# The Seqed and Modern Trigonometry Exploration

## The Seqed and the Cotangent

Several of the problems in the Rhind papyrus compute the so called seqed of a pyramid. The Egyptians computed the ratio (half the base)/height.

In the image of the triangle here the seqed is actually the run over the rise of the smaller right triangle that makes up the left half of the image. Note that in this case the seqed measures the inverse of the slope (which would be the rise over run). Recall that for a right triangle we can define several trigonometric functions. the best known of those are:

- sin(x) = opposite / hypothenuse
- cos(x) = adjacent / hypothenuse
- tan(x) = opposite / adjacent
- cotangent(x) = adjacent / opposite

So for the small right triangle that takes up half of the larger triangle - which can be thought of as a cross section of a pyramid - we can look at the cotangent and notice that it is exactly the seqed computed by the ancient Egyptians.

cotangent(x) = adjacent / opposite = half the base / height = seqed

So what exactly is the seqed (or if you prefer the cotangent) measuring? It gives a ratio of the base versus the height and hence gives a measuer of the steepness of the triangle. And because the triangle really represents the pyramid, it measures how steep the pyramid is.

Note that a very steep pyramid would have a relatively great height in comparison to the size of the base. So smaller seqeds correspond to higher pyramids, which in turn correspond to steeper pyramids

**Example:**

**Rhind Papyrus 56:** *Example of reckoning a pyramid 360 cubits wide and 250 cubits high.*
*Cause thou that I know the seked of it. You are to take half of 360; It becomes 180. You are to reckon with 250 to find 180. Result: 1/2 + 1/5 + 1/50.* (slight adjustment of the text to make it easier to read)

What the Egyptian scribe is doing here is showing how to compute the seqed.

The first part is straight forward:

*You are to take half of 360; It becomes 180.* We need to use half the base length, so we divide the given measurement by 2.

*You are to reckon with 250 to find 180. Result: 1/2 + 1/5 + 1/50.* This part means divide 250 into 180 and the answer is 1/2 + 1/5 + 1/50, which we in modern days would simplify to 18/25, or if we use a calculator would be represented as .72.

Question 1:

Compute problem 58 from the Rhind papyrus: In a pyramid whose height is 93 1/3 [cubits] make known the seqed of it when its base side is 140 [cubits].

Question 2:

Solve problem 57 from the Rhind papyrus: If the seqed is 3/2 and the base is 280 [cubits], what is the height of the pyramid?

Question 3:

Solve problem 59(a) from the Rhind papyrus: In a pyramid whose base side is 12 [cubits] and whose altitude is 8 [cubits]; what is its seqed?

## Real Pyramids, right triangles and their Seqeds

One theory for how the Egyptians planned the construction of their pyramids and maintain a constant slope is that they used right triangles. The idea is that they may have constructed wooden right triangles that could have been used as a guide during the construction of the monument. Egyptians may have known about perfect triangles from experimenting with their version of a measuring tape: knotted cords. It may have been noted for instance that if one has pieces of ropes of length 3, 4, and 5 that they form a right triangle. There is no real evidence that the Egyptians knew this back in the day of the pyramid builders, but it seems reasonable that they may have noticed that there are some perfect triangles out there.

Question 4:

Pythagorean triples refer to the side measures of right triangles, where the sides have integer length. One of the most well known Pythagorean triples is (3,4,5) which corresponds to a 3-4-5 right triangle. The side of length 5 is the hypothenuse. When it comes to identifying the base and the height we have a choice.

a) If we let 3 be the base and 4 be the height, compute the seqed (base/height).

b) If we let 4 be the base and 3 be the height, compute the seqed.

(This information will be used in problem 5)

Next suppose we have an isosceles triangle with both sides length 1. The hypothenuse would be <math>\sqrt{2}</math>, so this right triangle does not correspond to a Pythagorean triple, but it's interesting in it's own right.

c) Compute the seqed of the isosceles triangle.

Next, consider the triple ( 8, 15, 17)

d) If we let 8 be the base and 15 be the height, compute the seqed.

e) If we let 15 be the base and 8 be the height, compute the seqed.

Question 5:

For the following pyramids do the following:

(i) Compute the Seqed if possible.

(ii)Could the pyramid have been constructed using a technique involving right triangles?

Pyramid | Height | base | Seqed of the pyramid | Slope | Possible right triangle |
---|---|---|---|---|---|

Great Pyramid (Pharaoh Khufu) | 146.6 | 230.3 | 51.8 degrees | ||

Pharaoh Khafre | 143.5 | 215.25 | .75 | 53.1 degrees | 3-4-5 Triangle |

Pharaoh Menkaure | 66.45 | 103.4 | .79 | 51.3 degrees | Maybe 3-4-5 Triangle? |

Pharaoh Userkaf | 49 | 73.3 | 53 degrees | ||

Pharaoh Sahure | 48 | 78.5 | 50.5 degrees | ||

Queen Khentkawes | 72 | 25 | 52 degrees | ||

Pharaoh Djedkare | 52.5 | 78.75 | 52 degrees | ||

Djedkare's Queen | 21 | 41 | ca 45 degrees | ||

Pharaoh Teti | 52.5 | 78.5 | 53.1 degrees | ||

Teti's Queen (Iput) | 21 | 21 | 63 degrees |