What causes speed to speed to increase?

Answer 1

Presence of friction, incline and so on.

Answer 2

Mass does not increase as it approaches the speed of light. The interpretation is a reflection of errors in Einstein's Relativity Theory.

Consider the cyclotron the force is said to be f=qvxB = mv^2/R and the radial frequency is:

qvB=mv^2/R which gives qB/m=w the radial frequency.

In practice the cyclotron frequency is different w= qB/m sqrt(1 -(v/c)^2) this led to the conclusion that Einstein's mass increase was real m=m0/sqrt(1-(v/c)^2).

The real answer is that the mathematics is wrong. f=qvxB= qvBsin(x)= mv^2/R thus

w= (qB/m) sin(x).

where sin(x) = sqrt(1 -(v/c)^2).

Einstein's and Lorentz Relativity Factors Beta=v/c and Gamma= 1/sqrt(1 -(v/c)^2) are in reality the manifestation of Conservation of Energy and Equilibrium. Beta is the Redshift z=v/c=cos(x) and Gamma is 1/sin(x).

Simply put, the Total force F=qvB = -qv.B + qvxB = -qvBcos(x) + T qvBsin(x) where T is the unit vector transverse to the radial direction. Cos(x) =v/c reflects the radial component of force. This radial component is ignored in physics and sometimes claimed to be impossible. If v and B are not perpendicular, there is a scalar f=-qvBcos(x). Cos)x)= v/c is the Redshift of Hubble's measure and of the Quantum redshift and Fine Structure Constant.

Einstein's Relativity Theory needs revision, mass does not increase as it approaches the speed of light, the formula is incomplete and the Lorentz Factors are the fix and have been mis-interpreted. As the mass approaches the speed of light the cosine approaches z=v/c=cos(x)=1 and the sin(x) approaches zero so qvxB=qvBsin(x) goes to zero and qvBsin(x) = mwv gives w=(qB/m)sin(x) goes to zero not because of increased mass but because of the sin(x) going to zero as the angle goes to zero.

The scalar force -qvBcos(x) is a vibration force in parallel to the field. This is assumed to be impossible, e.g. no force parallel to the magnetic field. This is another mis-interpretation. Maxwell claimed that light was an electromagnetic field on the basis of the relationship E=cB or B=E/c. Thus if qv.E is real qv.B=qv.E/c = q(v/c).E is real.

Answer 3

when the speed of the object of mass nearly reaches the speed of light , its length will be smaller(the theory of special relativity) , and so its size in space ,which leads to an increasing of mass. the discreasment of length given by : L = L0 / (1 - v2/c2)^(0.5) . where v : the velocity of the object. c : the speed of light .

Answer 4

NO because mass is the space an objet takes up. weight changes from gravity! NO

Q: What about near speed of light? Khmmm