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String Article
by Bill Foley
One of
the never ending pleasures in life is the joy of playing your
guitar when it is sounding really good. What makes a guitar sound
really good is a complex issue, but it is a topic nonetheless
that can be analyzed, broken down into its constituent components,
and further analyzed.
One of the key constituent components of a good sounding guitar,
or any string instrument, is the user's choice of strings. This
is where things get interesting and fun.
The marketplace is a tangle of brands and constructions, so it
is helpful to have a rudimentary understanding of string behavior
to better interpret the manufacturers' accompanying claims.
Modern instrument strings are the culmination of many millennia
of intellectual advancements from a disparate group of innovators.
Prehistory hunters, classical philosophers, mathematicians and
physicists all have contributed to the contemporary body of knowledge
that governs the manufacture of today's strings.
Our most elementary experiences with musical string behavior stretch
back into the unwritten voids of prehistory. One would surmise
that anyone who had ever used a hunting bow would have noticed
a relationship between a tensioned string and musical pitch, but
when and where this event may have happened is a matter of conjecture.
The oldest archaeological evidence I have seen is a picture of
a drawing made circa 15,500 BC in the Magdalenian cave of Les
Trois Freres in southern France. This cave art shows what may
be interpreted to be a hunter using a musical bow. The musical
bow uses the mouth as a resonant chamber much like a jaw harp.
A hollow tortoise shell or a gourd could also be attached to the
bow to increase volume. The musical bow shows use of one length
of string with variable tensioning.
From 3000 BC onward the historic record (pottery, murals, written
records, etc.) shows use of differing string lengths and tensionings
in multi-string instruments. Harps, lyres, citharas and lutes
strung with gut and horsehair strings appeared at this time.
The first major advancement in the study of string behavior occurred
sometime during the lifetime of Pythagoras of Samos, who lived
from c.569 BC to c. 475 BC. Pythagoras' primary contribution to
civilization was the revolutionary concept of mathematical analysis.
Aristotle wrote that "the Pythagorean thought that things
are numbers, and that the whole cosmos is a scale and a number."
In other words, Pythagoras pioneered the abstraction of objects
into numbers.
Pythagoras' method of perpetuating his deeply held beliefs should
also be noted. In his time of many gods and great legends, passed
along by word of mouth, he chose to establish a religious school
to further his philosophy. Inspired by his studies in Egypt at
the temple of Diospolis (the only one who would accept him), he
structured his school into a society of a secretive inner circle
of "mathematikoi" and a not so exclusive outer circle
of' “acousmatics". He moved the school from Samos to
Croton in southern Italy c.518 BC.
After
his death, the schools expanded to other cities and split into
several factions. As is often the case with any new religion or
philosophy, the pre existing old schools can be less than welcoming
to any perception of competition. In 460 BC the meeting houses
were destroyed, between 50 and 60 Pythagoreans were killed in
Croton, and the survivors scattered to parts unknown. Truths tend
to endure fires and murders; Pythagoras' math and methods became
entrenched in civilization. When it comes to the power of word
of mouth, we who live now are not so unlike those who lived long
ago.
One of Pythagoras' experiments involved the study of differing
lengths of strings under differing tensions. He observed that
harmonic tones are produced when the ratios of differing lengths
of strings under equal tension are whole numbers. From this base
of knowledge he organized the first science derived Western musical
scale.
Pythagoras' main contribution to the understanding of string behavior
was the ability to use numbers to describe relationships between
string lengths, tensions, and pitches.
Though the art of mathematics and music progressed, fourteen centuries
elapsed before the next significant development in string evolution
occurred. Around 1100 AD, a Westphalian monk named Theophilus
wrote one of the earliest known descriptions of wire drawing.
The process involved hammering a metal bar into a long, thin rod,
then pulling the rod through iron dies to create wire.
By the
early 1300's wire drawing had become an important industry, and
within the next century iron and brass strings began to appear
on instruments. Wire strings not only were used on guitars, mandoras,
and bass lutes, but gave rise to a whole new family of string
instruments, which included zithers, citterns, the Irish harp,
psaltery, clavichord and others during the 15th and 16th centuries.
