Frequency and duration

Position and time

Mass and energy

Speed and distance

By amplifying the signal's amplitude

By viewing signals in terms of frequency strength

By converting signals into a series of sine waves

By measuring the intensity at each point in time

It becomes more concentrated

It becomes a constant value

It spreads out over a wide range of frequencies

It loses its frequency information

A change in the object's color

A change in the object's velocity

A change in the object's size

A change in the object's temperature

Matter is indestructible

Matter is made of energy

Matter has wave-like properties

Matter is composed of tiny particles

Momentum is the square of spatial frequency

Momentum is inversely proportional to spatial frequency

Momentum is unrelated to spatial frequency

Momentum is proportional to spatial frequency

It is a statement about randomness

It is a trade-off between wave concentration and frequency

It is a principle of classical mechanics

It is unrelated to quantum mechanics

The trade-off between wave concentration and frequency representation

The inability to measure sharp images

The sharpness of a musical note

The randomness of quantum particles

Mass and weight

Heat and temperature

Light and shadow

Sound and frequency

It is also concentrated

It is constant

It is non-existent

It is spread out