Talk:Origami
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One of the links needs to be fixed
[edit]Link 24 on this page: https://mitani.cs.tsukuba.ac.jp/pukiwiki-oripa/index.php?ORIPA%3B%20Origami%20Pattern%20Editor for the oripa software utility returns a 404 error. I found this github page: https://github.com/oripa/oripa which links to this: https://mitani.cs.tsukuba.ac.jp/oripa/ as the current main website for the project. I do not currently qualify to edit the article. Can someone who does edit it?
Origami in Space Science: Due to its ability to aid with the challenge of fitting massive constructions into constrained spaces, origami has proven to be a useful tool in space exploration. Currently, it is expensive to launch a satellite or other spacecraft into space, and the bigger the structure, the more expensive it is. This issue is resolved by origami, which enables massive constructions to be folded and condensed for easier and more affordable transportation NASA’s solar sail, a remarkably small, light, and reflecting sheet that uses solar radiation to drive spacecraft across space, is one illustration of the usage of origami in space science. The sail must be packed tightly and compactly for flight, and it must later be spread in space. Here's where origami comes in since it offers a technique to compactly pack the solar sail and then release it in a controlled fashion. The usage of this technology for next space missions is being explored by NASA after successful testing in space. The creation of foldable space habitats is another example of origami being used in space science. These habitats may be transported in a compact shape, enlarged, and put together in space to give astronauts a place to live and work. These constructions may be folded and packed compactly, which makes transportation simpler and more affordable. Origami in Medical Science: Also, there are uses for origami in the field of medicine. Medical device design is one area where origami is being used. An origami-inspired stent, for instance, has been created by a research team at Brigham and Women's Hospital in Boston. It can be folded and then expanded to fit inside blood channels. This technology offers a minimally invasive alternative to surgery, which has the potential to transform the way cardiovascular disease is treated. Drug delivery devices are also designed using origami. An origami-inspired medication delivery device has been created by researchers at the University of North Carolina at Chapel Hill. It can be folded up small for transportation and then extended inside the body to release pharmaceuticals at a specified place. This technology has the potential to lessen side effects and increase drug delivery effectiveness. Origami in Engineering: Engineering has also benefited from the use of origami. Buildings, bridges, and other structures may be designed in a completely new way thanks to the work of engineers who are using the controlled folding and unfolding of origami to create their designs. For instance, an engineering team at Harvard University created a robotic arm that can be folded and unfurled like an accordion. This innovation may improve the range of motion and flexibility of robotic arms. The design of airbags is another area of engineering where origami is used. By folding them securely and compactly, airbags can be made smaller and lighter while still providing the necessary protection. In the end Origami is a useful and flexible craft that has applications in many scientific disciplines, including engineering, medicine, and space research. It has become a popular choice for creating structures that can be compacted and then deployed in a controlled way because of its ability to turn this double sheet into complex three-dimensional structures. Technologies influenced by origami have the ability to completely change how we design and construct. This article's goal is to show the many and creative ways that origami has been used in science, as well as how it has the possibility of completely change the way that we create structures, tools, and systems.
Origami in Space Science: Due to its ability to aid with the challenge of fitting massive constructions into constrained spaces, origami has proven to be a useful tool in space exploration. Currently, it is expensive to launch a satellite or other spacecraft into space, and the bigger the structure, the more expensive it is. This issue is resolved by origami, which enables massive constructions to be folded and condensed for easier and more affordable transportation NASA’s solar sail, a remarkably small, light, and reflecting sheet that uses solar radiation to drive spacecraft across space, is one illustration of the usage of origami in space science. The sail must be packed tightly and compactly for flight, and it must later be spread in space. Here's where origami comes in since it offers a technique to compactly pack the solar sail and then release it in a controlled fashion. The usage of this technology for next space missions is being explored by NASA after successful testing in space. The creation of foldable space habitats is another example of origami being used in space science. These habitats may be transported in a compact shape, enlarged, and put together in space to give astronauts a place to live and work. These constructions may be folded and packed compactly, which makes transportation simpler and more affordable. Origami in Medical Science: Also, there are uses for origami in the field of medicine. Medical device design is one area where origami is being used. An origami-inspired stent, for instance, has been created by a research team at Brigham and Women's Hospital in Boston. It can be folded and then expanded to fit inside blood channels. This technology offers a minimally invasive alternative to surgery, which has the potential to transform the way cardiovascular disease is treated. Drug delivery devices are also designed using origami. An origami-inspired medication delivery device has been created by researchers at the University of North Carolina at Chapel Hill. It can be folded up small for transportation and then extended inside the body to release pharmaceuticals at a specified place. This technology has the potential to lessen side effects and increase drug delivery effectiveness.
