Well, honey, without knowing the force acting on that mass, you can't calculate acceleration. It's like trying to bake a cake with just flour and no recipe - you're missing a crucial ingredient. So, unless you have the force thrown into the mix, you're out of luck in finding that acceleration.
To find the acceleration of a mass, you can use the equation a = F/m, where a is the acceleration, F is the force acting on the mass, and m is the mass. Alternatively, if the mass is subject to gravity only, you can use the equation a = g, where g is the acceleration due to gravity (approximately 9.8 m/s^2).
To find the acceleration of the box, you need to know its mass. Using Newton's second law (F=ma), where F is the net force of 41N and m is the mass of the box, you can solve for acceleration. Given only the force of 41N, the acceleration cannot be determined without the mass of the box.
To calculate force when given speed, you would need to know the mass of the object. The equation that relates force, speed, and mass is F = m*a, where F is the force, m is the mass, and a is the acceleration (change in speed over time). Without knowing the mass or acceleration, it is not possible to calculate the force.
To find the magnitude of a force, you can use the equation F = ma, where F is the force, m is the mass, and a is the acceleration. By multiplying the mass and the acceleration, you can determine the magnitude of the force acting on an object.
Newton is a unit of force, not a measurement that can be directly calculated from mass. However, you can calculate weight by multiplying the mass in kilograms by the acceleration due to gravity (9.81 m/s^2 on Earth). Weight is a force measured in newtons.
You can't. Acceleration is change in velocity. If given a constant velocity, the acceleration is zero.
Acceleration = force(N) / mass(kg)
You cannot is you only know the acceleration
To find the acceleration of a mass, you can use the equation a = F/m, where a is the acceleration, F is the force acting on the mass, and m is the mass. Alternatively, if the mass is subject to gravity only, you can use the equation a = g, where g is the acceleration due to gravity (approximately 9.8 m/s^2).
If you are talking about problems involving Newton's second law of motion, F = ma, you would need to define two of the three variables of force, mass, and acceleration in order to find the third variable. If you have force and mass, you can find acceleration. If you have force and acceleration, you can find mass. If you have mass and acceleration you can find force.
-- In a reference book or on-line, look up the acceleration of gravity on the surface of that planet. -- Multiply the mass of the object by the acceleration of gravity in the place where the object is. The result is the object's weight in that place.
You can't; you don't have enough information. The two masses need not be in any specific relation therefore you can't calculate the second mass based on the first mass. Unless you have the acceleration and the total force.
To find the acceleration of the box, you need to know its mass. Using Newton's second law (F=ma), where F is the net force of 41N and m is the mass of the box, you can solve for acceleration. Given only the force of 41N, the acceleration cannot be determined without the mass of the box.
Weight = (mass) x (local acceleration of gravity). Mass = (weight) / (local acceleration of gravity) If you know the weight and the local acceleration of gravity, you can calculate the mass. Anywhere on or near the surface of the earth, the local acceleration of gravity is about 9.82 meters per second2 . As an example, an object with a weight of 9.82 newtons has a mass of one kilogram.
To get the potential energy when only the mass and velocity time has been given, simply multiply mass and the velocity time given.
It's not possible.
you weigh the water