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Maths-

General

Easy

Question

Consider the system of equations ax+by =0 , cx +dy=0 where a, b, c, d $€$ {0,1}
Statement ‐ I The probability that the system of equations has a unique solution is 3/8 Statement ‐ II The probability that the system has a solution is 1.

Statement ‐ I and Statement ‐ II are true Statement ‐ II is not a correct explanation for statement‐I
Statement ‐ I and Statement ‐ II are true Statement ‐ II is correct explanation for statement ‐I
Statement ‐ I is true Statement ‐ II is not true
Statement ‐ I is not true Statement ‐ II is true.

The correct answer is: Statement ‐ I and Statement ‐ II are true Statement ‐ II is not a correct explanation for statement‐I

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A bird in air is diving vertically over a tank with speed 5cm/s Base of the tank is silvered A fish in the tank is rising upward along the same line with speed 2cm/s Water level is falling at a rate of 2cm/s $open square brackets mu subscript text water end text end subscript equals fraction numerator 4 over denominator 3 end fraction close square brackets blank$ Speed of the image of fish as seen by the bird directly in cm/s is

A bird in air is diving vertically over a tank with speed 5cm/s Base of the tank is silvered A fish in the tank is rising upward along the same line with speed 2cm/s Water level is falling at a rate of 2cm/s $open square brackets mu subscript text water end text end subscript equals fraction numerator 4 over denominator 3 end fraction close square brackets blank$ Speed of the image of fish as seen by the bird directly in cm/s is

physics-General

A Ray of light goes from A in a medium where the speed of light is V₁ to a point B in a medium where the speed of light is V₂ as shown in figure The path of the rays as shown in figure Answer the following questions,based on the above paragraph The slope of $left parenthesis i minus r right parenthesis$ curve is

A Ray of light goes from A in a medium where the speed of light is V₁ to a point B in a medium where the speed of light is V₂ as shown in figure The path of the rays as shown in figure Answer the following questions,based on the above paragraph The slope of $left parenthesis i minus r right parenthesis$ curve is

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A Ray of light goes from A in a medium where the speed of light is V₁ to a point B in a medium where the speed of light is V₂ as shown in figure The path of the rays as shown in figure Answer the following questions,based on the above paragraph The time taken for the light to go from the point A to the point B in the figure

A Ray of light goes from A in a medium where the speed of light is V₁ to a point B in a medium where the speed of light is V₂ as shown in figure The path of the rays as shown in figure Answer the following questions,based on the above paragraph The time taken for the light to go from the point A to the point B in the figure

physics-General

Spherical aberration in spherical mirrors is a defect which is due to dependence of focal length ‘f’ on angle of incidence ‘ q ’ as shown in figure is given by $f equals R minus fraction numerator K over denominator 2 end fraction s e c invisible function application theta$ where R is radius of curvature of mirror and q is the angle of incidence The rays which are closed to principal axis are called paraxial rays and the rays far away from principal axis are called marginal rays As a result of above dependence different rays are brought to focus at different points and the image of a point object is on a point Which of the following statements are correct regarding spherical aberration :

Spherical aberration in spherical mirrors is a defect which is due to dependence of focal length ‘f’ on angle of incidence ‘ q ’ as shown in figure is given by $f equals R minus fraction numerator K over denominator 2 end fraction s e c invisible function application theta$ where R is radius of curvature of mirror and q is the angle of incidence The rays which are closed to principal axis are called paraxial rays and the rays far away from principal axis are called marginal rays As a result of above dependence different rays are brought to focus at different points and the image of a point object is on a point Which of the following statements are correct regarding spherical aberration :

physics-General

Spherical aberration in spherical mirrors is a defect which is due to dependence of focal length ‘f’ on angle of incidence ‘ q ’ as shown in figure is given by $f equals R minus fraction numerator K over denominator 2 end fraction s e c invisible function application theta$ where R is radius of curvature of mirror and q is the angle of incidence The rays which are closed to principal axis are called paraxial rays and the rays far away from principal axis are called marginal rays As a result of above dependence different rays are brought to focus at different points and the image of a point object is on a point For paraxial rays, focal length approximately is

