Wireless Power Transfer Systems

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This research focuses on concept of wireless power transfer system in daily uses. The use of power system has been described in the research. Access gained in the radio frequency analysis has been helping in detecting radiation from powering electronic stations. The challenges in the WPT systems have been discussed briefly in the study. A connection between previous studies and current literature have been provided in the study. Expected outcomes of the research have been discussed briefly.

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Running head: Wireless Power Transfer Systems
Wireless Power Transfer Systems
Name of the System
Name of the University
Author’s Note

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Wireless Power Transfer Systems
Table of Contents
Abstract............................................................................................................................................3
Literature Review............................................................................................................................4
Challenges in WPT systems........................................................................................................8
Research Questions..........................................................................................................................9
Significance.....................................................................................................................................9
Connection to current body of knowledge.....................................................................................10
Expected Outcomes.......................................................................................................................11
References......................................................................................................................................12
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Wireless Power Transfer Systems
Abstract
This research focuses on concept of wireless power transfer system in daily uses. The
use of power system has been described in the research. Access gained in the radio frequency
analysis has been helping in detecting radiation from powering electronic stations. The aim of
the research is to analyze the concept and impact of wireless power transfer system in daily uses.
The working of wireless power transfer system have been analyzed in the research. The
challenges in the WPT systems have been discussed briefly in the study. Eliminating power
radiation or wireless charging has not been feasible for enhancement of designing radioactive
magnetic field. A connection between previous studies and current literature have been provided
in the study. Expected outcomes of the research have been discussed briefly.
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Wireless Power Transfer Systems
Literature Review
Wireless Power Transfer has been developed from decades with the beginning of Tesla
claiming for transmitting power wirelessly. However, it is possible to transmit small amount of
power within far field radiation [1]. The power transfer for powering devices including
rechargeable batteries can be explored for efficient charging. Enhancement in the modern
electronics have been used in the warfare. Various hostile environments have been becoming
riskous for operators in order to complete missions. The access gained in the radio frequency
analysis has been helping in detecting radiation from powering electronic stations. Eliminating
power radiation or wireless charging has not been feasible for enhancement of designing
radioactive magnetic field [8]. The Helical Loop in the Moebius connection has been proposed in
order to develop wireless power transfer technology for mitigating power radiation with
cancelling E-fields.
Two loops near field distances can have power transfer capabilities including magnetic
induction. It has been considered in the research that two loops having one turn with transfer of
power originating from a large radius source loop to a small radius receiver loop. The source
loop have a radius of 0.1 meters and receiver loop have 1/10th of the source loop radius [3].
Therefore, both loops have been suspended in free space having no external interactions.
Assuming 1 ampere has been generated from the source, power equations has been utilized for
calculating power transmitted from generator and source loop. The amount of radiated power
loss has been calculated by radiation resistance observed in source combined within receiver and
calculating radiated power. The extra load on the resistor has been calculated in the Ohmic
Resistance of metal of the loops.

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Impedance and Admittance Matrix
The transducer theory has been showing that the voltages of both loops and current of
receiver has been calculated in the basis of realization of impedances Z11, Z22, Z12 and Z21 of
the system. The reciprocal circuit non-diagonal impedance matrix coefficients has been
symmetric.
Z21=Z12
Therefore, two coupled antennas has been modeled in transducer as long gaps in their iput
terminals have been small. Therefore, two loop system will be:
V1= Z11I1 + Z12I2
V2= Z21I1 + Z22I2
Where
V1 is the voltage across the terminals of Loop 1,
V2 is the voltage across the terminals of Loop 2,
I1 is current through Loop 1,
I2 is current through Loop 2,
Z11 is (self) impedance of Loop 1, Z11 = V1/I1 in the absence of loop 2.
Z12 is mutual impedance of Loop 1 to Loop 2. Z12 = V2/I1 the voltage induced in loop 2 due to
current in loop 1.
Z22 is (self) impedance of Loop 2, Z22 = V2/I2 in the absence of loop 1.
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Wireless Power Transfer Systems
Z21 is mutual impedance of Loop 2 to Loop 1, Z21 = V1/I2 the voltage induced in loop 1 due to the
current in Loop 2.
Shown in matrix form
V 1
V 2 = Z 11 Z 12
Z 21 Z 22 * I 1
I 2
Where, given the currents, the total voltages can be calculated. For a given voltage, the inverse of
impedance is the admittance and thus if z is a 2x2 matrix it can be defined as the corresponding
admittance matrix as follows. Let,
Z= a b
c d
Y= (1/(ad-bc)) * d b
c a
Resulting in:
Y = (1/ (Z11Z22 - Z12Z21) * Z 22 Z 12
Z 21 Z 11
Now, let D be the following expression:
D = (Z11Z22 - Z12Z21)
Finally, currents has been expressed as:
I1 = Y11V1 + Y12V2
I2 = Y21V1 + Y22V2
Inductive coupling has been working on the principle of electromagnetism. Transmission
of energy between wires through magnetic fields has been determined as inductive coupling.
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Wireless Power Transfer Systems
Magnetic resonant coupling has been using same principles as inductive coupling [2]. However,
it has been using resonance for increasing range for energy transfer. However, in both type of
resonance, principle of obtaining maximum energy has been same in different methods.
Figure 1: Magnetic coupling with four components fluxes
(Source: [5])
Figure 2: Equivalent circuit of Magnetic Resonant Coupling
(Source: [5])
Quality factor (Q-factor) has been dimensionless parameter which focuses on
characteristics of an oscillator [6]. Higher Q helps in indicating lower rate of energy loss than the
stored energy. However, Q factor help in determining the qualitative behavior of simple
oscillators.

