The Pythagorean trigonometric identity, also called simply the Pythagorean identity, is an identity expressing the

Pythagorean theorem In mathematics, the Pythagorean theorem or Pythagoras' theorem is a fundamental relation in Euclidean geometry between the three sides of a right triangle. It states that the area of the square whose side is the hypotenuse (the side opposite t ...

in terms of trigonometric functions. Along with the sum-of-angles formulae, it is one of the basic relations between the

sine In mathematics, sine and cosine are trigonometric functions of an angle. The sine and cosine of an acute angle are defined in the context of a right triangle: for the specified angle, its sine is the ratio of the length of the side that is oppo ...

and cosine functions. The identity is :

\sin^2 \theta + \cos^2 \theta = 1.

As usual, means

(\sin\theta)^2

Proofs and their relationships to the Pythagorean theorem

Proof based on right-angle triangles

Any similar triangles have the property that if we select the same angle in all of them, the ratio of the two sides defining the angle is the same regardless of which similar triangle is selected, regardless of its actual size: the ratios depend upon the three angles, not the lengths of the sides. Thus for either of the similar right triangles in the figure, the ratio of its horizontal side to its hypotenuse is the same, namely cos θ. The elementary definitions of the sine and cosine functions in terms of the sides of a right triangle are: :

\sin \theta = \frac= \frac

\cos \theta = \frac = \frac

The Pythagorean identity follows by squaring both definitions above, and adding; the

left-hand side In mathematics, LHS is informal shorthand for the left-hand side of an equation. Similarly, RHS is the right-hand side. The two sides have the same value, expressed differently, since equality is symmetric.Trigonometric symmetry, shifts, and periodicity may be employed. By the periodicity identities we can say if the formula is true for then it is true for all real ''θ''. Next we prove the range to do this we let ''t'' will now be in the range We can then make use of squared versions of some basic shift identities (squaring conveniently removes the minus signs): :

\sin^2\theta+\cos^2\theta = \sin^2\left(t+\frac\pi\right) + \cos^2\left(t+\frac\pi\right) = \cos^2t+\sin^2t = 1.

All that remains is to prove it for this can be done by squaring the symmetry identities to get :

\sin^2\theta=\sin^2(-\theta)\text\cos^2\theta=\cos^2(-\theta).

Related identities

Trigonometric functions and their reciprocals on the unit circle

The identities :

1 + \tan^2 \theta = \sec^2 \theta

and :

1 + \cot^2 \theta = \csc^2 \theta

are also called Pythagorean trigonometric identities. If one leg of a right triangle has length 1, then the tangent of the angle adjacent to that leg is the length of the other leg, and the secant of the angle is the length of the hypotenuse. :

\tan \theta =\frac \ ,

and: :

\sec \theta = \frac \ .

In this way, this trigonometric identity involving the tangent and the secant follows from the Pythagorean theorem. The angle opposite the leg of length 1 (this angle can be labeled φ = π/2 − θ) has cotangent equal to the length of the other leg, and cosecant equal to the length of the hypotenuse. In that way, this trigonometric identity involving the cotangent and the cosecant also follows from the Pythagorean theorem. The following table gives the identities with the factor or divisor that relates them to the main identity.

Proof using the unit circle

The unit circle centered at the origin in the Euclidean plane is defined by the equation: This result can be found using the distance formula

d = \sqrt

for the distance from the origin to the point

(x,\ y)

. See This approach assumes Pythagoras' theorem. Alternatively, one could simply substitute values and determine that the graph is a circle. :

x^2 + y^2 = 1.

Given an angle θ, there is a unique point ''P'' on the unit circle at an angle θ from the ''x''-axis, and the ''x''- and ''y''-coordinates of ''P'' are: :

x = \cos \theta \ \mathrm  \ y = \sin \theta \ .

Consequently, from the equation for the unit circle: :

\cos^2 \theta + \sin^2 \theta = 1 \ ,

the Pythagorean identity. In the figure, the point ''P'' has a ''negative'' x-coordinate, and is appropriately given by ''x'' = cos''θ'', which is a negative number: cos''θ'' = −cos(π−''θ'' ). Point ''P'' has a positive ''y''-coordinate, and sin''θ'' = sin(π−''θ'' ) > 0. As ''θ'' increases from zero to the full circle ''θ'' = 2π, the sine and cosine change signs in the various quadrants to keep ''x'' and ''y'' with the correct signs. The figure shows how the sign of the sine function varies as the angle changes quadrant. Because the ''x''- and ''y''-axes are perpendicular, this Pythagorean identity is equivalent to the Pythagorean theorem for triangles with hypotenuse of length 1 (which is in turn equivalent to the full Pythagorean theorem by applying a similar-triangles argument). See unit circle for a short explanation.

Proof using power series

The trigonometric functions may also be defined using power series, namely (for ''x'' an angle measured in radians): :

\begin
  \sin x &= \sum_^\infty \frac x^,\\
  \cos x &= \sum_^\infty \frac x^.
\end

Using the formal multiplication law for power series at Multiplication and division of power series (suitably modified to account for the form of the series here) we obtain :

\begin
\sin^2 x & = \sum_^\infty \sum_^\infty \frac \frac x^ \\
& = \sum_^\infty \left(\sum_^ \frac\right) x^ \\
& = \sum_^\infty \left( \sum_^  \right) \frac x^,\\
\cos^2 x & = \sum_^\infty \sum_^\infty \frac \frac x^ \\
& = \sum_^\infty \left(\sum_^n \frac\right) x^ \\
& = \sum_^\infty \left( \sum_^n  \right) \frac x^.
\end

In the expression for sin², ''n'' must be at least 1, while in the expression for cos², the constant term is equal to 1. The remaining terms of their sum are (with common factors removed) :

\sum_^n  - \sum_^ 
= \sum_^ (-1)^j 
= (1 - 1)^
= 0

by the binomial theorem. Consequently, :

\sin^2 x + \cos^2 x = 1 \ ,

which is the Pythagorean trigonometric identity. When the trigonometric functions are defined in this way, the identity in combination with the Pythagorean theorem shows that these power series parameterize the unit circle, which we used in the previous section. This definition constructs the sine and cosine functions in a rigorous fashion and proves that they are differentiable, so that in fact it subsumes the previous two.

Proof using the differential equation

Sine and cosine can be defined as the two solutions to the differential equation: ::

y'' + y = 0

satisfying respectively and . It follows from the theory of ordinary differential equations that the first solution, sine, has the second, cosine, as its derivative, and it follows from this that the derivative of cosine is the negative of the sine. The identity is equivalent to the assertion that the function :

z = \sin^2 x + \cos^2 x

is constant and equal to 1. Differentiating using the chain rule gives: :

\frac z = 2 \sin x \ \cos x + 2 \cos x \ (-\sin x) = 0 \ ,

so ''z'' is constant. A calculation confirms that ''z''(0) = 1, and ''z'' is a constant so ''z'' = 1 for all ''x'', so the Pythagorean identity is established. A similar proof can be completed using power series as above to establish that the sine has as its derivative the cosine, and the cosine has as its derivative the negative sine. In fact, the definitions by ordinary differential equation and by power series lead to similar derivations of most identities. This proof of the identity has no direct connection with Euclid's demonstration of the Pythagorean theorem.

Proof using Euler's formula

Euler's formula states that :

e^ = \cos\theta + i\sin\theta

So, :

\sin^2 \theta + \cos^2 \theta = (\cos\theta + i\sin\theta)(\cos\theta - i\sin\theta) = e^e^ = 1

Notes

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