How I can summarize wave characteristics and behaviors by comparing the longest, shortest, and tallest waves...

A oscillating wave-energy-converter (WEC) can be modelled as a mass-spring system forced by sinusoidal waves. A...

A oscillating wave-energy-converter (WEC) can be modelled as a mass-spring system forced by sinusoidal waves. A simple model would be given by the following DE: x''(t) + x'(t) + Kx(t) = h sin(ωt), where x measures the position of the WEC; K is a tuning parameter, chosen so that the WEC resonates with the waves; h is the height of the waves; and ω is the frequency of the waves. (a) Find a particular solution for the model. (b) Using...

The electric field for a sinusoidal electromagnetic wave is E = E0 sin(ky+wt) i with E0...

The electric field for a sinusoidal electromagnetic wave is E = E0 sin(ky+wt) i with E0 =40 V/m and k = 1.40E+8 m-1. Select the direction of propagation for this wave. Find the wave number of the wave. Find the wavelength of the wave. Find the period of the wave. Find the frequency of the wave. Find the angular frequency of the wave. Find the speed of the wave. Find the amplitude of the magnetic field. For sinusoidal electromagnetic waves,...

Open the Wave on a String PhET simulation. Set the following parameters: Simulation PAUSED Damping None...

Open the Wave on a String PhET simulation. Set the following parameters: Simulation PAUSED Damping None Tension High Rope’s End No End Source Oscillate Ruler Enabled Amplitude 0.5 cm Set the frequency of oscillation to 1.5 Hz. Run the simulation by clicking on the Play/Pause button. Measure the wavelength of the wave, using the ruler and the Play/Pause button. Repeat step 3 but increase the frequency to 3 Hz. Determine the wavelength of the wave. Summarize your data in Data...

Consider a shallow-water wave of length 1.5km propagating in an ocean that is 62.5m deep ....

Consider a shallow-water wave of length 1.5km propagating in an ocean that is 62.5m deep . The speed of the wave is 25m/s and the period T= 60 sec . a) Now suppose that this wave propagates into a region in which there is a current of strength U that opposes the wave propagation. Explain how this modifies the dispersion relation and the wave speed. b) Assuming that the wave’s frequency ω remains constant, create a plot of the wavelength...

Two waves traveling in opposite directions on a stretched rope interfere to give the standing wave...

Two waves traveling in opposite directions on a stretched rope interfere to give the standing wave described by the following wave function: y(x,t) = 4 sin⁡(2πx) cos⁡(120πt), where, y is in centimetres, x is in meters, and t is in seconds. The rope is two meters long, L = 2 m, and is fixed at both ends. In terms of the oscillation period, T, at which of the following times would all elements on the string have a zero vertical...

An electric field traveling through vacuum can be described as a plane wave E(r,t) = Eoexp[-i(ωt...

An electric field traveling through vacuum can be described as a plane wave E(r,t) = Eoexp[-i(ωt + k•z)]. (a) What is the angular frequency, wavelength, wave number, velocity, direction of propagation, and electric and magnetic field amplitude of this light wave? (b) Write equations describing the electric and magnetic fields in sinusoidal form, with all known quantities expressed numerically. (c) Write equivalent equations in complex exponential form. (d) What would be the maximum electric and magnetic forces exerted by this...

How to convert electromagnetic waves to light so I can see them? I can see light...

How to convert electromagnetic waves to light so I can see them? I can see light from a bulb becuase my eyes work on the frequency of light, buit how to see Wi-Fi signals? Imagine looking across a town and seeing all the radiation and making it more effidient perhaps. Perhaps there are sensors that can convert electromagnetix wabes to light so that we can see them!

As long as the amplitude is large enough, the human ear can respond to longitudinal waves...

As long as the amplitude is large enough, the human ear can respond to longitudinal waves within a frequency range of approximately 20.0 Hz to 20.0 kHz. a) If you had to mark the beginning of each complete wave pattern with a red dot for the long wavelength sound and with a blue dot the short wavelength sound, what distance would there be between the red dots and what Would there be the distance between the blue dots? b) Suppose...

Q1 i) : Dealing with atmospheric pressure, if one observes the Mercury level rises to 70...

Q1 i) : Dealing with atmospheric pressure, if one observes the Mercury level rises to 70 cm. Predict the atmospheric pressure of the air in mm of Hg. Can you represent it in bar? How can you evaluate the height of the Mercury column in a perfect barometer for standard pressure? Comparing both results, evaluate the percentage difference. Water is used instead of Mercury in a perfect barometer, can you assess the volume of water in SI unit, if cross...

Short Answers Conceptual Questions 1. (a) A lead cylinder floats in mercury at 0oC. Will the...

Short Answers Conceptual Questions 1. (a) A lead cylinder floats in mercury at 0oC. Will the lead float higher or lower if the temperature is raised? (b) Freezing a can of soda will cause its bottom and top to bulge so badly that the can will not stand up. What has happened? 2. (a) Is it possible to boil water at room temperature (20oC) without heating it? Explain. (b) Explain why burns caused by steam at 100oC on the skin...