Sixteen Experimental Investigations from the Harvard Psychological Laboratory - Hugo Münsterberg (best life changing books txt) 📗
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these differing modes of expression embody are to be made the subject
of experimental investigation their characteristic structures should
be kept intact as objects of analysis in independent experiments,
instead of being combined (and modified) in a single process.
The apparatus employed in the course of the present investigation
consisted of four different pieces of mechanism, one affording the
vehicle of expression throughout the series of reproduced rhythms, the
others providing the auditory material of the various rhythms
apperceived but not designedly reproduced. The first of these
consisted of a shallow Marey tambour, placed horizontally upon a table
with its rubber film upwards, and connected by means of rubber-tubing
with a pneumographic pen in contact with the revolving drum of a
kymograph. A Deprez electric marker, aligned with the pneumographic
stylus, afforded a time record in quarter seconds. Upon this tambour,
placed within comfortable reach of the reactor’s hand, the various
rhythm types were beaten out. The impact of the finger-tip on the
tense surface of the drum gave forth a faint and pleasing but at the
same time clearly discernible and distinctly limited sound, which
responded with audible variations of intensity to the differing
stresses involved in the process of tapping, and which I have
considered preferable to the short, sharp stroke of the Kraepelin
mouth-key employed by Ebhardt. The rate of revolution in the drum was
so adjusted to the normal range of excursion in the pneumographic pen
as to give sharp definition to every change of direction in the curve,
which hence allowed of exact measurements of temporal and intensive
phases in the successive rhythm groups. These measurements were made
to limits of 1.0 mm. in the latter direction and of 0.5 mm. in the
former.[2]
[2] Professor Binet’s doubt (_L’Année Psychologique_ 1895, p.
204) that the propulsion of air from the elastic chamber and
the rebound of the pen might interfere with the significance of
the graphic record is more serious in connection with the
application of this method to piano playing than here; since
its imperfection, as that writer says, was due to the force and
extreme rapidity of the reactions in the former case. The
present series involved only light tapping and was carried on
at a much slower average rate.
The second piece of apparatus consisted of an ordinary metronome
adjusted to beat at rates of 60, 90, and 120 strokes per minute. This
instrument was used in a set of preliminary experiments designed to
test the capacity of the various subjects for keeping time by finger
reaction with a regular series of auditory stimulations.
The third piece of apparatus consisted of an arrangement for producing
a series of sounds and silences, variable at will in absolute rate, in
duration, and, within restricted limits, in intensity, by the
interruptions of an electrical current, into the circuit of which had
been introduced a telephone receiver and a rheostat. Portions of the
periphery of a thin metallic disc were cut away so as to leave at
accurately spaced intervals, larger or smaller extents of the original
boundary. This toothed wheel was then mounted on the driving-shaft of
an Elbs gravity motor and set in motion. Electrical connections and
interruptions were made by contact with the edge of a platinum slip
placed at an inclination to the disc’s tangent, and so as to bear
lightly on the passing teeth or surfaces. The changes in form of a
mercury globule, consequent on the adhesion of the liquid to the
passing teeth, made it impossible to use the latter medium. The
absolute rate of succession in the series of sounds was controlled by
varying the magnitudes of the driving weights and the resistance of
the governing fans of the motor. As the relation of sounds and
intervals for any disc was unalterable, a number of such wheels were
prepared corresponding to the various numerical groups and temporal
sequences examined—one, for example, having the relations expressed
in the musical symbol 3/4 | >q e |*; another having that represented in
the symbol 4/4 | >q e e |;* and so on. Variations in intensity were
obtained by mounting a second series of contacts on the same shaft and
in alignment with those already described. The number of these
secondary contacts was less than that of the primary connections,
their teeth corresponding to every second or third of those. The
connections made by these contacts were with a second loop, which also
contained within its circuit the telephone receiver by which the
sounds were produced. The rheostatic resistances introduced into this
second circuit were made to depart more or less from that of the
first, according as it was desired to introduce a greater or slighter
periodic accent into the series. This mechanism was designed for the
purpose of determining the characteristic sequences of long and short
elements in the rhythm group.
*Transcriber’s Note:
The original article showed “3/4 | q q q |” and “4/4 | q q q q |”.
Applying the erratum after the article (below) resulted in
fewer beats per measure than indicated by the time signature.
Other possibilities are “3/4 | >q e q. |” and “4/4 | >q e e q q |”.
“ERRATUM:
On page 313, line 23, the musical symbols should be a quarter
note, accented, followed by an eighth note; in the following
line the symbols should be a quarter note, accented, followed
by two eighth notes.”
