It's a presentation where the update textile technology with Catwalk fashion is coloborated. It is done by Shazzadul Islam (Tushar), Student of City University, Permanent Campus, 26th Batch, Ashulia, Savar, Dhaka.
This document summarizes an academic report on advanced textiles. It discusses the history and evolution of textiles from ancient times to the present, focusing on the transition from natural to synthetic fibers and the rise of active textiles. Key definitions and applications of advanced textiles are provided across various sectors such as medical, sports, packaging and more. The ecosystem and innovation process in the industry is described involving manufacturers, end-users, academia, and partnerships. Industry characteristics like market size, trade patterns, and growth forecasts for different regions are presented. The focus section analyzes opportunities in the medical textiles sector for non-implantable, implantable and extracorporeal applications, highlighting a case study on reflective heartbeat sensors.
The textile , that keeps our body both cool and warm depending on which side faces out. its a new dimension in smart textile sector. In normal temperature this product will work effectively . this innovation can save huge amount of energy. It is developed by Stanford university researcher team.
This presentation is about evolution of Textile Industry from animan skin to most modern performance clothing. It gives overview of past, present & future innovations in Textile Industry.
This document describes a water jet loom for weaving textiles. The water jet loom inserts the weft thread through the opened space between warp curtains using high-pressure water injected through a small nozzle instead of a shuttle. It has integrated systems that save 25% power consumption compared to a conventional loom and reduce water consumption by 40%. The water jet loom is mainly used to weave thin to middle thickness fabrics of low to high density from synthetic materials.
Mr Gurudas Aras, Director, A.T.E. Enterprises made a presentation on "Technological advancements in technical textiles" at the inaugural session of the Techtextil International Conference, Mumbai on 21 November 2019. The presentation mainly focused on the most relevant technological developments in technical textiles in the Indian context today and covered 'sustainability', 'durability', and 'functionality' aspects of the business. The presentation covered products like flushable and bio-degradable wipes, textile reinforced concrete, thermoplastic UD tapes for automobiles and coating and lamination for special applications respectively. Click here to view the presentation.
Overview of different processes, technologies and chemical products for textile finishing, complemented with several case studies and successful stories of textile R&D projects.
Dr. S. Aishwariya presented on recent advancements in technical textiles, focusing on new generation fibers and technologies. She discussed 7 new fibers: 1) spider silk, which is stronger than steel, 2) modal fibers which are soft like a second skin, 3) soybean protein fiber which is soft and nutritious, 4) lyocell which is biodegradable, 5) microfibers which are lightweight and breathable, 6) PLA fiber which is renewable and compostable, and 7) super absorbent polymers. She also highlighted innovations using these fibers like drug delivery textiles, degradable products, medical implants, angioplasty devices, heat-producing garments
http://www.ualberta.ca/~jag3/smart_textiles/index.htm
Jose A. Gonzalez
Protective Clothing Research Group
Department of Human Ecology
University of Alberta
This document summarizes an academic report on advanced textiles. It discusses the history and evolution of textiles from ancient times to the present, focusing on the transition from natural to synthetic fibers and the rise of active textiles. Key definitions and applications of advanced textiles are provided across various sectors such as medical, sports, packaging and more. The ecosystem and innovation process in the industry is described involving manufacturers, end-users, academia, and partnerships. Industry characteristics like market size, trade patterns, and growth forecasts for different regions are presented. The focus section analyzes opportunities in the medical textiles sector for non-implantable, implantable and extracorporeal applications, highlighting a case study on reflective heartbeat sensors.
The textile , that keeps our body both cool and warm depending on which side faces out. its a new dimension in smart textile sector. In normal temperature this product will work effectively . this innovation can save huge amount of energy. It is developed by Stanford university researcher team.
This presentation is about evolution of Textile Industry from animan skin to most modern performance clothing. It gives overview of past, present & future innovations in Textile Industry.
This document describes a water jet loom for weaving textiles. The water jet loom inserts the weft thread through the opened space between warp curtains using high-pressure water injected through a small nozzle instead of a shuttle. It has integrated systems that save 25% power consumption compared to a conventional loom and reduce water consumption by 40%. The water jet loom is mainly used to weave thin to middle thickness fabrics of low to high density from synthetic materials.
Mr Gurudas Aras, Director, A.T.E. Enterprises made a presentation on "Technological advancements in technical textiles" at the inaugural session of the Techtextil International Conference, Mumbai on 21 November 2019. The presentation mainly focused on the most relevant technological developments in technical textiles in the Indian context today and covered 'sustainability', 'durability', and 'functionality' aspects of the business. The presentation covered products like flushable and bio-degradable wipes, textile reinforced concrete, thermoplastic UD tapes for automobiles and coating and lamination for special applications respectively. Click here to view the presentation.
Overview of different processes, technologies and chemical products for textile finishing, complemented with several case studies and successful stories of textile R&D projects.
Dr. S. Aishwariya presented on recent advancements in technical textiles, focusing on new generation fibers and technologies. She discussed 7 new fibers: 1) spider silk, which is stronger than steel, 2) modal fibers which are soft like a second skin, 3) soybean protein fiber which is soft and nutritious, 4) lyocell which is biodegradable, 5) microfibers which are lightweight and breathable, 6) PLA fiber which is renewable and compostable, and 7) super absorbent polymers. She also highlighted innovations using these fibers like drug delivery textiles, degradable products, medical implants, angioplasty devices, heat-producing garments
http://www.ualberta.ca/~jag3/smart_textiles/index.htm
Jose A. Gonzalez
Protective Clothing Research Group
Department of Human Ecology
University of Alberta
This document is Priyanshi Arora's submission for Assignment 1, Task 4 of her BTEC HND Level Fashion and Textile program from 2014-2018. It discusses technical textiles, which are materials and products made primarily for their performance properties rather than aesthetic qualities. It covers the large and growing technical textiles sector, classifications of technical textiles like agro tech, cloth tech, and sports tech, and emerging areas like e-textiles which integrate electronics and enhance performance.
The document discusses various natural and man-made fiber materials that can be used for textiles, including their properties and production methods. It describes fibers that can be extracted from banana, pineapple, soybeans and corn. It also covers bamboo fiber produced through hydrolysis and alkalization, as well as naturally colored cotton bred with colors other than white. The document notes new textile technologies like nano fibers less than 1000nm in diameter and smart textiles that can sense and react to the wearer's environment.
The document discusses smart textiles, which are textiles that can sense and react to environmental conditions. Originally textiles provided protection from weather, but now integrate technologies to increase functionality. Smart textiles are classified into passive, active, and ultra-smart varieties based on their ability to sense and react. Examples include fabrics that monitor health, control devices, and regulate temperature. Significant opportunities exist in medicine, sustainability, and wearable technology as the industry grows.