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Wireless Power Transfer Systems
The wireless power transfer technology has been used in electric vehicles. Electric
vehicles have been advanced concept in automobile industry. Then work on misalignment
resilience has had a go at redesigning the current traditional plan, and has made pay topologies to
counterbalance the adjustments in the framework, and keep it as most extreme power exchange
effectiveness Magnetic resounding coupling is considered as potential leap forward in WPT
techniques. It was presented by a gathering of specialists at Massachusetts Institute of
Technology (MIT) in 2007 [16]. The hidden idea is that two resonator circuits tuned at a similar
reverberation recurrence, can encounter control exchange at higher efficiencies, at more
noteworthy separations, when contrasted and ordinary IPT frameworks [19]. The test with MRC
frameworks, in any case, is keeping up the activity at reverberation. At point when the separation
between transmitter and beneficiary changes, for instance, or misalignment is presented, made
impedance jumble radically diminishes power exchange effectiveness.
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Wireless Power Transfer Systems
Figure 3: Wireless Charging of electric cars
(Source: [19])
Challenges in WPT systems
Foreign and Live Objects (FO/LO)
Transferring power through air by means of attractive motions comes at risk of
electromagnetic field being consumed by adjacent remote (metallic) questions. Not just does this
outcome in misfortunes by requiring essential for transmitting more elevated amounts of
influence, however hazard these situations can present in extensive warming of meddling bodies
[13]. Indeed, even frameworks of intensity transmission of as low as 5W can warm questions
levels unaccepted by ISO security standard levels [20].
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Misalignment
Appropriate exchange of capacity to an accepting curl requires for that loop not
exclusively to be in closeness to the transmitter loop, yet additionally in legitimate arrangement
with it, taking into consideration the attractive transitions to be grabbed [7]. Misalignment is a
noteworthy issue in WPT [14], and presents significant misfortunes to framework. A proportion
of adequacy of coupling between loops is shared inductance between them, indicated M. Area 2-
4 expounds on power exchange outcomes of ineffectively adjusted loops, demonstrating that the
power exchange is corresponding to M2. To delineate this impact, it demonstrates impact of
misalignment on common inductance between two indistinguishable square-formed curls. A
misalignment of half of edge of curl in beneath figure demonstrates a 44% drop in estimation of
shared inductance from its crest esteem, which means very nearly 70% drop in power exchanged.
Interoperability
WPT frameworks are under investigation, and approaches for upgrade execution is
warmed explore point. One way, streamlining is geometry of loops, as specific shapes could
offer likelihood of resistance for misalignment [11]. Round curls, for instance, offer the best
coupling contrasted with different shapes at ideal arrangement point. This is reason they have a
superior territory to-edge proportion, they can "gather" a greater amount of attractive transition
from essential. At beginning of misalignment, in any case, they have a poorer conduct in
common inductance. The air gap is of 10 mm.
Research Questions
Following will be the research questions used in the research?
1. Can we reduce radiation and preserve coupling of standard version of current?

