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i
OPTIMUM DESIGN OF RECTIFYING CIRCUIT OF RF ENERGY TRANSFER
RAHMIYENI BINTI ASWIR
This Report Is Submitted In Partial Fulfillment of Requirement of the Bachelor Degree of Electronic Engineering (Electronic Industry) With Honors
Faculty of Electronic and Computer Engineering
Universiti Teknikal Malaysia, Melaka.
June 2016
ii
UNIVERSTI TEKNIKAL MALAYSIA MELAKA
FAKULTI KEJURUTERAAN ELEKTRONIK DAN KEJURUTERAAN KOMPUTER
BORANG PENGESAHAN STATUS LAPORAN
PROJEK SARJANA MUDA II
Tajuk Projek
: OPTIMUM DESIGN OF RECTIFYING CIRCUIT OF RF ENERGY TRANSFER
Sesi Pengajian
: 1 5 / 1 6
Saya RAHMIYENI BINTI ASWIR
mengaku membenarkan Laporan Projek Sarjana Muda ini disimpan di Perpustakaan dengan syarat-syarat kegunaan seperti berikut:
1. Laporan adalah hakmilik Universiti Teknikal Malaysia Melaka. 2. Perpustakaan dibenarkan membuat salinan untuk tujuan pengajian sahaja. 3. Perpustakaan dibenarkan membuat salinan laporan ini sebagai bahan pertukaran antara institusi
pengajian tinggi. 4. Sila tandakan ( √ )
SULIT*
*(Mengandungi maklumat yang berdarjah keselamatan atau kepentingan Malaysia seperti yang termaktub di dalam AKTA RAHSIA RASMI 1972)
TERHAD**
**(Mengandungi maklumat terhad yang telah ditentukan oleh organisasi/badan di mana penyelidikan dijalankan)
TIDAK TERHAD
Disahkan oleh:
__ ________________________ ___________________________________
(TANDATANGAN PENULIS) (COP DAN TANDATANGAN PENYELIA)
Tarikh: ……………………….. Tarikh: ………………………..
iii
“I hereby declare that the work in this project is my own except for summaries and quotations which have been duly acknowledge.”
Signature : .......................................................
Author : Rahmiyeni binti Aswir
Date : .......................................................
iv
“I acknowledge that I have read this report and in my opinion this report is sufficient in term of scope and quality for the award of Bachelor of Electronic Engineering (Industrial Electronics/ Computer Engineering/ Electronic Telecommunication/ Wireless Communication)* with Honours.”
Signature : .......................................................
Supervisor’s Name : Assoc. Professor Dr. Zahriladha bin Zakaria
Date : .......................................................
v
By The Name of Allah the Most Gracious, Most Merciful
vi
ACKNOWLEDGMENT
I would like to express my deep gratitude and sincere appreciation to my
supervisor Assoc. Professor Dr. Zahriladha bin Zakaria for encouragement and
valuable guidance and critic towards this project. I am also indebted to Universiti
Teknikal Malaysia Melaka (UTeM) in completing my project with all laboratory
facilities.
In completing this thesis, I had worked with many academicians, senior,
friends, and laboratory technician. They have helped me towards my understanding,
thoughts and support. Special thanks to my parents and family with their continuous
inspiration and love. Last but not least, many thanks to my panels for the projects
presentation that has improved my presentation skills by their comments and tips.
Finally, I would like to thank who have helped and inspired me for this project
and during my degree study.
vii
ABSTRACT
Radio Frequency Energy Transfer is a research area of on demand technology,
related to sustainability which could turn into a promising alternative to existing
energy resources. Energy harvesting offer a potential solution to the barrier faced by
Wireless sensor networks (WSNs) in order to supply power without the need of wiring
and also replacement of battery. One of the crucial parts in RF Energy Harvesting is
rectifying circuit that converts the RF signal to DC signal. In this project an optimum
rectifying circuit is designed, simulated by using the Advance Design System (ADS)
2011 software then fabricated and measured in the laboratory. Frequency 2.4GHz are
proposed for this project. This rectifying circuit consists of a single stub matching
network, voltage doubler and dc to dc converter at the output port of rectifier. The
simulation result of rectifying circuit is 6.7V while in the measurement the output
result is 6.2V at input signal 20 dBm. When connect with dc to dc converter the output
voltage boost to 10.5V at 20 dBm power input.