Smart fabrics are fabrics that have been engineered to have enhanced functional properties through various technologies. Nanotechnology, thermochromics, conductivity, and shape memory polymers are some of the techniques used to develop smart textiles. Examples include fabrics treated with silver nanoparticles for antibacterial properties, thermochromic wallpaper that changes color with temperature, and light-sensitive curtains that open and close in response to light intensity without electricity. These smart fabrics have applications in interior design, architecture, healthcare and other fields.
Advances in technology have enabled textiles to be engineered for specialized applications and high performance. Smart textiles can now sense and react to stimuli in the environment. Future developments may integrate textiles with nano- and terascale technologies to create highly complex, cognitive, and integrated systems. These could endow textiles with new sensing, signaling, computing and tissue engineering capabilities.
Nanotechnology in textiles-wired and ready to wear textilessargow27
The document discusses the potential applications of nanotechnology and electronic textiles, or e-textiles. It describes how sensors and electronics can be embedded in fabrics to create "smart" or "wired and ready to wear" textiles. Some key applications mentioned include sportswear that monitors vital signs, clothing that charges electronic devices, and protective garments for firefighters equipped with environmental and health sensors. The document highlights the growing field of electronic textiles and their ability to make clothing more functional and interactive.
This document discusses smart textiles, which integrate microelectronics into textiles to endow them with new properties and active behaviors. Smart textiles can sense and react to stimuli in their environment. They are categorized as passive, active, or ultra smart depending on their sensing and response capabilities. The key functions of smart textiles are sensing, data processing, actuation, storage, and communication. Examples of smart textile applications discussed include thermoregulating materials, chromic materials, luminescent materials, conductive materials, voltaic materials, and electronic textiles. Areas of further research include sensors, actuators, signal transmission and control systems, and integrated textile processes.
Smart fabrics are defined as fabrics that can sense and react to environmental conditions or stimuli from mechanical, thermal, chemical, electrical or magnetic sources.
Also called as intelligent textiles.
Enable digital components.
Smart textiles are materials and structures that can sense and react to environmental stimuli. They include self-cleaning carpets, memory fabrics, and fabrics that regulate temperature. Smart textiles can be divided into passive materials that only sense stimuli, active materials that can both sense and respond, and very smart materials that can sense, respond, and adapt. They use materials like conductive fibers, shape memory alloys, and microencapsulated phase change materials. Applications include sportswear that regulates temperature, medical clothing that monitors vital signs, military uniforms that detect hazards, and fashionable apparel that changes color or plays music. The future of smart textiles may include clothing that emits scents, becomes rigid to immobilize injuries,
This document provides an overview of smart textiles. It defines smart textiles as textiles that can sense and react to environmental conditions or stimuli. It discusses the scope of smart textiles, including the integration of various disciplines required. It outlines different generations of textile wearable technologies and describes textronics. It also covers various topics related to smart textiles like classifications, materials, incorporation into textiles, components, working process, applications, and the relationship to technical textiles.
Smart textiles are materials and structures that can sense and react to environmental stimuli. There are four main types: passive smart materials that only sense stimuli, active smart materials that can both sense and respond, very smart materials that can sense, respond, and adapt, and materials with artificial intelligence. Smart textiles find applications in sports, healthcare, military, fashion and more. New developments include light-emitting, scent-emitting, shape-shifting, and health-monitoring textiles. Smart textiles have the potential to revolutionize clothing and other fabrics.
Smart textiles new possibilities in textile engineeringNasif Chowdhury
This document discusses smart textiles and provides several examples. It begins by defining smart textiles as textiles that can sense environmental stimuli and react to them by integrating functionalities into the textile structure. The stimulus and response can be electrical, thermal, chemical, magnetic, or other. Examples are given of smart textiles for clothing that can change color or provide light and regulate temperature. The document then discusses the different types of smart textiles and their various functions like sensing, data processing, actuation, storage, and communication. Several applications and examples of smart textiles are provided like the Gore-Tex jacket and Georgia Tech's wearable motherboard shirt. Adidas' and Nike's smart running shoes are also summarized.
Smart fabrics, also known as electronic textiles or smart clothing, are fabrics that have digital components like sensors, actuators and processors embedded in them. They are able to sense external conditions and respond accordingly. Smart fabrics have been in development since the 1990s and use materials like conductive threads, fibers and fabrics. They contain sensors to detect information and actuators to trigger responses. Processors then analyze the sensor data and control the actuators. Common applications of smart fabrics include uses in healthcare for monitoring health metrics, in military and safety gear for functions like GPS tracking, and in the fashion industry for customizable fabrics.
Electronic-textiles (e-textiles) incorporate electronic functionality into textiles by using conductive materials. They contain conductive yarns or fibers and can be produced using textile manufacturing techniques. E-textiles allow for innovative designs and integration of sensors, displays and other electronics into fabrics and garments. They provide benefits like flexibility, comfort and low-cost production compared to rigid electronics. However, challenges remain around reliability, mass production costs and limited processing capability due to power constraints. Ongoing research aims to address these issues and further the applications of intelligent textile technologies.
This document discusses smart textiles, which integrate microelectronics into textiles to endow them with new interactive properties. It defines three types of smart textiles - passive, active, and ultra smart - based on their ability to sense and react to environmental stimuli. The key functions of smart textiles are described as sensing, data processing, actuation, storage, and communication. Various materials used in smart textiles are also outlined, such as thermoregulating materials, chromic materials, luminescent materials, conductive materials, voltaic materials, and electronic textiles. The document concludes by noting several areas of research and development for smart textile sensors, actuators, signal transmission and control systems.
Smart textiles are textiles that can sense and react to environmental stimuli through integrated electronics or other technologies. They have a wide range of applications, including in medicine to monitor vital signs, in fashion as displays on clothing, and as soft interfaces. Smart textiles work by using conductive materials integrated into fabrics that can detect changes and respond accordingly, often transmitting related data. Common triggers sensed include touch, temperature, pressure, and other bodily functions.
This document discusses intelligent textiles that use phase change materials and shape memory materials. It begins with an introduction submitted by a textile engineering student. It then discusses intelligent textile systems using sensors, processors and actuators. It provides examples of intelligent textiles like phase change materials, shape memory materials, and conductive materials. It discusses applications of these intelligent textiles in apparel, home textiles, medical textiles, and more. It also provides details on phase change materials, how they work, and how they can be incorporated into textiles.
This document discusses smart fabrics and textiles that can sense and respond to environmental stimuli. It provides examples of smart fabrics like Gore-Tex that are waterproof and breathable, as well as microencapsulated fabrics that can release substances like antibacterial agents in response to heat, pressure or other triggers. The document also discusses using smart textiles for medical purposes like wound dressings and how they may help regulate body temperature and odor. It describes early experiments creating touch interfaces and circuits using conductive metallic yarns woven into fabrics.
