Trigonometry

Trigonometry (from Greek ''trigōnon'' "triangle" + ''metron'' "measure"¹), informally called '''trig''', is a branch of Mathematics that deals with Triangle s, particularly triangles in a Plane where one Angle of the triangle is 90 degrees ( Right Angled Triangle s). It specifically deals with the relationships between the sides and the angles of triangles; the Trigonometric Function s, and calculations based upon them. The insights of trigonometry permeate other branches of geometry, such as the study of Sphere s using Spherical Trigonometry .

Trigonometry has important applications in many branches of Pure Mathematics as well as of Applied Mathematics and, consequently remains applicable in natural Science s. Trigonometry is usually taught in Secondary School s, often in a Precalculus course.

robotic manipulator on the International Space Station is operated by controlling the angles of its joints. Calculating the final position of the astronaut at the end of the arm requires repeated use of the trigonometric functions of those angles.]]

HISTORY

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See Also: History of trigonometric functions

Trigonometry was probably invented for use in astronomy.² The origins of trigonometry can be traced to the civilizations of Ancient Egypt , Mesopotamia and the Indus Valley , more than 4000 years ago. The common practice of measuring angles in degrees, minutes and seconds comes from the Babylonia n's Base Sixty system of numeration. The Sulba Sutras written in India, between 800 BC and 500 BC, correctly computes the sine of π /4 (45 ° ) as 1/√2 in a procedure for circling the square (the opposite of Squaring The Circle ).

The first recorded use of trigonometry came from the using the Sine for solving triangles. Ptolemy further developed trigonometric calculations circa 100 AD.

The ancient Sinhalese in Sri Lanka , when constructing reservoirs in the Anuradhapura kingdom, used trigonometry to calculate the gradient of the water flow. Archeological research also provides evidence of trigonometry used in other unique hydrological structures dating back to 4 BC.http://www.lankalibrary.com/phpBB/viewtopic.php?p=1236&sid=88ab8557d1c7c641bb9da7821eded404

The Indian mathematician Aryabhata in 499, gave tables of half chords which are now known as Sine tables, along with Cosine tables. He used ''zya'' for sine, ''kotizya'' for cosine, and ''otkram zya'' for inverse sine, and also introduced the Versine . Another Indian mathematician, Brahmagupta in 628, used an Interpolation formula to compute values of sines, up to the second order of the Newton - Stirling interpolation formula.

In the 10th century, the Persian mathematician and astronomer Abul Wáfa introduced the tangent function and improved methods of calculating trigonometry tables. He established the angle addition identities, e.g. sin (''a'' + ''b''), and discovered the sine formula for spherical geometry:

:

rac{\sin(A)}{\sin(a)} = rac{\sin(B)}{\sin(b)} = rac{\sin(C)}{\sin(c)}.

Also in the late 10th and early 11th centuries, the Egyptian astronomer Ibn Yunus performed many careful trigonometric calculations and demonstrated the formula

\cos(a) \cos(b) = (1/2) + \cos(a-b)

.

Indian Mathematicians were the pioneers of variable computations Algebra for use in astronomical calculations along with trigonometry. Lagadha (circa 1350-1200 BC) is the first person thought to have used geometry and trigonometry for astronomy, in his '' Vedanga Jyotisha ''.

Persian Mathematician Omar Khayyám (1048-1131) combined trigonometry and Approximation Theory to provide methods of solving algebraic equations by geometrical means. Khayyam solved the cubic equation

x^3 + 200 x = 20 x^2 + 2000

and found a positive root of this cubic by considering the intersection of a rectangular Hyperbola and a circle. An approximate numerical solution was then found by interpolation in trigonometric tables.

Detailed methods for constructing a table of sines for any angle were given by the Indian mathematician Bhaskara in 1150, along with some sine and cosine formulae. Bhaskara also developed Spherical Trigonometry .

The 13th century Persian Mathematician Nasir Al-Din Tusi , along with Bhaskara, was probably the first to treat trigonometry as a distinct mathematical discipline. Nasir al-Din Tusi in his ''Treatise on the Quadrilateral'' was the first to list the six distinct cases of a right angled triangle in spherical trigonometry.

In the 14th century, Persian mathematician Al-Kashi and Timurid mathematician Ulugh Beg (grandson of Timur ) produced tables of trigonometric functions as part of their studies of astronomy.

The mathematician Bartholemaeus Pitiscus published an influential work on trigonometry in 1595 which may have coined the word "trigonometry".

OVERVIEW

By definition, one Angle of a right triangle is 90 degrees. If one of the other angles is known, the third can be calculated since all three angles of any triangle must add up to 180 degrees. The Shape of a right triangle is completely determined, up to Similarity , by the angles. This means that once one of the other angles is known, the Ratio s of the various sides are always the same regardless of the overall size of the triangle. These ratios are given by the following Trigonometric Function s of the known angle:

The sine function (sin), defined as the ratio of the side opposite the angle to the hypotenuse.