viii
ABSTRAK
Penuai tenaga radio frekuensi adalah bidang penyelidikan mengenai teknologi
permintaan, yang berkaitan dengan kelestarian tenaga dimana ia menjanjikan
alternatif bagi menggantikan sumber-sumber yang sedia ada. Penuai tenaga
menyediakan penyelesaian berpotensi bagi masalah yang dihadapi oleh rangkaian
sensor tanpa wayar (WSNs) bagi membekalkan kuasa tanpa memerlukan pendawaian
dan atau bagi menggantikan bateri. Salah satu bahagian yang terpenting dalam
penuai tenaga RF adalah litar penerus yang menukarkan isyarat RF kepada isyarat
DC. Dalam projek ini, optimum litar penerus telah direka, disimulasi, dibina dan
diukur dengan menggunakan perisian Advance Design System (ADS) 2011. Frekuensi
2.4GHz telah dicadangkan untuk projek ini. Litar penerus ini terdiri daripada “single
stub matching network”, litar voltan pengganda dan pengubah dc ke dc. Hasil
simulasi litar penerus adalah 6.7V manakala bagi hasil ukuran ialah 6.2V pada
isyarat masukan 20dBM dan apabila litar penerus disambung bersama pengubah dc
ke dc keluaran dihasilkan semakin meningkat kepada 10.5V.
ix
TABLE OF CONTENTS
CHAPTER TITLE
PAGE
PROJECT TITLE i
REPORT VERIFICATION STATUS FORM ii
DECLARATION iii
SUPERVISOR DECLARATION iv
DEDICATIONS v
ACKNOWLEDGEMENTS vi
ABSTRACT vii
ABSTRAK
viii
TABLE OF CONTENTS ix
LIST OF TABLES xii
LIST OF FIGURES
xiii
LIST OF ABBREVIATIONS xv
LIST OF APPENDICES
xvi
1 INTRODUCTION 1
1.1 Research Background 1
1.2 Problem Statement 4
1.3 Objective 5
1.4 Scope of Project 5
1.5 Project Planning 6
1.6 Outline of the Project 7
x
2 LITERATURE REVIEW 8
2.1 Introduction 8
2.2 Rectifying Circuit 9
2.3 Diode for Rectifier 11
2.4 Load Resistor 12
2.5 Matching Network 13
2.6 Power Divider 15
2.7 Tuning and Optimization 16
2.8 Harmonic Balance Simulator 17
2.9 Summary Literature Review 18
3 RESEARCH METHODOLOGY 20
3.1 Introduction 20
3.2Lumped Element for Rectifier 22
3.3 Interdigital Capacitor 23
3.4 Tuning and optimization 25
3.5 Matching Network 27
3.6 DC-DC Converter 29
3.7 Design Layout 30
3.8 Fabrication and Measurement 32
4 RESULT AND DISCUSSION 33
4.1 Introduction 33
4.2 Diode in the rectifier 33
4.3 Load in the rectifier 34
4.4 Matching Network 37
4.5 Simulation Result 38
4.6 Experimental Result 39
xi
5 CONCLUSION AND FUTURE WORK 44
5.1 Conclusion 44
5.2 Suggestion for Future Works 45
REFERENCES 46
APPENDIX 49
xii
LIST OF TABLES
NO TABLE PAGE
1 Parameter of interdigital capacitor 23
2 Parameter FR4 Board 30
3 The efficiency output voltage of different load at frequency
2.4GHz 36
4 The output voltage for the simulation. 39
5 The measured value of output current and output voltage
produce by the rectifier 40
6 The measured value of output current and output voltage
produce by the rectifier after connected with dc-dc converter. 40
7 The comparison value of the output voltage for the simulation
and measurement 41
xiii
LIST OF FIGURES
NO TITLE PAGE
1.1 The improvements in technology comparing batteries with
other devices 2
1.2 Complete system block diagram. 3
1.3 Gantt chart of the project planning 6
2.1 Schema of the rectifier 10
2.2 The impedance of rectifier without matching circuit as a function 10
of the frequency
2.3 Equivalent electrical circuit of a packaged diode 11
2.4 Calculated real (top) and imaginary (bottom) values of the input
impedance of a short-circuited, packaged Schottky diode as a
function of available input power at 2.45 GHz. 12
2.5 A losses network matching and arbitrary load impedance to
a transmission line 13
2.6 Single stub (a) shunt stub (b) series stub. 14
2.7 A two way Wilkinson power splitter 15
2.8 Tuning layout in ADS 16
2.9 Harmonic Balance Simulation in ADS 17
3.1 Project flow chart 21
3.2 Lumped element circuit of voltage double 22
3.3 Interdigital capacitor in voltage double circuit 24
3.4 Tuning layout in ADS 25
3.5 Graph comparison between before and after tuning of the circuit 26
3.6 Single stub matching network for frequency 2.45GHz 27
3.7 Double stub matching network for frequency 2.45 GHz 28
3.8 DC-DC Converter XL-6009 29
xiv
3.9 Function Block XL-6009 29
3.10 The schematic layout for the rectifier 30
3.11 Layout design by EM 31
3.12 The rectifier 32
3.13 Measuring process 32
4.1 The graph of output voltage of different diode 34
4.2 The graph of the output voltage of the difference load 35
4.3 Efficiency of the rectifier with the different load 35
4.4 Single stub matching network 37
4.5 Comparison between single stub, double stub and no matching. 37
4.6 The complete rectifier circuit 38
4.7 The rectifier with XL 6009 41