The document discusses smart and intelligent textiles. It begins by introducing textiles as the second skin of humans and notes they traditionally provide protection and aesthetics. It describes how intelligence is now being integrated into fabrics to create interactive textiles. It outlines several classifications of smart fibers and materials that can sense and react to environmental stimuli, including thermochromic, luminescent, conductive, and shape memory materials. Example applications are described for areas like military, healthcare, sports, and fashion. In closing, it argues textiles represent an attractive platform for biosensors and wearable electronics since many systems can be connected to clothing to create a versatile and customizable experience for the user.
Advance Research in Textile Engineering is an open access, peer reviewed, scholarly journal dedicated to publish articles covering all areas of Textile Engineering.
The journal aims to promote research communications and provide a forum for doctors, researchers, physicians and healthcare professionals to find most recent advances in all areas of Textile Engineering. Advance Research in Textile Engineering accepts original research articles, reviews, mini reviews, case reports and rapid communication covering all aspects of Textile Engineering.
Advance Research in Textile Engineering strongly supports the scientific up gradation and fortification in related scientific research community by enhancing access to peer reviewed scientific literary works. Austin Publishing Group brings universally peer reviewed journals under one roof thereby promoting knowledge sharing, mutual promotion of multidisciplinary science.
The document discusses the global and Bangladeshi home textile industries. It provides definitions of home textiles and describes the different types of home textile products. It then discusses key details about the global home textiles market such as its size, leading regions, and growth rates in different countries. For Bangladesh specifically, it outlines the country's leading home textile exporters and products, export countries, and contributions of home textiles to the Bangladeshi economy.
This document is Priyanshi Arora's submission for Assignment 1, Task 4 of her BTEC HND Level Fashion and Textile program from 2014-2018. It discusses technical textiles, which are materials and products made primarily for their performance properties rather than aesthetic qualities. It covers the large and growing technical textiles sector, classifications of technical textiles like agro tech, cloth tech, and sports tech, and emerging areas like e-textiles which integrate electronics and enhance performance.
The document discusses various natural and man-made fiber materials that can be used for textiles, including their properties and production methods. It describes fibers that can be extracted from banana, pineapple, soybeans and corn. It also covers bamboo fiber produced through hydrolysis and alkalization, as well as naturally colored cotton bred with colors other than white. The document notes new textile technologies like nano fibers less than 1000nm in diameter and smart textiles that can sense and react to the wearer's environment.
The document discusses smart textiles, which are textiles that can sense and react to environmental conditions. Originally textiles provided protection from weather, but now integrate technologies to increase functionality. Smart textiles are classified into passive, active, and ultra-smart varieties based on their ability to sense and react. Examples include fabrics that monitor health, control devices, and regulate temperature. Significant opportunities exist in medicine, sustainability, and wearable technology as the industry grows.
Smart fabrics are fabrics that have been engineered to have enhanced functional properties through various technologies. Nanotechnology, thermochromics, conductivity, and shape memory polymers are some of the techniques used to develop smart textiles. Examples include fabrics treated with silver nanoparticles for antibacterial properties, thermochromic wallpaper that changes color with temperature, and light-sensitive curtains that open and close in response to light intensity without electricity. These smart fabrics have applications in interior design, architecture, healthcare and other fields.
Advances in technology have enabled textiles to be engineered for specialized applications and high performance. Smart textiles can now sense and react to stimuli in the environment. Future developments may integrate textiles with nano- and terascale technologies to create highly complex, cognitive, and integrated systems. These could endow textiles with new sensing, signaling, computing and tissue engineering capabilities.
Nanotechnology in textiles-wired and ready to wear textilessargow27
The document discusses the potential applications of nanotechnology and electronic textiles, or e-textiles. It describes how sensors and electronics can be embedded in fabrics to create "smart" or "wired and ready to wear" textiles. Some key applications mentioned include sportswear that monitors vital signs, clothing that charges electronic devices, and protective garments for firefighters equipped with environmental and health sensors. The document highlights the growing field of electronic textiles and their ability to make clothing more functional and interactive.
This document discusses smart textiles, which integrate microelectronics into textiles to endow them with new properties and active behaviors. Smart textiles can sense and react to stimuli in their environment. They are categorized as passive, active, or ultra smart depending on their sensing and response capabilities. The key functions of smart textiles are sensing, data processing, actuation, storage, and communication. Examples of smart textile applications discussed include thermoregulating materials, chromic materials, luminescent materials, conductive materials, voltaic materials, and electronic textiles. Areas of further research include sensors, actuators, signal transmission and control systems, and integrated textile processes.
Smart fabrics are defined as fabrics that can sense and react to environmental conditions or stimuli from mechanical, thermal, chemical, electrical or magnetic sources.
Also called as intelligent textiles.
Enable digital components.
Smart textiles are materials and structures that can sense and react to environmental stimuli. They include self-cleaning carpets, memory fabrics, and fabrics that regulate temperature. Smart textiles can be divided into passive materials that only sense stimuli, active materials that can both sense and respond, and very smart materials that can sense, respond, and adapt. They use materials like conductive fibers, shape memory alloys, and microencapsulated phase change materials. Applications include sportswear that regulates temperature, medical clothing that monitors vital signs, military uniforms that detect hazards, and fashionable apparel that changes color or plays music. The future of smart textiles may include clothing that emits scents, becomes rigid to immobilize injuries,
This document provides an overview of smart textiles. It defines smart textiles as textiles that can sense and react to environmental conditions or stimuli. It discusses the scope of smart textiles, including the integration of various disciplines required. It outlines different generations of textile wearable technologies and describes textronics. It also covers various topics related to smart textiles like classifications, materials, incorporation into textiles, components, working process, applications, and the relationship to technical textiles.
Smart textiles are materials and structures that can sense and react to environmental stimuli. There are four main types: passive smart materials that only sense stimuli, active smart materials that can both sense and respond, very smart materials that can sense, respond, and adapt, and materials with artificial intelligence. Smart textiles find applications in sports, healthcare, military, fashion and more. New developments include light-emitting, scent-emitting, shape-shifting, and health-monitoring textiles. Smart textiles have the potential to revolutionize clothing and other fabrics.
Smart textiles new possibilities in textile engineeringNasif Chowdhury
This document discusses smart textiles and provides several examples. It begins by defining smart textiles as textiles that can sense environmental stimuli and react to them by integrating functionalities into the textile structure. The stimulus and response can be electrical, thermal, chemical, magnetic, or other. Examples are given of smart textiles for clothing that can change color or provide light and regulate temperature. The document then discusses the different types of smart textiles and their various functions like sensing, data processing, actuation, storage, and communication. Several applications and examples of smart textiles are provided like the Gore-Tex jacket and Georgia Tech's wearable motherboard shirt. Adidas' and Nike's smart running shoes are also summarized.
