Area









Area
Common symbols
A
SI unit
Square metre [m2]
In SI base units
1 m2

Three shapes on a square grid

The combined area of these three shapes is approximately 15.57 squares.


Area is the quantity that expresses the extent of a two-dimensional figure or shape, or planar lamina, in the plane. Surface area is its analog on the two-dimensional surface of a three-dimensional object. Area can be understood as the amount of material with a given thickness that would be necessary to fashion a model of the shape, or the amount of paint necessary to cover the surface with a single coat.[1] It is the two-dimensional analog of the length of a curve (a one-dimensional concept) or the volume of a solid (a three-dimensional concept).


The area of a shape can be measured by comparing the shape to squares of a fixed size.[2] In the International System of Units (SI), the standard unit of area is the square metre (written as m2), which is the area of a square whose sides are one metre long.[3] A shape with an area of three square metres would have the same area as three such squares. In mathematics, the unit square is defined to have area one, and the area of any other shape or surface is a dimensionless real number.


There are several well-known formulas for the areas of simple shapes such as triangles, rectangles, and circles. Using these formulas, the area of any polygon can be found by dividing the polygon into triangles.[4] For shapes with curved boundary, calculus is usually required to compute the area. Indeed, the problem of determining the area of plane figures was a major motivation for the historical development of calculus.[5]


For a solid shape such as a sphere, cone, or cylinder, the area of its boundary surface is called the surface area.[1][6][7] Formulas for the surface areas of simple shapes were computed by the ancient Greeks, but computing the surface area of a more complicated shape usually requires multivariable calculus.


Area plays an important role in modern mathematics. In addition to its obvious importance in geometry and calculus, area is related to the definition of determinants in linear algebra, and is a basic property of surfaces in differential geometry.[8] In analysis, the area of a subset of the plane is defined using Lebesgue measure,[9] though not every subset is measurable.[10] In general, area in higher mathematics is seen as a special case of volume for two-dimensional regions.[1]


Area can be defined through the use of axioms, defining it as a function of a collection of certain plane figures to the set of real numbers. It can be proved that such a function exists.




Contents





  • 1 Formal definition


  • 2 Units

    • 2.1 Conversions

      • 2.1.1 Non-metric units



    • 2.2 Other units including historical



  • 3 History

    • 3.1 Circle area


    • 3.2 Triangle area


    • 3.3 Quadrilateral area


    • 3.4 General polygon area


    • 3.5 Areas determined using calculus



  • 4 Area formulas

    • 4.1 Polygon formulas

      • 4.1.1 Rectangles


      • 4.1.2 Dissection, parallelograms, and triangles



    • 4.2 Area of curved shapes

      • 4.2.1 Circles


      • 4.2.2 Ellipses


      • 4.2.3 Surface area



    • 4.3 General formulas

      • 4.3.1 Areas of 2-dimensional figures


      • 4.3.2 Area in calculus


      • 4.3.3 Bounded area between two quadratic functions


      • 4.3.4 Surface area of 3-dimensional figures


      • 4.3.5 General formula for surface area



    • 4.4 List of formulas


    • 4.5 Relation of area to perimeter


    • 4.6 Fractals



  • 5 Area bisectors


  • 6 Optimization


  • 7 See also


  • 8 References


  • 9 External links




Formal definition



An approach to defining what is meant by "area" is through axioms. "Area" can be defined as a function from a collection M of special kind of plane figures (termed measurable sets) to the set of real numbers which satisfies the following properties:


  • For all S in M, a(S) ≥ 0.

  • If S and T are in M then so are ST and ST, and also a(ST) = a(S) + a(T) − a(ST).

  • If S and T are in M with ST then TS is in M and a(TS) = a(T) − a(S).

  • If a set S is in M and S is congruent to T then T is also in M and a(S) = a(T).

  • Every rectangle R is in M. If the rectangle has length h and breadth k then a(R) = hk.

  • Let Q be a set enclosed between two step regions S and T. A step region is formed from a finite union of adjacent rectangles resting on a common base, i.e. SQT. If there is a unique number c such that a(S) ≤ c ≤ a(T) for all such step regions S and T, then a(Q) = c.

It can be proved that such an area function actually exists.[11]



Units



A square made of PVC pipe on grass

A square metre quadrat made of PVC pipe.


Every unit of length has a corresponding unit of area, namely the area of a square with the given side length. Thus areas can be measured in square metres (m2), square centimetres (cm2), square millimetres (mm2), square kilometres (km2), square feet (ft2), square yards (yd2), square miles (mi2), and so forth.[12] Algebraically, these units can be thought of as the squares of the corresponding length units.


The SI unit of area is the square metre, which is considered an SI derived unit.[3]



Conversions



A diagram showing the conversion factor between different areas

Although there are 10 mm in 1 cm, there are 100 mm2 in 1 cm2.


