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The first thing that comes in to our mind is MATH right? We all know that Parabola is just a simple curve and we can often see it in our Math class. Parabola is important, for example. In Architecture, an Architect cannot design a blueprint without plotting just a simple graph of parabola.

If us, we cannot see how important parabola is, to Architects, parabolas and circles are important. And SaddleDome in Calgary, Canada. You can see how beautiful these places are. Notice how parabolas work out in a building. It gives a beautiful apperance and impression to the visitor.

Another example is the Warszawa Ochota Railway Station. The most unique Railway Station in the world. Now, in conclusion.

Parabola is not just about mathematics or on how we plot it. Parabola also has its importance, importance that only some can recognize, importance that can make something very unique and importance that can make other amused by its beauty and uniqueness in structures.

From the paths of thrown baseballs, to satellite dishes, to fountains, this geometric shape is prevalent, and even functions to help focus light and radio waves. Parabolas can, in fact, be seen everywhere, in nature as well as manmade items. Consider a fountain. The water shot into the air by the fountain falls back in a parabolic path. A ball thrown into the air also follows a parabolic path. Galileo had demonstrated this. Even architecture and engineering projects reveal the use of parabolas.

Parabolic shapes can be seen in The Parabola, a structure in London built in that boasts a copper roof with parabolic and hyperbolic lines. Parabolas are also commonly used when light needs to be focused. Over the centuries, lighthouses underwent many variations and improvements to the light they could emit. Flat surfaces scattered light too much to be useful to mariners.

Spherical reflectors increased brightness, but could not give a powerful beam. But using a parabola-shaped reflector helped focus light into a beam that could be seen for long distances. The first known parabolic lighthouse reflectors formed the basis of a lighthouse in Sweden in Many different versions of parabolic reflectors would be implemented over time, with the goal of reducing wasted light and improving the surface of the parabola.

Eventually, glass parabolic reflectors became preferable, and when electric lights arrived, the combination proved to be an efficient way of providing a lighthouse beam. The same process applies to headlights.

### The Parabola

Sealed-beam glass automobile headlights from the s to the s used parabolic reflectors and glass lenses to concentrate beams of light from bulbs, aiding driving visibility. Later, more efficient plastic headlights could be shaped in such a way that a lens was not required. These plastic reflectors are commonly used in headlights today. Using parabolic reflectors to concentrate light now aids the solar power industry.Worried about plagiarism? Read this. Help Login Sign Up. What exactly is a parabola?

Well it could quite possibly be the most powerful shape that our world has ever known. It is used in many designs since it is so sturdy and powerful. Countless structures and devices use the parabola and it does nothing but enhance whatever it is used in. What makes it so powerful?

Just keep reading and find out. Used in bridges, doors and buildings, the shape of the parabola is used throughout the world of structures. Most of the time, it is used as an arch or an arc. Have you ever seen a castle or even a movie with a castle in it? Well usually on the big great front doors, you will see it lined with stones ending in a curve at the top.

Usually the top-center stone is the biggest. It is the key stone to an arc structure like that. All the other stones in the curve try and slide into the middle, but they are stopped by the one on top. They all squeeze together towards the middle and the key stone at the center takes all this pressure and keeps it together.

If something is set on top of that curve, the curve will take the weight and try and push towards the middle, but since the stones are set to a curve, they push on each other and stay firm.

This design is used in bridges and even cars for strength. Another use of the parabola is in lights.

## The Importance of Parabola

Headlights, searchlights, flashlights and more. The reflective mirrors inside are one big parabola. The light is shone in the middle and the curved mirrors shoot the light out of the bottom of the parabola. There is no direction that the light can be shoneThe parabola is a beautiful and elegant curve. For this reason, not just mathematicians and physicists like it: but architects and engineers too. Not surprisingly, we find that it has been used in many man-made structures.

For a detailed discussion of the mathematics behind the Sydney Harbour bridge, check out the interesting post. A popular tourist activity to do in Sydney is walking up one of those parabolic arches; evidently the view is quite remarkable.

When a cable is hung between two points, it assumes a shape that looks much like that of a parabola near the vertex called a catenary. In such a case the cable is only supporting its own weight. The mathematics of a catenary is somewhat more advanced, and requires understanding of a hyperbolic function:.

But when the suspension cables are used to uniformly support a bridge, especially a heavy bridge, as in the Golden Gate bridge in San Francisco, then the shape is a parabola. This is another classic engineering masterpiece.

Arches and domes in the shape of parabolas have been known and used since antiquity. They have some particularly pleasant load-bearing properties. And they still feature prominently as aspects of modern architectural design. In our three-dimensional world, we are often interested in surfaces more than curves.

Mathematicians have of course also intensively studied degree-two surfaces, called quadrics : such as the sphere, or ellipsoid, or the hyperboloids of one and two sheets, and many more complicated, higher degree surfaces too. One quadric that is particularly subtle yet intriguing is the hyperbolic paraboloid : which pleasantly combines parabolas opening up in opposite directions! Sometimes also called a saddle shapefor obvious reasons, this is a favourite surface for mathematically minded architects:.

One of the intriguing aspects of the hyperbolic paraboloid is that although it is a completely smooth surface, it is also a ruled surface — in fact it is a doubly-ruled surface, with two families of lines that lie completely on it.

