Two. One for its location on the curve (which, because it is a curve, requires only a single piece of information) and another one for its speed along the curve. Its phase space is thus two-dimensional.
Number of independent coordinates that are required to describe the motion of a system is called degrees of freedom. In a system of N -particles, if there are k -equations of constraints, we have n  3N  k number of independent coordinates. n  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.
The state phase rule is:Number of freedom degrees in a system at equilibrium = Number of components in the system - Number of phases + 2
The number of protons equals the number of electrons.
an alpha particle
The position of the particle can be given by a number representing the distance of the particle from some fixed reference point (called the origin). This is not enough to describe the motion of the particle since for that you also required the time (or times) at which the particle is at any particular point.
The degrees of freedom for a chi-squarded test is k-1, where k equals the number of categories for the test.
Number all the structural degrees of freedom in your truss. In a 2D (planar) truss, each joint can have a maximum of two degrees of freedom: one in the global X-direction and one in the global Y -direction. If a degree of freedom is restrained by a reaction, then it doesn't get a number.
Number of independent coordinates that are required to describe the motion of a system is called degrees of freedom. In a system of N -particles, if there are k -equations of constraints, we have n  3N  k number of independent coordinates. n  degrees of freedom
degree of freedom is number of parameters required to specify the state of a particle. it can be used to calculate the energy of a system like in case of ideal gas equation.
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.
It is the value of a random variable which has a chi-square distribution with the appropriate number of degrees of freedom.
The degrees of freedom for any contingency table can be calculated simply by the formula (r-1)x(c-1) where r= the number of rows and c= the number of columns. Thus for a contingency table with four rows and four columns the degrees of freedom are 3x3 = 9.
The state phase rule is:Number of freedom degrees in a system at equilibrium = Number of components in the system - Number of phases + 2
when water vapour condense it again turns into water. In order to do so it must release heat; the enthalpy of condensation is the negative of the enthalpy of vaporization (i.e. going from liquid to gas).
The state phase rule is:Number of freedom degrees in a system at equilibrium = Number of components in the system - Number of phases + 2