In 1588, lutenist and music theorist Vincenzo Galilei performed
experiments showing that the ratios of tensions of strings of
equal lengths tuned an octave apart is 4:1, disproving the accepted
notion that the ratio was 2:1. His methodology of using experiment
to try to answer theoretical questions was emulated by his more
renowned son, Galileo Galilei.
STRING CHOICE
In 1636 French mathematician Marin Mersenne (whose translations
were responsible for the spread of Galileo's works outside of
Italy) formulated three basic laws governing string motion:
1. When the string's density and tension remain constant, but
the string's length is varied, the string's musical pitch (frequency)
is proportional to its length. (This is Pythagoras' law restated.)
2. When the string's density and length remain constant, but its
tension is varied, the string's musical pitch is proportional
to the square root of its tension.
3. For different composition strings of constant length and tension,
the strings' musical pitches are proportional to the square root
of the weight (density) of the strings.
Mersenne proved simply that as tension is increased in the string,
the forces tending to pull the string back to its original position
are increased, and the motion of the string is proportionately
increased. Conversely, if the mass of the string is increased
and the same tension is applied, the motion of the string is proportionately
decreased.
In 1686 Isaac Newton described mathematically how sound travels
in his Principia, and in 1747, Jean d'Alembert derived the general
wave equation in his study of vibrating strings.
These studies describe the two fundamental types of wave motion:
longitudinal and transverse.
Longitudinal waves propagate through a medium by a series of compressions
and rarefactions of the particles of the medium. This spring like
motion is the primary mechanism by which the resonant character
of an instrument's parts (bridge, body, etc.) bounce back into
the string.
Transverse waves propagate through a medium by disturbing the
particles of the medium in a direction perpendicular to the direction
of the wave flow. The transverse wave is the waveform of primary
interest in the description of string behavior.
Idealized, each transverse wave starts from an equilibrium point
of no motion, moves up to a peak and is pulled back down to the
equilibrium point, overshoots the starting point by a distance
equivalent to its peak, and returns to the equilibrium point.
This is considered one complete cycle of the wave. The time required
for one complete cycle is called the period of the wave and is
represented by, t. The length covered from start to finish of
one cycle of a transverse wave is called the wavelength and is
represented by, ?. The number of cycles a wave completes in one
second is called frequency, and is represented by, f. The velocity
of a wave in a string is represented by, v, and can be defined
as
 (1.)
Combining Mersenne's second and third laws we can get a more string
specific definition of wave velocity, thus
 (2.)
Equation ( 2.) shows wave velocity as the product of the square
root of the string's tension, t, divided by the string's average
weight, or linear mass density, µ.
So, if we want to calculate any frequency a string will support,
we can combine equations (1.) and (2.), producing
 (3.)
If we simply want the fundamental, or first harmonic, of the open
string, equation (3.) becomes.
 (3.a.)
Since the length of vibrating string between the nut and saddle
is one half wavelength, the ? product becomes twice the length,
, of the open string.
Of special interest for us in equations (2.) and (3.) is the µ,
or mass density value of the string. We can see mathematically
that as the size of this quantity changes, so changes the wave
velocity and thus the frequencies at which the string can resonate.
Another step forward in string evolution occurred in 1834 when
Webster and Horsfall's of England made steel wire commercially
available. This year could be considered the inception date of
all contemporary steel string instruments.
In 1843 Georg Simon Ohm published a description of the way combination
tones are heard. His work needed some refinement, however, which
was undertaken by Hermann von Helmholz in 1862. Helmholz proved
that the tone of a musical pitch of a string is determined by
the proportions of the harmonics constituting the note. Helmholz
recommended the use of Joseph Fourier's ( 1768-1830 ) mathematical
analysis of curves to show that a vibrating string's motion is
the sum total of its component harmonic motions.
Their work can be used to illustrate the distribution of the energies
of the harmonic series on a vibrating string. On an ideal plucked
string ( other starting motions will produce different results
) , neglecting resonant contributions, where the fundamental frequency
would have an arbitrary value of 1, the second harmonic's value
would become 1/4 the third harmonic 1/9, the fourth harmonic 1/16,
the fifth harmonic 1/25, etc. The point along the length of the
string at which it is plucked will also determine which group
of harmonics is excited or damped to some degree.
