2014, 1st ed., ISBN 9781449336516, xviii, 257
"Make: Wearable Electronics is intended for those with an interest in physical computing who are looking to create interfaces or systems that live on the body....
Human-computer interaction | Design and construction | Wearable computers | Interactive computer systems
Human-computer interaction | Design and construction | Wearable computers | Interactive computer systems
Book
2005, ISBN 0849325951, xiv, 250
Book
Nature Nanotechnology, ISSN 1748-3387, 09/2017, Volume 12, Issue 9, pp. 839 - 840
Journal Article
Biosensors & bioelectronics, ISSN 0956-5663, 1989
Journal
Advanced Materials, ISSN 0935-9648, 06/2016, Volume 28, Issue 22, pp. 4497 - 4505
Stretchable hydrogel electronics and devices are designed by integrating stretchable conductors, functional chips, drug‐delivery channels, and reservoirs into...
flexible electronics | wearable devices | hydrogels | drug delivery | biointegrated electronics | 25TH ANNIVERSARY ARTICLE | PHYSICS, CONDENSED MATTER | GELLAN GUM | COMPLEX | DESIGN | PHYSICS, APPLIED | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | NETWORKS | CHEMISTRY, MULTIDISCIPLINARY | SKIN | TOUGH HYDROGELS | SURFACES | Drugs | Drug delivery systems | Vehicles | Electronic devices | Hydrogels | Electronics | Conductors | Sustained release | Devices | Channels
flexible electronics | wearable devices | hydrogels | drug delivery | biointegrated electronics | 25TH ANNIVERSARY ARTICLE | PHYSICS, CONDENSED MATTER | GELLAN GUM | COMPLEX | DESIGN | PHYSICS, APPLIED | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | NETWORKS | CHEMISTRY, MULTIDISCIPLINARY | SKIN | TOUGH HYDROGELS | SURFACES | Drugs | Drug delivery systems | Vehicles | Electronic devices | Hydrogels | Electronics | Conductors | Sustained release | Devices | Channels
Journal Article
2014, The John D. and Catherine T. Macarthur Foundation series on digital media and learning, ISBN 9780262027847, xxxviii, 368
Soft Circuitsintroduces students to the world of wearable technology. Using Modkit, an accessible DIY electronics toolkit, students learn to create e-textile...
Dress accessories | Activity programs | Activity programs in education | Electronic circuits | Study and teaching (Middle school) | Education | Technology
Dress accessories | Activity programs | Activity programs in education | Electronic circuits | Study and teaching (Middle school) | Education | Technology
Book
Advanced Functional Materials, ISSN 1616-301X, 09/2017, Volume 27, Issue 33, pp. 1701513 - n/a
Epidermal electronics are extensively explored as an important platform for future biomedical engineering. Epidermal devices are typically fabricated using...
reduced graphene oxide | solution‐based approach | strain sensors | bioelectrodes | electronic skins | solution-based approach | SYSTEM | PHYSICS, CONDENSED MATTER | DESIGN | PHYSICS, APPLIED | MATERIALS SCIENCE, MULTIDISCIPLINARY | STRETCHABLE ELECTRONICS | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | OXIDE SHEETS | CHEMISTRY, MULTIDISCIPLINARY | BIOINTEGRATED DEVICES | TRANSPARENT | MUSCLES | Thin films | Graphene | Graphite | Electroencephalography | Skin | Dimethylpolysiloxane | Dielectric films | Sensors | Biomedical engineering | Stretchability | Silicone resins | Electronics | Polydimethyl siloxanes | Signal monitoring | Biomedical materials | Stretching | Wearable technology
reduced graphene oxide | solution‐based approach | strain sensors | bioelectrodes | electronic skins | solution-based approach | SYSTEM | PHYSICS, CONDENSED MATTER | DESIGN | PHYSICS, APPLIED | MATERIALS SCIENCE, MULTIDISCIPLINARY | STRETCHABLE ELECTRONICS | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | OXIDE SHEETS | CHEMISTRY, MULTIDISCIPLINARY | BIOINTEGRATED DEVICES | TRANSPARENT | MUSCLES | Thin films | Graphene | Graphite | Electroencephalography | Skin | Dimethylpolysiloxane | Dielectric films | Sensors | Biomedical engineering | Stretchability | Silicone resins | Electronics | Polydimethyl siloxanes | Signal monitoring | Biomedical materials | Stretching | Wearable technology
Journal Article
Advanced Materials, ISSN 0935-9648, 06/2016, Volume 28, Issue 22, pp. 4184 - 4202
Graphene provides outstanding properties that can be integrated into various flexible and stretchable electronic devices in a conventional, scalable fashion....