Calculation of the area of a square whose length and width are 1 metre would be:


1 metre x 1 metre = 1 m2


and so, a rectangle with different sides (say length of 3 metres and width of 2 metres) would have an area in square units that can be calculated as:


3 metres x 2 metres = 6 m2. This is equivalent to 6 million square millimetres. Other useful conversions are:


  • 1 square kilometre = 1,000,000 square metres

  • 1 square metre = 10,000 square centimetres = 1,000,000 square millimetres

  • 1 square centimetre = 100 square millimetres.


Non-metric units


In non-metric units, the conversion between two square units is the square of the conversion between the corresponding length units.


1 foot = 12 inches,

the relationship between square feet and square inches is


1 square foot = 144 square inches,

where 144 = 122 = 12 × 12. Similarly:


  • 1 square yard = 9 square feet

  • 1 square mile = 3,097,600 square yards = 27,878,400 square feet

In addition, conversion factors include:


  • 1 square inch = 6.4516 square centimetres

  • 1 square foot = 0.09290304 square metres

  • 1 square yard = 0.83612736 square metres

  • 1 square mile = 2.589988110336 square kilometres


Other units including historical



There are several other common units for area. The are was the original unit of area in the metric system, with:


  • 1 are = 100 square metres

Though the are has fallen out of use, the hectare is still commonly used to measure land:[12]


  • 1 hectare = 100 ares = 10,000 square metres = 0.01 square kilometres

Other uncommon metric units of area include the tetrad, the hectad, and the myriad.


The acre is also commonly used to measure land areas, where


  • 1 acre = 4,840 square yards = 43,560 square feet.

An acre is approximately 40% of a hectare.


On the atomic scale, area is measured in units of barns, such that:[12]


  • 1 barn = 10−28 square meters.

The barn is commonly used in describing the cross-sectional area of interaction in nuclear physics.[12]


In India,


  • 20 dhurki = 1 dhur

  • 20 dhur = 1 khatha

  • 20 khata = 1 bigha

  • 32 khata = 1 acre


History



Circle area


In the 5th century BCE, Hippocrates of Chios was the first to show that the area of a disk (the region enclosed by a circle) is proportional to the square of its diameter, as part of his quadrature of the lune of Hippocrates,[13] but did not identify the constant of proportionality. Eudoxus of Cnidus, also in the 5th century BCE, also found that the area of a disk is proportional to its radius squared.[14]


Subsequently, Book I of Euclid's Elements dealt with equality of areas between two-dimensional figures. The mathematician Archimedes used the tools of Euclidean geometry to show that the area inside a circle is equal to that of a right triangle whose base has the length of the circle's circumference and whose height equals the circle's radius, in his book Measurement of a Circle. (The circumference is 2πr, and the area of a triangle is half the base times the height, yielding the area πr2 for the disk.) Archimedes approximated the value of π (and hence the area of a unit-radius circle) with his doubling method, in which he inscribed a regular triangle in a circle and noted its area, then doubled the number of sides to give a regular hexagon, then repeatedly doubled the number of sides as the polygon's area got closer and closer to that of the circle (and did the same with circumscribed polygons).


Swiss scientist Johann Heinrich Lambert in 1761 proved that π, the ratio of a circle's area to its squared radius, is irrational, meaning it is not equal to the quotient of any two whole numbers.[15] In 1794 French mathematician Adrien-Marie Legendre proved that π2 is irrational; this also proves that π is irrational.[16] In 1882, German mathematician Ferdinand von Lindemann proved that π is transcendental (not the solution of any polynomial equation with rational coefficients), confirming a conjecture made by both Legendre and Euler.[15]:p. 196



Triangle area


Heron (or Hero) of Alexandria found what is known as Heron's formula for the area of a triangle in terms of its sides, and a proof can be found in his book, Metrica, written around 60 CE. It has been suggested that Archimedes knew the formula over two centuries earlier,[17] and since Metrica is a collection of the mathematical knowledge available in the ancient world, it is possible that the formula predates the reference given in that work.[18]


In 499 Aryabhata, a great mathematician-astronomer from the classical age of Indian mathematics and Indian astronomy, expressed the area of a triangle as one-half the base times the height in the Aryabhatiya (section 2.6).


A formula equivalent to Heron's was discovered by the Chinese independently of the Greeks. It was published in 1247 in Shushu Jiuzhang ("Mathematical Treatise in Nine Sections"), written by Qin Jiushao.



Quadrilateral area


In the 7th century CE, Brahmagupta developed a formula, now known as Brahmagupta's formula, for the area of a cyclic quadrilateral (a quadrilateral inscribed in a circle) in terms of its sides. In 1842 the German mathematicians Carl Anton Bretschneider and Karl Georg Christian von Staudt independently found a formula, known as Bretschneider's formula, for the area of any quadrilateral.



General polygon area


The development of Cartesian coordinates by René Descartes in the 17th century allowed the development of the surveyor's formula for the area of any polygon with known vertex locations by Gauss in the 19th century.



Areas determined using calculus


The development of integral calculus in the late 17th century provided tools that could subsequently be used for computing more complicated areas, such as the area of an ellipse and the surface areas of various curved three-dimensional objects.