4.8 Measurement process 42
4.9 Testing process 42
4.10 Charging small powered device 42
xv
LIST OF ABBREVIATIONS AND ACRONYMS AC - Alternate Current
ADS - Advanced System Design
DC - Direct Current
EM - Electromagnetic
HB - Harmonic Balance
FR4 - Flame Retardant 4
PCB - Printed Circuit Board
RF - Radio Frequency
WLAN - Wireless Local Area Networks
xvi
LIST OF APPENDICES
Appendix A Diode HSMS 286X series
Appendix B DC-DC ConverterXL-6009
1
CHAPTER 1
INTRODUCTION
1.1 Research Background
Power, when talking about wireless communications, is a feature that is really important to
take into account because of the influence it has on the autonomy, weight and size of portable
devices. Therefore, energy harvesting techniques have been proposed to try to give solution to this
problem: there have a variety of alternative energy sources that are less harmful to the environment.
This kind of environmental friendly energy sources include energy harvesting from rectennas,
passive human power, wind energy and solar power. Power can extract from those techniques is
limited by regulations and free-space path loss. As a general idea, small dimensions are a basic
feature of portable devices, so the rectenna should be the same way. The small sizes devices, the
received power will be low. As a conclusion, can be said that wireless power transfer is better
suitable for low-power applications, e.g., a low-power wireless sensor.
2
The way technology advance every year allow the decrease of certain characteristics in digital
systems, like size and power consumption, that will lead to the gain of new ways of computing
and use of electronics, as an example wearable devices and wireless sensor networks. Currently,
these devices are powered by batteries, however, they present many disadvantages such as: the
need to either replace them or recharge them periodically and their big size and weight compared
to high technology electronics. A solution proposed to this problem was stated before: to extract
(harvest) energy from the environment to either recharge a battery, or even to directly power the
electronic device. Fig.1.1 shows the improvements in technology comparing batteries with other
devices.
Figure 1.1: The improvements in technology comparing batteries with other devices [1].
3
Harvesting wireless power techniques are mostly based on radio-frequency identification,
or RFID. Basically, the transmission part sends RF signals that carries information to a chip to
convert it to DC electricity to power the application. Then, a tag composed by an antenna and a
microchip responds by sending back data about the object it is attached to. In order to be able to
transfer power wirelessly an efficient rectenna is needed. Therefore, a rectenna design modeled
with numerical analysis and harmonic balance simulation. This provides a good insight in the
effect of the several parameters on the performance of the rectenna. In Figure 1.2 show the system
works: First, the antenna (a circularly polarized antenna) is in charge of capturing all the RF
signals; then the rectifier circuit will“extract” the power from those signals and convert it in DC
voltage efficiently. Finally there is a regulator circuit capable of working with low input voltages
which is desirable for this kind of project.
Figure 1.2: Complete system block diagram.
Several operating frequencies for the rectenna have been investigated in the literature.
Traditionally the 2.45 GHz Industrial Scientific and Medical (ISM) band has been utilized due to
the presence of Wi-Fi networks; additionally the 5.8 GHz ISM band has also been considered
which implies a smaller antenna aperture area than that of 2.45 GHz. Both frequency bands present
similar advantages because they have comparably low atmospheric loss, cheap components
availability, and high conversion efficiency. The frequency bands corresponding to mobile
telephone systems such as 800 MHz, 900 MHz and 1800MHz also present good alternatives for
electromagnetic energy harvesting systems, although they require a larger antenna size.
DC
Stable
DC
4
This work has two goals: (1) powering of low-power applications and (2) RF energy
recycling. If consider the use of batteries has some disadvantages like the limited life period they
have, plus the pollution generated from their disposal, it is very encouraging to think that if every
wireless sensor in the world have the kind of power source presented in this work, it would be a
great progress in the way try to keep our planet clean.