sensors | graphene | energy‐harvesting | wearable electronics | electronic devices | energy-harvesting | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | OXIDE | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | STRAIN SENSORS | LOW-TEMPERATURE | CHEMISTRY, MULTIDISCIPLINARY | FIELD-EFFECT TRANSISTORS | HYBRID STRUCTURE | PRESSURE SENSOR | GROWTH | THIN-FILM TRANSISTORS | HIGH-MOBILITY | TRANSPARENT | Graphene | Graphite | Electronic devices | Production methods | Optical properties | Electronics | Sensors | Devices | Energy harvesting
sensors | graphene | energy‐harvesting | wearable electronics | electronic devices | energy-harvesting | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | OXIDE | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | STRAIN SENSORS | LOW-TEMPERATURE | CHEMISTRY, MULTIDISCIPLINARY | FIELD-EFFECT TRANSISTORS | HYBRID STRUCTURE | PRESSURE SENSOR | GROWTH | THIN-FILM TRANSISTORS | HIGH-MOBILITY | TRANSPARENT | Graphene | Graphite | Electronic devices | Production methods | Optical properties | Electronics | Sensors | Devices | Energy harvesting
Journal Article
Advanced Materials, ISSN 0935-9648, 05/2018, Volume 30, Issue 18, pp. 1870128 - n/a
In article number 1705925, Lei Liu, Y. Norman Zhou, and co‐workers demonstrate a highly efficient moisture‐driven electrical generator based on the diffusive...
fluidic electricity | moisture | self‐powered sensors | nanogenerators | Electric power production | Three dimensional flow | Moisture | Electric generators | Electronics | Organic light emitting diodes | Breathing | Nanowires | Wearable technology | Man machine interaction
fluidic electricity | moisture | self‐powered sensors | nanogenerators | Electric power production | Three dimensional flow | Moisture | Electric generators | Electronics | Organic light emitting diodes | Breathing | Nanowires | Wearable technology | Man machine interaction
Journal Article
Advanced Materials, ISSN 0935-9648, 06/2016, Volume 28, Issue 22, pp. 4283 - 4305
Flexible nanogenerators that efficiently convert mechanical energy into electrical energy have been extensively studied because of their great potential for...
triboelectric nanogenerators | energy harvesting | flexible electronics | piezoelectric nanogenerators | self‐powered systems | self-powered systems | LARGE-AREA | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | WATER-WAVE ENERGY | PRESSURE SENSORS | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | HYBRID NANOGENERATOR | MECHANICAL ENERGY | CHEMISTRY, MULTIDISCIPLINARY | PERFORMANCE TRIBOELECTRIC NANOGENERATOR | WEARABLE ELECTRONICS | PIEZOELECTRIC NANOGENERATOR | ZNO NANOWIRE ARRAYS | BIOMECHANICAL ENERGY | Power electronics | Electric generators | Electric power production | Electric power generation | Piezoelectricity | Electronics | Direct power generation | Sensors | Energy harvesting | Nanotechnology | Lead zirconate titanates
triboelectric nanogenerators | energy harvesting | flexible electronics | piezoelectric nanogenerators | self‐powered systems | self-powered systems | LARGE-AREA | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | WATER-WAVE ENERGY | PRESSURE SENSORS | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | HYBRID NANOGENERATOR | MECHANICAL ENERGY | CHEMISTRY, MULTIDISCIPLINARY | PERFORMANCE TRIBOELECTRIC NANOGENERATOR | WEARABLE ELECTRONICS | PIEZOELECTRIC NANOGENERATOR | ZNO NANOWIRE ARRAYS | BIOMECHANICAL ENERGY | Power electronics | Electric generators | Electric power production | Electric power generation | Piezoelectricity | Electronics | Direct power generation | Sensors | Energy harvesting | Nanotechnology | Lead zirconate titanates
Journal Article
ACS Nano, ISSN 1936-0851, 08/2017, Volume 11, Issue 8, pp. 7634 - 7641
Tattoo-like epidermal sensors are an emerging class of truly wearable electronics, owing to their thinness and softness. While most of them are based on thin...
epidermal electronics | electronic tattoo | biosensor | graphene | wearable electronics | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | SKIN | CHEMISTRY, MULTIDISCIPLINARY
epidermal electronics | electronic tattoo | biosensor | graphene | wearable electronics | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | SKIN | CHEMISTRY, MULTIDISCIPLINARY
Journal Article
Nature Biotechnology, ISSN 1087-0156, 2014, Volume 32, Issue 7, pp. 642 - 643
Son et al. describe a new class of integrated electronic sensors and memory elements packaged in fabric-like material that can record mechanical strains when...
BIOTECHNOLOGY & APPLIED MICROBIOLOGY | Female | Male | Monitoring, Physiologic | Movement Disorders | Humans | Biomechanics | Wearable computers | Biotechnology
BIOTECHNOLOGY & APPLIED MICROBIOLOGY | Female | Male | Monitoring, Physiologic | Movement Disorders | Humans | Biomechanics | Wearable computers | Biotechnology
Journal Article
Small, ISSN 1613-6810, 08/2019, Volume 15, Issue 32, pp. 1970169 - n/a
The dawn of the age of wearable electronics: buckling structures, which are widely used in nature, provide the required deformability of wearable electronic...
buckles | geometrical engineering | fabrication | stretchable electronics | wearable electronics | Deformation wear | Electronic devices | Electronics | Formability | Clothing industry | Buckling | Wearable technology | Man machine interaction
buckles | geometrical engineering | fabrication | stretchable electronics | wearable electronics | Deformation wear | Electronic devices | Electronics | Formability | Clothing industry | Buckling | Wearable technology | Man machine interaction
Journal Article
14.