Area formulas



Polygon formulas



For a non-self-intersecting (simple) polygon, the Cartesian coordinates (xi,yi)displaystyle (x_i,y_i)(x_i,y_i) (i=0, 1, ..., n-1) of whose n vertices are known, the area is given by the surveyor's formula:[19]


A=12|∑i=0n−1(xiyi+1−xi+1yi)|sum _i=0^n-1(x_iy_i+1-x_i+1y_i)A=frac 12|sum _i=0^n-1(x_iy_i+1-x_i+1y_i)|

where when i=n-1, then i+1 is expressed as modulus n and so refers to 0.



Rectangles



A rectangle with length and width labelled

The area of this rectangle is lw.


The most basic area formula is the formula for the area of a rectangle. Given a rectangle with length l and width w, the formula for the area is:[2][20]



A = lw (rectangle).

That is, the area of the rectangle is the length multiplied by the width. As a special case, as l = w in the case of a square, the area of a square with side length s is given by the formula:[1][2][21]



A = s2 (square).

The formula for the area of a rectangle follows directly from the basic properties of area, and is sometimes taken as a definition or axiom. On the other hand, if geometry is developed before arithmetic, this formula can be used to define multiplication of real numbers.



A diagram showing how a parallelogram can be re-arranged into the shape of a rectangle

Equal area figures.



Dissection, parallelograms, and triangles



Most other simple formulas for area follow from the method of dissection.
This involves cutting a shape into pieces, whose areas must sum to the area of the original shape.


For an example, any parallelogram can be subdivided into a trapezoid and a right triangle, as shown in figure to the left. If the triangle is moved to the other side of the trapezoid, then the resulting figure is a rectangle. It follows that the area of the parallelogram is the same as the area of the rectangle:[2]



A = bh  (parallelogram).

A parallelogram split into two equal triangles

Two equal triangles.


However, the same parallelogram can also be cut along a diagonal into two congruent triangles, as shown in the figure to the right. It follows that the area of each triangle is half the area of the parallelogram:[2]



A=12bhdisplaystyle A=frac 12bhA=frac 12bh  (triangle).

Similar arguments can be used to find area formulas for the trapezoid[22] as well as more complicated polygons.[23]



Area of curved shapes



Circles



A circle divided into many sectors can be re-arranged roughly to form a parallelogram

A circle can be divided into sectors which rearrange to form an approximate parallelogram.



The formula for the area of a circle (more properly called the area enclosed by a circle or the area of a disk) is based on a similar method. Given a circle of radius r, it is possible to partition the circle into sectors, as shown in the figure to the right. Each sector is approximately triangular in shape, and the sectors can be rearranged to form an approximate parallelogram. The height of this parallelogram is r, and the width is half the circumference of the circle, or πr. Thus, the total area of the circle is πr2:[2]



A = πr2  (circle).

Though the dissection used in this formula is only approximate, the error becomes smaller and smaller as the circle is partitioned into more and more sectors. The limit of the areas of the approximate parallelograms is exactly πr2, which is the area of the circle.[24]


This argument is actually a simple application of the ideas of calculus. In ancient times, the method of exhaustion was used in a similar way to find the area of the circle, and this method is now recognized as a precursor to integral calculus. Using modern methods, the area of a circle can be computed using a definite integral:


A=2∫−rrr2−x2dx=πr2.displaystyle A;=;2int _-r^rsqrt r^2-x^2,dx;=;pi r^2.displaystyle A;=;2int _-r^rsqrt r^2-x^2,dx;=;pi r^2.


Ellipses



The formula for the area enclosed by an ellipse is related to the formula of a circle; for an ellipse with semi-major and semi-minor axes x and y the formula is:[2]


A=πxy.displaystyle A=pi xy.displaystyle A=pi xy.


Surface area




A blue sphere inside a cylinder of the same height and radius


Archimedes showed that the surface area of a sphere is exactly four times the area of a flat disk of the same radius, and the volume enclosed by the sphere is exactly 2/3 of the volume of a cylinder of the same height and radius.


Most basic formulas for surface area can be obtained by cutting surfaces and flattening them out. For example, if the side surface of a cylinder (or any prism) is cut lengthwise, the surface can be flattened out into a rectangle. Similarly, if a cut is made along the side of a cone, the side surface can be flattened out into a sector of a circle, and the resulting area computed.


The formula for the surface area of a sphere is more difficult to derive: because a sphere has nonzero Gaussian curvature, it cannot be flattened out. The formula for the surface area of a sphere was first obtained by Archimedes in his work On the Sphere and Cylinder. The formula is:[6]



A = 4πr2  (sphere),

where r is the radius of the sphere. As with the formula for the area of a circle, any derivation of this formula inherently uses methods similar to calculus.



