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Hei Tim<br>
<br>
I agree this is an interesting question, and also was on my mind when I
wrote my bit about vertical displacement of the string. Seems to me
that there are some self conflicting ideas being tossed around by some
folks.... and I've yet to get a clear idea of what is meant or not in
some instances.<br>
<br>
But this much seems clear to me because of my own looking into things.
Vertical displacement of the string in degrees enough to cause
significant pitch change form all but the highest part of the scale
has got to be nearly negligible as a factor in all this. <br>
<br>
On the other hand, the idea that a strings length changes by virture of
a change in offset angle through the bridge pins resulting from
climatic effects is interesting tho. And these length changes can
certainly account for significant pitch changes. But the problem I
have with this is that as explained it precepts the strings moving up
and down the bridge pins in response to the bridge surface pushing up
and retreating from the strings due to climatic changes. Three things
bother me about that :<br>
<br>
<blockquote>1: This comes from the same corner that has also
previoiusly demanded that strings do not move up and down the bridge
pins in the first place. That the friction of the pins will instead
cause crushing of the bridge cap.<br>
2: The amount of height change on the bridge pins needed to cause the
pitch change also changes downbearing pressure to a point where either
it pushes the limit of what a soundboard can actually hold up thereby
probably causing the panel to flaten a bit in response.<br>
3: The result of a bridge surface response to climate would be quite
even growth or shrinkage.. i.e. an even change in the offset angle and
and even increase in tension of the strings which will be directly
related to their length. In other words we'd see a very evenly
graduated curve of increase/decrease in pitch relating to the strings
length. And we dont see anything like this in the real world.<br>
</blockquote>
Still.. One DOES notice that seating strings results often enough in
very significant pitch drops... which could very easily be explained by
the resultant decrease in string offset angle through the bridge pins.
I like the idea myself... but it does have some head scratching bits
about it.<br>
<br>
As far as the surface of the bridge crushing.. This gets even more
complicated because this doenst happen evenly over the length of the
string on the bridge suface. At the edges, assuming the indentation
was deep enough to be significant... the middle would still be higher.
Strikes me that tho on the one hand you would be decreasing offset
angle by forceing the string into the indentation, you would on the
other hand be changing the distance the string has to travel over the
surface of the bridge by way of how well the strings horizontal path
conforms to its theoretical line of deflection. <br>
<br>
Cheers<br>
RicB<br>
<br>
<blockquote>I think Jeff Tanner asked a question that was interesting.
There was a lot of discussion about crushed bridge surface causing the
pitch to drop, but then the thread changed to wire stretch causing the
pitch to drop. I thought his question was: which is it? I don't
believe I've seen anyone answer his question yet.<br>
<br>
<br>
Tim Coates<br>
</blockquote>
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