\sin A=rac{	extrm{opposite}}{	extrm{hypotenuse}}

The cosine function (cos), defined as the ratio of the adjacent leg to the hypotenuse.

\cos A=rac{	extrm{adjacent}}{	extrm{hypotenuse}}

The tangent function (tan), defined as the ratio of the opposite leg to the adjacent leg.

an A=rac{	extrm{opposite}}{	extrm{adjacent}}=rac{\sin A}{\cos A}

The adjacent leg is the side of the angle that is not the hypotenuse. The '''hypotenuse''' is the side opposite to the 90 degree angle in a right triangle; it is the longest side of the triangle. The terms '''perpendicular''' and '''base''' are sometimes used for the opposite and adjacent sides respectively.

The Reciprocals of these functions are named the cosecant (csc or cosec), '''secant''' (sec) and '''cotangent''' (cot), respectively. The Inverse Functions are called the '''arcsine''', '''arccosine''', and '''arctangent''', respectively. There are arithmetic relations between these functions, which are known as Trigonometric Identities .

With these functions one can answer virtually all questions about arbitrary triangles by using the Law Of Sines and the Law Of Cosines . These laws can be used to compute the remaining angles and sides of any triangle as soon as two sides and an angle or two angles and a side or three sides are known. These laws are useful in all branches of geometry, since every Polygon may be described as a finite combination of triangles.

Extending the definitions

The above definitions apply to angles between 0 and 90 degrees (0 and π/2 Radian s) only. Using the Unit Circle , one may extend them to all positive and negative arguments (see Trigonometric Function ). The trigonometric functions are Periodic , with a period of 360 degrees or 2π radians. That means their values repeat at those intervals.

The trigonometric functions can be defined in other ways besides the geometrical definitions above, using tools from Calculus and Infinite Series . With these definitions the trigonometric functions can be defined for Complex Number s. The complex function cis is particularly useful

:

\operatorname{cis} (x) = \cos x + i\sin x \! = e^{ix}

See Euler's Formula .

Mnemonics

Students often make use of Mnemonic s to remember the relationships and facts in trigonometry. For example, the ''sine'', ''cosine'' and ''tangent'' ratios in right triangles can be remembered by representing all three ratios at once as a string of letters; SOH CAH TOA (sine-opposite-hypotenuse cosine-adjacent-hypotenuse tangent-opposite-adjacent), which can be pronounced as a single word. In addition, many remember similar letter sequences by creating sentences that consist of words that begin with the letters to be remembered, so that they are remembered in the correct order. For example, to remember Tan = Opposite/Adjacent, the letters TOA must be remembered in order. Any memorable phrase constructed of words beginning with the letters 'T, O, A' will serve, and often sentences are constructed to remember all three ratios at once. Other types of mnemonic simply describe facts in a simple, memorable way, such as "Plus to the right, minus to the left, positive height, negative depth" when referring to the trigonometric functions of a revolving line.

Rule of quarters

The rule of quarters makes it easy to remember the sine function of special angles:
:

\begin{align}
\sin (0) &=  \sqrt{rac{0}{4}} &= 0\
\sin (30) &=  \sqrt{rac{1}{4}} &= rac {1}{2}\
\sin (45) &=  \sqrt{rac{2}{4}} &= rac {\sqrt{2}}{2}\
\sin (60) &=  \sqrt{rac{3}{4}} &= rac {\sqrt{3}}{2}\
\sin (90) &=  \sqrt{rac{4}{4}} &= 1
\end{align}

Calculating trigonometric functions

See Also: Generating trigonometric tables

Trigonometric functions were among the earliest uses for Mathematical Table s. Such tables were incorporated into mathematics textbooks and students were taught to look up values and how to Interpolate between the values listed to get higher accuracy. Slide Rule s had special scales for trigonometric functions.

Today Scientific Calculator s have buttons for calculating the main trigonometric functions (sin, cos, tan and sometimes cis) and their inverses. Most allow a choice of angle measurement methods, degrees, radians and, sometimes, Grad . Most computer Programming Language s provide function libraries that include the trigonometric functions. The Floating Point Unit hardware incorporated into the microprocessor chips used in most personal computers have built in instructions for calculating trigonometric functions.

APPLICATIONS OF TRIGONOMETRY

s like this are used to measure the angle of the sun or stars with respect to the horizon. Using trigonometry and a Marine Chronometer , the position of the ship can then be determined from several such measurements.]]

See Also: Uses of trigonometry

There are an enormous number of Applications Of Trigonometry and trigonometric functions. For instance, the technique of Triangulation is used in Astronomy to measure the distance to nearby stars, in Geography to measure distances between landmarks, and in Satellite Navigation System s. The sine and cosine functions are fundamental to the theory of Periodic Function s such as those that describe sound and Light waves.