The fourth piece of apparatus consisted essentially of a horizontal
steel shaft having rigidly attached to it a series of metallic
anvils, fifteen in number, on which, as the shaft revolved, the
members of a group of steel hammers could be made to fall in
succession from the same or different heights. The various parts of
the mechanism and their connections may be readily understood by
reference to the illustration in Plate VIII. On the right, supported
upon two metal standards and resting in doubly pivoted bearings,
appears the anvil-bearing shaft. On a series of shallow grooves cut
into this shaft are mounted loose brass collars, two of which are
visible on the hither end of the shaft. The anvils, the parts and
attachments of which are shown in the smaller objects lying on the
table at the base of the apparatus, consist of a cylinder of steel
partly immersed in a shallow brass cup and made fast to it by means of
a thumb-screw. This cup carries a threaded bolt, by which it may be
attached to the main shaft at any position on its circumference by
screwing through a hole drilled in the collar. The adjustment of the
anvils about the shaft may be changed in a moment by the simple
movement of loosening and tightening the thumb-screw constituted by
the anvil and its bolt. The device by which the extent of the
hammer-fall is controlled consists of cam-shaped sheets of thin wood
mounted within parallel grooves on opposite sides of the loose collars
and clamped to the anvils by the resistance of two wedge-shaped
flanges of metal carried on the anvil bolt and acting against the
sides of slots cut into the sheets of wood at opposite sides. The
periphery of these sheets of wood—as exhibited by that one lying
beside the loose anvils on the table—is in the form of a spiral which
unfolds in every case from a point on the uniform level of the anvils,
and which, by variations in the grade of ascent, rises in the course
of a revolution about its center to the different altitudes required
for the fall of the hammers. These heights were scaled in inches and
fractions, and the series employed in these experiments was as
follows: 1/8, 2/8, 3/8, 5/8, 7/8, 15/8, 24/8 inch. Upon a
corresponding pair of standards, seen at the left of the illustration,
is mounted a slender steel shaft bearing a series of sections of brass
tubing, on which, in rigid sockets, are carried the shafts of a set of
hammers corresponding in number and position to the anvils of the
main axis. By means of a second shaft borne upon two connected arms
and pivoted at the summit of the standards the whole group of hammers
may at any moment be raised from contact with the cams of the main
shaft and the series of sounds be brought to a close without
interrupting the action of the motor or of the remainder of the
apparatus. By this means phases of acceleration and retardation in the
series, due to initial increase in velocity and its final decrease as
the movement ceases, are avoided. The pairs of vertical guides which
appear on this gearing-shaft and enclose the handles of the several
hammers are designed to prevent injury to the insertions of the hammer
shafts in their sockets in case of accidental dislocations of the
heads in arranging the apparatus. This mechanism was driven by an
electrical motor with an interposed reducing gear.
[Illustration: PSYCHOLOGICAL REVIEW. MONOGRAPH SUPPLEMENT, 17. PLATE VIII.
Opposite p. 314.]
The intervals between the successive hammer-strokes are controlled in
the following way: on the inner face of the group of pulleys mounted
on the main shaft of the mechanism (this gang of pulleys appears at
the extreme right in the illustration) is made fast a protractor
scaled in half degrees. Upon the frame of the standard supporting
these pulleys is rigidly screwed an index of metal which passes
continuously over the face of the scale as the shaft revolves. The
points of attachment (about the shaft) of the cams are determined by
bringing the point of fall of each cam in succession into alignment
with this fixed index, after the shaft has been turned through the
desired arc of its revolution and made fast by means of the
thumb-screw seen in the illustration at the near end of the shaft.
Thus, if three strokes of uniform intensity are to be given at equal
intervals apart and in continuous succession, the points of fall of
the hammers will be adjusted at equal angular distances from one
another, for example, at 360°, 240°, and 120°; if the temporal
relations desired be in the ratios 2:1:1, the arrangement will be
360°, 180°, 90°; if in the ratios 5:4:3, it will be 360°, 210°, 90°;
and so on. If double this number of hammers be used in a continuous
series the angular distances between the points of fall of the
successive hammers will of course be one half of those given above,
and if nine, twelve, or fifteen hammers be used they will be
proportionately less.
An interruption of any desired relative length may be introduced
between repetitions of the series by restricting the distribution of
angular distances among the cams to the requisite fraction of the
whole revolution. Thus, if an interruption equal to the duration
included between the first and last hammer-falls of the series be
desired, the indices of position in the three cases described above
will become: 360°, 270°, 180°; 360°, 240°, 180°, and 360°, 260°, 180°.
In the case of series in which the heights of fall of the various
hammers are not uniform, a special adjustment must be superimposed
upon the method of distribution just described. The fall of the hammer
occupies an appreciable time, the duration of which varies with the
distance through which the hammer passes. The result, therefore, of an
adjustment of the cams on the basis adopted when the height of fall is
uniform for all would appear in a reduction of the interval following
the sound produced by a hammer falling from a greater height than the
rest, and the amount of this shortening would increase with every
addition to the distance through which the hammer must pass in its
fall. In these experiments such lags were corrected by determining
empirically the angular magnitude of the variation
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