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Wireless Power Transfer Using Metamaterial

Bonded Microstrip Antenna for

Smart Grid WSN

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Outline

• Background

• Microwave Power Transmission

• System Model

• Metamaterials

• Metamaterials used in Microwave Power Transmission

• Conclusion

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Background

Nikola Tesla

Innovations:

• Alternating current

• Wireless power transmission experiments at Wardenclyffe.

• In 1899 he was able to light lamps over 25 miles away without

using wires.

• High frequency current, of a Tesla coil, could light lamps filled

with gas (like neon).

(1856-1943)

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Block Diagram For WPT

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Single Element M.R.P.A.

Design of a Patch Antenna

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Cavity Model For Patch Antenna

A radiating patch is fabricated on a dielectric

substrate at a small fraction away from ground

plane.

It is feeded by microstrip line feed technique.

The region between ground plane and microstip

patch, bounded by electric conductors is a resonance

cavity

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Radiation and Polar Plot

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Gain 7.14 dB

Radiation Efficiency -0.8591 dB

Total Efficiency -1.196 dB

3-D Radiation Plot Polar Plot

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4 x Element Array

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4 element Array of Patch antenna

• Increase the overall gain

• Provide diversity reception

• Cancel out interference from a particular set of directions

• The Array Factor is a function of the positions of the antennas

in the array and the weights used

• Total radiation

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Radiation and Polar Plot

3-D Radiation Plot Polar Plot

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Gain 11.9 dB

Radiation Efficiency -1.4032 dB

Total Efficiency -1.926 dB

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Metamaterial

• Metamaterials are a new class of ordered composites that exhibit exceptional properties not readily

observed in nature.

• A periodic material that derives its properties from its structure rather than its components

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D.R. Smith - “Any material composed of a periodic microscopic structures so as to achieve desired electromagnetic

response can be referred as a metamaterial”.

Metamaterial unit cell Metamaterial structure

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History

• A. Schuster, An Introduction to the Theory of Optics 1904.

• L.I. Mandelshtam, May 5 1944 “In fact, the direction of wave propagation

is determined by its phase velocity, while energy is transported at the

group velocity.”

• A German scientist Victor Veselago in 1967 by his article “The

electrodynamics of substances with simultaneous negative values of ε

and μ”, was able to predict that :

Metamaterials act in exact opposite manner than natural

materials (like negative refractive index).

Waves behavior in negative refractive material.

• Dr. John Pendry showed practical method of making metamaterials in

1999 .

Describes a perfect lens that can focus all four Fourier

components.

• David R. Smith demonstrated experimentally metamaterial in his article

"Experimental verification of a negative index of refraction“.

The first person to create a functioning cloak of invisibility that

renders an object invisible in microwave wavelengths

V. G. Veselago

Sir John Pendry

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Properties of Metamaterials

Unique Properties Of Metamaterials

• Refractive Index is negative

• Opposes Snell’s law

• Opposes Doppler's Effect

• Positive Impedance

• Cherenkov radiation points the other way

rrn

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Due to their unique properties they are propagating in left hand side, they are often called as Left handed

material

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Classification of Material and

Achieving N.R.I.

Classification Of Materials Found In Nature

Achieving Negative Refractive Index (N.R.I.)

• By Using Material Having Negative Permittivity.

They are often found in nature in some metals and

semiconductor..

Do not give positive impedance

• By using material having negative Permeability.

They are rarely exist in nature and that to for very low

frequency

Do not give positive impedance

• By using material having both permittivity and

permeability negative.

They are not found in nature.

They are the combination of above two materials

Posses positive impedance

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Behavior of Waves With

Metamaterials

• Maxwell equations describe all electromagnetic phenomena.

• Metamterial (Negative refractive index) changes the Maxwell’s equations which inter changes the direction of

propagation of waves.

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Normal material Metamaterial

Pointing vector represent the direction of

propagation of waves .

Pointing vector

Comparison Of Maxwell’s Equation

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Metamaterial as Lens

• Lens tries to focus the field by applying phase correction to each Fourier

component but it did not provide amplitude amplification.

• Pendry’s proved by his articles that when an evanescent wave is passed

through a matameterial it provides:

Phase correction

Amplitude amplification

• Multiple refraction will focus the beam and reflection is zero when there

is no mismatch loss

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Multiple Refraction Through A Lens Metamaterial Lens

Wave propagation through metamaterial

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Antenna Incorporated with Metamaterial

M.R.P.A single Element 4 Element M.R.P.A array

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• Array of metamaterial structure that we have proposed had placed above the M.R.P.A. array at a

certain height from ground plane.

• Distance Between antenna and metamaterial lens is based on Impedance matching.

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Comparison of Patch Antenna Result

Without and With Metamaterial

Without metamaterial lens With metamaterial lens

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S-parameters for Patch Antenna

Without and With Lens

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Gain 7.33 dB 8.22 dB

Radiation Efficiency -0.694 dB -0.045 dB

Total Efficiency -1.025 dB -0.662 dB

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Comparison of Antenna Array Result

Without and With Metamaterial

Without metamaterial lens With metamaterial lens

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S-parameters for Antenna Array Without

And With Lens

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Gain 14.05 dBi

Directivity 14.47dBi

Radiation Efficiency --0.2242 dBi

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Free Space Transmission

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• The received power is for linear values of

transmitting antenna gain and it can be seen that Pr

is increasing with increasing value of Gt.

• The receiver antenna will extract the microwave

power and provide to a schottky diode for its

conversion to dc.

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Conclusion

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• Wireless power can be transmitted to an increased range by using metamaterial with

antenna

• Use of metamaterial will improve the antenna performance.

• No altercation is required in antenna structure for achieving better or desired

performance.

• Metamaterial used with antenna can also help in avoiding interference

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Vikaram SinghAntenna and Microwave Group

Intelligent Communication Lab (INTELCOM)Mumbai, India

E vikram.singh@intelcomlab.com M +91 9767371987