General formulas



Areas of 2-dimensional figures


  • A triangle: 12Bhdisplaystyle tfrac 12Bhtfrac 12Bh (where B is any side, and h is the distance from the line on which B lies to the other vertex of the triangle). This formula can be used if the height h is known. If the lengths of the three sides are known then Heron's formula can be used: s(s−a)(s−b)(s−c)displaystyle sqrt s(s-a)(s-b)(s-c)sqrt s(s-a)(s-b)(s-c) where a, b, c are the sides of the triangle, and s=12(a+b+c)displaystyle s=tfrac 12(a+b+c)s=tfrac 12(a+b+c) is half of its perimeter.[2] If an angle and its two included sides are given, the area is 12absin⁡(C)displaystyle tfrac 12absin(C)tfrac 12absin(C) where C is the given angle and a and b are its included sides.[2] If the triangle is graphed on a coordinate plane, a matrix can be used and is simplified to the absolute value of 12(x1y2+x2y3+x3y1−x2y1−x3y2−x1y3)displaystyle tfrac 12(x_1y_2+x_2y_3+x_3y_1-x_2y_1-x_3y_2-x_1y_3)tfrac 12(x_1y_2+x_2y_3+x_3y_1-x_2y_1-x_3y_2-x_1y_3). This formula is also known as the shoelace formula and is an easy way to solve for the area of a coordinate triangle by substituting the 3 points (x1,y1), (x2,y2), and (x3,y3). The shoelace formula can also be used to find the areas of other polygons when their vertices are known. Another approach for a coordinate triangle is to use calculus to find the area.

  • A simple polygon constructed on a grid of equal-distanced points (i.e., points with integer coordinates) such that all the polygon's vertices are grid points: i+b2−1displaystyle i+frac b2-1i+frac b2-1, where i is the number of grid points inside the polygon and b is the number of boundary points. This result is known as Pick's theorem.[25]


Area in calculus



A diagram showing the area between a given curve and the x-axis

Integration can be thought of as measuring the area under a curve, defined by f(x), between two points (here a and b).



A diagram showing the area between two functions

The area between two graphs can be evaluated by calculating the difference between the integrals of the two functions


  • The area between a positive-valued curve and the horizontal axis, measured between two values a and b (b is defined as the larger of the two values) on the horizontal axis, is given by the integral from a to b of the function that represents the curve:[1]
A=∫abf(x)dx.displaystyle A=int _a^bf(x),dx.displaystyle A=int _a^bf(x),dx.
  • The area between the graphs of two functions is equal to the integral of one function, f(x), minus the integral of the other function, g(x):

A=∫ab(f(x)−g(x))dx,displaystyle A=int _a^b(f(x)-g(x)),dx,displaystyle A=int _a^b(f(x)-g(x)),dx, where f(x)displaystyle f(x)f(x) is the curve with the greater y-value.
  • An area bounded by a function r = r(θ) expressed in polar coordinates is:[1]
A=12∫r2dθ.displaystyle A=1 over 2int r^2,dtheta .displaystyle A=1 over 2int r^2,dtheta .
  • The area enclosed by a parametric curve u→(t)=(x(t),y(t))displaystyle vec u(t)=(x(t),y(t))vec u(t)=(x(t),y(t)) with endpoints u→(t0)=u→(t1)displaystyle vec u(t_0)=vec u(t_1)vec u(t_0)=vec u(t_1) is given by the line integrals:
∮t0t1⁡xy˙dt=−∮t0t1⁡yx˙dt=12∮t0t1⁡(xy˙−yx˙)dtdisplaystyle oint _t_0^t_1xdot y,dt=-oint _t_0^t_1ydot x,dt=1 over 2oint _t_0^t_1(xdot y-ydot x),dtoint _t_0^t_1xdot y,dt=-oint _t_0^t_1ydot x,dt=1 over 2oint _t_0^t_1(xdot y-ydot x),dt

(see Green's theorem) or the z-component of


12∮t0t1⁡u→×u→˙dt.displaystyle 1 over 2oint _t_0^t_1vec utimes dot vec u,dt.1 over 2oint _t_0^t_1vec utimes dot vec u,dt.


Bounded area between two quadratic functions


To find the bounded area between two quadratic functions, we subtract one from the other to write the difference as


f(x)−g(x)=ax2+bx+c=a(x−α)(x−β)displaystyle f(x)-g(x)=ax^2+bx+c=a(x-alpha )(x-beta )displaystyle f(x)-g(x)=ax^2+bx+c=a(x-alpha )(x-beta )

where f(x) is the quadratic upper bound and g(x) is the quadratic lower bound. Define the discriminant of f(x)-g(x) as


Δ=b2−4ac.displaystyle Delta =b^2-4ac.Delta =b^2-4ac.

By simplifying the integral formula between the graphs of two functions (as given in the section above) and using Vieta's formula, we can obtain[26][27]


A=ΔΔ6a2=a6(β−α)3,a≠0.displaystyle A=frac Delta sqrt Delta 6a^2=frac a6(beta -alpha )^3,qquad aneq 0.displaystyle A=frac Delta sqrt Delta 6a^2=frac a6(beta -alpha )^3,qquad aneq 0.

The above remains valid if one of the bounding functions is linear instead of quadratic.



