Have a query? Ask a Tutor!!

Access to best educators and exclusive paper discussions

Offsite Campus Turito Championship

Can’t find what you’re looking for?

Our tutors are from top schools around the world, and they are waiting for you 24/7, anytime, anywhere.

Homework- One to One Solutions
Understand concepts to solve better
Get your doubts solved instantly

Maths-

General

Easy

Question

If $integral subscript 0 superscript pi divided by 3 end superscript fraction numerator blank c o s blank x over denominator 3 plus 4 blank s i n blank x end fraction d x equals k blank l o g blank left parenthesis fraction numerator 3 plus 2 square root of 3 over denominator 3 end fraction right parenthesis$ then k is‐

$\frac{1}{2}$
$\frac{1}{3}$
$\frac{1}{4}$
$\frac{1}{8}$

The correct answer is: $fraction numerator 1 over denominator 4 end fraction$

Related Questions to study

In the figure shown in YDSE, a parallel beam of light is incident on the slit from a medium of refractive index n₁ The wavelength of light in this medium is l₁ A transparent slab of thickness ‘t’ and refractive index n₃ is put infront of one slit. The medium between the screen and the plane of the slits is n₂ The phase difference between the light waves reaching point ‘O’ (symmetrical, relative to the slits) is :

In the figure shown in YDSE, a parallel beam of light is incident on the slit from a medium of refractive index n₁ The wavelength of light in this medium is l₁ A transparent slab of thickness ‘t’ and refractive index n₃ is put infront of one slit. The medium between the screen and the plane of the slits is n₂ The phase difference between the light waves reaching point ‘O’ (symmetrical, relative to the slits) is :

physics-General

In YDSE, the source placed symmetrically with respect to the slit is now moved parallel to the plane of the slits so that it is closer to the upper slit, as shown. Then,

In YDSE, the source placed symmetrically with respect to the slit is now moved parallel to the plane of the slits so that it is closer to the upper slit, as shown. Then,

physics-General

A parallel beam of light 500nm is incident at an angle 30° with the normal to the slit plane in a young's double slit experiment. The intensity due to each slit is Io. Point O is equidistant from S₁ and S₂ . The distance between slits is 1mm.

A parallel beam of light 500nm is incident at an angle 30° with the normal to the slit plane in a young's double slit experiment. The intensity due to each slit is Io. Point O is equidistant from S₁ and S₂ . The distance between slits is 1mm.

physics-General

parallel

In the figure shown if a parallel beam of white light is incident on the plane of the slits then the distance of the white spot on the screen from O is [Assume d << D, $lambda$ << d]

In the figure shown if a parallel beam of white light is incident on the plane of the slits then the distance of the white spot on the screen from O is [Assume d << D, $lambda$ << d]

physics-General

Two slits are separated by 0.3 mm. A beam of 500 nm light strikes the slits producing an interference pattern. The number of maxima observed in the angular range – 30° < $theta$ < 30°.

Two slits are separated by 0.3 mm. A beam of 500 nm light strikes the slits producing an interference pattern. The number of maxima observed in the angular range – 30° < $theta$ < 30°.

physics-General

A monochromatic light source of wavelength $lambda$ is placed at S. Three slits S₁ , S₂ and S₃ are equidistant from the source S and the point P on the screen. S₁P – S₂P = $lambda$ /6 and S₁P – S₃P = 2 $lambda$ /3. If I be the intensity at P when only one slit is open, the intensity at P when all the three slits are open is

A monochromatic light source of wavelength $lambda$ is placed at S. Three slits S₁ , S₂ and S₃ are equidistant from the source S and the point P on the screen. S₁P – S₂P = $lambda$ /6 and S₁P – S₃P = 2 $lambda$ /3. If I be the intensity at P when only one slit is open, the intensity at P when all the three slits are open is

physics-General

parallel

In a double slit experiment, the separation between the slits is d =0.25 cm and the distance of the screen D = 100 cm from the slits. If the wavelength of light used is $lambda$ = 6000 $text Å end text$ and I₀ is the intensity of the central bright fringe, the intensity at a distance x= 4×10^–5m from the central maximum is

In a double slit experiment, the separation between the slits is d =0.25 cm and the distance of the screen D = 100 cm from the slits. If the wavelength of light used is $lambda$ = 6000 $text Å end text$ and I₀ is the intensity of the central bright fringe, the intensity at a distance x= 4×10^–5m from the central maximum is

physics-General

In a Young's Double slit experiment, first maxima is observed at a fixed point P on the screen. Now the screen is continuously moved away from the plane of slits. The ratio of intensity at point P to the intensity at point O (centre of the screen)

