Researchers at the Georgia Institute of Technology have pinpointed the elusive factor that makes the ancient amphitheatre an acoustic marvel, the Archaeological News Network reports. It's not the slope, or the wind--it's the seats. The rows of limestone seats at Epidaurus form an efficient acoustics filter that hushes low-frequency background noises like the murmur of a crowd and reflects the high-frequency noises of the performers on stage off the seats and back toward the seated audience member, carrying an actor's voice all the way to the back rows of the theatre.
The research, done by acoustician and ultrasonics expert Nico Declercq, an assistant professor in the Woodruff School of Mechanical Engineering at Georgia Tech and Georgia Tech Lorraine in France, and Cindy Dekeyser, an engineer who is fascinated by the history of ancient Greece, appeared in the Journal of the Acoustical Society of America.
While many experts speculated on the possible causes for Epidaurus' acoustics, few guessed that the seats themselves were the secret of its acoustics success. There were theories that the site's wind--which blows primarily from the stage to the audience--was the cause, while others credited masks that may have acted as primitive loudspeakers or the rhythm of Greek speech. Other more technical theories took into account the slope of the seat rows.
When Declercq set out to solve the acoustic mystery, he too had the wrong idea about how Epidaurus carries performance sounds so well. He suspected that the corrugated, or ridged, material of the theater's limestone structure was acting as a filter for sound waves at certain frequencies, but he didn't anticipate how well it was controlling background noise.
But as Declercq's team experimented with ultrasonic waves and numerical simulations of the theatre's acoustics, they discovered that frequencies up to 500 Hz were held back while frequencies above 500 Hz were allowed to ring out. The corrugated surface of the seats was creating an effect similar to the ridged acoustics padding on walls or insulation in a parking garage.
So, how did the audience hear the lower frequencies of an actor's voice if they were being suppressed with other background low frequencies? There's a simple answer, said Declercq. The human brain is capable of reconstructing the missing frequencies through a phenomenon called virtual pitch. Virtual pitch helps us appreciate the incomplete sound coming from small loudspeakers (in a laptop or a telephone), even though the low (bass) frequencies aren't generated by a small speaker.
The ancient Hellenes misunderstanding the role the limestone seats played in Epidaurus' acoustics likely kept them from being able to duplicate the effect. Later theatres included different bench and seat materials, including wood, which may have played a large role in the gradual abandonment of Epidaurus' design over the years by the Hellenes and Romans, Declercq said.
While many experts speculated on the possible causes for Epidaurus' acoustics, few guessed that the seats themselves were the secret of its acoustics success. There were theories that the site's wind--which blows primarily from the stage to the audience--was the cause, while others credited masks that may have acted as primitive loudspeakers or the rhythm of Greek speech. Other more technical theories took into account the slope of the seat rows.
When Declercq set out to solve the acoustic mystery, he too had the wrong idea about how Epidaurus carries performance sounds so well. He suspected that the corrugated, or ridged, material of the theater's limestone structure was acting as a filter for sound waves at certain frequencies, but he didn't anticipate how well it was controlling background noise.
"When I first tackled this problem, I thought that the effect of the splendid acoustics was due to surface waves climbing the theatre with almost no damping. While the voices of the performers were being carried, I didn't anticipate that the low frequencies of speech were also filtered out to some extent."
But as Declercq's team experimented with ultrasonic waves and numerical simulations of the theatre's acoustics, they discovered that frequencies up to 500 Hz were held back while frequencies above 500 Hz were allowed to ring out. The corrugated surface of the seats was creating an effect similar to the ridged acoustics padding on walls or insulation in a parking garage.
So, how did the audience hear the lower frequencies of an actor's voice if they were being suppressed with other background low frequencies? There's a simple answer, said Declercq. The human brain is capable of reconstructing the missing frequencies through a phenomenon called virtual pitch. Virtual pitch helps us appreciate the incomplete sound coming from small loudspeakers (in a laptop or a telephone), even though the low (bass) frequencies aren't generated by a small speaker.
The ancient Hellenes misunderstanding the role the limestone seats played in Epidaurus' acoustics likely kept them from being able to duplicate the effect. Later theatres included different bench and seat materials, including wood, which may have played a large role in the gradual abandonment of Epidaurus' design over the years by the Hellenes and Romans, Declercq said.
I've been to Epidaurus and the theatre is truly amazing. You can drop a coin in the centre and hear it up in the furthest rows. I would love to see a production of one of the Greek plays there or maybe the whole Orestia.
ReplyDelete