to each side. According to Harman/Toole wide dispersion like 180° is a benefit. But I think this depends very much on the room and how one listens. I believe both wide and narrow horizontal dispersion has its place and what’s better will depend.
Originally, we wanted to maintain the wide dispersion in high in frequency as possible. Doing that with a wide band driver is challenging though, because such drivers are larger. Something we experimented quite a bit with was using an acoustical lens to keep wide directivity high in frequency. This wasn’t completely successful as it lead to other issues.
By using a coxial driver it’s easier to maintain directivity in the higher frequency. We tested a good number of coaxial drivers and did AB tests besides obviously measuring. The problem with most coxial drivers are frequency deviation as the two drivers effect it each other. They neither sounded or measured as well as other options. Below is a crude indoor measurement of a coaxial driver used in a prototype. No gating is used.
After testing many drivers we had initially landed on a wide band driver. This driver could cover a large frequency area, maintained the 180° dispersion quite high in frequency, and sounded like a good piston tweeter in the highs. However, we made a decision to try out several other types of drivers, and among these were several planar/ribbon transducers. Two of these sounded incredible good, and one slightly better than the other. Despite that the planar driver narrowed horizontal earlier in frequency, it had a clarity, detail and insight into the music material the piston driver couldn’t match. So it was an easy choice.
The directivity of the planar driver changed the dispersion of the speaker. The speaker narrowed now earlier in frequency horizontally. The narrowing from 180° starts around 5 KHz. One can discuss if this is negative compared to maintaining a wide dispersion in the highs. I think there are points for both sides.
Vertically by changing from the piston driver to the planar we went to a wide dispersion high in frequency till a very narrow vertical directivity in parts of the frequency. This is something I believe is very beneficial as vertical reflections from ceiling and floor are only detrimental.
But the narrowing vertically means that you basically have to sit to get a good treble and higher mid response. If you stand up, the higher frequencies will be partially lost because it’s outside the listening window. This gets better further away from the speaker.
So the horizontal directivity is constant from about 200 Hz area till 5 KHz and narrows above. Vertically, we’re going to need to do 100% anechoic measurements to be certain. But the trait is that the dispersion narrows some above 400-500 Hz area, remains much the same till 1.5 KHz and narrows again above this frequency. It’s quite beamy vertically in the highest frequencies.