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assuredlonewo
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How where all the possible tangents, cosines, and sines of angles found?
How where all the possible tangents, cosines, and sines of angles found?
- Thread starter assuredlonewo
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In summary, the concept of sine was developed through the use of geometry and interpolation, and was used in ancient times to calculate sines of specific angles. In the 20th century, mathematicians discovered the infinite series for sine, allowing for more accurate calculations. Personal electronic calculators with trig function capabilities became available in the 1970s.
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Hi assuredlonewo 
What do you mean with this question. I understand it in three ways:
- How did they come up with the concept of sine
- how did they find the sine of a specific nice angle, say 45°
- how do they find the sine of all possible angles
Which of these (if any) do you mean?
What do you mean with this question. I understand it in three ways:
- How did they come up with the concept of sine
- how did they find the sine of a specific nice angle, say 45°
- how do they find the sine of all possible angles
Which of these (if any) do you mean?
- #3
assuredlonewo
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micromass said:Hi assuredlonewo
What do you mean with this question. I understand it in three ways:
- How did they come up with the concept of sine
- how did they find the sine of a specific nice angle, say 45°
- how do they find the sine of all possible angles
Which of these (if any) do you mean?
how do they find the sine of all possible angles
- #4
Studiot
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Trigonometric functions like sin, cos and tan can be calculated as the sum of a series to any desired accuracy by taking sufficient terms.
This is how trigonometric tables were originally prepared.
For example the sin of any angle is given by
[tex]\sin (x) = x - \frac{{{x^3}}}{{3*2*1}} + \frac{{{x^5}}}{{5*4*3*2*1}} - \frac{{{x^7}}}{{7*6*5*4*3*2*1}}[/tex]
If you ask a computer or calculator for sin(x) it works the value out this way each time, it does not store tables.
go well
This is how trigonometric tables were originally prepared.
For example the sin of any angle is given by
[tex]\sin (x) = x - \frac{{{x^3}}}{{3*2*1}} + \frac{{{x^5}}}{{5*4*3*2*1}} - \frac{{{x^7}}}{{7*6*5*4*3*2*1}}[/tex]
If you ask a computer or calculator for sin(x) it works the value out this way each time, it does not store tables.
go well
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assuredlonewo
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Thanks studiot, I am going to have to dive deeper into this.
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I don't know how they did it in the ancient times. It was probably just drawing a large enough triangle and measuring correctly. But right now, they can do it amazingly accurate. This is thanks though a tool called "Taylor series".
Briefly, mathematicians have shown that
[tex]\sin(x)=\sum_{n=0}^{+\infty}{\frac{(-1)^nx^{2n+1}}{(2n+1)!}}[/tex].
Of course, this is an infinite sum, so it's not really useful in practice, however, we can limit the sum to obtain a reasonable approximation to the sine. For example, if we take n to 4, then we get
[tex]\sin(x)\approx x-\frac{x^3}{3!}+\frac{x^5}{5!}-\frac{x^7}{7!}+\frac{x^9}{9!}[/tex]
This approximation won't be exact, but it'll be a good approximation nonetheless. If we take n even bigger, then we get even better approximations for sines.
There is however, no exact formula to calculate sines (unless in specific examples). But for most applications, we have no need for exact formula's...
Briefly, mathematicians have shown that
[tex]\sin(x)=\sum_{n=0}^{+\infty}{\frac{(-1)^nx^{2n+1}}{(2n+1)!}}[/tex].
Of course, this is an infinite sum, so it's not really useful in practice, however, we can limit the sum to obtain a reasonable approximation to the sine. For example, if we take n to 4, then we get
[tex]\sin(x)\approx x-\frac{x^3}{3!}+\frac{x^5}{5!}-\frac{x^7}{7!}+\frac{x^9}{9!}[/tex]
This approximation won't be exact, but it'll be a good approximation nonetheless. If we take n even bigger, then we get even better approximations for sines.
There is however, no exact formula to calculate sines (unless in specific examples). But for most applications, we have no need for exact formula's...
- #7
Deveno
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the earliest trigonometric tables were computed using geometry and interpolation. it is possible to construct a (somewhat horrendous) algebraic expression of sin(1 degree) and work from there. many ancient mathematicians devoted a good portion of their lives to creating such tables, which were used as references for centuries.
the concept of sine was not the first basic concept of trigonometry, but came rather later than the concept of a chord (a straight line segment connecting the ends of a circular arc). later, "half-chords" came to be frequently used, these are what we now call sines. all of these developed in the absence of any way of coordinatizing curves.
it was not uncommon, even into the 20th century, for most people using sines to reference tabulated values. for example, when i was young, i owned a book full of such tables, published by the chemical rubber company (and known popularly as "CRC tables"). these are still published, and are a good reference for anyone using mathematics in any kind of professional capacity (filled with all kinds of neat formulas you might want to remember).
the use of infinite series pre-dates calculus somewhat, although even mathematicians got confused as to which series were convergent, and which weren't. it was probably Liebnitz who first found the infinite series for sin(x), allowing values to be calculated to any desired accuracy.
the concept of sine was not the first basic concept of trigonometry, but came rather later than the concept of a chord (a straight line segment connecting the ends of a circular arc). later, "half-chords" came to be frequently used, these are what we now call sines. all of these developed in the absence of any way of coordinatizing curves.
it was not uncommon, even into the 20th century, for most people using sines to reference tabulated values. for example, when i was young, i owned a book full of such tables, published by the chemical rubber company (and known popularly as "CRC tables"). these are still published, and are a good reference for anyone using mathematics in any kind of professional capacity (filled with all kinds of neat formulas you might want to remember).
the use of infinite series pre-dates calculus somewhat, although even mathematicians got confused as to which series were convergent, and which weren't. it was probably Liebnitz who first found the infinite series for sin(x), allowing values to be calculated to any desired accuracy.
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jtbell
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Deveno said:
Personal electronic calculators that could do trig functions became available in about the 1972-1975 period. When I was an undergraduate, my roommate had one of the early Texas Instruments calculators which could not do trig functions. This was about 1973. Shortly after I started graduate school in 1975, I bought my first calculator, a Hewlett-Packard which could do trig functions. Before that, I used a book of tables like the CRC book.
1. How were the original formulas for tangent, cosine, and sine derived?
The original formulas for tangent, cosine, and sine were derived using geometric constructions and ratios in ancient civilizations like Babylon, Egypt, and India. These civilizations used these trigonometric functions for practical purposes such as astronomy and surveying.
2. Who discovered the relationship between tangents, cosines, and sines?
The relationship between tangents, cosines, and sines was first discovered by the Greek mathematician Hipparchus in the 2nd century BC. He developed the first known trigonometric table, which contained values for the tangent function.
3. How did trigonometry evolve over time?
Trigonometry evolved over time as more mathematicians, such as Ptolemy and Aryabhata, contributed to its development. They expanded upon Hipparchus' work and introduced new trigonometric identities and functions. In the 16th century, the concept of radians was introduced, which greatly simplified the calculation of trigonometric functions.
4. How are modern methods used to calculate tangents, cosines, and sines?
Modern methods for calculating tangents, cosines, and sines use advanced mathematical techniques such as calculus, complex numbers, and computer algorithms. These methods allow for more accurate and efficient calculations compared to the geometric constructions used in ancient times.
5. What are some practical applications of trigonometry?
Trigonometry has countless practical applications in fields such as engineering, physics, astronomy, and navigation. It is used to calculate distances and angles, design structures, and analyze wave patterns. It is also essential in the development of technologies such as GPS and radar.
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