# What is a wave described by?

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## Top best answers to the question «What is a wave described by»

- A wave can be described as a
**disturbance that travels through a medium from one location to another location**. Consider a slinky wave as an example of a wave. When the slinky is stretched from end to end and is held at rest, it assumes a natural position known as the equilibrium or rest position.

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Those who are looking for an answer to the question «What is a wave described by?» often ask the following questions:

### 👋 What can a wave be described as?

- A wave can be described as an
**energy disturbance that travels through a medium from one location to another**. Waves, simply put, are energy moving from one place to another. As the wave moves through the medium (water, slinky , air), energy is being passed from one particle to the next.

- A sound wave is described by?
- A wave can be described as?
- Electromagnetic waves are described as what type of wave?

### 👋 What is light described by the wave model?

Light as a wave: Light can be described (modeled) as **an electromagnetic wave**. In this model, a changing electric field creates a changing magnetic field. This changing magnetic field then creates a changing electric field and BOOM - you have light.

- What is described by the frequency of a wave?
- What is the motion of a wave described as?
- What is the second wave that alvin toffler described?

### 👋 A sinusoidal wave is described by?

The sinusoidal wave is the **simplest type of transverse curve**. The curve of a sinusoidal wave is the mathematical curve that describes a smooth periodic motion of the oscillation…

- What is the speed of the wave described by?
- A sinusoidal wave train is described by?
- How is light described as a wave?

1 other answer

Speed, direction, transverse or longitudinal, frequency and amplitude.

We've handpicked 24 related questions for you, similar to «What is a wave described by?» so you can surely find the answer!

Is are described as slow wave sleep?Slow-wave sleep (SWS), often referred to as **deep sleep**, consists of stage three of non-rapid eye movement sleep. Initially, SWS consisted of both Stage 3, which has 20–50 percent delta wave activity, and Stage 4, which has more than 50 percent delta wave activity.

**Christian Huygens**, who was a contemporary of Isaac Newton, suggested that light travels in waves. Isaac Newton, however, thought that light was compsed of particles that were too small to detect individually. In 1801 a physicist in England, Thomas Young, performed an experiment that showed that light behaves as a wave.

- The physical characteristics of sound waves influence the three psychological features of sound:
**loudness, pitch, and timbre**. Loudness depends on the amplitude,or height, of sound waves. The greater the amplitude, the louder the sound perceived. Amplitude is measured in decibels.

Light behaves as a wave - **it undergoes reflection, refraction, and diffraction** just like any wave would.

- This is the sound
**wave**described by a**sine**function with f = 220 oscillations per second. Problems playing this file? See media help. The oscillation of an undamped spring-mass system around the equilibrium is a**sine wave**.

The distance from one wave peak to the next wave peak

Question: A certain transverse wave is described by y**(x,t)=Bcos**[2π(xL−tτ)], where B = 5.20 mm , L = 25.0 cm , and τ = 3.60×10−2 s Part A Determine the wave's amplitude.

**The wave function**of**a particle**, at**a**particular time, contains all**the**information that anybody at that time can have about**the particle**. But the wave function itself has no physical interpretation. It**is**not measurable.

- A sinusoidal sound wave moves through a medium and is described by the
**displacement wave function s (x, t) = 2.00 cos (15.7 x − 858 t)**where s is in micrometers, x is in meters, and t is in seconds.

- Electrons may be described using a wave function. The wave function's symbol is the Greek letter psi, Ψ or ψ . The wave function Ψ is a mathematical expression. It carries crucial information about the electron it is associated with: from the wave function we obtain the electron's energy, angular momentum,...

- All
**wave**characteristics can be described by a small set of underlying principles. A**wave**is a disturbance that propagates, or moves from the place it was created. The simplest waves repeat themselves for several cycles and are associated with simple harmonic motion. Let us start by considering the simplified water wave in Figure 2.

- Wave Properties. Amplitude is the maximum displacement (change in position) from the undisturbed position. Wavelength (λ) is the distance in metres from any point on the wave to an exactly similar point. Frequency is the number of waves that pass a point in one second. This depends on how fast the source of the waves is vibrating.

- All matter has intrinsic wave properties. These are described mathematically by the Schrödinger Equations and it's solutions. The wavenature of electrons and other fundamental principles (eg charge and momentum) together produce the wave mechanics of electron.

- When waves encounter new mediums, barriers, or other waves they can behave in different ways. In physics these behaviors are described using some of the terms below. The word "reflection"
**is**used in everyday life to describe**what**we see in a mirror or on the surface of the water.

- A
**wave**can be described as a disturbance that travels from one location**to**another location. If the first coil**of**the**slinky**is given a single back-and-forth vibration, then we call the observed motion of the disturbance through the slinky a pulse. A pulse is a single disturbance moving through a medium from one location to another location.

**The**compression**of the wave**at any point along**the**string can be described by**a**scalar quantity. Particle motion is parallel to**the**direction**of**travel**of the wave**. 2. Transverse waves (vector).**The**motion**of**particles in a transverse**wave**is perpendicular to the direction of travel of the wave.

- Frequency refers to how many waves are made per time interval. This
**is**usually described as how many waves are made per second, or as cycles per second.**The following**interactive diagram lets you adjust**the**frequency**of the wave**train.

As is shown on the figure, wave height is defined as the height of the wave from the wave top, called the wave crest to the bottom of the wave, called the wave trough. The wave length is defined as **the horizontal distance between two successive crests or troughs**.

Question: A sinusoidal sound wave moves through a medium and is described by the displacement wave **function s(x, t) = 2.13 cos(15.9x - 884t)** where s is in micrometers, x is in meters, and t is in seconds.

- Light, or electromagnetic radiation, also can be described as a wave. The energy
**of**light travels through a medium called an electromagnetic field. This field exists everywhere in the universe. It oscillates when energy**disturbs**it, just like the rope moves up and down as someone shakes it.

- All sound waveforms (your stone) is comprised of 7 characteristics. Here they are, and why you need to know them. 1.
**Frequency**Think of sound like a wave in the ocean washing up on a beach. “Frequency” is how fast the waves are crashing on the shore. In more sonic terms, frequency is the rate at which a sound wave completes a cycle

- For
**a sound wave**traveling through air, the vibrations**of**the particles are best described as longitudinal. Longitudinal waves are waves in which the motion**of**the individual particles**of**the medium is in**a**direction that is parallel to the direction of energy transport.

- A particle is described by a wave function ψ(x) = Ae−αx2, where A and α are real, positive constants. If the value of α is increased, what eﬀect does this have on (a) the particle’s uncertainty in

- When is non-zero, the entire waveform appears to be shifted in time by the amount φ / ω seconds. A negative value represents a delay, and a positive value represents an advance. 2 seconds of a 220 Hz sine wave. This is the sound wave described by a sine function with f = 220 oscillations per second.