High frequency dispersion and driver size [message #15466] |
Fri, 09 March 2007 15:48 |
DanTheMan
Messages: 84 Registered: May 2009
|
Viscount |
|
|
Does anyone nkow how to calculate when a driver of any particular size will start beamimg? I know I've read the formula somewhere before, but I can't find it. Also, does anyone know how to use this information to find how high a given driver will go before its high frequency response reaches 90degree or 80degree.......dispersion? Thanks! Dan
|
|
|
Re: High frequency dispersion and driver size [message #15467 is a reply to message #15466] |
Fri, 09 March 2007 18:42 |
Duke
Messages: 297 Registered: May 2009
|
Grand Master |
|
|
As a general rule of thumb, a driver's radiation pattern will narrow to about 90 degrees at the frequency where the cone diameter (or diaphragm dimension if non-circular) is equal to one wavelength. Cone break-up preserves a wider radiation pattern to a high frequency than if the cone were behaving as a rigid piston. A dome driver acts as an annular radiaton in breakup mode, which from what I understand also gives a wider pattern than rigid piston theory would predict but not as much so as a cone in breakup. If you want to get into mathematics that will describe real-world loudspeaker behavior rather that idealized rigid pistons, I recommend "Audio Transducers" by Geddes. Duke
|
|
|
|
Cone flex and ripples, breakup modes [message #15469 is a reply to message #15467] |
Mon, 12 March 2007 10:31 |
|
Wayne Parham
Messages: 18787 Registered: January 2001
|
Illuminati (33rd Degree) |
|
|
I studied Geddes book "Audio Transducers" but don't recall him going into much detail about cone flex, or drivers in breakup. Please refresh my memory, what chapters he has written on it and what he said. I'll try to remember to re-examine that book this weekend when I get back to Tulsa.To understand the movement of a cone in breakup, one would need to know the geometry and shape of the cone, as well as its material properties, stiffness, placticity, elasticity, etc. The drive and mount points and stiffness of those would also have to be entered. It would be possible to model something like this with finite element analysis but it would take a lot of input data parameters to adequately describe.
|
|
|
|
Re: Cone flex and ripples, breakup modes [message #15471 is a reply to message #15469] |
Mon, 12 March 2007 12:31 |
Duke
Messages: 297 Registered: May 2009
|
Grand Master |
|
|
He doesn't devote much English text to the subject. Starting on page 72: "Most transducers do not have radiating surfaces which are rigid pistons and so it would be convenient to generalize the approach shown above to consider non-rigid piston behavior... [calculus calculus calculus... Duke doesn't speak calculus... reverting now to English on page 75]... The above result can be greatly simplified for the case where the source is axi-symmetric but still not a rigid piston - by far the most common situation... [less calculus]..." I can't comment on how complete Earl's mathematical model is. That would be like me critiquing subjunctive tense conjugations in ancient Summarian poetry. Duke
|
|
|
|
|