Today’s studies about horns are actually based almost completely upon directivity control. In fact, while a good power response is finally recognized so important in professional loudspeaker systems engineering, the directivity behaviour of horns represents certainly a useful tool to get it. The directional properties of these devices are governed by the wavefront’s shape presented at the mouth. An analisys of the sound pressure’s magnitude and phase distribution across the horn’s mouth could certainly be helpful to understand how the wavefront is shaped there. Moreover, this could help to understand what happen in some particular circumstances. For example midrange beaming or high frequency mouth diffraction phenomena are two well known obstacles to overcome designing a broad band constant directivity horn. A method forwarded by us to perform such analisys will be shown through graphic illustrations. Presented will be even the results obtained performing measurements upon real devices and the correlation to the polar plots.
[1]
Clifford A. Henricksen,et al.
The Manta-Ray Horns
,
1978
.
[2]
Lawrence E. Kinsler,et al.
Fundamentals of acoustics
,
1950
.
[3]
Clifford A. Henricksen,et al.
Blasphemy-The Manta-Ray Horns!
,
1977
.
[4]
Tonni F. Johansen,et al.
On the Directivity of Horn Loudspeakers
,
1994
.
[5]
Mario Di Cola,et al.
A New Approach to Waveguides
,
1999
.
[6]
Earl R. Geddes.
Sound Radiation from Acoustic Apertures
,
1993
.
[7]
Gavin R. Putland.
Every One-Parameter Acoustic Field Obeys Webster's Horn Equation
,
1993
.
[8]
D. B. Keele,et al.
What's So Sacred About Exponential Horns?
,
1975
.
[9]
David Bie.
Vibration Resonances of a Titanium Loudspeaker Diaphragm
,
1998
.
[10]
Earl R. Geddes.
Acoustic Waveguide Theory
,
1989
.