The 1900's were a time of great technological advancement, especially
with the advent of the computer age at the end of the century.
As computers became entwined into the fabric of civilization,
string variety and availability reached unprecedented levels,
which is good news for all of us instrument players.
In the contemporary marketplace there are steel strings, nickel
plated steel strings, bronze plated steel strings, cryogenically
treated steel strings, gold plated steel strings, anodized steel
strings, plus nickel, bronze, phosphor bronze, copper, silver
plated copper, nylon, silk core, and many other constructions.
The linear mass density of each of these materials is different.
From this impressive assortment of materials , an equally impressive
variety of construction methods are in use, specifically in wound
strings. Thinner wound guitar strings are constructed from a wire
core with another length of wire wound around the core. To attain
any diameter string, the thickness of both pieces of wire can
be varied. A thinner core could be used with a thicker wrap and
vice-versa to create the same diameter string. The core wire is
also variable as to round or hex shaped. The wrap wire can be
round, ground to a smooth surface, burnished, roller-pressed to
a smooth surface, flat ribbon wound, plastic coated, etc. Thicker
wound strings can be built with two outer wraps using the above
methods. The termination of a thicker bass string can taper toward
the ball end or even leave the core exposed. All these factors,
of course, vary the µ value.
This variation in the linear mass density and the specific mechanical
manifestation of this density sets the conditions for the harmonic
grouping the string will be able to produce.
Enough analysis! Let's look at this same picture now through the
perspective of experimentation.
The following tables show some real life examples of different
types of strings tuned to musical pitch. The string types included
in the tests are GHS manufactured plain steel, wound steel ( Super
Steels™ ), wound nickel ( Nickel Rockers™ ), wound
nickel plated steel ( Boomers™ ), and wound alloy 52 ( B52™
). The tests show different gauges of strings tuned to standard
pitches, using the frequencies of equal temperament, on a scale
length of 25 inches. These tests were performed by assistant David
Ferbrache and myself in the fall of 2003. Special thanks go to
Elizabeth Randall and Ben Cole of GHS Strings for supplying the
test samples.
String Data - Click on the link below and save to your computer.
Nickel
Calculations 1
Steel
Calculations 1
NPS
Calculations 1
B52
Calculations 1
Note:Click on Tabs at bottom of each table to see different string
results.
The experimental data shows that the tension, as well as the intonation
points, will vary with different types of strings.
It can be concluded, then, that each type of string will have
a tone unique to its construction. This tone, when activated by
playing, will be the starting force for the inherent resonant
character of the instrument. The string's interaction with the
resonant character of the instrument will likewise be unique.
This brings us to the final part of string choice, and this is
where I will leave you on your own. The aural examination is the
test you will have to perform on your own instruments to discover
which unique voicing appeals the most powerfully to your own tastes.
My recommendation is try every construction and brand of string
that interests you; one type will generally stand out from the
crowd, but you won't know which one it is until you hear it. Keeping
a string journal for each instrument may be helpful, too. You
can record the type of string used, the playing conditions, your
observations, and any other relevant factors.
The best string will ultimately be the one that you like the best
on any particular instrument. It is not unusual to end up using
different strings on different guitars after extensive application
of the three E words: experiment, experiment, and experiment.
Have fun!
© Copyright 2004 GVM Publishing Columbus, Ohio USA
All rights reserved. No part of this article may be reproduced
or transmitted in any form or by any means, electronic or mechanical,
including photocopying, recording, or by any information storage
and retrieval system, without permission in writing from the publisher.
The Groove Tubes Rating System
A matched set of Groove Tubes will show a number between 1 - 10,
noting it's gain to distortion ratio.
1-3 Early distortion (wider range of distortion)
4-7 Normal distortion
8-10 Late distortion (more clean power/headroom)
Once you've biased your amp for your ideal tube rating number,
you will not have to rebias your amp the next time you changed
tubes provided you stay with the same tube and rating. the GT
rating system is so consistent, you can change tubes yourself
with complete confidence. Courtesy of Groove Tubes
© Copyright 2004 GVM Publishing Columbus, Ohio USA
All rights reserved. No part of this article may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying, recording, or by any information storage and retrieval system, without permission in writing from the publisher.
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