The momentum of an object is the product of its mass and its velocity.
p = mv
The equation is force multiplied by accelaratin
Momentum= Mass X Velocity
yes
momentum is described as mass times velocity. p=mv.
To determine whether a polynomial equation has imaginary solutions, you must first identify what type of equation it is. If it is a quadratic equation, you can use the quadratic formula to solve for the solutions. If the equation is a cubic or higher order polynomial, you can use the Rational Root Theorem to determine if there are any imaginary solutions. The Rational Root Theorem states that if a polynomial equation has rational solutions, they must be a factor of the constant term divided by a factor of the leading coefficient. If there are no rational solutions, then the equation has imaginary solutions. To use the Rational Root Theorem, first list out all the possible rational solutions. Then, plug each possible rational solution into the equation and see if it is a solution. If there are any solutions, then the equation has imaginary solutions. If not, then there are no imaginary solutions.
The equation is force multiplied by accelaratin
Momentum= Mass X Velocity
yes
momentum is described as mass times velocity. p=mv.
A way to designate momentum is using P. You can simply write Pi=Pf. If you have multiple particles, use P1i, P2i, etc.
Usually you would use some fact you know about the physical system, and then write an equation that states that the total angular momentum "before" = the total angular momentum "after" some event.
Use the Equation of State (EOS) in combination with the Antoine's Equation to determine vapor pressure.
the equation you would use would be Aa=2pq
using the t-table determine 3 solutions to this equation: y equals 2x
The idea is to use conservation of momentum. The momentum before the shot is fired is assumed to be zero, so write an equation that states that the momentum after the shot is zero, and solve it. The total momentum, of course, is the sum of the momentum of the two parts; for each part, the momentum is mass x velocity.
Use this formula:Final momentum = (initial momentum) + (change in momentum)
When there is no further use of derived class obect in execution sequence then It gets deleted. calling of distructor sequence is reverse of constructor calling sequence ,so first derived class obect deleted than base class obect.