Origami in Engineering: Engineering has also benefited from the use of origami. Buildings, bridges, and other structures may be designed in a completely new way thanks to the work of engineers who are using the controlled folding and unfolding of origami to create their designs. For instance, an engineering team at Harvard University created a robotic arm that can be folded and unfurled like an accordion. This innovation may improve the range of motion and flexibility of robotic arms. The design of airbags is another area of engineering where origami is used. By folding them securely and compactly, airbags can be made smaller and lighter while still providing the necessary protection. In the end Origami is a useful and flexible craft that has applications in many scientific disciplines, including engineering, medicine, and space research. It has become a popular choice for creating structures that can be compacted and then deployed in a controlled way because of its ability to turn this double sheet into complex three-dimensional structures. Technologies influenced by origami have the ability to completely change how we design and construct. This article's goal is to show the many and creative ways that origami has been used in science, as well as how it has the possibility of completely change the way that we create structures, tools, and systems.
References
- ^ Badagavi, Pratik, Vinay Pai, and Abhishek Chinta. “Use of Origami in Space Science and Various Other Fields of Science.” In 2017 2nd IEEE International Conference on Recent Trends in Electronics, Information & Communication Technology (RTEICT), 628–32, 2017. https://doi.org/10.1109/RTEICT.2017.8256673
multiple tetrahedral family that can be folded on a single A4 sheet
[edit][1]2^N multiple tetrahedral family that can be folded on a single rectangle sheet Using a sheet of √1:√2 paper such as A4, you can fold a tetrahedron with four identical √3:√4 isosceles triangular faces into multiple pieces that are multiples of 2^N without cutting. Each of these tetrahedrons has four triangular paper faces, which do not overlap. That is, there are four times as many triangular faces as there are tetrahedra. In the case of a single sheet, groups of 2, 4, 8, and 16 tetrahedra of the same size are folded in various strange ways. Also, if you follow a certain rule (pattern), you can fold an infinite number of 2^N tetrahedra. 183.177.128.238 (talk) 05:20, 29 November 2023 (UTC) 183.177.128.238 (talk) 05:32, 29 November 2023 (UTC)
Origami
[edit]في اي عام تصنع من صنعه 185.255.44.181 (talk) 11:07, 6 December 2023 (UTC)
Europe
[edit]it mentions European traditions, but provides no source or further information. 64.110.254.75 (talk) 15:40, 1 January 2024 (UTC)
Semi-protected edit request on 15 February 2024
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In the section on Tessellation, Alex Bateman's name is not linked to his article: https://en.wikipedia.org/wiki/Alex_Bateman Biroclouds (talk) 16:52, 15 February 2024 (UTC)
Black Mirror episode 2 "15 Million Merits" Penguin origami
[edit]In season 1 episode 2 of the Netflix show Black Mirror, "Bing goes with Abi to the audition and she gives him an origami penguin." This simple gift is a powerful symbol - of creating something valuable and special to the character out of a piece of trash - in the story and I feel like this should be in the "in pop culture" section.
https://en.m.wikipedia.org/wiki/Fifteen_Million_Merits Jessefloria (talk) 00:38, 8 April 2024 (UTC)
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