Question

Increasing the applied force on an object affects its motion by causing it to accelerate or change its velocity. According to Newton's second law of motion, the acceleration of an object is directly proportional to the force applied to it and inversely proportional to its mass. This relationship is described by the equation F = ma, where F is the force applied, m is the mass of the object, and a is the acceleration produced.

If the force applied on an object is increased while keeping its mass constant, the object will experience a greater acceleration. This means that the object will move faster or change its direction more quickly. For example, if you push a shopping cart harder, it will accelerate more rapidly.

It is important to note that the effect of increasing the applied force also depends on other factors such as the frictional force acting on the object. If the force of friction remains constant or negligible, the object will continue to accelerate as long as the applied force exceeds the opposing forces. However, if the force of friction becomes significant, it will limit the object's acceleration and eventually reach a maximum speed known as terminal velocity.

In summary, increasing the applied force on an object generally leads to an increase in its acceleration, causing it to move faster or change its direction more rapidly, assuming other factors like friction remain constant.

In the context of the question, the variables can be defined as:

Independent variable: The independent variable is the force applied on the object. It is the variable that is purposely varied or manipulated by the experimenter. By changing the force applied, we can observe how it affects the object's motion.
Dependent variable: The dependent variable is the motion of the object. It is the variable that is measured or observed, and its value is affected by changes in the independent variable. In this case, the motion can be described by parameters such as acceleration, velocity, or position.
Control(s) or constant(s): Controls or constants are the variables that are kept constant during the experiment to ensure that any changes in the dependent variable are solely due to variations in the independent variable. In this scenario, examples of controls or constants can include the mass of the object, the surface on which the object is placed, or any other external forces such as friction or air resistance that can impact the object's motion. By maintaining these variables constant, the experimenter can isolate the effect of the independent variable on the dependent variable.

It is important to control the other variables to accurately determine the relationship between the applied force and the resulting motion of the object. This helps to ensure that any observed changes in the object's motion can be confidently attributed to changes in the applied force alone.

In the context of the specific experiment, the variables can be defined as:

Independent (Manipulated) Variable: The force applied on the object. It is the variable that is purposely varied or manipulated by the experimenter. By changing the force applied, we can observe its effect on the motion of the object.

Dependent (Responding) Variable: The motion of the object. It is the variable that is measured or observed, and its value is affected by changes in the independent variable. The motion can be described by parameters such as acceleration, velocity, or position.

Controls or Constants: The variables or factors that are kept constant during the experiment to ensure that any changes in the dependent variable are solely due to variations in the independent variable. Examples of controls or constants can include the mass of the object, the surface on which the object is placed, or any other external forces such as friction or air resistance that can impact the object's motion.