Full Text
Conductive Fiber‐Based Ultrasensitive Textile Pressure Sensor for Wearable Electronics
Advanced Materials, ISSN 0935-9648, 04/2015, Volume 27, Issue 15, pp. 2433 - 2439
A flexible and sensitive textile‐based pressure sensor is developed using highly conductive fibers coated with dielectric rubber materials. The pressure sensor...
conductive fiber | metal nanoparticles | electronic textiles | capacitive pressure sensor | wearable electronics | Metal nanoparticles | Electronic textiles | Capacitive pressure sensor | Wearable electronics | Conductive fiber | GOLD | PHYSICS, CONDENSED MATTER | DESIGN | PHYSICS, APPLIED | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | STRAIN SENSORS | YARNS | CHEMISTRY, MULTIDISCIPLINARY | FORCE SENSOR | PLATFORM | FABRICATION | SKIN | Time Factors | Clothing | Electrical Equipment and Supplies | Humans | Electric Conductivity | Rubber | Pressure | Textiles | Pressure sensors | Stability | Gloves | Electronics | Weaving | Dielectrics | Man machine interfaces
conductive fiber | metal nanoparticles | electronic textiles | capacitive pressure sensor | wearable electronics | Metal nanoparticles | Electronic textiles | Capacitive pressure sensor | Wearable electronics | Conductive fiber | GOLD | PHYSICS, CONDENSED MATTER | DESIGN | PHYSICS, APPLIED | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | STRAIN SENSORS | YARNS | CHEMISTRY, MULTIDISCIPLINARY | FORCE SENSOR | PLATFORM | FABRICATION | SKIN | Time Factors | Clothing | Electrical Equipment and Supplies | Humans | Electric Conductivity | Rubber | Pressure | Textiles | Pressure sensors | Stability | Gloves | Electronics | Weaving | Dielectrics | Man machine interfaces
Journal Article
Accounts of Chemical Research, ISSN 0001-4842, 05/2018, Volume 51, Issue 5, pp. 1033 - 1045
Conspectus Future electronics will take on more important roles in people’s lives. They need to allow more intimate contact with human beings to enable...
ATTACHABLE WEARABLE ELECTRONICS | STRETCHABLE ELECTRONICS | THIN-FILM TRANSISTORS | TRANSIENT ELECTRONICS | STRAIN SENSORS | SEMICONDUCTING POLYMER | TRANSPARENT | CHEMISTRY, MULTIDISCIPLINARY | FIELD-EFFECT TRANSISTORS | SILVER NANOPARTICLES | COMPOSITE | Humans | Wearable Electronic Devices | Electronics, Medical - instrumentation | Prostheses and Implants | Polymers - chemistry | Mechanical Phenomena | Biodegradable Plastics - chemistry | Transistors, Electronic | Chemistry
ATTACHABLE WEARABLE ELECTRONICS | STRETCHABLE ELECTRONICS | THIN-FILM TRANSISTORS | TRANSIENT ELECTRONICS | STRAIN SENSORS | SEMICONDUCTING POLYMER | TRANSPARENT | CHEMISTRY, MULTIDISCIPLINARY | FIELD-EFFECT TRANSISTORS | SILVER NANOPARTICLES | COMPOSITE | Humans | Wearable Electronic Devices | Electronics, Medical - instrumentation | Prostheses and Implants | Polymers - chemistry | Mechanical Phenomena | Biodegradable Plastics - chemistry | Transistors, Electronic | Chemistry
Journal Article
Advanced Materials, ISSN 0935-9648, 05/2017, Volume 29, Issue 19, pp. 1604965 - n/a
A fully automated additive manufacturing process that produces all‐printed flexible and stretchable electronics is demonstrated. The printing process combines...
flexible electronics | additive manufacturing | printed electronics | liquid metal | stretchable electronics | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | ANTENNAS | LIQUID-METALS | CHEMISTRY, MULTIDISCIPLINARY | FILMS | SUBSTRATE | FABRICATION | INDIUM | GALLIUM | 3D printing | Pressure sensors | Printing | Circuits | Reproducibility | Elastomers | Electronics | Wearable technology
flexible electronics | additive manufacturing | printed electronics | liquid metal | stretchable electronics | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | ANTENNAS | LIQUID-METALS | CHEMISTRY, MULTIDISCIPLINARY | FILMS | SUBSTRATE | FABRICATION | INDIUM | GALLIUM | 3D printing | Pressure sensors | Printing | Circuits | Reproducibility | Elastomers | Electronics | Wearable technology
Journal Article