The mechanical tower clock originated in Europe during the 14th century to sound hourly bells and later display hands on a dial. An important innovation was the escapement mechanism, which converts stored energy into oscillatory motion for fixed time intervals through the pendulum swing. Previous work has modeled the escapement mechanism in terms of inelastic and elastic collisions. We derive and experimentally verify a theoretical model in terms of impulsive differential equations for the Graham escapement mechanism in a Seth Thomas tower clock. The model offers insight into the clock’s mechanical behavior and the functionality of the deadbeat escapement mechanism.
REFERENCES
1.
D.
Boorstin
, A History of Man’s Search to Know His World and Himself
(Random House
, New York
, 1983
).2.
A. L.
Rawlings
, The Science of Clocks and Watches
, 3rd ed. (British Horological Institute, Upton
, England,
1993
).3.
D.
Bernstein
, “Feedback control: An invisible thread in the history of technology
,” IEEE Control Syst. Mag.
22
(2
), 53
–68
(2002
).4.
M. V.
Headrick
, “Origin and evolution of the anchor clock escapement
,” IEEE Control Syst. Mag.
22
(2
), 41
–52
(2002
).5.
A. A.
Andronov
, A. A.
Vitt
, and S. E.
Khaikin
, Theory of Oscillators
, edited by W.
Fishwick
and translated by F.
Immirzi
(Addison-Wesley
, Reading, MA
, 1966
).6.
M.
Kesteven
, “On the mathematical theory of clock escapements
,” Am. J. Phys.
46
(2
), 125
–129
(1978
).7.
A.
Lepschy
, G.
Mian
, and U.
Viaro
, “Feedback control in ancient water and mechanical clocks
,” IEEE Trans. Educ.
35
(1
), 3
–10
(1992
).8.
A. V.
Roup
and D. S.
Bernstein
, “On the dynamics of the escapement mechanism of a mechanical clock
,” in Proceedings of the 38th Conference on Decision and Control
, IEEE Control System Society, Vol. 3, Phoenix, AZ, December 1999
, pp. 2599
–2604
.9.
10.
A. V.
Roup
, D. S.
Bernstein
, S. G.
Nersesov
, W. M.
Haddad
, and V.
Chellaboina
, “Limit cycle analysis of the verge and foliot clock escapement using impulsive differential equations and Poincare maps
,” Int. J. Control
76
(17
), 1685
–1698
(2003
).11.
12.
J.
Wagner
, C.
Huey
, K.
Knaub
, E.
Volk
, and A.
Jagarwal
, “Modeling and analysis of a weight driven mechanical tower clock
,” in Proceedings of the 2010 American Controls Conference
, Baltimore, MD, June 2010
, pp. 634
–639
.13.
14.
J.
Wagner
, D.
Moline
, and E.
Volk
, “Derivation of a Seth Thomas tower clock nonlinear mathematical model
,” Technical Report No. TR-2011-Wagner, <myweb.clemson.edu/jwagner/archive-data>.15.
P.
Reigel
, “A spring-driven No. 2? What did Seth have in mind?
,” NAWCC Bull.
353
, 797
–800
(2004
).16.
D. A.
Bateman
, “Accuracy of pendulums and many factors that influence it
,” NAWCC Bull.
290
, 300
–312
(1994
).17.
D. A.
Bateman
, “Pendulum timekeepers and the factors that determine their accuracy
,” Horological J.
132
, 83
–85
134
–135
164
–165
203
–204
(1989
).18.
Analog Devices, “ADXRS150 ±150°/s single chip yaw rate gyro with signal conditioning,” <www.analog.com/en/mems-sensors/mems-inertial-sensors/adxrs150/products/product.html>.
19.
Mumford Micro Systems, 3933 Antone Road, Santa Barbara, CA 93110.
© 2012 American Association of Physics Teachers.
2012
American Association of Physics Teachers
AAPT members receive access to the American Journal of Physics and The Physics Teacher as a member benefit. To learn more about this member benefit and becoming an AAPT member, visit the Joining AAPT page.