RF Energy Harvesting By Y.G.SAI RAGHU(124576) Under the guidance of Dr. P. SREE HARI RAO
RF Energy Harvesting
By Y.G.SAI RAGHU(124576)
Under the guidance ofDr. P. SREE HARI RAO
INDEXIntroductionRequirements of Energy HarvestingSources of Energy HarvestingNeed for the RF based HarvestingOrigin of RF Energy HarvestingChallenges with RF Energy HarvestingArchitecture of RF Energy Harvesting system
Energy HarvestingEH is the process by which energy is derived
from the external sources; captured and stored
Why do we need EH
Sufficient power as/when needed
Adequate life time-no/low maintaince
Easy low cost installation
Flexibility
Sources of EnergyPhotovoltaic solar cells
Vibrations Piezoelectric Capacitive Inductive
Radio-Frequency (RF)
Thermoelectric conversion
Wind/air flow
Pressure variations
Why RF based wireless PowerIndustrial Minimizes Operating Costs Eliminates cost to hard wire or replace batteries – e.g.
wireless sensors. Eliminates service downtime caused by depleted batteries. Reduces battery handling and disposal.End-Users Convenience and Usability Placement flexibility – no charging mats or charging
stations. Transparent charging – no user action required. In some deployments, owing to the sensor location, battery
replacement may be both practically and economically infeasible.
There is an elephant in the room
His name is Battery
There is an elephant in the room
His name is Battery
How are we going to look
after him?
OriginThe Wireless electricity transmission system pioneered by
Dr Nikola Tesla has the potential to meet our future global energy needs
RF Energy is every where
Sources of RF Energy for harvestingFM Radio systems ( 88 – 108 MHz, tens of
KW )TV Transmission ( 180 – 220 MHz, tens of KW )Cell Tower Transmission ( 800 – 1800 MHz, 10 –
20 KW per carrier )Wi-Fi ( 2.45 GHz, 5.8 GHz)AM Transmission ( 540 – 1600 KHz, few hundred
KW)Mobile phones ( 1W to 2W )
Out of which cell towers can be considered as renewable source as they transmit whole 24 hours of the day.
Power Sources Categories
Architecture Of RF Energy Harvesting System
Receive the power from RF Source and rectify the AC voltage in to DC through rectification circuit.
Stepping up of the voltage level of the rectified output through dc – dc converter.
Feeding the stepped voltage to charge a battery through the charging circuit.
Challenges with RF Energy HarvestingAvailable input power to the rectifier is low
and there is no external bias voltage applied. Non-linear dependence of the rectifier
impedance on the frequency and power, broadband impedance matching network is essential for maximum power transfer.
High efficiency of RF-DC conversion and low power DC-DC converter is required.
The rectifier should have minimum power loss to increase the overall efficiency.
Matching circuitThe matching circuit is composed of
inductive and capacitive elements ensure smooth deliver to the load.
A slight change in the matching circuit parameters alters significantly the frequency range in which efficiency of energy conversion is maximum.
Rectification using Schottky diodesRF EH is able to operate even for the low RF
power. As the peak voltage of the a.c signal is very smaller than the diode thershold. These diodes must operate with low thershold and high frequency.
A voltage doubler is designed with silicon based Schottky diode having threshold voltage of 230mV and diode capacitance of .26pF.(HSMS-2852,HSMS-2822).
At microwave frequency, the non-linear capacitance of the diode governs the maximum power transfer to the load and amplitude of the rectified output as input impedance of the rectifier changes with the frequency.
VOLTAGE MULTIPLIERSingle stage voltage doublers is used generally
for doubling the voltage that from the rectifier.Number of voltage multiplier stages can be
increased to have more voltage, but by increasing the number of stages the current will be decreased resulting in the increase of the delay.
single stage voltage doublers
Microstrip antenna designThe main challenge faced in harvesting RF
energy is the free space path loss of transmitted signal with distance.
Pr=PtGrGt(λ⁄4∏R)² Proposed antenna for RF Energy Harvesting
is broadband electromagnetically coupled Square microstrip antenna ( SMSA ).
Effect of Input power
EH circuit consists of diodes, which are non-linear devices, the circuit itself exhibits non-linear.
The impedence of EH circuit varies by the amount of power received from the antenna.
RF EH from the multiple antennasThe use of multiple antenna in addition to the
existing circuits the amount of EH can be increase depending on the number of antennas implimented.
By using this mode does not increase the efficiency of the circuit.
Applications: Bulk Trickle Charging
Freedom of placement
Eliminate wires and connectors
Automatic/transparent charging
Multiple battery types/chemistry
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future for energy harvesting?
System integration
Low power electronics
Biological systems
Falling costs
ConclusionsHarvesters must supply sufficient power from
immediately available energy sources and meet the full operating condition requirements .
Energy Harvesting is now a practical reality with choice of solutions offered by leading global businesses .
While significant progress has been made in many areas including indoor photovoltaic systems, micro-fuel cells, thermoelectrics, micro-heat engines, and vibration-to-electricity conversion, much more research and new approaches need to be pursued.
References1. N. Kumar and G. Kumar, Biological Effects of Cell Tower
Radiation on Human Body, IEEE Conf. ISMOT, pp.1365-1368, Aug. 2012.
2. Z. W. Sim, R. Shuttleworth, and B. Grieve Investigation of PCB Microstrip patch receiving antenna for outdoor RF energy harvesting in wireless sensor networks, IEEE Conf. Antenna and Propagation Conference, Loughborough, pp.129-132, Feb. 2012
3. A.C. Patel, et al, Power Harvesting for Low Power Wireless Sensor Networks. IEEE Conf. Antenna and Propagation Conference, Loughborough, pp.633-636, Nov. 2009
4. V.Rizzoli, et al, CAD Multi-Resonator rectenna for micro power generation. Proc. of 4th European Microwave Conference, pp.1684-168, Sep. 2009.
5. J.A. Hagetry, et al, Recycling Ambient Microwave Energy With Broad- Band Rectenna Arrays. IEEE Trans. Microw. Theory. Tech vol. 52, no 3, pp.1014-1024, Mar. 2004
6. G. Kumar and K. P. Ray Broadband Microstrip Antenna, Artech House, USA 2003.
7. IE3D software from Zealand ,USA