A function is stretched vertically when its values are multiplied by a constant factor greater than 1, making it taller. It is compressed vertically when its values are multiplied by a constant factor between 0 and 1, making it shorter. Additionally, a function is stretched horizontally when the input values are divided by a constant factor greater than 1, making it narrower. It is compressed horizontally when the input values are divided by a constant factor between 0 and 1, making it wider.
Yes, you could say so. These cells appear to be square with a rounded surface when the organ or the tube in which they are found is not stretched. When the organ or tube is stretched (e.g. when the bladder is filled with urine), the tissue is compressed and the cells become stretched and more flat.
An example is sand on a beach stores the energy from the sun in it. A stretched spring has stored potential energy that is released when the spring is returned to its unstretched state.
compressed marble
The amount the spring is stretched is called the displacement.
Gas can be compressed easily because of space between them is big so then when compressed,the space between them get smaller. Liquid can be compressed but you can only compress it slightly since the particles are already touching Solid can't be compressed since their locked into place.
Elastic potential energy is stored in compressed or stretched objects. This type of energy is potential energy that is stored when an object is deformed (compressed or stretched) and has the potential to return to its original shape.
Elastic energy is the energy stored in an object when it is compressed, stretched, or deformed. It is a form of potential energy that can be released when the object returns to its original shape. Examples include a stretched rubber band or a compressed spring.
When a solid is stretched or compressed beyond the point that it can return to its original shape it has passed its elastic limit.
Yes. Objects can be stretched and compressed.
The work done by a spring when it is compressed or stretched is the energy stored in the spring due to the deformation. This energy is potential energy that can be released when the spring returns to its original shape.
Elastic energy is the energy stored in an object when it is compressed, stretched, or deformed. It is potential energy that can be released when the object returns to its original shape. Examples include a compressed spring or a stretched rubber band.
Yes.Yes.Yes.Yes.
When an object is stretched or compressed, it possesses potential energy due to the work done in deforming the object. This potential energy is stored within the object and is released when the object returns to its original shape.
Elastic potential energy. When a spring is compressed or a rubber band is stretched, work is done on the object to store potential energy that can be released when the object returns to its original shape.
Elastic Potential energy
Elastic potential energy is stored in a stretched spring. When the spring is compressed or stretched, it gains potential energy that can be released when the spring returns to its original shape.
The parameter that does not depend on how resistant a spring is to being compressed or stretched is its mass. Mass is an intrinsic property of an object that remains constant regardless of the material or design of the spring.