In a Young's Double slit experiment, first maxima is observed at a fixed point P on the screen. Now the screen is continuously moved away from the plane of slits. The ratio of intensity at point P to the intensity at point O (centre of the screen)

physics-General

Light of wavelength 520 nm passing through a double slit, produces interference pattern of relative intensity versus deflection angle $theta$ as shown in the figure. The separation d between the slits is

Light of wavelength 520 nm passing through a double slit, produces interference pattern of relative intensity versus deflection angle $theta$ as shown in the figure. The separation d between the slits is

physics-General

parallel

A student is asked to measure the wavelength of monochromatic light. He sets up the apparatus sketched below. S₁ , S₂ , S₃ are narrow parallel slits, L is a sodium lamp and M is a microscope eyepiece. The student fails to observe interference fringes. Your first advice to him will be

A student is asked to measure the wavelength of monochromatic light. He sets up the apparatus sketched below. S₁ , S₂ , S₃ are narrow parallel slits, L is a sodium lamp and M is a microscope eyepiece. The student fails to observe interference fringes. Your first advice to him will be

physics-General

Two identical narrow slits S₁ and S₂ are illuminated by light of wavelength $lambda$ from a point source P. If, as shown in the diagram above the light is then allowed to fall on a screen, and if n is a positive integer, the condition for destructive interference at Q is that

Two identical narrow slits S₁ and S₂ are illuminated by light of wavelength $lambda$ from a point source P. If, as shown in the diagram above the light is then allowed to fall on a screen, and if n is a positive integer, the condition for destructive interference at Q is that

physics-General

Two coherent narrow slits emitting light of wavelength $lambda$ in the same phase are placed parallel to each other at a small separation of 3 $lambda$ . The light is collected on a screen S which is placed at a distance D (>> $lambda$ ) from the slits. The smallest distance x such that the P is a maxima

Two coherent narrow slits emitting light of wavelength $lambda$ in the same phase are placed parallel to each other at a small separation of 3 $lambda$ . The light is collected on a screen S which is placed at a distance D (>> $lambda$ ) from the slits. The smallest distance x such that the P is a maxima

physics-General

parallel

Two point source separated by d = 5 mm emit light of wavelength $lambda$ = 2 $mu m$ in phase. A circular wire of radius 20 mm is placed around the source as shown in figure.

Two point source separated by d = 5 mm emit light of wavelength $lambda$ = 2 $mu m$ in phase. A circular wire of radius 20 mm is placed around the source as shown in figure.

physics-General

Figure shown plane waves refracted for air to water using Huygen's principle a, b, c, d, e are lengths on the diagram. The refractive index of water wrt air is the ratio.

Figure shown plane waves refracted for air to water using Huygen's principle a, b, c, d, e are lengths on the diagram. The refractive index of water wrt air is the ratio.

physics-General

Two point monochromatic and coherent sources of light of wavelength l are placed on the dotted line in front of an large screen. The source emit waves in phase with each other. The distance between S₁ and S₂ is 'd' while their distance from the screen is much larger. Then,

1) $rightwards arrow$ If d = 7 $lambda$ /2, O will be a minima
2) $rightwards arrow$ If d = 4.3 $lambda$ , there will be a total of 8 minima on y axis.
3) $rightwards arrow$ If d = 7 $lambda$ , O will be a maxima.
4) $rightwards arrow$ If d = $lambda$ , there will be only one maxima on the screen.
Which is the set of correct statement :

Two point monochromatic and coherent sources of light of wavelength l are placed on the dotted line in front of an large screen. The source emit waves in phase with each other. The distance between S₁ and S₂ is 'd' while their distance from the screen is much larger. Then,

1) $rightwards arrow$ If d = 7 $lambda$ /2, O will be a minima
2) $rightwards arrow$ If d = 4.3 $lambda$ , there will be a total of 8 minima on y axis.
3) $rightwards arrow$ If d = 7 $lambda$ , O will be a maxima.
4) $rightwards arrow$ If d = $lambda$ , there will be only one maxima on the screen.
Which is the set of correct statement :

physics-General

parallel

card img

With Turito Academy.

card img

With Turito Foundation.

card img

Get an Expert Advice From Turito.

Turito Academy

card img

With Turito Academy.

Test Prep

card img

With Turito Foundation.