Electronic skin is a material that mimics human skin and can measure vital signs like heart rate and brain waves. It is made of flexible silicon sensors laminated onto skin like a temporary tattoo. The sensors form a spider web-like circuit that detects pressure, temperature and other bodily functions and transmits the signals to monitoring devices. Electronic skin has applications in healthcare for wound monitoring and in robotics for making machines more human-like. While promising, challenges remain in reducing the cost and enabling reuse of electronic skin technologies.

1. Presented by Muhammad Azim

2.  Introduction
 Electronic skin
 Idea
 Development of e-skin
 Working
 Application
 Advantage
 Disadvantage
 Uses
 Conclusion

3.  Electronic plays a very important role in developing
simple devices used for any purpose.
 Material which mimics the Human Skin in one or
more ways
 The best achievement as well the future example of
integrated electronics in the medical field is the
electronic skin.

4.  It made from biocompatible silicon rubber with
pressure sensitive sensors.
 It can measure electrical activity of the heart, brain
waves and other vital signs.
 Ultra thin skin turn on hand
 e-skin can be directly laminated on the surface of the
skin, allowing us to electronically functionalize human
skin.
 It attaches to the skin like a stick-on tattoo.

5.  It borrowed directly kids temporary transfer tattoos.
 It attaches through the weak forces of van de wals
interactions.
 Circuitry “spider web” of materials
 Narrow snake like silicon filaments that serve as wires
connected to tiny the sensors designed to monitor
particular bodily functions.

8.  2010:
a) attaching nanowire transistor to sticky substrate,
embedded in thin pressure sensitive rubber capable
of sensing wide range of pressure (california
university)
b) First prototype for e-skin
 2011:
a) a) stretchable solar cell used to power the electronic
skin (stanford).
 2012:
a) self healing capacity
b) Made by nickel and plastic

9.  Antenna is used to transmit the recorded
electrical signals of skin to the receiver.
 Strain gauges are used for measuring the
signals generated by the heart.
 Temperature sensors are used for measuring
the temperature.

10.  It takes the signals from the body and transfer
them to the device.
 Localized electrical stimulation: “smart bandage”:
temperature changes across the wound.
 Muscle contractions in the neck can control the
mouse in computer game.

13.  Stretchable sensor system able to measure pressure.
 Strain composed of buckled CNT-based electrodes.
 The right-most pane depicts the pressure distribution
measured by pressing on the center pixel.
 Recent devices have already surpassed the capabilities
of biological skin in terms of sensitivity, spatial
resolution, and stretchability.

14.  COST IS VERY HIGH
 SINGLE USE

15.  ROBOTICS
 HEALTH APPLICATION
 SMART WALLPAPERS
 E-PAPERS

16.  In future even virtual screens may be placed on the
device for knowing our body function.
 It has bright future in robotics industries to make it
sensible also.

17.  The electronics skin is one such device that
depicts the beauty of electronics and its uses
in daily life.
 The electronic devices gain more demand in
the market when they are in compact in size
and best in functioning.