You can make such a surface yourself if you join corresponding points on two parallel pencils with rubber bands, stretch the bands, and then twist the pencils so they are no longer parallel. Or for something more permanent, just join up corresponding points on two fixed skew line segments in space with thread. Because a hyperbolic parabola can be constructed with straight beams, it is particularly amenable to construction for buildings.

Do you know of any pleasant or interesting examples of parabolas used in architecture or design?The construction of the parabolas is described with the X and Y equations.

The parabolas are used because it has the curves that easy to lay it out mathematically. The parabolas in architecture are the studying material that should be learned by many architects. Many great landmarks building use this to make the building looks great and to get the antiques feeling. Parabolas were used from Baroque and Renaissance era. It has been used for years ago to make the building looks elegant with the curves the parabolas made.

This was simply because architects are dealing with math as well, so that it would make the building that has the parabola looks symmetric and cool. Parabolas are used in architecture to make the shape of the building, such as gate or roof. The roof of some great landmarks are usually used the parabolas shape because it looks less edgy that it would make the roof looks smooth. This would help to get you to know about parabolas in architecture so you could know what exactly its function is.

This post topic: Architecture. Makeover Drop Leaf Kitchen Table. Hip Ideas Loft Bed with Slide. The Value of White Kitchen Table. Architectural Model Making. This site uses cookies No problem More info.Any time the surfaces of a room focus the sound which is reflected from them, they create spots of high intensity and other spots with low intensity.

This is generally undesirable in an auditorium since you want a uniform, evenly dispersed sound to all listeners. Even large flat reflective surfaces are to be avoided because of the prominant reflection which will be produced. Parallel flat walls can produce a pattern of reflections known as a "flutter echo" as the sound waves travel back and forth between the surfaces.

Such flutter echoes are often encountered in high school gymnasiums where there are parallel side walls and also a reflective floor and ceiling.

Even dispersion is such an important contributer to good acoustics that it is sometimes desirable to use anti-focusing surfaces in a music making area.

Older architecture often had columns, decorative sculpture and woodwork, and other dispersing surfaces. In modern architecture with its flat expanses, it is necessary to design in some anti-focusing properties.

An ellipse has two focus points. Sound projected in any direction from one focus point will travel to the other. Sound from any point will tend to be focused toward some point, so ellipses are certainly to be avoided for most acoustical purposes.

Then, quite by accident, someone discovered that behind the high altar feet away the murmuring from the confessional could be clearly heard. The configuration of the walls behind the altar had focused sound waves from a point at the other end of the cathedral, although people in between could hear nothing.

It is useful for projecting sound. Two parabolas as shown below can direct sound from the focus point of one to the focus point of the other with great efficiency. A microphone element can be placed at the focus point of a parabola and then aimed at a distant sound source - parabolic microphones can pick up selected sounds at surprising distances. A popular practice at the U. Capitol building in Washington, D. Ordinary conversation can be if the speaker and listener are both close to the wall of the dome.

Many buildings with dome-like rotundas exhibit this guided reflection phenomena. Locations where the rotunda effect is experienced are sometimes called "whispering galleries". The dome of St. Paul's Cathedral in London is a famous example. Non-focusing Surfaces Any time the surfaces of a room focus the sound which is reflected from them, they create spots of high intensity and other spots with low intensity.

Index Auditorium acoustics. Focused Reflections Click on any of the geometries for further details.

Influence of reflections on acoustics. Elliptical Enclosure An ellipse has two focus points. Parabolic Surfaces. All rays from the focus of a parabola to its surface will be directed outward as parallel rays. Rotunda Effect A popular practice at the U. Anti-focusing Surfaces Since even dispersion of sound is highly desirable in an auditorium, it may be necessary to take steps to overcome any focusing surfaces.

If an architect decides that some curved surface is desirable for some reason, then the undesirable focusing effect may be partially overcome by covering the curved surface with anti-focusing surfaces.It would be very helpfull if anyone could help with any info or ideas.

Architectural Design Process - Form, Orientation and Sunlight

I know the Mcdonald's sign is a double parabola Also the difference between a parabola and a catenary? Mathematically, the parabola and the catenary are described by two completely different Y vs. X equations. The equation of the catenary corresponds precisely to the shape of a freely hanging flexible chain.

## PARABOLA is a design innovation and research studio led by carrie meinberg burke and kevin burke.

A suspension bridge would look like that before you hung the roadway from the cables, but not afterwards. The web site for the St. Louis Gateway Arch says that its curve is not a parabola but a "weighted catenary". Obviously it's an inverted one, but that's too obvious to have been worth saying. There are good physical reasons why the curves used in architecture would be more like catenaries than parabolas, because the mathematics that define the required shape of curve come from real physical laws, as the catenary does, while the parabola is much more of an idealised mathematical abstraction.

However, for a relatively shallow curve, the two are very very close, and the parabola is so much easier to lay out that architects probably use long shallow parabolas even though they mathematically shouldn't. Louis Ms. Any arch in architecture is a parabola, such as domes. Lots of McDonalds restaurants The shape of suspension bridges is a catenary, which is a slightly different shape. They look neat. Golden gate bridge And forces are more evenly distributed than a circular arch say.