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When dealing with sound and its interaction with various objects in space, a resonant frequency of a wave is the natural frequency of vibration determined by the physical and chemical properties of said object.The existence of resonance in and of itself depends on the existence of natural frequencies. Objects often have multiple natural vibrating resonant frequencies, and it will pick out those frequencies from a series of excitations, making it an even more useful tool when identifying the properties of an object. | When dealing with sound and its interaction with various objects in space, a resonant frequency of a wave is the natural frequency of vibration determined by the physical and chemical properties of said object.The existence of resonance in and of itself depends on the existence of natural frequencies. Objects often have multiple natural vibrating resonant frequencies, and it will pick out those frequencies from a series of excitations, making it an even more useful tool when identifying the properties of an object. | ||
===History=== | ===History=== | ||
One of the most famous visible examples of resonance in history is the disaster at the Tacoma Narrows Bridge in 1940. This bridge, in Tacoma, Washington, spanned the Tacoma Narrows Strait, but it collapsed into the waters of Puget Sound on November 7, 1940 | One of the most famous visible examples of resonance in history is the disaster at the Tacoma Narrows Bridge in 1940. This bridge, in Tacoma, Washington, spanned the Tacoma Narrows Strait, but it collapsed into the waters of Puget Sound on November 7, 1940. [[File:Tacoma-narrows-bridge-collapse.jpg|thumb|This is the bridge during its collapse in 1940.]]This bridge had such a short lived existence due to resonance. Since its construction, workers observed vertical movement in the suspension bridge on windy days. This brought about the origin of the bridge's nickname: "Galloping Gertie". However, on a particularly windy day, the wind provided the bridge with a periodic vibrating frequency that matched the bridge's natural vibrational frequency, causing the bridge to become a massive oscillating standing wave. This intense oscillation proved too much for the structural integrity of the bridge, and it collapsed. No human lives were lost in the accident, but a black, male cocker spaniel named Tubby passed away from the incident. | ||
==Standing Waves== | ==Standing Waves== | ||
Studying resonance requires knowledge of what a standing wave is and how it behaves because resonance within objects have patterns of this nature. A standing wave is formed when a wave propagates through a medium and experiences both constructive and destructive interference with itself when reverberating off of a barrier. An important characteristic of a standing wave is that when the wave reaches a fixed barrier at the end of the propagation medium, it changes phase and travels in the reverse direction instead of continuing forward. In that, a change in phase means a 180 degree transformation in the period of the wave. This can be more easily understood when viewed in the visuals provided below. A standing wave also consists of nodes and antinodes. A node is the term used to describe a place where the medium does not move due to the vibration. On the other hand, an antinode is the point where the maximum displacement of the medium occurs due to the vibration of the wave. | |||
===A Visual Model Model=== | ===A Visual Model Model=== | ||
The concept of standing waves, nodes, and antinodes can be seen easily in these models. | |||
http://hyperphysics.phy-astr.gsu.edu/hbase/waves/imgwav/dispre2.gif | |||
===A Mathematical Model=== | ===A Mathematical Model=== |
Revision as of 17:56, 29 November 2015
Resonance
Resonance is the physical phenomenon in which a system vibrates in response to an applied frequency, but the external force of this frequency interacts with the object in such a way that it causes the system to oscillate with a maximum amplitude due to the specific frequency induced. This property applies to many fields of physics when studying the way an object behaves in certain situations.
Natural Frequencies
When dealing with sound and its interaction with various objects in space, a resonant frequency of a wave is the natural frequency of vibration determined by the physical and chemical properties of said object.The existence of resonance in and of itself depends on the existence of natural frequencies. Objects often have multiple natural vibrating resonant frequencies, and it will pick out those frequencies from a series of excitations, making it an even more useful tool when identifying the properties of an object.
History
One of the most famous visible examples of resonance in history is the disaster at the Tacoma Narrows Bridge in 1940. This bridge, in Tacoma, Washington, spanned the Tacoma Narrows Strait, but it collapsed into the waters of Puget Sound on November 7, 1940.
This bridge had such a short lived existence due to resonance. Since its construction, workers observed vertical movement in the suspension bridge on windy days. This brought about the origin of the bridge's nickname: "Galloping Gertie". However, on a particularly windy day, the wind provided the bridge with a periodic vibrating frequency that matched the bridge's natural vibrational frequency, causing the bridge to become a massive oscillating standing wave. This intense oscillation proved too much for the structural integrity of the bridge, and it collapsed. No human lives were lost in the accident, but a black, male cocker spaniel named Tubby passed away from the incident.
Standing Waves
Studying resonance requires knowledge of what a standing wave is and how it behaves because resonance within objects have patterns of this nature. A standing wave is formed when a wave propagates through a medium and experiences both constructive and destructive interference with itself when reverberating off of a barrier. An important characteristic of a standing wave is that when the wave reaches a fixed barrier at the end of the propagation medium, it changes phase and travels in the reverse direction instead of continuing forward. In that, a change in phase means a 180 degree transformation in the period of the wave. This can be more easily understood when viewed in the visuals provided below. A standing wave also consists of nodes and antinodes. A node is the term used to describe a place where the medium does not move due to the vibration. On the other hand, an antinode is the point where the maximum displacement of the medium occurs due to the vibration of the wave.
A Visual Model Model
The concept of standing waves, nodes, and antinodes can be seen easily in these models.
http://hyperphysics.phy-astr.gsu.edu/hbase/waves/imgwav/dispre2.gif
A Mathematical Model
Open Cylinder
Closed Cylinder
Applications
Strings
Tuning Forks
Connectedness
See also
Further reading
External links
References
https://www.grc.nasa.gov/www/k-12/airplane/thermo0.html http://hyperphysics.phy-astr.gsu.edu/hbase/thermo/thereq.html https://www.grc.nasa.gov/www/k-12/airplane/thermo2.html http://www.phys.nthu.edu.tw/~thschang/notes/GP21.pdf http://www.eoearth.org/view/article/153532/