![]() However, his work is certainly impressive and has attracted some attention towards using a design drawn from nature to gather energy more efficiently. After all, scientists have been observing and investigating plants for centuries. Whether Dwyer’s work is actually “groundbreaking” is probably open for debate. The tree design made 50% more electricity, and the collection time of sunlight was up to 50% longer! But the most interesting results were in December, when the Sun was at its lowest point in the sky. The tree design made 20% more electricity and collected 2 1/2 more hours of sunlight during the day. The Fibonacci tree design performed better than the flat-panel model. He compared the amount of energy collected by his tree against a normal, flat array of solar cells. His results may surprise you: Except on his tree, Dwyer placed photovoltaic cells instead of leaves. These numbers, 34 and 21, are numbers in the Fibonacci series, and their ratio 1.6190476 closely approximates Phi, 1.6180339.To do so, he constructed a “tree” using the sequence of leaves found on an oak tree. The DNA molecule measures 34 angstroms long by 21 angstroms wide for each full cycle of its double helix spiral. Looking at the length of our fingers, each section - from the tip of the base to the wrist - is larger than the preceding one by roughly the ratio of phi.Įven the microscopic realm is not immune to Fibonacci. It’s quite possible that, from an evo-psych perspective, that we are primed to like physical forms that adhere to the golden ratio - a potential indicator of reproductive fitness and health. As an example, the most “beautiful” smiles are those in which central incisors are 1.618 wider than the lateral incisors, which are 1.618 wider than canines, and so on. It has also been said that the more closely our proportions adhere to phi, the more “attractive” those traits are perceived. It’s worth noting that every person’s body is different, but that averages across populations tend towards phi. Similar proportions can been seen from the side, and even the eye and ear itself (which follows along a spiral). The mouth and nose are each positioned at golden sections of the distance between the eyes and the bottom of the chin. It’s call the logarithmic spiral, and it abounds in nature.įaces, both human and nonhuman, abound with examples of the Golden Ratio. This shape, a rectangle in which the ratio of the sides a/b is equal to the golden mean (phi), can result in a nesting process that can be repeated into infinity - and which takes on the form of a spiral. The unique properties of the Golden Rectangle provide another example. Root systems and even algae exhibit this pattern. This pattern of branching is repeated for each of the new stems. Then, one of the new stems branches into two, while the other one lies dormant. A main trunk will grow until it produces a branch, which creates two growth points. The Fibonacci sequence can also be seen in the way tree branches form or split. Phi appears in petals on account of the ideal packing arrangement as selected by Darwinian processes each petal is placed at 0.618034 per turn (out of a 360° circle) allowing for the best possible exposure to sunlight and other factors. Famous examples include the lily, which has three petals, buttercups, which have five, the chicory’s 21, the daisy’s 34, and so on. The number of petals in a flower consistently follows the Fibonacci sequence. It is often symbolized using phi, after the 21st letter of the Greek alphabet. The Golden ratio is a special number found by dividing a line into two parts so that the longer part divided by the smaller part is also equal to the whole length divided by the longer part. Similarly, the 3 is found by adding the two numbers before it (1+2) The Fibonacci Sequence is the series of numbers: 0, 1, 1, 2, 3, 5, 8, 13, 21, 34,… The next number is found by adding up the two numbers before it.
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