Surface area of 3-dimensional figures



  • Cone:[28]πr(r+r2+h2)displaystyle pi rleft(r+sqrt r^2+h^2right)pi rleft(r+sqrt r^2+h^2right), where r is the radius of the circular base, and h is the height. That can also be rewritten as πr2+πrldisplaystyle pi r^2+pi rlpi r^2+pi rl[28] or πr(r+l)displaystyle pi r(r+l),!pi r(r+l),! where r is the radius and l is the slant height of the cone. πr2displaystyle pi r^2pi r^2 is the base area while πrldisplaystyle pi rlpi rl is the lateral surface area of the cone.[28]


  • cube: 6s2displaystyle 6s^26s^2, where s is the length of an edge.[6]


  • cylinder: 2πr(r+h)displaystyle 2pi r(r+h)2pi r(r+h), where r is the radius of a base and h is the height. The 2πdisplaystyle pi pi r can also be rewritten as πdisplaystyle pi pi d, where d is the diameter.


  • prism: 2B + Ph, where B is the area of a base, P is the perimeter of a base, and h is the height of the prism.


  • pyramid: B+PL2displaystyle B+frac PL2B + fracPL2, where B is the area of the base, P is the perimeter of the base, and L is the length of the slant.


  • rectangular prism: 2(ℓw+ℓh+wh)displaystyle 2(ell w+ell h+wh)2(ell w+ell h+wh), where ℓdisplaystyle ell ell is the length, w is the width, and h is the height.


General formula for surface area


The general formula for the surface area of the graph of a continuously differentiable function z=f(x,y),displaystyle z=f(x,y),z=f(x,y), where (x,y)∈D⊂R2displaystyle (x,y)in Dsubset mathbb R ^2(x,y)in Dsubset mathbb R^2 and Ddisplaystyle DD is a region in the xy-plane with the smooth boundary:


A=∬D(∂f∂x)2+(∂f∂y)2+1dxdy.displaystyle A=iint _Dsqrt left(frac partial fpartial xright)^2+left(frac partial fpartial yright)^2+1,dx,dy.A=iint _Dsqrt left(frac partial fpartial xright)^2+left(frac partial fpartial yright)^2+1,dx,dy.

An even more general formula for the area of the graph of a parametric surface in the vector form r=r(u,v),displaystyle mathbf r =mathbf r (u,v),mathbf r=mathbf r(u,v), where rdisplaystyle mathbf r mathbf r is a continuously differentiable vector function of (u,v)∈D⊂R2displaystyle (u,v)in Dsubset mathbb R ^2(u,v)in Dsubset mathbb R^2 is:[8]


A=∬D|∂r∂u×∂r∂v|dudv.frac partial mathbf r partial utimes frac partial mathbf r partial vrightA=iint _Dleft|frac partial mathbf rpartial utimes frac partial mathbf rpartial vright|,du,dv.


List of formulas














































































Additional common formulas for area:
Shape
Formula
Variables
Regular triangle (equilateral triangle)

34s2displaystyle frac sqrt 34s^2,!frac sqrt 34s^2,!

sdisplaystyle ss is the length of one side of the triangle.

Triangle[1]

s(s−a)(s−b)(s−c)displaystyle sqrt s(s-a)(s-b)(s-c),!sqrt s(s-a)(s-b)(s-c),!

sdisplaystyle ss is half the perimeter, adisplaystyle aa, bdisplaystyle bb and cdisplaystyle cc are the length of each side.

Triangle[2]

12absin⁡(C)displaystyle tfrac 12absin(C),!tfrac 12absin(C),!

adisplaystyle aa and bdisplaystyle bb are any two sides, and Cdisplaystyle CC is the angle between them.

Triangle[1]

12bhdisplaystyle tfrac 12bh,!tfrac 12bh,!

bdisplaystyle bb and hdisplaystyle hh are the base and altitude (measured perpendicular to the base), respectively.

Isosceles triangle

12ba2−b24=b44a2−b2displaystyle frac 12bsqrt a^2-frac b^24=frac b4sqrt 4a^2-b^2frac 12bsqrt a^2-frac b^24=frac b4sqrt 4a^2-b^2

adisplaystyle aa is the length of one of the two equal sides and bdisplaystyle bb is the length of a different side.

Rhombus/Kite

12abdisplaystyle tfrac 12abtfrac 12ab

adisplaystyle aa and bdisplaystyle bb are the lengths of the two diagonals of the rhombus or kite.

Parallelogram

bhdisplaystyle bh,!bh,!

bdisplaystyle bb is the length of the base and hdisplaystyle hh is the perpendicular height.

Trapezoid

(a+b)h2displaystyle frac (a+b)h2,!frac (a+b)h2,!

adisplaystyle aa and bdisplaystyle bb are the parallel sides and hdisplaystyle hh the distance (height) between the parallels.
Regular hexagon

323s2displaystyle frac 32sqrt 3s^2,!frac 32sqrt 3s^2,!

sdisplaystyle ss is the length of one side of the hexagon.
Regular octagon

2(1+2)s2displaystyle 2(1+sqrt 2)s^2,!2(1+sqrt 2)s^2,!

sdisplaystyle ss is the length of one side of the octagon.

