Giving physical shape to invisible

Giving physical shape to invisible signals

When a newly renovated apartment in San Francisco went on the market earlier this year for roughly $8.5 million, its asking price included a somewhat unexpected amenity: "excellent EMF protection". The entire flat had been rigorously fortified against electromagnetic fields.
Architects used to be concerned primarily with questions of light, visual aesthetics and maintaining a comfortable temperature – with an ear for acoustic privacy. Today, however, in an age of mobile phone communications, Bluetooth and home WiFi – to name just a few of the sources of electromagnetic waves now coursing through the built environment – architects must consider a whole new range of forces and energies. Put another way, electromagnetism is beginning to have a physical influence on the way we construct and manage the built environment.
In the case of the San Francisco apartment, the home's electromagnetic profile was achieved by applying heavy graphite-based paints on all interior surfaces. Conductive wire tape was then applied in a large network, connecting the walls, floors and ceilings. Finally, the windows were coated with transparent, EMF-resistant films. Taken as a whole, these measures prevent electromagnetic signals from entering the apartment. It is a live-in Faraday cage, an enclosure made from conductive materials, named after 19th-century inventor Michael Faraday who discovered how to block and redirect electrical fields.

Shimmering curtains of WiFi
Why? Among photos of the renovation process on the marketing website for the San Francisco property were lengthy descriptions of the potential health risks posed by electromagnetic fields. The house was being sold as a peculiar kind of isolation chamber, sealed off from the outside world. But what is particularly noteworthy here from an architectural perspective is the way in which interior design – including specific building materials – can be used to sculpt otherwise invisible electromagnetic environments.

Signal architecture
Architects could use computational simulations to sculpt home interiors that offer the best electromagnetic reception. Of course, this would not leave architects with much to do. The ultimate solution would be to simply build a big, open-plan interior with no obstructions or walls. Indeed, welcome to modern architecture! But in a large, multi-room house or apartment, architects may not have that luxury and must instead balance the competing demands of walls and WiFi.
Still, hidden in mathematical models are the shadowy outlines of an electromagnetically improved home. This realisation opens a vast and strange new world for architectural design. Developers might boast of WiFi efficiency ratings the same way they now tout sustainable design and luxury amenities. Architects will learn to build with electromagnetically porous materials in configurations that boost both wireless internet transmission and square footage. Designers are not yet prepared for this scenario - an entirely new class of design parameters has emerged and architects have not had time to adapt. For now, adding WiFi or Bluetooth to a home is nothing more than an aftermarket add-on, something the residents themselves will do through a chaotic assemblage of gadgets, antennae and routers.

Giving physical shape to invisible signals

When a newly renovated apartment in San Francisco went on the market earlier this year for roughly $8.5 million, its asking price included a somewhat unexpected amenity: "excellent EMF protection". The entire flat had been rigorously fortified against electromagnetic fields.
Architects used to be concerned primarily with questions of light, visual aesthetics and maintaining a comfortable temperature – with an ear for acoustic privacy. Today, however, in an age of mobile phone communications, Bluetooth and home WiFi – to name just a few of the sources of electromagnetic waves now coursing through the built environment – architects must consider a whole new range of forces and energies. Put another way, electromagnetism is beginning to have a physical influence on the way we construct and manage the built environment.
In the case of the San Francisco apartment, the home's electromagnetic profile was achieved by applying heavy graphite-based paints on all interior surfaces. Conductive wire tape was then applied in a large network, connecting the walls, floors and ceilings. Finally, the windows were coated with transparent, EMF-resistant films. Taken as a whole, these measures prevent electromagnetic signals from entering the apartment. It is a live-in Faraday cage, an enclosure made from conductive materials, named after 19th-century inventor Michael Faraday who discovered how to block and redirect electrical fields.