Smart fabrics, also known as electronic textiles or smart clothing, are fabrics that have digital components like sensors, actuators and processors embedded in them. They are able to sense external conditions and respond accordingly. Smart fabrics have been in development since the 1990s and use materials like conductive threads, fibers and fabrics. They contain sensors to detect information and actuators to trigger responses. Processors then analyze the sensor data and control the actuators. Common applications of smart fabrics include uses in healthcare for monitoring health metrics, in military and safety gear for functions like GPS tracking, and in the fashion industry for customizable fabrics.
Electronic-textiles (e-textiles) incorporate electronic functionality into textiles by using conductive materials. They contain conductive yarns or fibers and can be produced using textile manufacturing techniques. E-textiles allow for innovative designs and integration of sensors, displays and other electronics into fabrics and garments. They provide benefits like flexibility, comfort and low-cost production compared to rigid electronics. However, challenges remain around reliability, mass production costs and limited processing capability due to power constraints. Ongoing research aims to address these issues and further the applications of intelligent textile technologies.
This document discusses smart textiles, which integrate microelectronics into textiles to endow them with new interactive properties. It defines three types of smart textiles - passive, active, and ultra smart - based on their ability to sense and react to environmental stimuli. The key functions of smart textiles are described as sensing, data processing, actuation, storage, and communication. Various materials used in smart textiles are also outlined, such as thermoregulating materials, chromic materials, luminescent materials, conductive materials, voltaic materials, and electronic textiles. The document concludes by noting several areas of research and development for smart textile sensors, actuators, signal transmission and control systems.
Smart textiles are textiles that can sense and react to environmental stimuli through integrated electronics or other technologies. They have a wide range of applications, including in medicine to monitor vital signs, in fashion as displays on clothing, and as soft interfaces. Smart textiles work by using conductive materials integrated into fabrics that can detect changes and respond accordingly, often transmitting related data. Common triggers sensed include touch, temperature, pressure, and other bodily functions.
This document discusses intelligent textiles that use phase change materials and shape memory materials. It begins with an introduction submitted by a textile engineering student. It then discusses intelligent textile systems using sensors, processors and actuators. It provides examples of intelligent textiles like phase change materials, shape memory materials, and conductive materials. It discusses applications of these intelligent textiles in apparel, home textiles, medical textiles, and more. It also provides details on phase change materials, how they work, and how they can be incorporated into textiles.
This document discusses smart fabrics and textiles that can sense and respond to environmental stimuli. It provides examples of smart fabrics like Gore-Tex that are waterproof and breathable, as well as microencapsulated fabrics that can release substances like antibacterial agents in response to heat, pressure or other triggers. The document also discusses using smart textiles for medical purposes like wound dressings and how they may help regulate body temperature and odor. It describes early experiments creating touch interfaces and circuits using conductive metallic yarns woven into fabrics.
The document discusses smart and intelligent textiles. It begins by introducing textiles as the second skin of humans and notes they traditionally provide protection and aesthetics. It describes how intelligence is now being integrated into fabrics to create interactive textiles. It outlines several classifications of smart fibers and materials that can sense and react to environmental stimuli, including thermochromic, luminescent, conductive, and shape memory materials. Example applications are described for areas like military, healthcare, sports, and fashion. In closing, it argues textiles represent an attractive platform for biosensors and wearable electronics since many systems can be connected to clothing to create a versatile and customizable experience for the user.
Advance Research in Textile Engineering is an open access, peer reviewed, scholarly journal dedicated to publish articles covering all areas of Textile Engineering.
The journal aims to promote research communications and provide a forum for doctors, researchers, physicians and healthcare professionals to find most recent advances in all areas of Textile Engineering. Advance Research in Textile Engineering accepts original research articles, reviews, mini reviews, case reports and rapid communication covering all aspects of Textile Engineering.
Advance Research in Textile Engineering strongly supports the scientific up gradation and fortification in related scientific research community by enhancing access to peer reviewed scientific literary works. Austin Publishing Group brings universally peer reviewed journals under one roof thereby promoting knowledge sharing, mutual promotion of multidisciplinary science.
The document discusses the global and Bangladeshi home textile industries. It provides definitions of home textiles and describes the different types of home textile products. It then discusses key details about the global home textiles market such as its size, leading regions, and growth rates in different countries. For Bangladesh specifically, it outlines the country's leading home textile exporters and products, export countries, and contributions of home textiles to the Bangladeshi economy.
The document discusses the history and uses of scarves. It traces the origins of scarves back to Ancient Rome. In the early 19th century, scarves became a real fashion accessory for both men and women. In Islam, scarves are called hijabs and are compulsory for Muslim women to wear. In Malaysia, many scarves have cultural designs like the popular "nasi lemak" scarf. The document also discusses different styles of scarves and the importance of modest dress in Islam for women.
The document provides forecasts and directions for fall/winter 2009-2010 colours, prints, and trends in women's and men's fashion. Key trends include art forms inspired by sculpture and architecture, layered and textured knits for both men and women, and colours ranging from rich jewel tones to softer pastels and neutrals. Silhouettes emphasize slim fits, higher necklines, and exaggerated proportions. Fabrics feature intricate patterns, mixed gauges, and technical blends.
The document provides a fashion forecast and trends for winter 2014-2015. It outlines four key themes - Tenderness, Highlands, Artistic, and Scientific. Each theme explores colors, materials, silhouettes and details that will be popular. It also identifies "must have" items for men and women, including knitwear, woven tops, skirts, trousers, jackets and outerwear. The trends focus on new technologies and craftsmanship, with an emphasis on comfort, protection and functionality in the designs.
GHCL Limited faced several challenges after implementing SAP, including frequent changes in management and business processes. To address this, they standardized costing calculations and created a generic process flow model. They also automated data entry through interfaces to reduce errors and delays. Data entry positions were eliminated and existing employees were reassigned. Transactions that allowed adjustments or disturbances were locked down. Key transactions were gradually transferred to authorized users with training on user-friendly screens. These approaches helped simplify the system and provide error-free data analysis to decision makers.
GHCL Limited implemented several automation projects to improve data collection and entry processes across various textile departments. This reduced paperwork, duplicate data entry, and reliance on skilled users. Specifically:
1) A weaving automation project transferred loom machine data to SAP online, reducing data collection time from 4 hours to 10 minutes per shift.
2) An inspection automation project uploaded inspection machine data directly to SAP via an interface, reducing data entry time from 20 minutes to fully automated and requiring only one operator per shift.
