Today’s high-end wearables can support an impressive array of sensors to record, for example, the wearer’s V02 max, blood oxygen saturation (Sp02), temperature, heart rate, and heart rate variability (HRV), as well as the sleep and activity data their early predecessors pioneered.
Today’s high-end wearables can support an impressive array of sensors to record, for example, the wearer’s V02 max, blood oxygen saturation (Sp02), temperature, heart rate, and heart rate variability (HRV), as well as the sleep and activity data their early predecessors pioneered.
Transitioning from Lab-scale in Printed Electronics: Going from lab and pilot equipment to rotary screen printing. Learn about example applications in printed low-power displays for use in retail as well as cost-per unit calculation comparing flat-bed vs. rotary screen printing for mass production
R2R Sputtering + Direct Laser Patterning is a great way to create large-area circuits on flexible circuits, even with materials such as graphene or MoS2. The technology R2R produces high-quality uniform films on large substrates whilst the laser forms precision circuit patterns without photolith.
Learn how edge AI in wireless vibration sensors improves machine health monitoring, extends battery life, and enables smarter predictive maintenance in factories.
Today’s high-end wearables can support an impressive array of sensors to record, for example, the wearer’s V02 max, blood oxygen saturation (Sp02), temperature, heart rate, and heart rate variability (HRV), as well as the sleep and activity data their early predecessors pioneered.
Transitioning from Lab-scale in Printed Electronics: Going from lab and pilot equipment to rotary screen printing. Learn about example applications in printed low-power displays for use in retail as well as cost-per unit calculation comparing flat-bed vs. rotary screen printing for mass production
R2R Sputtering + Direct Laser Patterning is a great way to create large-area circuits on flexible circuits, even with materials such as graphene or MoS2. The technology R2R produces high-quality uniform films on large substrates whilst the laser forms precision circuit patterns without photolith.
Globally recognized event, on 17-18 October 2023, seeks to explore the forefront of electronic innovations, drawing a bridge between the traditional and the groundbreaking, and taking you on a journey through the very fabric of next-gen electronics.
Fine-pitch dense die assembly process with only a single adhesive application without pressure, without underfill, without fine patterning, without complex alignment vs solder ball-to-solder pad, etc? Learn here how magnetically aligned Anisotropic Conductive Epoxy (ACE) enable this
Textiles are tactile, sensorial and visual. Qualities can be modified or even expanded when technology is added, transforming passive textiles into active and interactive devices, monitoring and detecting bodily functions due to their constant contact with our skin.
Embroidery was historically a means of adorning fabrics with intricate patterns,a testament to human skill.In the modern era, this ancient art form has significantly evolved, becoming a pioneering tech at the intersection of artistry & functionality. Learn here about Embroidered Electronics Textiles
Cavitation dispersion process improves the properties of materials used in additive manufacturing of circuits. You will learn how one can control hydrodynamic cavitation to produce unique dispersions, formulated inks & pastes, high aspect ratio nanoparticle & ‘2D’ filler particle masterbatches.
The key enabler for reliable device fabrication in printed electronics is functional inks with tunable electrical properties incl. conductivity, dielectric strength & electrical resistance. Here, you will learn about unique polyimide based pastes able to withstand temperatures up to 300°C.
Status and evolution of intelligent skin patches, enabled by flexible hybrid electronics, going from a single wired sensors to complex wireless multi-function capability. Learn about trends, archirectures and challenges from a manufacturer's point of view to understand how to design for production.
In this episode, we discuss the breakthrough research by MIT engineers to effectively deliver drugs through the skin allowing for a lower dosage of active ingredients needed per use and a potentially pill-free implementation of commonly used drugs!
While humans can tell each other what they need, it’s not quite so simple for a cat or a dog armed only with a meow or a bark. To better help owners understand their pets’ needs, technology is coming to the rescue. The wearables that have been used to keep tabs on human health and fitness are now being adapted for animals.
Healthcare is undergoing a transformative shift with the rise of stick-to-skin wearable monitoring devices. These data-collecting marvels, such as continuous glucose or cardiac monitoring devices, offer convenience & real-time insights.This article explores capabilities, applications & market trends
In wearables, the design on paper often does not work in practice. In this world, your idea may only go as far as your chosen contract manufacturer can take you. It is the key role of the contract manufacturers to help you make the vital adjustment to make your product a success.