Spherical aberration in spherical mirrors is a defect which is due to dependence of focal length ‘f’ on angle of incidence ‘ q ’ as shown in figure is given by $f equals R minus fraction numerator K over denominator 2 end fraction s e c invisible function application theta$ where R is radius of curvature of mirror and q is the angle of incidence The rays which are closed to principal axis are called paraxial rays and the rays far away from principal axis are called marginal rays As a result of above dependence different rays are brought to focus at different points and the image of a point object is on a point For paraxial rays, focal length approximately is

physics-General

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Spherical aberration in spherical mirrors is a defect which is due to dependence of focal length ‘f’ on angle of incidence ‘ q ’ as shown in figure is given by $f equals R minus fraction numerator K over denominator 2 end fraction s e c invisible function application theta$ where R is radius of curvature of mirror and q is the angle of incidence The rays which are closed to principal axis are called paraxial rays and the rays far away from principal axis are called marginal rays As a result of above dependence different rays are brought to focus at different points and the image of a point object is on a point The total deviation suffered by the ray falling on mirror at an angle of incidence equal to 60° is

Spherical aberration in spherical mirrors is a defect which is due to dependence of focal length ‘f’ on angle of incidence ‘ q ’ as shown in figure is given by $f equals R minus fraction numerator K over denominator 2 end fraction s e c invisible function application theta$ where R is radius of curvature of mirror and q is the angle of incidence The rays which are closed to principal axis are called paraxial rays and the rays far away from principal axis are called marginal rays As a result of above dependence different rays are brought to focus at different points and the image of a point object is on a point The total deviation suffered by the ray falling on mirror at an angle of incidence equal to 60° is

physics-General

Spherical aberration in spherical mirrors is a defect which is due to dependence of focal length ‘f’ on angle of incidence ‘ q ’ as shown in figure is given by $f equals R minus fraction numerator K over denominator 2 end fraction s e c invisible function application theta$ where R is radius of curvature of mirror and q is the angle of incidence The rays which are closed to principal axis are called paraxial rays and the rays far away from principal axis are called marginal rays As a result of above dependence different rays are brought to focus at different points and the image of a point object is on a point If f_p and f_m represent the focal length of paraxial and marginal rays respectively, then correct relationship is :

Spherical aberration in spherical mirrors is a defect which is due to dependence of focal length ‘f’ on angle of incidence ‘ q ’ as shown in figure is given by $f equals R minus fraction numerator K over denominator 2 end fraction s e c invisible function application theta$ where R is radius of curvature of mirror and q is the angle of incidence The rays which are closed to principal axis are called paraxial rays and the rays far away from principal axis are called marginal rays As a result of above dependence different rays are brought to focus at different points and the image of a point object is on a point If f_p and f_m represent the focal length of paraxial and marginal rays respectively, then correct relationship is :

physics-General

Most materials have the refractive index, n > 1 So, when a light ray from air enters a naturally occurring material, then by Snell’s $text law, end text fraction numerator sin invisible function application theta subscript 1 end subscript over denominator sin invisible function application theta subscript 2 end subscript end fraction equals fraction numerator n subscript 1 end subscript over denominator n subscript 2 end subscript end fraction comma$ it is understood that the refracted ray bends towards the normal But it never emerges on the same side of the normal as the incident ray According to electromagnetism, the refractive index of the medium is given by the relation, $n equals open parentheses fraction numerator c over denominator V end fraction close parentheses equals plus-or-minus square root of epsilon subscript r end subscript mu subscript r end subscript end root$ , where c is the speed of the electromagnetic waves in vacuum, v its speed in the medium, e_r and m_r are negative, one must choose the negative root of n Such negative refractive index materials can now be artificially prepared and are called metamaterials They exhibit signficantly different optical behaviour, without violating any physical laws Since n is negative, it results in a change in the direction of propagation of the refracted light However, similar to normal materials, the frequency of light remains unchanged upon refraction even in metamaterials For light incident from air on a meta-material, the appropriate ray diagrams

