When θ1 is at the critical angle, θ2 = ?

A random variable Y has a uniform distribution over the interval (θ1, θ2). Derive the variance...

A random variable Y has a uniform distribution over the interval (θ1, θ2). Derive the variance of Y. Find E(Y)2 in terms of (θ1, θ2).

A light ray enters a rectangular block of plastic at an angle of θ1 = 45.5°...

A light ray enters a rectangular block of plastic at an angle of θ1 = 45.5° and emerges at an angle of θ2 = 74.0°. (a) Determine the index of refraction of the plastic. _______ (b) If the light ray enters the plastic at a point L = 50.0 cm from the bottom edge, what time interval is required for the light ray to travel through the plastic? _____ns

F1 = (150g) dyne, θ1 = 20 & F2 = (200g) dyne, θ2 = 80 Determine...

F1 = (150g) dyne, θ1 = 20 & F2 = (200g) dyne, θ2 = 80 Determine the magnitude & the direction of the resultant force: Analytically: (Components method) I dont understand what they mean in g dyne? And how to know which fx or Fy is cos or sin

7.5) If X1 and X2 are independent random variables having exponential densities with the parameters θ1...

7.5) If X1 and X2 are independent random variables having exponential densities with the parameters θ1 and θ2, use the distribution function technique to find the probability density of Y=X1+X2 when a) θ1 ≠ θ2 b) θ1 = θ2 7.7) With reference to the two random variables of Exercise 7.5, show that if θ1 = θ2 = 1, the random variable Z1=X1/(X1 + X2) has the uniform density with α=0 and β=1.                                      (I ONLY NEED TO ANSWER 7.7)

7.5) If X1 and X2 are independent random variables having exponential densities with the parameters θ1...

7.5) If X1 and X2 are independent random variables having exponential densities with the parameters θ1 and θ2, use the distribution function technique to find the probability density of Y=X1+X2 when a) θ1 ≠ θ2 b) θ1 = θ2 7.7) With reference to the two random variables of Exercise 7.5, show that if θ1 = θ2 = 1, the random variable Z1=X1/(X1 + X2) has the uniform density with α=0 and β=1.                                      (I ONLY NEED TO ANSWER 7.7)

A ray of light strikes a flat glass block at an incidence angle of θ1 =...

A ray of light strikes a flat glass block at an incidence angle of θ1 = 34.2°. The glass is 2.00 cm thick and has an index of refraction that equals ng = 1.76. PICTURE: A light ray incident on a glass block of thickness 2.00 cm is shown. The ray travels down and to the right and is incident to the top of the block at an angle θ1 to the normal of the surface. The ray inside the...

1. Let θ < 0 be an angle in standard position. (a) Choose a value for...

1. Let θ < 0 be an angle in standard position. (a) Choose a value for θ (in radians) and graph θ. (b) Find the reference angle of θ. (c) Find numbers 0 < x < 2π and n ∈ Z so that θ = x + 2πn. (d) Convert θ into degrees. 2. Let θ1 and θ2 be coterminal angles in standard position. (a) Choose a value for θ1 and θ2 (in radians) and graph both angles. (b) Find...

If a ray of light traveling in the glass is incident on the interface with the...

If a ray of light traveling in the glass is incident on the interface with the water at an angle of θ1 = 36.20,then the ray refracted into the water makes an angle of θ2 = 49.80 with the normal to the interface.(Refractive index of water is 1.333) (a) Find the refractive index of glass? (b) What is the smallest value of the incident angle (i.e. critical angle) for which none of the ray refracts into the water? (c) What...

An astronomer is calibrating a spectrometer that uses a diffraction grating to separate light in order...

An astronomer is calibrating a spectrometer that uses a diffraction grating to separate light in order of increasing wavelength (λA, λB, and λC). She observes three distinct first-order spectral lines at the following respective angles θm (where m denotes order). θ1 = 12.8°, θ1 = 13.9°, θ1 = 15.2° (a) If the grating has 3,680 grooves per centimeter, what wavelength (in nm) describes each of these spectral lines? at θ1 = 12.8° λA = nmat θ1 = 13.9° λB =...

The critical angle of internal reflection is when: A. Light only refracts and leaves the medium...

The critical angle of internal reflection is when: A. Light only refracts and leaves the medium B. When light reflects and refracts equally when hitting a medium C. When light only reflects off a medium D. When the angle neither refracts nor reflects off a medium