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According to newton second law of motion, the acceleration of an object equals the net force acting on the object divide by the object?
Javari Coburn
Mass.
Pamela McGlynn
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According to newton's second law of motion the acceleration of an object equals the net force acting on the object divided by the object's?
Newton's Second Law is usually written as:F = ma (Newton didn't write it like this, originally.) Solving for acceleration: a = F/m So, to get the acceleration, you divide the net force by the mass.
Mass x acceleration equals?
Force, according to Newton's second law.
When the cardboard is at rest how would you compare the magnitudes and directions of the pair of forces acting on it?
Since the cardboard is at rest we know that it is not experiencing any acceleration, hence, the net forces acting on it add up to zero (in magnitude and direction). Force equals mass times acceleration.
What if your weight equals your what A. Mass. B. Mass divided by the net force acting on you c. Mass times the acceleration due to gravity D. mass times your speed?
B. Mass divided by the net force acting on you
Force is equal to an object's acceleration multiplied by its?
F=ma Force equals its mass times its acceleration.
According to newton's second law of motion the acceleration of an object equals the net force acting on the object divided by the object's?
Newton's Second Law is usually written as:F = ma (Newton didn't write it like this, originally.) Solving for acceleration: a = F/m So, to get the acceleration, you divide the net force by the mass.
How are mass and acceleration related?
Newton's Second Law: force = mass x acceleration
How does force equals mass x acceleration apply to volleyball?
If the mass and acceleration of the volleyball are known, the force acting on it can be found using the above equation.
What is the relationship between and object's acceleration and the unbalanced force acting on it?
The acceleration plus other driving forces minus retarding forces equals the unbalanced force (force net.)
Mass x acceleration equals?
Force, according to Newton's second law.
That the unbalanced forcing acting on an object equals the object mass times its acceleration is?
yo mama. Ha Ha Ha Ha
When the cardboard is at rest how would you compare the magnitudes and directions of the pair of forces acting on it?
Since the cardboard is at rest we know that it is not experiencing any acceleration, hence, the net forces acting on it add up to zero (in magnitude and direction). Force equals mass times acceleration.
How do you find the acceleration for a moving object?
Divide the change in position, (total distance covered) by the time it took. Xf = xi +at a = xf-xi / t That is the definition of velocity, not acceleration. Acceleration is rate of change of velocity. (vfinal - vinitial)/t for constant acceleration so vf equals vi + at. Or a equals dV/dt otherwise.
When is acceleration equals half of the sum of initial and final velocities?
If you have a particle with constant acceleration, and you add the initial and final velocities and then divide them by two, what you get is the average velocity of the particle in that period of time.
How could you solve the following equation for mass F equals ma?
In the equation: F is force, m is mass, and a is acceleration. Divide both sides by a, and you have:m = F/a, which is Force divided by acceleration.
Are balanced forces acting on the earth?
Yes - the Sun's gravity acting on the Earth is exactly matched by the Earth's inward acceleration according to Newton's second law: force equals mass times acceleration. In this case the quantities are: Force = 3.542E22 Newtons Earth Mass = 5.976E24 kilograms Acceleration: 0.00593 metres/sec per second. Try it on your calculator. (In this answer E22 means 'times ten to the power twenty two' but a fault on answers.com prevents use of the correct notation.
What if your weight equals your what A. Mass. B. Mass divided by the net force acting on you c. Mass times the acceleration due to gravity D. mass times your speed?
B. Mass divided by the net force acting on you