Regular polygon

14nl2⋅cot⁡(π/n)displaystyle frac 14nl^2cdot cot(pi /n),!frac 14nl^2cdot cot(pi /n),!

ldisplaystyle ll is the side length and ndisplaystyle nn is the number of sides.
Regular polygon

14np2⋅cot⁡(π/n)displaystyle frac 14np^2cdot cot(pi /n),!frac 14np^2cdot cot(pi /n),!

pdisplaystyle pp is the perimeter and ndisplaystyle nn is the number of sides.
Regular polygon

12nR2⋅sin⁡(2π/n)=nr2tan⁡(π/n)displaystyle frac 12nR^2cdot sin(2pi /n)=nr^2tan(pi /n),!frac 12nR^2cdot sin(2pi /n)=nr^2tan(pi /n),!

Rdisplaystyle RR is the radius of a circumscribed circle, rdisplaystyle rr is the radius of an inscribed circle, and ndisplaystyle nn is the number of sides.
Regular polygon

12ap=12nsadisplaystyle tfrac 12ap=tfrac 12nsa,!tfrac 12ap=tfrac 12nsa,!

ndisplaystyle nn is the number of sides, sdisplaystyle ss is the side length, adisplaystyle aa is the apothem, or the radius of an inscribed circle in the polygon, and pdisplaystyle pp is the perimeter of the polygon.

Circle

πr2 or πd24displaystyle pi r^2 textor frac pi d^24,!pi r^2 textor frac pi d^24,!

rdisplaystyle rr is the radius and ddisplaystyle dd the diameter.

Circular sector

θ2r2 or L⋅r2displaystyle frac theta 2r^2 textor frac Lcdot r2,!frac theta 2r^2 textor frac Lcdot r2,!

rdisplaystyle rr and θdisplaystyle theta theta are the radius and angle (in radians), respectively and Ldisplaystyle LL is the length of the perimeter.

Ellipse[2]

πabdisplaystyle pi ab,!pi ab,!

adisplaystyle aa and bdisplaystyle bb are the semi-major and semi-minor axes, respectively.
Total surface area of a cylinder

2πr(r+h)displaystyle 2pi r(r+h),!2pi r(r+h),!

rdisplaystyle rr and hdisplaystyle hh are the radius and height, respectively.
Lateral surface area of a cylinder

2πrhdisplaystyle 2pi rh,!2pi rh,!

rdisplaystyle rr and hdisplaystyle hh are the radius and height, respectively.
Total surface area of a sphere[6]
4πr2 or πd2displaystyle 4pi r^2 textor pi d^2,!4pi r^2 textor pi d^2,!

rdisplaystyle rr and ddisplaystyle dd are the radius and diameter, respectively.
Total surface area of a pyramid[6]
B+PL2displaystyle B+frac PL2,!B+frac PL2,!

Bdisplaystyle BB is the base area, Pdisplaystyle PP is the base perimeter and Ldisplaystyle LL is the slant height.
Total surface area of a pyramid frustum[6]
B+PL2displaystyle B+frac PL2,!B+frac PL2,!

Bdisplaystyle BB is the base area, Pdisplaystyle PP is the base perimeter and Ldisplaystyle LL is the slant height.

Square to circular area conversion

4πAdisplaystyle frac 4pi A,!frac 4pi A,!

Adisplaystyle AA is the area of the square in square units.

Circular to square area conversion

π4Cdisplaystyle frac pi 4C,!frac pi 4C,!

Cdisplaystyle CC is the area of the circle in circular units.

The above calculations show how to find the areas of many common shapes.


The areas of irregular polygons can be calculated using the "Surveyor's formula".[24]



Relation of area to perimeter


The isoperimetric inequality states that, for a closed curve of length L (so the region it encloses has perimeter L) and for area A of the region that it encloses,


4πA≤L2,displaystyle 4pi Aleq L^2,4pi Aleq L^2,

and equality holds if and only if the curve is a circle. Thus a circle has the largest area of any closed figure with a given perimeter.


At the other extreme, a figure with given perimeter L could have an arbitrarily small area, as illustrated by a rhombus that is "tipped over" arbitrarily far so that two of its angles are arbitrarily close to 0° and the other two are arbitrarily close to 180°.


For a circle, the ratio of the area to the circumference (the term for the perimeter of a circle) equals half the radius r. This can be seen from the area formula πr2 and the circumference formula 2πr.


The area of a regular polygon is half its perimeter times the apothem (where the apothem is the distance from the center to the nearest point on any side).



Fractals


Doubling the edge lengths of a polygon multiplies its area by four, which is two (the ratio of the new to the old side length) raised to the power of two (the dimension of the space the polygon resides in). But if the one-dimensional lengths of a fractal drawn in two dimensions are all doubled, the spatial content of the fractal scales by a power of two that is not necessarily an integer. This power is called the fractal dimension of the fractal.
[29]



Area bisectors



There are an infinitude of lines that bisect the area of a triangle. Three of them are the medians of the triangle (which connect the sides' midpoints with the opposite vertices), and these are concurrent at the triangle's centroid; indeed, they are the only area bisectors that go through the centroid. Any line through a triangle that splits both the triangle's area and its perimeter in half goes through the triangle's incenter (the center of its incircle). There are either one, two, or three of these for any given triangle.