3) A cutting automation project allowed online data entry at cutting machines with validation, eliminating the need for a data entry operator.
4) A madeups automation project was being implemented to similarly
미국섬유역사박물관에서 만든 자료다. 방문객 또는 아이들을 위해 나무가지, 종이상자, 프라스틱 바구니 등을 이용해서 간단히 직조의 기본 원리를 이해하고 체험할 수 있는 프로그램의 교안이라 할 수 있다. 평직, 능직에 대한 설명도 있다. 뒷편엔 용어사전도 포함되어 있다. 36쪽 정도의 간단한 자료지만 아동이나 처음 직조를 접하는 이들을 위한 프로그램 자료로 충분하다. 국내에선 이런 간단한 자료 하나 구하기 어렵다. 그뿐 아니라 공개하질 않는다.
This document discusses forbidden dyestuffs in the textile industry that are banned due to health and environmental reasons. It provides examples of forbidden dyestuffs such as azo dyes, phthalates, brominated flame retardants, and heavy metals. These chemical dyes are restricted because they can accumulate in living organisms and the environment, are toxic or cause cancer, hormone disruption, and damage to organs like the liver, kidneys and nervous system over time. The document also describes methods for detecting banned azo dyes in textiles and laws regulating forbidden dyestuffs in Turkey.
The document provides information about fashion merchandising and why people wear clothes. It discusses the basic needs that clothing fulfills such as protection, adornment, modesty, and status. It also covers fashion terminology like silhouette, haute couture, knock-offs, and classics. Key factors that influence clothing choices are described as values, attitudes, conformity, and personality.
This document outlines topics related to fashion merchandising including the functions of a production merchandiser such as communication, coordination, product development, sampling, tech packs, costing, sourcing, timelines, meetings, and post-shipment analysis. The document provides an index of 13 topics on fashion merchandising written by Vasant Kothari.
The document provides a trend forecast for fashion in spring/summer 2016. It identifies the top 10 colors for women's and men's fashion, including coral, burgundy, and grass turf. It also highlights key prints and patterns, such as bold florals and revamped classic prints for men. Different silhouettes, fabrics, and embellishments are forecasted for categories like women's, men's, and children's wear. Trend predictions are provided for areas including accessories, activewear, and women's intimates. The report aims to help retailers and designers identify popular styles and colors for the upcoming season.
This document summarizes a fashion forecasting project completed by students for Biba, an Indian women's clothing brand. The students presented a wedding collection inspired by mood boards and color schemes. They forecasted 12 looks including lehengas, saris, and kurtas made of materials like velvet, brocade and silk. The looks featured trims like laces, embroidery and thread work. The overarching themes were comfort and grace to make brides feel elegant on their special day.
The document provides an overview of the key beliefs and practices of Islam. It discusses that Muhammad received revelations from God and preached monotheism, establishing Islam. The five pillars of Islam are outlined as professing faith, daily prayers, charity, fasting during Ramadan, and pilgrimage to Mecca. Jihad involves struggle, which can be military or peaceful. The Quran is the holy book that outlines how Muslims should live, including prohibitions on pork and alcohol. Mosques are places of worship for Muslims.
This document discusses non-woven textiles. It covers raw materials like cotton, rayon, wool, polyamide/polyester and acrylic. It describes properties of non-wovens like fiber description, bonding agents, binder mechanisms, classification of binders and types of binders. It also discusses manufacturing steps for non-wovens including wet laid, dry laid, air laying, spun laid and melt blown processes. Finally, it outlines bonding techniques such as mechanical, chemical and thermal bonding.
This document provides an overview of key beliefs and practices in Islam. It discusses the origins and meaning of Islam and the terms Muslim, as well as the life and teachings of the prophet Muhammad. The six articles of Islamic faith are explained, including belief in God, the unseen, prophethood, revelation, judgment day, and divine decree. The two main sects of Islam, Sunni and Shia, are introduced. The five pillars of Islam - declaration of faith, prayer, alms, fasting, and pilgrimage - are outlined as the core duties of Muslims. Overall, the document presents foundational concepts and tenets of the Islamic faith.
This document provides an overview of an Islamic cultural awareness course, including introductions, guidelines, background information on Muslims in the local community and workplace, and key Islamic beliefs and practices. It outlines the five pillars of Islam, articles of faith, sensitivities to consider, and importance of interfaith dialogue. Contact details are provided for further information.
Islam is a monotheistic religion that believes in one God called Allah and follows the teachings of the Prophet Muhammad. Muslims adhere to the Five Pillars of Islam which are the confession of faith, ritual prayer five times a day, charitable donations, fasting during Ramadan, and performing the Hajj pilgrimage to Mecca at least once in their lifetime. The two main branches of Islam are the Sunni and Shi'a, who differ on who should have succeeded Muhammad as the leader of the Muslim community.
The document provides an overview of the global textile and apparel industry, including its history and key statistics. It discusses the shift in growth towards developing countries due to the end of quotas in 2005. India's large and growing textile industry is highlighted, with major players like Raymond and Bombay Dyeing mentioned. Key factors influencing consumer purchasing decisions are identified. The various stakeholders in the industry are mapped out.
Vanderveer Designers recently traveled to the Techtextil exhibit in Frankfurt to see where the industry is heading with new substances and developments in technical textiles. Our team was inspired by the wide range of applications — from fashion and clothing to architecture, healthcare, the outdoors and automotives. Once again, we have left with many new creative and innovative ideas. In part, thanks to the awesome presentations given by @nextnaturenetwork. Until next year!
A presentation for Research in Humanities and the Arts 2017 (DRHA): DataAche, Plymouth, UK - on the WEAR Sustain EU funded project progress, challenges and values on ethical and sustainable wearable technologies and e-textiles.
Wearable computers can now be incorporated directly into clothing through the use of conductive textiles, circuits, and components. This paper describes techniques for building circuits using commercially available fabrics, yarns, fasteners, and electronic components which allow data and power distribution as well as sensing to be integrated into washable clothing.
