No, the TOTAL energy of an object is the sum of its potential energy, kinetic energy, thermal energy, electrical energy and its inherent energy - inherent energy is given by Einstein's famous formula.
Speed is directly proportional to energy in case of Einstein equation.
Energy is the capacity of a body to do work. Mass and energy are directly proportional according to Einstein's famous equation, E=mc^2.
How did scientists apply albert einsteins equation e equals mc2?"
Tension is directly proportional to extension. Force = k x extension
Mass and force are directly proportional, therefore: more mass = greater force (Equation: F = ma). Mass and speed are inversely proportional, so: more mass = lesser speed (Equation: p = mv).
According to the equation [ y = 2x ], 'y' is directly proportional to 'x' .
Speed is directly proportional to energy in case of Einstein equation.
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Energy is the capacity of a body to do work. Mass and energy are directly proportional according to Einstein's famous equation, E=mc^2.
How did scientists apply albert einsteins equation e equals mc2?"
No. Although this an equation of a straight line and y increases when x increases, a directly proportional equation has y/x = constant. So if b is zero it is in direct proportion, but not if b is non zero
If a variable (such as y) is directly proportional to another variable (such as x), they both increase and decrease simultaneously. An equation for two directly proportional variables is:y = axIt's sort of like a linear equation, but it always goes through the origin.An example is y = 6x. Notice that it forms a straight line and crosses the origin, and that y and x increase in the same direction.
Tension is directly proportional to extension. Force = k x extension
No.A directly proportional graph has an equation of the form y = mx. It always passes through the origin.A linear graph will have an equation in the from y = mx + c. This has a y-intercept at (0, c). It doesn't pass through the origin unless c = 0. The directly proportional graph is a special case of a linear graph.
The change in energy represented by a thermochemical equation is directly proportional to the number of moles in substances undergoing a change.
To say that an equation is directly proportional is somewhat incorrect. What we say instead is that a variable on one side of the equation (in other words, on one side of the equals sign) is directly proportional to another variable on the other side.What this means is that if when one variable increases (gets bigger), the other one does, too, then these variables are directly proportional to each other.For example, take the equation for velocity.v = d/tHere, v is velocity, d is distance, and tis time. Lets try a few numbers.v = 100 miles/2 hours = 50mi/hr.v = 200 miles/2 hours = 100mi/hr.v = 400 miles/2 hours = 200mi/hr.What you may notice here is that as the value of d (the number of miles being traveled), gets bigger, so does the value of v (velocity, or speed, in miles/hour). This is because, in this equation, velocity is directly proportional to distance.
P(watt)=energy/time. Where power in measure in watt directly proportional to energy(work) and inversely proportional to time in seconds. 1W = .001kW