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2. Can misalignment be a major issue for wireless power transfer system?
3. Can wireless power transfer system be used in electric vehicles for battery recharging?
Significance
The three issues discussed about above can be drawn closer by a solitary arrangement.
This proposition proposes the plan of a measured essential comprising of associated curl
modules which can be worked [9]. The thought is that turning on just loops in palatable
arrangement with optional, and which have not impeded by outside objects, can give sheltered
and effective power exchange. This would offer adaptability in providing food for various
auxiliary curl geometries. The favorable position, but the test with this framework, is that it can
work with various quantities of curls. This implies the aggregate inductance estimation of the
essential can be unique, contingent upon the working loops [8]. To consistently work at the
outlined recurrence of reverberation, be that as it may, capacitance of the framework needs to
track inductance of working loops. A controlled capacitor bank should be outlined.
Connection to current body of knowledge
The enthusiasm for remote power exchange, as said prior, has developed for the most part
in the ongoing decades. The enthusiasm for misalignment resilience and FO/LO identification
has gotten its flood all the more as of late, inside the most recent decade. Up until this point, past
work in remote and live protest location in has been for the most part centered around
identification instead of relief or avoidance [10]. Then work on misalignment resilience has had
a go at redesigning the current traditional plan, and has made pay topologies to counterbalance
the adjustments in the framework, and keep it as most extreme power exchange effectiveness
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Wireless Power Transfer Systems
[17]. However, respecting these kind of topologies into a FO/LO situation could thus raise the
warming issues.
Figure 4: Wireless Power Transfer System Concept
(Source: [5])
The secluded plan of this proposal, however as outline and control-serious as the past
strategies, offers the benefit of providing food for two issues, instead of fathoming one and
exacerbating other. Past researches in writing have researched measured outline approach [6].
The distinction between two outlines is that the past plan couples one converter and capacitor to
each sub-curl, though this proposal drives the entire framework with single source, and utilizing
one arrangement capacitor framework. Above all, this methodology in this proposal more
healthy, and adaptable and appropriate to press centers, if those non-straight models had been
created here [3].
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Expected Outcomes
In diagnostic displaying, the separating of the essential inductor has demonstrated a
superior reaction to misalignment when contrasted with the customary outline. The square
measured loop geometry at last recommended in this proposal falls in accordance with past
works in writing. Multi-turn curls are not been contemplated. The additional resistive
misfortunes, there is more grounded attractive field created that converts into more grounded
coupling. The more grounded field in its turn implies a more grounded field aversion between
loops also, making more serious no man's lands. The exchange offs included in this have the
right to be concentrated to evaluate net result of multi-turn loops in outline of measured essential.
Press cored loops merit consideration too, as they offer better attractive conduct in coupling.
Their investigation has been expelled in this postulation because of their complex, non-straight
conduct. The introduced expository models are verified. Additionally ponders are required
around there to check the models, ideally in a trial setup. The aggregate inductance for a
gathering of curls, for the loop measurements picked for this situation consider, are effectively
confirmed. The self-inductance and the common inductance between two adjusted,
indistinguishable loops is demonstrated tentatively and utilizing FEM reenactments. At long last,
contrasting the measured essential with its ordinary partner, more material is utilized, prompting
higher resistive misfortunes.

