mc2 could mean many things, but I assume you are talking about Einstein's famous equation E=mc2. I won't even pretend to know all the information behind this equation, but my understanding is that it basically calculates the amount of energy that could be spontaneously created by any mass. In the equation, E=mc2 E = Energy M = Mass C = Speed of Light (or 299,792,458 meters/second)
I'm pretty sure the answer is: C= de3k/ √m (C equals d times e cubed times k, divided by the square root of m).
C = k*a*d*e^3/sqrt(m) where k is a constant.
70 m x 30 m = 2100 m^(2)
M2
The integral of cot (x) dx is ln (absolute value (sin (x))) + C. Without using the absolute value, you can use the square root of the square, i.e. ln (square root (sin2x)) + C
I'm pretty sure the answer is: C= de3k/ √m (C equals d times e cubed times k, divided by the square root of m).
pie = m c square
It would be the year of production. M represents 1000 and C represents 100. This would translate to 1900.
C = k*a*d*e^3/sqrt(m) where k is a constant.
In the equation E=M times C squared, the C stands for the speed of light. C can also mean 100, just as K can mean 1,000. C can also mean Centigrade
10 Centuries in a Millenium
(Y)Young(M) money (C)cash (M)money (B) billionaire.
e=energy m=mass c=square speed of light
This call girl let's you C*m On Body!
C)heck Y)a D)irect M)essages
61 Dialling Code of Melbourne (Australia)
A set of numbers will have a mean, which is defined as the sum of all the values divided by the number of values. Suppose this mean is m. For each of the values, the squared deviation is the square of the difference between that value and m. Algebraicly, if you have a set {x1, x2, x3, ... , xn}, whose mean is m, then the squared deviation from the mean for x1 is (x1 - m)2.