The big secret of the great Italian masters is they made fiddles of a completely different construction than what they are today. Almost every one of these old fiddles has undergone major surgery to be able to play at modern concert pitch. Stradivari fiddles made the transition well. But a violin made by Stainer not so well even though the Stainer was evidently sought after for as a baroque instrument which is the era of music that all of these old fiddles were originally constructed to play.

Basically I think that most every testing technique has been in use since the 70's and the only thing that has really changed has been the quality of the graphic rendition of the results.. Things like CT scans etc. have been done as the resolution of those improves. All lot of these test can be done with a bare bones set up of a frequency counter and a lap top and the right microphones which is what I do in my home shop. But the masters could do the same thing with tapping, flexing the violin and blowing into the violin f holes. These research projects are usually interesting to read but after you have read enough of them you quickly see the repetition of themes and theories with them. Some seem valid and some seem totally wacky.

What is the basic new information in this article from a scientific standpoint? I think the major thing that sets golden era Italian violins apart is their approach to the design and construction.

Pre-19th century
Until the 19th century there was no concerted effort to standardize musical pitch, and the levels across Europe varied widely. Pitches did not just vary from place to place, or over time—pitch levels could vary even within the same city. The pitch used for an English cathedral organ in the 17th century, for example, could be as much as five semitones lower than that used for a domestic keyboard instrument in the same city.
Even within one church, the pitch used could vary over time because of the way organs were tuned. Generally, the end of an organ pipe would be hammered inwards to a cone, or flared outwards, to raise or lower the pitch. When the pipe ends became frayed by this constant process they were all trimmed down, thus raising the overall pitch of the organ.

Some idea of the variance in pitches can be gained by examining old pitchpipes, organ pipes and other sources. For example, an English pitchpipe from 1720 plays the A above middle C at 380 Hz, while the organs played by Johann Sebastian Bach in Hamburg, Leipzig and Weimar were pitched at A = 480 Hz, a difference of around four semitones. In other words, the A produced by the 1720 pitchpipe would have been at the same frequency as the F on one of Bach's organs.

From the early 18th century, pitch could be also controlled with the use of tuning forks (invented in 1711), although again there was variation. For example, a tuning fork associated with Handel, dating from 1740, is pitched at A = 422.5 Hz, while a later one from 1780 is pitched at A = 409 Hz, almost a semitone lower. Nonetheless, there was a tendency towards the end of the 18th century for the frequency of the A above middle C to be in the range of 400 to 450 Hz.

The frequencies quoted here are based on modern measurements and would not have been precisely known to musicians of the day. Although Mersenne had made a rough determination of sound frequencies as early as the 1600s, such measurements did not become scientifically accurate until the 19th century, beginning with the work of German physicist Johann Scheibler in the 1830s. The unit hertz (Hz), replacing cycles per second (cps), was not introduced until the twentieth century.