$L t subscript x not stretchy rightwards arrow 0 end subscript fraction numerator open parentheses 1 minus e to the power of x close parentheses sin begin display style space end style x over denominator x squared plus x cubed end fraction equals$

$L subscript x not stretchy rightwards arrow 0 end subscript fraction numerator x left parenthesis 1 plus a cos space x right parenthesis minus b sin space x over denominator x cubed end fraction equals 1 text then end text straight a equals comma straight b equals$

The correct relation is.

A vessel whose bottom has round holes with diameter of 0.1 mm is filled with water. The maximum height to which the water can be filled without leakage is
(S.T. of water $== fraction numerator 75 text dyne end text over denominator cm end fraction straight g equals 1000 straight m over straight s squared times$ )

$L t subscript x not stretchy rightwards arrow 0 end subscript fraction numerator x 10 to the power of x minus x over denominator 1 minus cos space x end fraction equals$

In general, we say that f(x) tends to a real limit l as x tends to infinity if, however small a distance we choose, f(x) gets closer than that distance to l and stays closer as x increases. f(x) =

$L t subscript n not stretchy rightwards arrow straight infinity end subscript fraction numerator n open parentheses 1 cubed plus 2 cubed plus midline horizontal ellipsis times plus n cubed close parentheses squared over denominator open parentheses 1 squared plus 2 squared plus midline horizontal ellipsis plus n squared close parentheses cubed end fraction equals$

infinity

$L t subscript n not stretchy rightwards arrow straight infinity end subscript fraction numerator n open parentheses 1 cubed plus 2 cubed plus midline horizontal ellipsis times plus n cubed close parentheses squared over denominator open parentheses 1 squared plus 2 squared plus midline horizontal ellipsis plus n squared close parentheses cubed end fraction equals$

infinity

A capillary tube at radius R is immersed in water and water rises in it to a height H. Mass of water in the capillary tube is M. If the radius of the tube is doubled. Mass of water that will rise in the, capillary tube will now be

$Lt subscript x not stretchy rightwards arrow 0 end subscript fraction numerator 1 over denominator sin squared space x end fraction minus fraction numerator 1 over denominator space x squared end fraction$

Direct substitution can sometimes be used to calculate the limits for functions involving trigonometric functions.

$Lt subscript x not stretchy rightwards arrow 0 end subscript fraction numerator 1 over denominator sin squared space x end fraction minus fraction numerator 1 over denominator space x squared end fraction$

Direct substitution can sometimes be used to calculate the limits for functions involving trigonometric functions.

If the excess pressure inside a soap bubble is balanced by oil column of height 2 mm then the surface tension of soap solution will be $C r equals 1 space a n d space d e n s i t y space d equals 0.8 g m divided by c c right parenthesis$

maths-

The quadratic equation whose roots are I and m where $l equals lim for theta not stretchy rightwards arrow 0 of open parentheses fraction numerator 3 sin space theta minus 4 sin cubed space theta over denominator theta end fraction close parentheses m equals lim for theta not stretchy rightwards arrow 0 of open parentheses fraction numerator 2 tan space theta over denominator theta open parentheses 1 minus tan squared space theta close parentheses end fraction close parentheses$ is

maths-General

Two bubbles A and B (A>B) are joined through a narrow tube than,

$L subscript x not stretchy rightwards arrow 0 end subscript fraction numerator tan cubed begin display style space end style x minus sin cubed space x over denominator x cubed end fraction$

Direct substitution can sometimes be used to calculate the limits for functions involving trigonometric functions.

$L subscript x not stretchy rightwards arrow 0 end subscript fraction numerator tan cubed begin display style space end style x minus sin cubed space x over denominator x cubed end fraction$

Direct substitution can sometimes be used to calculate the limits for functions involving trigonometric functions.

In capillary pressure below the curved surface at water will be

$L subscript x not stretchy rightwards arrow 0 end subscript fraction numerator sin begin display style space end style open parentheses pi cos squared space x close parentheses over denominator x squared end fraction$ is equal to

The substitution rule for calculating limits is a method of finding limits, by simply substituting the value of x with the point at which we want to calculate the limit.

$L subscript x not stretchy rightwards arrow 0 end subscript fraction numerator sin begin display style space end style open parentheses pi cos squared space x close parentheses over denominator x squared end fraction$ is equal to

The substitution rule for calculating limits is a method of finding limits, by simply substituting the value of x with the point at which we want to calculate the limit.

A spherical drop of coater has radius 1 mm if surface tension of context is $70 cross times 10 to the power of negative 3 end exponent straight N divided by straight m$ difference of pressures betweca inside and outside of the spherical drop is