Talk:Kinematics: Difference between revisions
imported>Paul Wormer (→Definition: new section) |
imported>Peter Lyall Easthope (Reply to Paul Wormer) |
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I didn't know what a ''truss'' was. I checked it, and read that it is a stationary (non-moving) object. Are you sure that one can talk about the kinematics of a truss? (When a truss starts moving under influence of external forces, storms or earthquakes, I can see it, but that would be an exceptional situation). To me the science of a truss belongs to ''statics'' a different subfield of mechanics than ''kinematics''. --[[User:Paul Wormer|Paul Wormer]] 04:43, 3 May 2008 (CDT) | I didn't know what a ''truss'' was. I checked it, and read that it is a stationary (non-moving) object. Are you sure that one can talk about the kinematics of a truss? (When a truss starts moving under influence of external forces, storms or earthquakes, I can see it, but that would be an exceptional situation). To me the science of a truss belongs to ''statics'' a different subfield of mechanics than ''kinematics''. --[[User:Paul Wormer|Paul Wormer]] 04:43, 3 May 2008 (CDT) | ||
Hello Paul, | |||
I have several arguments. No offense intended! | |||
pw> I learned: kinematics is all that regards kinetic energy, | |||
which is why I added a brief clause. | |||
Where is that from? Is there a publication which mentions | |||
kinetic energy in reference to kinematics? | |||
According to the online OED, http://www.askoxford.com/, | |||
kinematics is "the branch of mechanics concerned with the | |||
motion of objects without reference to the forces which | |||
cause the motion." No mention of kinetic energy. Some | |||
sources mention <i>geometry</i>; more about that later. | |||
There is a critical problem in attempting to describe a | |||
trajectory by kinetic energy. Motion is inherently vectorial | |||
while energy is a scalar quantity. If the Universe were | |||
one dimensional, a motion of a point could be specified by | |||
a starting location and the kinetic energy as a function | |||
of time. In our universe that fails. | |||
In a more general sense, kinematics provides a means to | |||
describe a problem in mechanics, without presuming | |||
the solution. For example, we can say that at 3:00 pm | |||
the railcar is released from a siding at Yale and begins | |||
to roll down grade to Vancouver. Given the profile | |||
of the track, the frictions on the car and the assumption | |||
of no collision, what time does it reach Vancouver? The | |||
track profile and the concepts of position and speed of | |||
the car constitute the kinematics. No assumption about | |||
the actual speed as a function of position or time is | |||
in the kinematics. The full mechanical solution is the | |||
working out of the effect of gravity and frictions to | |||
produce a speed at each point and ulimately the | |||
calculation of elapsed time. | |||
pw> ... statics a different subfield of mechanics than kinematics. | |||
Statics/dynamics and kinematics/mechanics are orthogonal | |||
concepts. There is no parallelism between statics and | |||
kinematics. | |||
Statics is the particular case of dynamics where the | |||
subject is nearly stationary in the chosen frame of | |||
reference. "Nearly" because we know that even a | |||
static structure deforms as it is loaded. Of course | |||
deformations should be small in structures such | |||
as bridges and milling machines. | |||
Kinematics on the other hand, is not a special case | |||
of mechanics but is a fundamental part of it. | |||
pw> Are you sure that one can talk about the kinematics of a truss? | |||
Certainly! The kinematic description of a truss entails the | |||
configuration, dimensions and locations of loads. If a deformation | |||
analysis is called for, then deformations are also a part of the | |||
kinematics. Any static problem has a kinematic description | |||
just as well as a dynamic problem does. According to the | |||
Principle of Relativity, there is no reason to discriminate | |||
against a static problem. | |||
More about <i>geometry</i>.<br> | |||
Thermal mechanics involves temperture, which is not a | |||
geometrical concept. Electrical circuit theory involves | |||
circuit topology and currents but not geometry. By referring | |||
to the trajectory of the system, rather than its geometry, any | |||
theory of mechanics can have a kinematics. | |||
I can not agree with the sentence you have added. If you | |||
want to keep it there, I am happy to discuss further. An | |||
expert in formal axiomatic theories of mechanics might | |||
be able to add something more definite and convincing. | |||
I'm not really happy with my examples from thermal | |||
mechanics. They seem too indefinite. Suggestions for | |||
improvements are welcome, although I want to consider | |||
changes very carefully. | |||
Best Regards, [[User:Peter Lyall Easthope|Peter Lyall Easthope]] 11:18, 7 May 2008 (CDT) | |||
Revision as of 11:18, 7 May 2008
Definition
I learned: kinematics is all that regards kinetic energy, which is why I added a brief clause.
I didn't know what a truss was. I checked it, and read that it is a stationary (non-moving) object. Are you sure that one can talk about the kinematics of a truss? (When a truss starts moving under influence of external forces, storms or earthquakes, I can see it, but that would be an exceptional situation). To me the science of a truss belongs to statics a different subfield of mechanics than kinematics. --Paul Wormer 04:43, 3 May 2008 (CDT)
Hello Paul,
I have several arguments. No offense intended!
pw> I learned: kinematics is all that regards kinetic energy, which is why I added a brief clause.
Where is that from? Is there a publication which mentions kinetic energy in reference to kinematics?
According to the online OED, http://www.askoxford.com/, kinematics is "the branch of mechanics concerned with the motion of objects without reference to the forces which cause the motion." No mention of kinetic energy. Some sources mention geometry; more about that later.
There is a critical problem in attempting to describe a trajectory by kinetic energy. Motion is inherently vectorial while energy is a scalar quantity. If the Universe were one dimensional, a motion of a point could be specified by a starting location and the kinetic energy as a function of time. In our universe that fails.
In a more general sense, kinematics provides a means to describe a problem in mechanics, without presuming the solution. For example, we can say that at 3:00 pm the railcar is released from a siding at Yale and begins to roll down grade to Vancouver. Given the profile of the track, the frictions on the car and the assumption of no collision, what time does it reach Vancouver? The track profile and the concepts of position and speed of the car constitute the kinematics. No assumption about the actual speed as a function of position or time is in the kinematics. The full mechanical solution is the working out of the effect of gravity and frictions to produce a speed at each point and ulimately the calculation of elapsed time.
pw> ... statics a different subfield of mechanics than kinematics.
Statics/dynamics and kinematics/mechanics are orthogonal concepts. There is no parallelism between statics and kinematics.
Statics is the particular case of dynamics where the subject is nearly stationary in the chosen frame of reference. "Nearly" because we know that even a static structure deforms as it is loaded. Of course deformations should be small in structures such as bridges and milling machines.
Kinematics on the other hand, is not a special case of mechanics but is a fundamental part of it.
pw> Are you sure that one can talk about the kinematics of a truss?
Certainly! The kinematic description of a truss entails the configuration, dimensions and locations of loads. If a deformation analysis is called for, then deformations are also a part of the kinematics. Any static problem has a kinematic description just as well as a dynamic problem does. According to the Principle of Relativity, there is no reason to discriminate against a static problem.
More about geometry.
Thermal mechanics involves temperture, which is not a
geometrical concept. Electrical circuit theory involves
circuit topology and currents but not geometry. By referring
to the trajectory of the system, rather than its geometry, any
theory of mechanics can have a kinematics.
I can not agree with the sentence you have added. If you want to keep it there, I am happy to discuss further. An expert in formal axiomatic theories of mechanics might be able to add something more definite and convincing.
I'm not really happy with my examples from thermal mechanics. They seem too indefinite. Suggestions for improvements are welcome, although I want to consider changes very carefully.
Best Regards, Peter Lyall Easthope 11:18, 7 May 2008 (CDT)