Wood testing and voicing

Click to enlarge photos.   Click on the enlargement to magnify them.

Obviously a great many very good guitars have been made, and are still being made, without the aid of computers and audio analysis equipment. I have a lot of respect for “intuitive” builders who have developed their sensitivities to the point that they can tell, by flexing and tapping, when a soundboard is the right thickness, or when a brace is shaved down to the right height. I came under the influence of engineers at a tender age, and it works for me to use an engineering approach to selecting wood and voicing the instrument. This is not science as I was taught to practice it. There is neither time nor money for that. I use obsolete equipment, donated by friends, some shop built equipment, and one good software program to test my wood for it's acoustic properties, and to check my backs and soundboards as I move through the various stages of construction. But make no mistake ~ it's the thrill that the player gets from playing an instrument that is the measure of  the success of any method of   guitar construction. I'm looking for that exciting sound and responsiveness in a guitar that makes me want to keep on playing it. It's what master luthier Jeff  Elliot calls "allure", and there is no need for any test equipment to measure it. Flamenco is a very intuitive art, and all thoughts of a resonance's position in the audio spectrum go away, as soon as my thumb hits the sixth string.

Experimental guitar under test in my shop in Claremont in 1964

Guitar getting final resonance check before the back goes on ~ 2005

My "voicing form" replicates the interior cavity of the sound box, and allows me to clamp a top and/or back for resonance testing.

Soundboard without braces gets its initial resonance test on the voicing form. This is the point where I decide on the thickness.

Back having the height of its braces checked. This mode is called the "long tripole"

Print-out of "response curves" from Spectra Plus, a wonderful audio analysis program that works on my PC. I use this program for testing backs and soundboards by themselves, as well as partially assembled and finished instruments. It really points out the subtleties. These graphs compare the main resonance locations before and after shaving the back braces. The range covered in this graph is from just below the open 6th string to about the 14th fret of the first string. The program will display as much, or as little, of the audio spectrum as you want to see.

Wood testing ~ click to enlarge photos. Click on the enlargement to magnify them.

To say that I'm fussy about the wood that I use is to really understate the case. I test all my backs and soundboards for long grain and cross grain stiffness, density, and internal damping (Q). I've accumulated a lot of data over the years, and I'll only use wood that meets my specifications for excellence. There is some good evidence that, for nylon string guitars, tone quality is really dependent on wood quality, particularly for getting great treble. If you're interested in wood testing, contact me, and I'll send you the handout from my talks at the Healdsburg Guitar Festivals.

Deflection testing for measuring stiffness

Testing the "Q" of a soundboard ~ a measure of its sound damping characteristics. This gives an index to how efficient this piece of wood will be at turning string energy into sound, instead of heat. Higher Q numbers mean higher efficiency.

Typical wood test data sheet. The things that really seem to matter are stiffness to density ratios, and Q (internal damping). The Q value provides an accurate measure of how long the tap-tone lasts. Higher Q numbers mean longer sustain, and greater volume.

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