Computer Aided Designs CAD Printing and Production of Cut Wood Motif on FabricsEditorIJTSRD1
Fabric decoration is an art that has existed for many centuries but usually done manually. Before now, most Artists used conventional methods of art production, which is cumbersome, tedious, time consuming but with the introduction of Computer aided design in textile arts, the whole design process become easier and more efficient as well as ensures precise and accurate reproduction of the artwork also in creating more striking and intricate designs that translate into beautiful fabric decorations. Hence, Computer aided design software CAD is an invaluable application for textile design and fabric decoration. This study computer aided design printing and production of cut wood motif on fabrics, aims at developing motifs from the woods fell at different locations in Anambra State Polytechnic, Mgbakwu. The motifs developed are arranged into appropriate repeat patterns, then digitally transferred into CAD software for colours separation and finally printed on laser films for production. It employed the textile techniques of screen printing process. The experiment at the end resulted in fully designed fabrics and interior decoration items ready for the market. The study serves as a resource material as well as an inspiration for designers researcher working on projects of complex designs with great precision to explore computer aided design software and for further advances in the field of textile arts. Okonkwo, Cecilia Chiedonma | Ekwezia, Awele Vivian | Engr. Ernest-Okoye Ngozi "Computer-Aided Designs (CAD): Printing and Production of Cut-Wood Motif on Fabrics" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-7 | Issue-3 , June 2023, URL: https://www.ijtsrd.com.com/papers/ijtsrd58603.pdf Paper URL: https://www.ijtsrd.com.com/engineering/computer-engineering/58603/computeraided-designs-cad-printing-and-production-of-cutwood-motif-on-fabrics/okonkwo-cecilia-chiedonma
The document outlines the Great Festival of Creativity event taking place from 20-22 May 2014 in Istanbul. It provides information on several speakers and their areas of research related to textiles, materials, and design. These include projects focused on sustainability, emerging technologies, biomimetics, and speculative design. The event aims to showcase how academic research in these fields can translate to commercial innovation and benefit brands.
Project Jacquard is a wearable technology project that embeds conductive yarns into fabrics to enable touch-sensitive interactions. It was developed by Google's ATAP department to create garments that can control smartphone functions through gestures without making people feel uncomfortable wearing them. The conductive yarns are woven into fabrics using standard industrial looms and can be incorporated with different fiber types. This allows for large-scale production of interactive textiles for uses in clothing, toys, furniture and more.
This document summarizes 10 apparel innovations from 2015 that promote sustainability. Some of the innovations highlighted include fabric made from milk, tea and coffee; air dyeing which saves water; digital printing; recycled plastic bags and bottles turned into fiber; hand dyeing with locally sourced dyes; online shopping tools that consider body measurements; water-free stone washing; bio-filtering wastewater treatment; smart tailoring technology; and new global standards for organic textiles. The innovations aim to reduce water and energy usage, minimize waste, and create clothing with recycled or sustainably sourced materials.
Anne Prahl PhD, WEAR Sustain PresentationWEAR Sustain
Responsible innovation for Wearable Technology: Designing for Circularity, Anne Prahl PhD Presentation, WEAR Sustain Open Call London Launch, Digital Catapult, 3rd May 2017
Part III: Workwear Fashion, Human Anatomy, Transparency & TechnologyDr. Lydia Kostopoulos
Workwear Fashion, Human Anatomy, Transparency & Technology: A National Security Professional's Journey to Functional Women's Workwear
Part 1: Dissects popular women’s workwear designs through the lens of anatomy, exploring what tight waistlines mean for digestion and offers reflection on how workwear can be better designed for menstrual cycles and hot flashes of menopause.
Part 2: Reflects on the polluting nature of fast fashion and the sustainable fashion initiatives that are coming about to combat this.
Part 3: Explores the exciting new technologies that are emerging in the field of fashion such as 3D printing, nanotechnology, and digital fashion.
Part 4: Expands on what the purpose driven brand "Empowering Workwear by Lydia" is trying to do with its four-tiered agenda for women’s workwear fashion.
More information on Empowering Workwear: www.empoweringworkwear.com
www.lkcyber.com
This document summarizes an innovative cotton denim collection created through a collaboration between Jeanologia and Cotton Incorporated. The collection utilizes Jeanologia's eco-friendly finishing technologies to create fashion-forward designs while minimizing environmental impact. Each design is analyzed using Jeanologia's Environmental Impact Measurement software to quantify reductions in water, chemicals, energy and labor. Design concepts range from laser-etched patterns and distressed effects to digitally printed images and tinted fabrics.
The document discusses emerging technologies in wearable tech and fashion. It describes fabrics that change transparency, emit lasers or generate electricity. 3D printing is discussed as the future of art and design. Tracking chips and intelligent sports bras that monitor health are presented as examples of integrating tech into clothing. The styles showcase layers for adding materials, cuts and shapes focusing on innovative prints, colors and 3D structures to create sophisticated wearable tech designs.
The document discusses smart fabrics, which are fabrics embedded with digital technologies or nanomaterials to enhance their functionality. It provides examples of smart fabrics using optical fibers, nano-particles, chromic materials, and shape memory materials. Key applications discussed include uses in sports, military, healthcare, and fashion. Innovation leaders are profiled who are developing smart yoga pants, jackets, dresses, and baby socks. The presentation concludes by discussing the future potential of smart fabrics to be more adaptive, connected to IoT, and developed with sustainability and safety in mind.
The document summarizes the WEAR Sustain project, a 3 million Euro EU-funded initiative from 2017-2018 that aimed to promote more sustainable and ethical development of wearable technologies. The project brought together wearable technology stakeholders across Europe to address issues like data privacy, environmental impact, and labor practices. It had four main elements: sustainable innovation funding; knowledge exchange events; developing an online wearables ecosystem; and creating ethics and sustainability guidelines. Selected collaborative teams received up to €50,000 to prototype projects addressing themes like reuse/waste, batteries, and data privacy. While schedules delays and production challenges were common, the project helped broaden views on sustainability and ethics in wearable technology development.
This document provides an abstract for a master's thesis titled "Made in Europe" that examines fashion production in Europe compared to the global market. The thesis uses a socio-cultural analysis and fieldwork in Italy and Denmark to investigate how culture, materiality, and social practices are intertwined in fashion systems. It aims to illustrate the learning that occurs through social and material interactions between businesses of different cultures. The thesis also explores possibilities for reshoring production to Europe based on experiences reconstructing the textile and leather industries.
Sandy Black, Centre for Sustainable Fashion, University of the Arts, WEAR Sus...WEAR Sustain
Presentation from Professor Sandy Black, Centre for Sustainable Fashion, University of the Arts, WEAR Sustain Open Call London Launch, Digital Catapult 3rd May 2017
The presentation discusses future trends in knitting, including the growing popularity of knitting due to new fibers and techniques. It outlines developments in warp knitting technology using new materials like CFRP. Whole garment knitting technology allows entire garments to be knitted in one piece without seams. Photographic weaving and super-thin polyester fabrics represent new frontiers for replicating fine images and producing extremely lightweight textiles. Overall the document highlights many innovations in knitting machinery and materials that are expanding the applications and possibilities of knitted fabrics.
Embroidery machines will likely play a pivotal role. Machines with increased precision, speed, and the ability to handle a broader range of fabrics will empower digitizers and designers to push the boundaries of what can be achieved.
