E-TEXTILES
E-Textile means
Electronic Textile. It is also known as smart textile. Electronic textiles are
the textile fabrics with electronics and interconnections woven in their
structure that enable the integration of electronic functions and attachments.
They possess the physical flexibility and size not known in conventional
electronics. Components and interconnections are intrinsic to the fabric
structure with reduced chance to be seen, tangled together or snagged by the
surroundings. Thinking for electronics that can be draped over a vehicle or a
tank is achievable using textile fabrics.
Electronic
textiles can be created by using minute electrically conductive fibers. These
metallic fibers have been used for years in various industrial applications for
the purpose of controlling static and electromagnetic interference shielding.
Today, metallic fibers are finding new applications in the development of
electronic textiles. Electrically conductive fibers can be classified into two
general categories, those that are naturally conductive and those that are
specially
treated to create conductivity.
The design process of an e- textile should appreciate the complexity, cost, and effectiveness of system. This process must be based on a set of percept derived from the experience and developing concepts. Software/ hardware architecture of an e- textile using defined percept would facilitate the future research, and produce applicable models. An understanding of theories, fabrics, embedded conductive threads/ fibers, and the connections in electronics and fabric are significant in producing a prototype.
Application of Electronic Textiles
E Textiles can be worn in everyday situations where currently available wearable computers would hinder the user. E Textiles can also more easily adapt to changes in the computational and sensing requirements of an application, a useful feature for power management and context awareness.
The Uses of E Textiles can be divided into two main categories:
The design process of an e- textile should appreciate the complexity, cost, and effectiveness of system. This process must be based on a set of percept derived from the experience and developing concepts. Software/ hardware architecture of an e- textile using defined percept would facilitate the future research, and produce applicable models. An understanding of theories, fabrics, embedded conductive threads/ fibers, and the connections in electronics and fabric are significant in producing a prototype.
Application of Electronic Textiles
E Textiles can be worn in everyday situations where currently available wearable computers would hinder the user. E Textiles can also more easily adapt to changes in the computational and sensing requirements of an application, a useful feature for power management and context awareness.
The Uses of E Textiles can be divided into two main categories:
§ E-textiles with classical
electronic devices such as conducting wires, integrated circuits, LEDs, and
conventional batteries into garments. This is the common type of e-textile.
§ E-textiles with modern
electronics directly on the textile fibers. This can include can either passive
electronics such as pure wires, conducting textile fibers, or more advanced
electronics such as transistors, diodes and solar cells. The field of embedding
advanced electronic components onto textile fibers is sometimes called fibertronics.
SAGARA S G
ASSISTANT PROFESSOR OF IDD
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