Any line through the midpoint of a parallelogram bisects the area.


All area bisectors of a circle or other ellipse go through the center, and any chords through the center bisect the area. In the case of a circle they are the diameters of the circle.



Optimization


Given a wire contour, the surface of least area spanning ("filling") it is a minimal surface. Familiar examples include soap bubbles.


The question of the filling area of the Riemannian circle remains open.[30]


The circle has the largest area of any two-dimensional object having the same perimeter.


A cyclic polygon (one inscribed in a circle) has the largest area of any polygon with a given number of sides of the same lengths.


A version of the isoperimetric inequality for triangles states that the triangle of greatest area among all those with a given perimeter is equilateral.[31]


The triangle of largest area of all those inscribed in a given circle is equilateral; and the triangle of smallest area of all those circumscribed around a given circle is equilateral.[32]


The ratio of the area of the incircle to the area of an equilateral triangle, π33displaystyle frac pi 3sqrt 3frac pi 3sqrt 3, is larger than that of any non-equilateral triangle.[33]


The ratio of the area to the square of the perimeter of an equilateral triangle, 1123,displaystyle frac 112sqrt 3,frac112sqrt3, is larger than that for any other triangle.[31]



See also



  • Brahmagupta quadrilateral, a cyclic quadrilateral with integer sides, integer diagonals, and integer area.

  • Equi-areal mapping


  • Heronian triangle, a triangle with integer sides and integer area.

  • List of triangle inequalities#Area


  • One-seventh area triangle, an inner triangle with one-seventh the area of the reference triangle.


  • Routh's theorem, a generalization of the one-seventh area triangle.

  • Orders of magnitude (area)—A list of areas by size.

  • Pentagon#Derivation of the area formula


  • Planimeter, an instrument for measuring small areas, e.g. on maps.

  • Quadrilateral#Area of a convex quadrilateral

  • Region (mathematics)


  • Robbins pentagon, a cyclic pentagon whose side lengths and area are all rational numbers.


References




  1. ^ abcdefgh Weisstein, Eric W. "Area". Wolfram MathWorld. Archived from the original on 5 May 2012. Retrieved 3 July 2012..mw-parser-output cite.citationfont-style:inherit.mw-parser-output .citation qquotes:"""""""'""'".mw-parser-output .citation .cs1-lock-free abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/6/65/Lock-green.svg/9px-Lock-green.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .citation .cs1-lock-limited a,.mw-parser-output .citation .cs1-lock-registration abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/d/d6/Lock-gray-alt-2.svg/9px-Lock-gray-alt-2.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .citation .cs1-lock-subscription abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/a/aa/Lock-red-alt-2.svg/9px-Lock-red-alt-2.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .cs1-subscription,.mw-parser-output .cs1-registrationcolor:#555.mw-parser-output .cs1-subscription span,.mw-parser-output .cs1-registration spanborder-bottom:1px dotted;cursor:help.mw-parser-output .cs1-ws-icon abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/4/4c/Wikisource-logo.svg/12px-Wikisource-logo.svg.png")no-repeat;background-position:right .1em center.mw-parser-output code.cs1-codecolor:inherit;background:inherit;border:inherit;padding:inherit.mw-parser-output .cs1-hidden-errordisplay:none;font-size:100%.mw-parser-output .cs1-visible-errorfont-size:100%.mw-parser-output .cs1-maintdisplay:none;color:#33aa33;margin-left:0.3em.mw-parser-output .cs1-subscription,.mw-parser-output .cs1-registration,.mw-parser-output .cs1-formatfont-size:95%.mw-parser-output .cs1-kern-left,.mw-parser-output .cs1-kern-wl-leftpadding-left:0.2em.mw-parser-output .cs1-kern-right,.mw-parser-output .cs1-kern-wl-rightpadding-right:0.2em


  2. ^ abcdefghijk "Area Formulas". Math.com. Archived from the original on 2 July 2012. Retrieved 2 July 2012.


  3. ^ ab Bureau International des Poids et Mesures Resolution 12 of the 11th meeting of the CGPM (1960) Archived 2013-04-14 at WebCite, retrieved 15 July 2012


  4. ^ Mark de Berg; Marc van Kreveld; Mark Overmars; Otfried Schwarzkopf (2000). "Chapter 3: Polygon Triangulation". Computational Geometry (2nd revised ed.). Springer-Verlag. pp. 45–61. ISBN 978-3-540-65620-3.


  5. ^ Boyer, Carl B. (1959). A History of the Calculus and Its Conceptual Development. Dover. ISBN 978-0-486-60509-8.


  6. ^ abcdef Weisstein, Eric W. "Surface Area". Wolfram MathWorld. Archived from the original on 23 June 2012. Retrieved 3 July 2012.


  7. ^ Foundation, CK-12. "Surface Area". CK-12 Foundation. Retrieved 2018-10-09.


  8. ^ ab do Carmo, Manfredo (1976). Differential Geometry of Curves and Surfaces. Prentice-Hall. p. 98,
    ISBN 978-0-13-212589-5



  9. ^ Walter Rudin (1966). Real and Complex Analysis, McGraw-Hill,
    ISBN 0-07-100276-6.