The document discusses various aspects of green and sustainable textile production, including natural dyeing processes, recycling of textiles, use of organic materials, and reducing environmental pollution from the textile industry. It notes that textile production can be harmful through the use of chemicals and release of wastewater, but that more sustainable practices include using natural dyes extracted from plants, recycling fabrics into new materials, and switching to organic cotton and other natural fibers. The document provides details on different natural dye sources and colors, as well as other green textile processes like chlorine-free bleaching and low-temperature dyeing.
Ecofriendly technology for textile industry preranawagh1
ecofriendly technology for our textile industry. this is most important aspect for our new technology. we should influence people for ecofriendly technology.
Similar to Textile technological innovation in fashion(Concept to CAtwalk) by shazzadul islam (20)
Taking AI to the Next Level in Manufacturing.pdfssuserfac0301
Read Taking AI to the Next Level in Manufacturing to gain insights on AI adoption in the manufacturing industry, such as:
1. How quickly AI is being implemented in manufacturing.
2. Which barriers stand in the way of AI adoption.
3. How data quality and governance form the backbone of AI.
4. Organizational processes and structures that may inhibit effective AI adoption.
6. Ideas and approaches to help build your organization's AI strategy.
Northern Engraving | Nameplate Manufacturing Process - 2024Northern Engraving
Manufacturing custom quality metal nameplates and badges involves several standard operations. Processes include sheet prep, lithography, screening, coating, punch press and inspection. All decoration is completed in the flat sheet with adhesive and tooling operations following. The possibilities for creating unique durable nameplates are endless. How will you create your brand identity? We can help!
Fueling AI with Great Data with Airbyte WebinarZilliz
This talk will focus on how to collect data from a variety of sources, leveraging this data for RAG and other GenAI use cases, and finally charting your course to productionalization.
Monitoring and Managing Anomaly Detection on OpenShift.pdfTosin Akinosho
Monitoring and Managing Anomaly Detection on OpenShift
Overview
Dive into the world of anomaly detection on edge devices with our comprehensive hands-on tutorial. This SlideShare presentation will guide you through the entire process, from data collection and model training to edge deployment and real-time monitoring. Perfect for those looking to implement robust anomaly detection systems on resource-constrained IoT/edge devices.
Key Topics Covered
1. Introduction to Anomaly Detection
- Understand the fundamentals of anomaly detection and its importance in identifying unusual behavior or failures in systems.
2. Understanding Edge (IoT)
- Learn about edge computing and IoT, and how they enable real-time data processing and decision-making at the source.
3. What is ArgoCD?
- Discover ArgoCD, a declarative, GitOps continuous delivery tool for Kubernetes, and its role in deploying applications on edge devices.
4. Deployment Using ArgoCD for Edge Devices
- Step-by-step guide on deploying anomaly detection models on edge devices using ArgoCD.
5. Introduction to Apache Kafka and S3
- Explore Apache Kafka for real-time data streaming and Amazon S3 for scalable storage solutions.
6. Viewing Kafka Messages in the Data Lake
- Learn how to view and analyze Kafka messages stored in a data lake for better insights.
7. What is Prometheus?
- Get to know Prometheus, an open-source monitoring and alerting toolkit, and its application in monitoring edge devices.
8. Monitoring Application Metrics with Prometheus
- Detailed instructions on setting up Prometheus to monitor the performance and health of your anomaly detection system.
9. What is Camel K?
- Introduction to Camel K, a lightweight integration framework built on Apache Camel, designed for Kubernetes.
10. Configuring Camel K Integrations for Data Pipelines
- Learn how to configure Camel K for seamless data pipeline integrations in your anomaly detection workflow.
11. What is a Jupyter Notebook?
- Overview of Jupyter Notebooks, an open-source web application for creating and sharing documents with live code, equations, visualizations, and narrative text.
12. Jupyter Notebooks with Code Examples
- Hands-on examples and code snippets in Jupyter Notebooks to help you implement and test anomaly detection models.
High performance Serverless Java on AWS- GoTo Amsterdam 2024Vadym Kazulkin
Java is for many years one of the most popular programming languages, but it used to have hard times in the Serverless community. Java is known for its high cold start times and high memory footprint, comparing to other programming languages like Node.js and Python. In this talk I'll look at the general best practices and techniques we can use to decrease memory consumption, cold start times for Java Serverless development on AWS including GraalVM (Native Image) and AWS own offering SnapStart based on Firecracker microVM snapshot and restore and CRaC (Coordinated Restore at Checkpoint) runtime hooks. I'll also provide a lot of benchmarking on Lambda functions trying out various deployment package sizes, Lambda memory settings, Java compilation options and HTTP (a)synchronous clients and measure their impact on cold and warm start times.
Introduction of Cybersecurity with OSS at Code Europe 2024Hiroshi SHIBATA
I develop the Ruby programming language, RubyGems, and Bundler, which are package managers for Ruby. Today, I will introduce how to enhance the security of your application using open-source software (OSS) examples from Ruby and RubyGems.
The first topic is CVE (Common Vulnerabilities and Exposures). I have published CVEs many times. But what exactly is a CVE? I'll provide a basic understanding of CVEs and explain how to detect and handle vulnerabilities in OSS.
Next, let's discuss package managers. Package managers play a critical role in the OSS ecosystem. I'll explain how to manage library dependencies in your application.
I'll share insights into how the Ruby and RubyGems core team works to keep our ecosystem safe. By the end of this talk, you'll have a better understanding of how to safeguard your code.
inQuba Webinar Mastering Customer Journey Management with Dr Graham HillLizaNolte
HERE IS YOUR WEBINAR CONTENT! 'Mastering Customer Journey Management with Dr. Graham Hill'. We hope you find the webinar recording both insightful and enjoyable.
In this webinar, we explored essential aspects of Customer Journey Management and personalization. Here’s a summary of the key insights and topics discussed:
Key Takeaways:
Understanding the Customer Journey: Dr. Hill emphasized the importance of mapping and understanding the complete customer journey to identify touchpoints and opportunities for improvement.
Personalization Strategies: We discussed how to leverage data and insights to create personalized experiences that resonate with customers.
Technology Integration: Insights were shared on how inQuba’s advanced technology can streamline customer interactions and drive operational efficiency.
Conversational agents, or chatbots, are increasingly used to access all sorts of services using natural language. While open-domain chatbots - like ChatGPT - can converse on any topic, task-oriented chatbots - the focus of this paper - are designed for specific tasks, like booking a flight, obtaining customer support, or setting an appointment. Like any other software, task-oriented chatbots need to be properly tested, usually by defining and executing test scenarios (i.e., sequences of user-chatbot interactions). However, there is currently a lack of methods to quantify the completeness and strength of such test scenarios, which can lead to low-quality tests, and hence to buggy chatbots.
