Mass and damping are associated with the motion of a dynamic system. Degrees-of-freedom with mass or damping are often called dynamic degrees-of-freedom; degrees-of-freedom with stiffness are called static degrees-of-freedom. It is possible (and often desirable) in models of complex systems to have fewer dynamic degrees-of-freedom than static degrees-of-freedom.
please help me search about different scientist other than lakoff and johnsons' theory and examples of emotion metaphor as orientational
By degrees of freedom, I believe you meant dimensions. Everything in this universe has 3 degrees of freedom.
A tri-atomic molecule should have 3 vibrational degrees of freedom (one for each "end" atom vibrating on its bond with the central atom and one for the flexing of the bonds like scissors opening and closing). If it is non-linear, it should also have a three rotational degrees of freedom. All molecules (including a triatomic one) will have 3 degrees of freedom for translational motion. All totaled, it will have 3+3+3 = 9 degrees of freedom. Note that this does not address the question of independence of the degrees of freedom - for example - if the two "end" atoms are identical, not all the rotational degrees of freedom are independent.
An orientational metaphor is a figure of speech that uses spatial relationships or directions to convey abstract ideas or emotions. For example, phrases like "seeing things from a new perspective" or "feeling lost in life" are examples of orientational metaphors that use spatial terms to describe inner experiences.
A scara robot uaually have 4 degrees of freedom
The knee has 2 degrees of freedom. Flexion/Extension and varus/valgus rotation.
A rigid object has up to 6 degrees of freedom: 3 degrees of freedom of location: In both directions of x,y,z axis 3 degrees of freedom of rotation (attitude): pitch, roll, and yaw, rotation about the x,y,z axis.
How many degrees of freedom does any unconstrained object have in 3D modeling
Diatomic gases have more degrees of freedom. They are also larger in size and mass. specific heat is proportional to the number of degrees of freedom; monatomic gases can only move linearly and have 3 degrees of freedom, molecules can also rotate and vibrate, so have more degrees of freedom.
Diatomic gases have more degrees of freedom. They are also larger in size and mass. specific heat is proportional to the number of degrees of freedom; monatomic gases can only move linearly and have 3 degrees of freedom, molecules can also rotate and vibrate, so have more degrees of freedom.
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