Fields which make use of trigonometry or trigonometric functions include Astronomy (especially, for locating the apparent positions of celestial objects, in which spherical trigonometry is essential) and hence Navigation (on the oceans, in aircraft, and in space), Music Theory , Acoustics , Optics , analysis of financial markets, Electronics , Probability Theory , Statistics , Biology , Medical Imaging ( CAT Scan s and Ultrasound ), Pharmacy , Chemistry , Number Theory (and hence Cryptology ), Seismology , Meteorology , Oceanography , many Physical Science s, land Surveying and Geodesy , Architecture , Phonetics , Economics , Electrical Engineering , Mechanical Engineering , Civil Engineering , Computer Graphics , Cartography , Crystallography and Game Development .

COMMON FORMULAE

See Also: Trigonometric identity

See Also: Trigonometric function

Certain equations involving trigonometric functions are true for all angles and are known as ''trigonometric identities.'' Many express important geometric relationships. For example, the Pythagorean identities are an expression of the Pythagorean Theorem . Here are some of the more commonly used identities, as well as the most important formulae connecting angles and sides of an arbitrary triangle. For more identities see Trigonometric Identity .

Trigonometric identities

Pythagorean identities

:

\begin{align}
\sin^2 A + \cos^2 A &= 1 \
	an^2 A + 1 &= \sec^2 A \
1+\cot^2 A &= \csc^2 A \end{align}

Miscellaneous identities

:

\begin{align}
\cos^6 A &= rac {1}{32}\cos 6A + rac {3}{16}\cos 4A + rac {15}{32}\cos 2A + rac {5}{16} \end{align}

Sum and difference identities

:

\begin{align}
\sin(A \pm B) &= \sin A \cos B \pm \cos A \sin B \
\cos(A \pm B) &= \cos A \cos B \mp \sin A \sin B \
	an(A \pm B) &= rac{	an A \pm 	an B}{1 \mp 	an A 	an B} \
\cot(A \pm B) &= rac{\cot A \cot B \mp 1}{\cot B \pm \cot A}
\end{align}

Sum and product identities

=Sum to product:

:

\begin{align}
\sin(A) \pm \sin (B) &= 2\sin \left( rac{A \pm B}{2}
ight)\cos \left(rac{A \mp B}{2} 
ight)\
\cos(A) + \cos (B) &= 2\cos \left(rac{A + B}{2} 
ight)\cos  \left(rac{A - B}{2}
ight)\
\cos(A) - \cos (B) &= -2\sin \left(rac{A + B}{2} 
ight) \sin \left(rac{A - B}{2}
ight)
\end{align}

=Product to sum:

:

\end{align}

Double-angle identities

:

\begin{align}
\sin 2A &= 2 \sin A \cos A \
        &= rac{2 	an A}{1 + 	an^2 A}\
\cos 2A &= \cos^2 A - \sin^2 A \
        &= 2 \cos^2 A -1 \
        &= 1-2 \sin^2 A \
        &= {1 - 	an^2 A \over 1 + 	an^2 A}\
	an 2A &= rac{2 	an A}{1 - 	an^2 A}\
        &= rac{2 \cot A}{\cot^2 A - 1}\
        &= rac{2}{\cot A - 	an A}
\end{align}

Half-angle identities

Note that

\pm

is correct, it means it may be either one, depending on the value of ''A/2''.

:

\begin{align}
\sin rac{A}{2} &= \pm \sqrt{rac{1-\cos A}{2}} \
\cos rac{A}{2} &= \pm \sqrt{rac{1+\cos A}{2}} \	an rac{A}{2} &= \pm \sqrt{rac{1-\cos A}{1+\cos A}} = rac {\sin A}{1+\cos A} = rac {1-\cos A}{\sin A}
\end{align}

Triangle identities

In the following identities, ''A'', ''B'' and ''C'' are the angles of a triangle and ''a'', ''b'' and ''c'' are the lengths of sides of the triangle opposite the respective angles.

Law of sines

The Law Of Sines for an arbitrary triangle states:

:

rac{a}{\sin A} = rac{b}{\sin B} = rac{c}{\sin C} = 2R

where ''R'' is the radius of the Circumcircle of the triangle.

Law of cosines

The Law Of Cosines (also known as the cosine formula) is an extension of the Pythagorean Theorem to arbitrary triangles:

:

c^2=a^2+b^2-2ab\cos C ,\,

or equivalently:

:

\cos C=rac{a^2+b^2-c^2}{2ab}\,

Law of tangents

The Law Of Tangents :

:

rac{a+b}{a-b}=rac{	an\left[	frac{1}{2}(A+B)
ight]}{	an\left[	frac{1}{2}(A-B)
ight]}

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	geometry

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