To fill this gap, we propose adapting mutation testing (MuT) for task-oriented chatbots. To this end, we introduce a set of mutation operators that emulate faults in chatbot designs, an architecture that enables MuT on chatbots built using heterogeneous technologies, and a practical realisation as an Eclipse plugin. Moreover, we evaluate the applicability, effectiveness and efficiency of our approach on open-source chatbots, with promising results.
Dandelion Hashtable: beyond billion requests per second on a commodity serverAntonios Katsarakis
This slide deck presents DLHT, a concurrent in-memory hashtable. Despite efforts to optimize hashtables, that go as far as sacrificing core functionality, state-of-the-art designs still incur multiple memory accesses per request and block request processing in three cases. First, most hashtables block while waiting for data to be retrieved from memory. Second, open-addressing designs, which represent the current state-of-the-art, either cannot free index slots on deletes or must block all requests to do so. Third, index resizes block every request until all objects are copied to the new index. Defying folklore wisdom, DLHT forgoes open-addressing and adopts a fully-featured and memory-aware closed-addressing design based on bounded cache-line-chaining. This design offers lock-free index operations and deletes that free slots instantly, (2) completes most requests with a single memory access, (3) utilizes software prefetching to hide memory latencies, and (4) employs a novel non-blocking and parallel resizing. In a commodity server and a memory-resident workload, DLHT surpasses 1.6B requests per second and provides 3.5x (12x) the throughput of the state-of-the-art closed-addressing (open-addressing) resizable hashtable on Gets (Deletes).
Must Know Postgres Extension for DBA and Developer during MigrationMydbops
Mydbops Opensource Database Meetup 16
Topic: Must-Know PostgreSQL Extensions for Developers and DBAs During Migration
Speaker: Deepak Mahto, Founder of DataCloudGaze Consulting
Date & Time: 8th June | 10 AM - 1 PM IST
Venue: Bangalore International Centre, Bangalore
Abstract: Discover how PostgreSQL extensions can be your secret weapon! This talk explores how key extensions enhance database capabilities and streamline the migration process for users moving from other relational databases like Oracle.
Key Takeaways:
* Learn about crucial extensions like oracle_fdw, pgtt, and pg_audit that ease migration complexities.
* Gain valuable strategies for implementing these extensions in PostgreSQL to achieve license freedom.
* Discover how these key extensions can empower both developers and DBAs during the migration process.
* Don't miss this chance to gain practical knowledge from an industry expert and stay updated on the latest open-source database trends.
Mydbops Managed Services specializes in taking the pain out of database management while optimizing performance. Since 2015, we have been providing top-notch support and assistance for the top three open-source databases: MySQL, MongoDB, and PostgreSQL.
Our team offers a wide range of services, including assistance, support, consulting, 24/7 operations, and expertise in all relevant technologies. We help organizations improve their database's performance, scalability, efficiency, and availability.
Contact us: info@mydbops.com
Visit: https://www.mydbops.com/
Follow us on LinkedIn: https://in.linkedin.com/company/mydbops
For more details and updates, please follow up the below links.
Meetup Page : https://www.meetup.com/mydbops-databa...
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Blogs: https://www.mydbops.com/blog/
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Main news related to the CCS TSI 2023 (2023/1695)Jakub Marek
An English 🇬🇧 translation of a presentation to the speech I gave about the main changes brought by CCS TSI 2023 at the biggest Czech conference on Communications and signalling systems on Railways, which was held in Clarion Hotel Olomouc from 7th to 9th November 2023 (konferenceszt.cz). Attended by around 500 participants and 200 on-line followers.
The original Czech 🇨🇿 version of the presentation can be found here: https://www.slideshare.net/slideshow/hlavni-novinky-souvisejici-s-ccs-tsi-2023-2023-1695/269688092 .
The videorecording (in Czech) from the presentation is available here: https://youtu.be/WzjJWm4IyPk?si=SImb06tuXGb30BEH .
The Department of Veteran Affairs (VA) invited Taylor Paschal, Knowledge & Information Management Consultant at Enterprise Knowledge, to speak at a Knowledge Management Lunch and Learn hosted on June 12, 2024. All Office of Administration staff were invited to attend and received professional development credit for participating in the voluntary event.
The objectives of the Lunch and Learn presentation were to:
- Review what KM ‘is’ and ‘isn’t’
- Understand the value of KM and the benefits of engaging
- Define and reflect on your “what’s in it for me?”
- Share actionable ways you can participate in Knowledge - - Capture & Transfer
AppSec PNW: Android and iOS Application Security with MobSFAjin Abraham
Mobile Security Framework - MobSF is a free and open source automated mobile application security testing environment designed to help security engineers, researchers, developers, and penetration testers to identify security vulnerabilities, malicious behaviours and privacy concerns in mobile applications using static and dynamic analysis. It supports all the popular mobile application binaries and source code formats built for Android and iOS devices. In addition to automated security assessment, it also offers an interactive testing environment to build and execute scenario based test/fuzz cases against the application.
This talk covers:
Using MobSF for static analysis of mobile applications.
Interactive dynamic security assessment of Android and iOS applications.
Solving Mobile app CTF challenges.
Reverse engineering and runtime analysis of Mobile malware.
How to shift left and integrate MobSF/mobsfscan SAST and DAST in your build pipeline.
How to Interpret Trends in the Kalyan Rajdhani Mix Chart.pdfChart Kalyan
A Mix Chart displays historical data of numbers in a graphical or tabular form. The Kalyan Rajdhani Mix Chart specifically shows the results of a sequence of numbers over different periods.
7. The brown and blue dress
on the left was produced
without any pigments or
dyes. The colors were
created by coating cotton
fibers with nanoparticles
and manipulating the way
matter and light interacts
between the particles.
Smart textiles or garments that merge
fashion and technology
8. Air Dye works with
proprietary dyes that are
heat-transferred from paper
to fabric in a one-step
process. This can save
between seven and 75
gallons of water in the dying
of a pound of fabric, save
energy, and produces no
harmful by-products. The
technology uses 85 percent
less energy then traditional
dying methods.
Dying with Air, Saving Gallons of Water
13. Self-healing Fabrics
Self-healing fabrics are actually a part of our lives
right now, and they’re about to start multiplying.
While rips and tears in any item of clothing are an
annoyance, when it comes to waterproof garments
the problem affects more than just looks.
14. Solar Panel Jackets
The technology
creates solar
power that can
do awesome
things like
charge the
phone.
19. E-textile
In "third generation"
wearable's, the garment
is the sensor. A growing
number of companies
are creating pressure,
strain and temperature
sensors for this purpose.