স্পর্শক

টেকসেন্ট লাইনের সীমা লাইন সীমা লাইনের জ্যামিতিক ধারণা বিশ্লেষণাত্মক পদ্ধতিগুলির প্রেরণা হিসাবে কাজ করে যা স্পর্শকাতর টানেন্ট লাইনগুলি খুঁজে পেতে ব্যবহৃত হয়। 17 ই শতকের ক্যালকুলাসের বিকাশের দিকে পরিচালিত কেন্দ্রীয় প্রশ্নগুলির মধ্যে একটি গ্রাফে ট্যানজেন্ট লাইন বা ট্যানজেন্ট লাইন সমস্যাটি খোঁজার প্রশ্নটি ছিল। তার জ্যামিতি এর দ্বিতীয় বইয়ের মধ্যে , রেনি ডিসকার্টেস ^[8]একটি বক্ররেখা টানেন্ট তৈরির সমস্যা সম্পর্কে বলেন , "এবং আমি সাহস করে বলছি যে এই জ্যামিতি যা আমি জানি তা শুধুমাত্র সবচেয়ে দরকারী এবং সর্বাধিক সাধারণ সমস্যা নয়, এমনকি যে আমি কখনও জানতে চেয়েছিলেন।

Suppose that a curve is given as the graph of a function, y = f(x). To find the tangent line at the point p = (a, f(a)), consider another nearby point q = (a + h, f(a + h)) on the curve. The slope of the secant line passing through p and q is equal to the difference quotient

${\displaystyle {\frac {f(a+h)-f(a)}{h}}.}$

As the point q approaches p, which corresponds to making h smaller and smaller, the difference quotient should approach a certain limiting value k, which is the slope of the tangent line at the point p. If k is known, the equation of the tangent line can be found in the point-slope form:

${\displaystyle y-f(a)=k(x-a).\,}$

To make the preceding reasoning rigorous, one has to explain what is meant by the difference quotient approaching a certain limiting value k. The precise mathematical formulation was given by Cauchy in the 19th century and is based on the notion of limit. Suppose that the graph does not have a break or a sharp edge at p and it is neither plumb nor too wiggly near p. Then there is a unique value of k such that, as h approaches 0, the difference quotient gets closer and closer to k, and the distance between them becomes negligible compared with the size of h, if h is small enough. This leads to the definition of the slope of the tangent line to the graph as the limit of the difference quotients for the function f. This limit is the derivative of the function f at x = a, denoted f ′(a). Using derivatives, the equation of the tangent line can be stated as follows:

${\displaystyle y=f(a)+f'(a)(x-a).\,}$

Calculus provides rules for computing the derivatives of functions that are given by formulas, such as the power function, trigonometric functions, exponential function, logarithm, and their various combinations. Thus, equations of the tangents to graphs of all these functions, as well as many others, can be found by the methods of calculus.

Calculus also demonstrates that there are functions and points on their graphs for which the limit determining the slope of the tangent line does not exist. For these points the function f is non-differentiable. There are two possible reasons for the method of finding the tangents based on the limits and derivatives to fail: either the geometric tangent exists, but it is a vertical line, which cannot be given in the point-slope form since it does not have a slope, or the graph exhibits one of three behaviors that precludes a geometric tangent.

The graph y = x^1/3 illustrates the first possibility: here the difference quotient at a = 0 is equal to h^1/3/h = h^−2/3, which becomes very large as h approaches 0. This curve has a tangent line at the origin that is vertical.

The graph y = x^2/3 illustrates another possibility: this graph has a cusp at the origin. This means that, when h approaches 0, the difference quotient at a = 0 approaches plus or minus infinity depending on the sign of x. Thus both branches of the curve are near to the half vertical line for which y=0, but none is near to the negative part of this line. Basically, there is no tangent at the origin in this case, but in some context one may consider this line as a tangent, and even, in algebraic geometry, as a double tangent.

The graph y = |x| of the absolute value function consists of two straight lines with different slopes joined at the origin. As a point q approaches the origin from the right, the secant line always has slope 1. As a point q approaches the origin from the left, the secant line always has slope −1. Therefore, there is no unique tangent to the graph at the origin. Having two different (but finite) slopes is called a corner.

Finally, since differentiability implies continuity, the contrapositive states discontinuity implies non-differentiability. Any such jump or point discontinuity will have no tangent line. This includes cases where one slope approaches positive infinity while the other approaches negative infinity, leading to an infinite jump discontinuity

When the curve is given by y = f(x) then the slope of the tangent is ${\displaystyle {\frac {dy}{dx}},}$ so by the point–slope formula the equation of the tangent line at (X, Y) is

${\displaystyle y-Y={\frac {dy}{dx}}(X)\cdot (x-X)}$

where (x, y) are the coordinates of any point on the tangent line, and where the derivative is evaluated at ${\displaystyle x=X}$.[1]

When the curve is given by y = f(x), the tangent line's equation can also be found[2] by using polynomial division to divide ${\displaystyle f\,(x)}$ by ${\displaystyle (x-X)^{2}}$; if the remainder is denoted by ${\displaystyle g(x)}$, then the equation of the tangent line is given by

${\displaystyle y=g(x).}$

When the equation of the curve is given in the form f(x, y) = 0 then the value of the slope can be found by implicit differentiation, giving

${\displaystyle {\frac {dy}{dx}}=-{\frac {\frac {\partial f}{\partial x}}{\frac {\partial f}{\partial y}}}.}$

The equation of the tangent line at a point (X,Y) such that f(X,Y) = 0 is then[1]

${\displaystyle {\frac {\partial f}{\partial x}}(X,Y)\cdot (x-X)+{\frac {\partial f}{\partial y}}(X,Y)\cdot (y-Y)=0.}$

This equation remains true if ${\displaystyle {\frac {\partial f}{\partial y}}(X,Y)=0}$ but ${\displaystyle {\frac {\partial f}{\partial x}}(X,Y)\neq 0}$ (in this case the slope of the tangent is infinite). If ${\displaystyle {\frac {\partial f}{\partial y}}(X,Y)={\frac {\partial f}{\partial x}}(X,Y)=0,}$ the tangent line is not defined and the point (X,Y) is said singular.

