-
Not Synced
Gripped with vengeful passion,
-
Not Synced
The Queen of the Night tears
across the stage.
-
Not Synced
She begins to sing her titular aria,
-
Not Synced
one of the most famous sections from
Mozart’s beloved opera, The Magic Flute.
-
Not Synced
The orchestra fills the hall with music,
-
Not Synced
but the queen’s voice soars above
the instruments.
-
Not Synced
Its melody rings out across thousands
of patrons,
-
Not Synced
reaching seats 40 meters away— all
without any assistance from a microphone.
-
Not Synced
How is it possible that this single voice
can be heard so clearly,
-
Not Synced
above the strains of dozens
of instruments?
-
Not Synced
The answer lies in the physics of the
human voice,
-
Not Synced
and the carefully honed technique
of an expert opera singer.
-
Not Synced
All the music in this opera house
originates from the vibrations
-
Not Synced
created by instruments—
-
Not Synced
whether it’s the strings of a violin
or the vocal folds of a performer.
-
Not Synced
These vibrations send waves into the air,
which our brains interpret as sound.
-
Not Synced
The frequency of these vibrations––
-
Not Synced
specifically, the number of
waves per second––
-
Not Synced
is how our brains determine the
pitch of a single note.
-
Not Synced
But in fact, every note we hear
-
Not Synced
is actually a combination
of multiple vibrations.
-
Not Synced
Imagine a guitar string vibrating at its
lowest frequency.
-
Not Synced
This is called the fundamental,
-
Not Synced
and this low pitch is what our ears
mostly use to identify a note.
-
Not Synced
But this lowest vibration triggers
additional frequencies called overtones,
-
Not Synced
which layer on top of the fundamental.
-
Not Synced
These overtones break down into specific
frequencies called harmonics, or partials–
-
Not Synced
and manipulating them is how
opera singers work their magic.
-
Not Synced
Every note has a set of frequencies that
comprise its harmonic series.
-
Not Synced
The first partial vibrates at twice the
frequency of the fundamental.
-
Not Synced
The next partial is three times the
fundamental’s frequency, and so on.
-
Not Synced
Virtually all acoustic instruments
produce harmonic series,
-
Not Synced
but each instrument’s shape and material
changes the balance of its harmonics.
-
Not Synced
For example, a flute emphasizes the
first few partials,
-
Not Synced
but in a clarinet’s lowest register,
-
Not Synced
the odd-numbered partials
resonate most strongly.
-
Not Synced
The strength of various partials
-
Not Synced
is part of what gives each instrument
its unique sonic signature.
-
Not Synced
It also affects an instrument’s ability
to stand out in a crowd,
-
Not Synced
because our ears are more strongly
attuned to some frequencies than others.
-
Not Synced
This is the key to an opera singer’s power
of projection.
-
Not Synced
An operatic soprano— the highest
of the four standard voice parts—
-
Not Synced
can produce notes with fundamental
frequencies
-
Not Synced
ranging from 250 to 1,500 vibrations
per second.
-
Not Synced
Human ears are most sensitive to
frequencies
-
Not Synced
between 2,000 and 5,000
vibrations per second.
-
Not Synced
So if the singer can bring out the partials
in this range,
-
Not Synced
she can target a sensory sweet spot
where she’s most likely to be heard.
-
Not Synced
Higher partials are also advantageous
-
Not Synced
because there’s less competition
from the orchestra,
-
Not Synced
whose overtones are weaker at
those frequencies.
-
Not Synced
The result of emphasizing these
partials
-
Not Synced
is a distinctive ringing timbre
called a singer’s squillo.
-
Not Synced
Opera singers work for decades to
create their squillo.
-
Not Synced
They can produce higher frequencies
-
Not Synced
by modifying the shape and tension
in their vocal folds and vocal tract.
-
Not Synced
And by shifting the position of their
tongues and lips,
-
Not Synced
they accentuate some overtones
while dampening others.
-
Not Synced
Singers also increase their range of
partials with vibrato––
-
Not Synced
a musical effect in which a note slightly
oscillates in pitch.
-
Not Synced
This creates a fuller sound that rings
out
-
Not Synced
over the instruments’ comparatively
narrow vibratos.
-
Not Synced
Once they have the right partials,
-
Not Synced
they employ other techniques to
boost their volume.
-
Not Synced
Singers expand their lung capacity and
perfect their posture
-
Not Synced
for consistent, controlled airflow.
-
Not Synced
The concert hall helps as well,
-
Not Synced
with rigid surfaces that reflect sound
waves towards the audience.
-
Not Synced
All singers take advantage of these
techniques,
-
Not Synced
but different vocal signatures demand
different physical preparation.
-
Not Synced
A Wagnerian singer needs to build up
stamina
-
Not Synced
to power through the composer’s
four-hour epics.
-
Not Synced
While bel canto singers require versatile
vocal folds
-
Not Synced
to vault through acrobatic arias.
-
Not Synced
Biology also sets some limits—
-
Not Synced
not every technique is feasible for every
set of muscles,
-
Not Synced
and voices change as singers age.
-
Not Synced
But whether in an opera hall or a
shower stall,
-
Not Synced
these techniques can turn unamplified
voices
-
Not Synced
into thundering musical masterpieces.
closed TED