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References
[1] K. Obrien, G. Scheible, and H. Gueldner, “Analysis of wireless power supplies for
industrial automation systems,”,IECON03. 29th Annual Conference of the IEEE
Industrial Electronics Society (IEEE Cat. No.03CH37468),2003
[2] G. Wang, W. Liu, R. Bashirullah, M. Sivaprakasam, G. Kendir, Y. Ji, M. Humayun, and
J. Weiland, “A closed loop transcutaneous power transfer system for implantable devices
with enhanced stability,” IEEE International Symposium on Circuits and Systems (IEEE
Cat. No.04CH37512),2004.
[3] Transfer via Strongly Coupled Magnetic Resonances", Science, vol. 317, no. 5834, pp.
83-86, 2007. djemouai, a.,& sawan,circuit techniques for effective wireless transfer of
power and data to electronic implants. Journal Of Circuits, Systems And Computers,
16(05), 801-818. doi: 10.1142/s0218126607003903,2007
[4] K. Song, Z. Li, J. Jiang, and C. Zhu, “Constant Current/Voltage Charging Operation for
Series-Series and Series-Parallel Compensated Wireless Power Transfer Systems
Employing Primary-Side Controller,” IEEE Transactions on Power Electronics, pp. 1–1,
2017
[5] Z. Rong, M. S. Leeson, M. D. Higgins, and Y. Lu, “Nano-rectenna powered body-centric
nano networks in the terahertz band,” Healthcare Technology Letters, vol. 5, no. 4, pp.
113–117, Jan. 2018
[6] S. Zhong and X. Wang, “Energy Allocation and Utilization for Wirelessly Powered IoT
Networks,” IEEE Internet of Things Journal, vol. 5, no. 4, pp. 2781–2792, 2018
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[7] S. Li and C. C. Mi, “Wireless Power Transfer for Electric Vehicle Applications,” IEEE
Journal of Emerging and Selected Topics in Power Electronics, vol. 3, no. 1, pp. 4–17,
2015
[8] J. Jiang, K. Song, Z. Li, C. Zhu, and Q. Zhang, “System Modeling and Switching Control
Strategy of Wireless Power Transfer System,” IEEE Journal of Emerging and Selected
Topics in Power Electronics, vol. 6, no. 3, pp. 1295–1305, 2018
[9] R. Tavakoli and Z. Pantic, “Analysis, Design, and Demonstration of a 25-kW Dynamic
Wireless Charging System for Roadway Electric Vehicles,” IEEE Journal of Emerging
and Selected Topics in Power Electronics, vol. 6, no. 3, pp. 1378–1393, 2018
[10] Y. Li, K. Song, Z. Li, J. Jiang, and C. Zhu, “Optimal Efficiency Tracking Control
Scheme Based on Power Stabilization for a Wireless Power Transfer System with
Multiple Receivers,” Energies, vol. 11, no. 5, p. 1232, Dec. 2018
[11] Kurs, A. Karalis, R. Moffatt, J. D. Joannopoulos, P. Fisher, and M. Soljacic,
“Wireless Power Transfer via Strongly Coupled Magnetic Resonances,” Science, vol.
317, no. 5834, pp. 83–86, 2007
A. P. Sample, D. A. Meyer, and J. R. Smith, “Analysis, Experimental Results, and
Range
[12] Adaptation of Magnetically Coupled Resonators for Wireless Power Transfer,”
IEEE Transactions on Industrial Electronics, vol. 58, no. 2, pp. 544–554, 2011
[13] X. Zhou, R. Zhang, and C. K. Ho, “Wireless Information and Power Transfer:
Architecture Design and Rate-Energy Tradeoff,” IEEE Transactions on Communications,
vol. 61, no. 11, pp. 4754–4767, 2013.
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[14] Song, Kai, Zhenjie Li, Jinhai Jiang, and Chunbo Zhu. "Constant Current/Voltage
Charging Operation for Series–Series and Series–Parallel Compensated Wireless Power
Transfer Systems Employing Primary-Side Controller." IEEE Transactions on Power
Electronics 33, no. 9 (2018): 8065-8080.
[15] Assawaworrarit, Sid, Xiaofang Yu, and Shanhui Fan. "Robust wireless power
transfer using a nonlinear parity–time-symmetric circuit." Nature 546, no. 7658 (2017):
387.
[16] Huang, Kaibin, and Vincent KN Lau. "Enabling wireless power transfer in
cellular networks: Architecture, modeling and deployment." IEEE Transactions on
Wireless Communications 13, no. 2 (2014): 902-912.
[17] Hui, Shu Yuen Ron, Wenxing Zhong, and Chi Kwan Lee. "A critical review of
recent progress in mid-range wireless power transfer." IEEE Transactions on Power
Electronics 29, no. 9 (2014): 4500-4511.
[18] Li, Siqi, Weihan Li, Junjun Deng, Trong Duy Nguyen, and Chunting Chris Mi.
"A double-sided LCC compensation network and its tuning method for wireless power
transfer." IEEE Transactions on Vehicular Technology 64, no. 6 (2015): 2261-2273.
[19] Zhao, Nan, F. Richard Yu, and Victor CM Leung. "Opportunistic
communications in interference alignment networks with wireless power transfer." IEEE
Wireless Communications 22, no. 1 (2015): 88-95.
[20] Dai, Jiejian, and Daniel C. Ludois. "A survey of wireless power transfer and a
critical comparison of inductive and capacitive coupling for small gap applications."
IEEE Trans. Power Electron 30, no. 11 (2015): 6017-6029.
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