For algebraic curves, computations may be simplified somewhat by converting to homogeneous coordinates. Specifically, let the homogeneous equation of the curve be g(x, y, z) = 0 where g is a homogeneous function of degree n. Then, if (X, Y, Z) lies on the curve, Euler's theorem implies

$${\displaystyle {\frac {\partial g}{\partial x}}\cdot X+{\frac {\partial g}{\partial y}}\cdot Y+{\frac {\partial g}{\partial z}}\cdot Z=ng(X,Y,Z)=0.}$$

It follows that the homogeneous equation of the tangent line is

${\displaystyle {\frac {\partial g}{\partial x}}(X,Y,Z)\cdot x+{\frac {\partial g}{\partial y}}(X,Y,Z)\cdot y+{\frac {\partial g}{\partial z}}(X,Y,Z)\cdot z=0.}$

The equation of the tangent line in Cartesian coordinates can be found by setting z=1 in this equation.[3]

To apply this to algebraic curves, write f(x, y) as

${\displaystyle f=u_{n}+u_{n-1}+\dots +u_{1}+u_{0}\,}$

where each u_r is the sum of all terms of degree r. The homogeneous equation of the curve is then

${\displaystyle g=u_{n}+u_{n-1}z+\dots +u_{1}z^{n-1}+u_{0}z^{n}=0.\,}$

Applying the equation above and setting z=1 produces

${\displaystyle {\frac {\partial f}{\partial x}}(X,Y)\cdot x+{\frac {\partial f}{\partial y}}(X,Y)\cdot y+{\frac {\partial g}{\partial z}}(X,Y,1)=0}$

as the equation of the tangent line.[4] The equation in this form is often simpler to use in practice since no further simplification is needed after it is applied.[3]

If the curve is given parametrically by

${\displaystyle x=x(t),\quad y=y(t)}$

then the slope of the tangent is

${\displaystyle {\frac {dy}{dx}}={\frac {\frac {dy}{dt}}{\frac {dx}{dt}}}}$

giving the equation for the tangent line at ${\displaystyle \,t=T,\,X=x(T),\,Y=y(T)}$ as[5]

${\displaystyle {\frac {dx}{dt}}(T)\cdot (y-Y)={\frac {dy}{dt}}(T)\cdot (x-X).}$

If ${\displaystyle {\frac {dx}{dt}}(T)={\frac {dy}{dt}}(T)=0,}$ the tangent line is not defined. However, it may occur that the tangent line exists and may be computed from an implicit equation of the curve.

The line perpendicular to the tangent line to a curve at the point of tangency is called the normal line to the curve at that point. The slopes of perpendicular lines have product −1, so if the equation of the curve is y = f(x) then slope of the normal line is

${\displaystyle -{\frac {1}{\frac {dy}{dx}}}}$

and it follows that the equation of the normal line at (X, Y) is

${\displaystyle (x-X)+{\frac {dy}{dx}}(y-Y)=0.}$

Similarly, if the equation of the curve has the form f(x, y) = 0 then the equation of the normal line is given by[6]

${\displaystyle {\frac {\partial f}{\partial y}}(x-X)-{\frac {\partial f}{\partial x}}(y-Y)=0.}$

If the curve is given parametrically by

${\displaystyle x=x(t),\quad y=y(t)}$

then the equation of the normal line is[5]

${\displaystyle {\frac {dx}{dt}}(x-X)+{\frac {dy}{dt}}(y-Y)=0.}$

The angle between two curves at a point where they intersect is defined as the angle between their tangent lines at that point. More specifically, two curves are said to be tangent at a point if they have the same tangent at a point, and orthogonal if their tangent lines are orthogonal.[7]

The limaçon trisectrix: a curve with two tangents at the origin.

The formulas above fail when the point is a singular point. In this case there may be two or more branches of the curve that pass through the point, each branch having its own tangent line. When the point is the origin, the equations of these lines can be found for algebraic curves by factoring the equation formed by eliminating all but the lowest degree terms from the original equation. Since any point can be made the origin by a change of variables (or by translating the curve) this gives a method for finding the tangent lines at any singular point.

For example, the equation of the limaçon trisectrix shown to the right is

${\displaystyle (x^{2}+y^{2}-2ax)^{2}=a^{2}(x^{2}+y^{2}).\,}$

Expanding this and eliminating all but terms of degree 2 gives

${\displaystyle a^{2}(3x^{2}-y^{2})=0\,}$

which, when factored, becomes

${\displaystyle y=\pm {\sqrt {3}}x.}$

So these are the equations of the two tangent lines through the origin.[8]

When the curve is not self-crossing, the tangent at a reference point may still not be uniquely defined because the curve is not differentiable at that point although it is differentiable elsewhere. In this case the left and right derivatives are defined as the limits of the derivative as the point at which it is evaluated approaches the reference point from respectively the left (lower values) or the right (higher values). For example, the curve y = |x | is not differentiable at x = 0: its left and right derivatives have respective slopes –1 and 1; the tangents at that point with those slopes are called the left and right tangents.[9]

Sometimes the slopes of the left and right tangent lines are equal, so the tangent lines coincide. This is true, for example, for the curve y = x ^2/3, for which both the left and right derivatives at x = 0 are infinite; both the left and right tangent lines have equation x = 0.