  10. ^ Gerald Folland (1999). Real Analysis: modern techniques and their applications, John Wiley & Sons, Inc., p. 20,
    ISBN 0-471-31716-0



  11. ^ Moise, Edwin (1963). Elementary Geometry from an Advanced Standpoint. Addison-Wesley Pub. Co. Retrieved 15 July 2012.


  12. ^ abcd Bureau international des poids et mesures (2006). "The International System of Units (SI)" (PDF). 8th ed. Archived (PDF) from the original on 2013-11-05. Retrieved 2008-02-13. Chapter 5.


  13. ^ Heath, Thomas L. (2003), A Manual of Greek Mathematics, Courier Dover Publications, pp. 121–132, ISBN 978-0-486-43231-1, archived from the original on 2016-05-01


  14. ^ Stewart, James (2003). Single variable calculus early transcendentals (5th. ed.). Toronto ON: Brook/Cole. p. 3. ISBN 978-0-534-39330-4. Archived from the original on 2012-08-15. However, by indirect reasoning, Eudoxus (fifth century B.C.) used exhaustion to prove the familiar formula for the area of a circle: A=πr2.displaystyle A=pi r^2.A= pi r^2.


  15. ^ ab Arndt, Jörg; Haene l, Christoph (2006). Pi Unleashed. Springer-Verlag. ISBN 978-3-540-66572-4. Retrieved 2013-06-05. English translation by Catriona and David Lischka.


  16. ^ Eves, Howard (1990), An Introduction to the History of Mathematics (6th ed.), Saunders, p. 121, ISBN 978-0-03-029558-4


  17. ^ Heath, Thomas L. (1921). A History of Greek Mathematics (Vol II). Oxford University Press. pp. 321–323.


  18. ^ Weisstein, Eric W. "Heron's Formula". MathWorld.


  19. ^ Bourke, Paul (July 1988). "Calculating The Area And Centroid Of A Polygon" (PDF). Archived (PDF) from the original on 2012-09-16. Retrieved 6 Feb 2013.


  20. ^ "Area of Parallelogram/Rectangle". ProofWiki.org. Archived from the original on 20 June 2015. Retrieved 29 May 2016.


  21. ^ "Area of Square". ProofWiki.org. Archived from the original on 4 November 2017. Retrieved 29 May 2016.


  22. ^ Averbach, Bonnie; Chein, Orin (2012), Problem Solving Through Recreational Mathematics, Dover, p. 306, ISBN 978-0-486-13174-0, archived from the original on 2016-05-13


  23. ^ Joshi, K. D. (2002), Calculus for Scientists and Engineers: An Analytical Approach, CRC Press, p. 43, ISBN 978-0-8493-1319-6, archived from the original on 2016-05-05


  24. ^ ab Braden, Bart (September 1986). "The Surveyor's Area Formula" (PDF). The College Mathematics Journal. 17 (4): 326–337. doi:10.2307/2686282. JSTOR 2686282. Archived (PDF) from the original on 27 June 2012. Retrieved 15 July 2012.


  25. ^ Trainin, J. (November 2007). "An elementary proof of Pick's theorem". Mathematical Gazette. 91 (522): 536–540.


  26. ^ Matematika. PT Grafindo Media Pratama. pp. 51–. ISBN 978-979-758-477-1. Archived from the original on 2017-03-20.


  27. ^ Get Success UN +SPMB Matematika. PT Grafindo Media Pratama. pp. 157–. ISBN 978-602-00-0090-9. Archived from the original on 2016-12-23.


  28. ^ abc Weisstein, Eric W. "Cone". Wolfram MathWorld. Archived from the original on 21 June 2012. Retrieved 6 July 2012.


  29. ^
    Mandelbrot, Benoît B. (1983). The fractal geometry of nature. Macmillan. ISBN 978-0-7167-1186-5. Archived from the original on 20 March 2017. Retrieved 1 February 2012.



  30. ^ Gromov, Mikhael (1983), "Filling Riemannian manifolds", Journal of Differential Geometry, 18 (1): 1–147, CiteSeerX 10.1.1.400.9154, MR 0697984, archived from the original on 2014-04-08


  31. ^ ab Chakerian, G.D. (1979) "A Distorted View of Geometry." Ch. 7 in Mathematical Plums. R. Honsberger (ed.). Washington, DC: Mathematical Association of America, p. 147.


  32. ^ Dorrie, Heinrich (1965), 100 Great Problems of Elementary Mathematics, Dover Publ., pp. 379–380.


  33. ^ Minda, D.; Phelps, S. (October 2008). "Triangles, ellipses, and cubic polynomials". American Mathematical Monthly. 115 (8): 679–689: Theorem 4.1. JSTOR 27642581. Archived from the original on 2016-11-04.




External links











這個網誌中的熱門文章

How to read a connectionString WITH PROVIDER in .NET Core?

Node.js Script on GitHub Pages or Amazon S3

Museum of Modern and Contemporary Art of Trento and Rovereto