Shimmering curtains of WiFi
Why? Among photos of the renovation process on the marketing website for the San Francisco property were lengthy descriptions of the potential health risks posed by electromagnetic fields. The house was being sold as a peculiar kind of isolation chamber, sealed off from the outside world. But what is particularly noteworthy here from an architectural perspective is the way in which interior design – including specific building materials – can be used to sculpt otherwise invisible electromagnetic environments.

Signal architecture
Architects could use computational simulations to sculpt home interiors that offer the best electromagnetic reception. Of course, this would not leave architects with much to do. The ultimate solution would be to simply build a big, open-plan interior with no obstructions or walls. Indeed, welcome to modern architecture! But in a large, multi-room house or apartment, architects may not have that luxury and must instead balance the competing demands of walls and WiFi.
Still, hidden in mathematical models are the shadowy outlines of an electromagnetically improved home. This realisation opens a vast and strange new world for architectural design. Developers might boast of WiFi efficiency ratings the same way they now tout sustainable design and luxury amenities. Architects will learn to build with electromagnetically porous materials in configurations that boost both wireless internet transmission and square footage. Designers are not yet prepared for this scenario - an entirely new class of design parameters has emerged and architects have not had time to adapt. For now, adding WiFi or Bluetooth to a home is nothing more than an aftermarket add-on, something the residents themselves will do through a chaotic assemblage of gadgets, antennae and routers.

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Giving physical shape to invisible signalsWhen a newly renovated apartment in San Francisco went on the market earlier this year for roughly $8.5 million, its asking price included a somewhat unexpected amenity: "excellent EMF protection". The entire flat had been rigorously fortified against electromagnetic fields.Architects used to be concerned primarily with questions of light, visual aesthetics and maintaining a comfortable temperature – with an ear for acoustic privacy. Today, however, in an age of mobile phone communications, Bluetooth and home WiFi – to name just a few of the sources of electromagnetic waves now coursing through the built environment – architects must consider a whole new range of forces and energies. Put another way, electromagnetism is beginning to have a physical influence on the way we construct and manage the built environment.In the case of the San Francisco apartment, the home's electromagnetic profile was achieved by applying heavy graphite-based paints on all interior surfaces. Conductive wire tape was then applied in a large network, connecting the walls, floors and ceilings. Finally, the windows were coated with transparent, EMF-resistant films. Taken as a whole, these measures prevent electromagnetic signals from entering the apartment. It is a live-in Faraday cage, an enclosure made from conductive materials, named after 19th-century inventor Michael Faraday who discovered how to block and redirect electrical fields.Shimmering curtains of WiFiWhy? Among photos of the renovation process on the marketing website for the San Francisco property were lengthy descriptions of the potential health risks posed by electromagnetic fields. The house was being sold as a peculiar kind of isolation chamber, sealed off from the outside world. But what is particularly noteworthy here from an architectural perspective is the way in which interior design – including specific building materials – can be used to sculpt otherwise invisible electromagnetic environments.Signal architectureArchitects could use computational simulations to sculpt home interiors that offer the best electromagnetic reception. Of course, this would not leave architects with much to do. The ultimate solution would be to simply build a big, open-plan interior with no obstructions or walls. Indeed, welcome to modern architecture! But in a large, multi-room house or apartment, architects may not have that luxury and must instead balance the competing demands of walls and WiFi.Still, hidden in mathematical models are the shadowy outlines of an electromagnetically improved home. This realisation opens a vast and strange new world for architectural design. Developers might boast of WiFi efficiency ratings the same way they now tout sustainable design and luxury amenities. Architects will learn to build with electromagnetically porous materials in configurations that boost both wireless internet transmission and square footage. Designers are not yet prepared for this scenario - an entirely new class of design parameters has emerged and architects have not had time to adapt. For now, adding WiFi or Bluetooth to a home is nothing more than an aftermarket add-on, something the residents themselves will do through a chaotic assemblage of gadgets, antennae and routers.