Most materials have the refractive index, n > 1 So, when a light ray from air enters a naturally occurring material, then by Snell’s $text law, end text fraction numerator sin invisible function application theta subscript 1 end subscript over denominator sin invisible function application theta subscript 2 end subscript end fraction equals fraction numerator n subscript 1 end subscript over denominator n subscript 2 end subscript end fraction comma$ it is understood that the refracted ray bends towards the normal But it never emerges on the same side of the normal as the incident ray According to electromagnetism, the refractive index of the medium is given by the relation, $n equals open parentheses fraction numerator c over denominator V end fraction close parentheses equals plus-or-minus square root of epsilon subscript r end subscript mu subscript r end subscript end root$ , where c is the speed of the electromagnetic waves in vacuum, v its speed in the medium, e_r and m_r are negative, one must choose the negative root of n Such negative refractive index materials can now be artificially prepared and are called metamaterials They exhibit signficantly different optical behaviour, without violating any physical laws Since n is negative, it results in a change in the direction of propagation of the refracted light However, similar to normal materials, the frequency of light remains unchanged upon refraction even in metamaterials For light incident from air on a meta-material, the appropriate ray diagrams

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The element in the first row and third column of the inverse of the matrix $open square brackets table row 1 2 cell negative 3 end cell row 0 1 2 row 0 0 1 end table close square brackets$ is

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$C subscript 6 H subscript 5 minus C H equals C H C H O not stretchy rightwards arrow with X on top C subscript 6 H subscript 5 C H equals C H C H subscript 2 O H$ In the above sequence X can be

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chemistry-General

A ray of light traveling in air is incident at grazing angle (Ð >i 90º) on a long rectangular slab of a transparent medium of thickness t = 1.0 m The point of incidence is the medium A (0, 0) The medium has a variable index of refraction n(y) given by $n left parenthesis y right parenthesis equals open square brackets k y to the power of 3 divided by 2 end exponent plus 1 close square brackets to the power of 1 divided by 2 end exponent$ where $k equals 1.0 left parenthesis m right parenthesis to the power of negative 3 divided by 2 end exponent$ The refractive index of air is 1 The coordinates (x1, y(A) of the point P where the ray intersects the upper surface of the slabair boundary are

A ray of light traveling in air is incident at grazing angle (Ð >i 90º) on a long rectangular slab of a transparent medium of thickness t = 1.0 m The point of incidence is the medium A (0, 0) The medium has a variable index of refraction n(y) given by $n left parenthesis y right parenthesis equals open square brackets k y to the power of 3 divided by 2 end exponent plus 1 close square brackets to the power of 1 divided by 2 end exponent$ where $k equals 1.0 left parenthesis m right parenthesis to the power of negative 3 divided by 2 end exponent$ The refractive index of air is 1 The coordinates (x1, y(A) of the point P where the ray intersects the upper surface of the slabair boundary are

physics-General

A ray of light traveling in air is incident at grazing angle (Ð >i 90º) on a long rectangular slab of a transparent medium of thickness t = 1.0 m The point of incidence is the medium A (0, 0) The medium has a variable index of refraction n(y) given by $n left parenthesis y right parenthesis equals open square brackets k y to the power of 3 divided by 2 end exponent plus 1 close square brackets to the power of 1 divided by 2 end exponent$ where $k equals 1.0 left parenthesis m right parenthesis to the power of negative 3 divided by 2 end exponent$ The refractive index of air is 1 Equation for the trajectory y(x) of the ray in the medium is

A ray of light traveling in air is incident at grazing angle (Ð >i 90º) on a long rectangular slab of a transparent medium of thickness t = 1.0 m The point of incidence is the medium A (0, 0) The medium has a variable index of refraction n(y) given by $n left parenthesis y right parenthesis equals open square brackets k y to the power of 3 divided by 2 end exponent plus 1 close square brackets to the power of 1 divided by 2 end exponent$ where $k equals 1.0 left parenthesis m right parenthesis to the power of negative 3 divided by 2 end exponent$ The refractive index of air is 1 Equation for the trajectory y(x) of the ray in the medium is

physics-General

parallel

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