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Предоставление физическую форму невидимых сигналов Когда недавно отремонтированная квартира в Сан-Франциско пошел на рынке в начале этого года примерно за $ 8,5 млн, его запрашиваемая цена включала несколько неожиданный удобств: "Отличная защита" ЭДС. Вся квартира была тщательно укреплен от электромагнитных полей. Архитекторы использовали для беспокойства в первую очередь с вопросами света, визуальной эстетики и поддерживая комфортную температуру - с ухом для акустической частной жизни. Сегодня, однако, в эпоху мобильной связи телефон, Bluetooth и WiFi дома - это лишь немногие из источников электромагнитных волн в настоящее время пронизала антропогенной среды - архитекторы должны рассмотреть целый ряд новых сил и энергии. Иными словами, электромагнетизм начинает иметь физическое воздействие на то, как мы строим и управлять искусственной среды. В случае квартиры в Сан-Франциско, электромагнитное профиль доме было достигнуто путем применения тяжелых графитовые краски на основе всех внутренних поверхностей. Проводник, лента была затем применяются в большой сети, подключения стены, полы и потолки. Наконец, окна были покрыты прозрачными, EMF-устойчивых пленок. Взятые в целом, эти меры предотвращают электромагнитные сигналы от входа в квартиру. Это живая в клетке Фарадея, в корпусе из из проводящих материалов, имени изобретателя 19-го века Майкл Фарадей, открывший как блокировать и перенаправлять электрические поля. Мерцающие шторы WiFi Почему? Среди фотографий процесса обновления на сайте маркетинговой имущества Сан-Франциско были длительные описания потенциальных рисков для здоровья, связанных с электромагнитными полями. Дом был продаются как своеобразной изоляции камеры, закрытой от внешнего мира. Но то, что особенно примечательно здесь с архитектурной точки зрения является способ, в котором дизайн интерьера - в том числе конкретных строительных материалов -. Может быть использован, чтобы ваять иначе невидимые электромагнитные сред сигнала архитектура Архитекторы могут использовать вычислительные моделирования лепить домашние интерьеры, которые предлагают лучшее электромагнитное прием , Конечно, это не оставит архитекторам многое предстоит сделать. Окончательное решение будет просто построить большой, открытой планировки интерьера с каких-либо препятствий или стен. В самом деле, добро пожаловать в современной архитектуре! Но в большой, мульти-комнатной квартиры или дома, архитекторы не могут иметь такую роскошь и должны вместо сбалансировать конкурирующие требования стен и WiFi. Тем не менее, скрытые в математические модели являются темные очертания электромагнитным улучшенной дома. Это осознание открывает обширную и странный новый мир для архитектурного проектирования. Разработчики могут похвастаться WiFi рейтингов эффективности так же они теперь рекламируют устойчивого проектирования и роскошные удобства. Архитекторы научитесь строить с электромагнитным пористых материалов в конфигурациях, которые повышают как беспроводную передачу в Интернет и квадратные метры. Дизайнеры еще не готовы к этому сценарию - совершенно новый класс конструктивных параметров стала и архитекторы не было времени, чтобы адаптироваться. В настоящее время, добавив, WiFi или Bluetooth к дому не более чем послепродажного дополнения, то сами жители будут делать через хаотический сборки гаджетов, антенн и маршрутизаторов.

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С физической формы в невидимые сигналы

при a недавно отремонтированные квартиру в Сан-Франциско выходит на рынок ранее в этом году в примерно 8.5 млн. человек, его просят в несколько неожиданном блага: "отличный ЭМП защита". Всего плоский был строго укрепленных от электромагнитных полей.
архитекторов было главным образом вопросы,Визуальная эстетика и поддержания комфортной температуры - с ухо для акустических конфиденциальности. Сегодня, однако, в эпоху мобильной телефонной связи, Bluetooth и WiFi - это только некоторые из источников электромагнитных волн сейчас подпорные стены через окружающую среду - архитекторы должны рассмотреть целый ряд новых сил и энергии. Иначе говоря,

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