1.2 Problem Statement
In recent years, there is a rapid increase in using of wireless devices in many applications
such as mobile phones and sensor networks. These devices are powered by a portable and limited
energy device such as a battery. This means that the increasing of application usage will cause the
used of batteries also increased and these battery needs to be replaced so often. These batteries are
containing of heavy metals, where if improperly disposed it can leak it contain into the surrounding
environment thus increased pollution. Thus, the use of green technology like this RF energy system
is one of the solutions to overcome this problem due to advance in wireless broadcasting and
communication system that generated the availability of free energy.
The main problem in RF energy harvesting system is the amount of captured energy from
ambient RF sources is very low. The current design of rectifier DC conversion efficiency about
50%. This low level power maybe caused by the level of RF energy and the mismatching of the
antenna to the rectifier. In order to capture maximum power, the receiving antenna should be
designed properly by taking consideration of many factors to achieve impedance matching
between the antenna and the rectifier at the operating frequency and also to obtain maximum power
transfer and reducing transmission loss from PCB traces. In this project the optimum design of
rectifier DC conversion about 70%. Thus, to convert more of the antenna surface incident RF
power to DC power, high efficiency of RF to DC conversion is required by the rectifying circuit.
5
1.3 Objective
The objective of this project is to study and analyze the behavior of impedance matching,
power divider and rectifier circuit. Besides, to design cascade circuit to produce optimum
efficiency as well as to fabricate and validate the design in the laboratory that can operate at
frequency 2.4GHz
1.4 Scope of Project
The main purpose of this project is to design optimum rectifier that able to convert RF
energy to DC energy efficiently. This project start with understanding and analyzing rectifying
circuit that consists of single stub matching network, Wilkinson power combiner and also voltage
divider. All the information is obtain through journals, books and paperwork on the internet.
This project is focus on the designing the optimum rectifier able to convert RF energy to
DC power. The proposed frequency of this project is 2.4GHz. The performance of the rectifier
influence by the load of the resistor. Several value of the loads is analyzed to give the optimum
performance of the rectifier circuit. Besides, other main element that affect the circuit is the
selection of the diode. A diode with fast switching time will produce high efficiency of the circuit.
The designing and simulation of all the circuit is using Advance Design System (ADS
2011) which is use the Harmonic Balance as simulation method. Last but not least, the complete
circuit is fabricated and performance of the circuit is measured in the laboratory by using signal
generator as power source.
6
1.5 Project Planning
The Gantt chart in Figure 1.3 show the step by step work need to be done on the right time.
This Gantt chart helps to guide and complete each task on time. The flow chart show in Figure 1.4
the flow of the project development. This project start with the briefing on the final year project
then analyze the specification of the rectifying. Lastly end with submission of fabrication circuit
as well as thesis report.
Figure 1.3: Gantt chart of the project planning
7
1.6 Outline of the Project
In this thesis consist of five chapter which organized as follow:
First of all, chapter 1 describe about research background of RF energy harvesting. This
chapter consist of problem statement and objective of the project. Besides, the scope of the project
and organization of the thesis as well.
In chapter 2, the theoretical of the main components of the project such as rectifier, matching
network, power combiner, diode and loads use in rectifier, harmonic balance simulator as well as
tuning and optimization are briefly explained in this chapter. Relevant work also presented.
Chapter 3 highlight on the methodology of the project, step by step task is carry on to complete
the project. In this chapter also show the calculation part of impedance matching and the Wilkinson
power divider. The transformation of lumped element to the transmission line also be explained.
On top of that, the fabrication and the measurement part also be explained in this chapter.
Chapter 4 focuses on the result of simulation rectifier and the full circuit. The measurement will
be compared with the measurement results. The result and finding are discussed and the setup used
for RF measurement is also introduced.
In last chapter, chapter 5 highlight the outcome and conclusion of the project. It provides
recommendations and future work for this project.
8
CHAPTER 2
LITERATURE REVIEW
2.1 Introduction
In recent years the use of wireless devices is growing in many applications like mobile
phones or sensor networks. This increase in wireless applications has generated an increasing use
of batteries. Many research teams are working on the autonomy of the batteries by reducing the
consumption of the devices. The charging of multiple applications is easy because the user can do
it easily, like for mobile phones. But for other applications, like wireless sensor nodes located in
difficult access environments, the charging of the batteries remains a major problem. This problem
increase when the number of devices is large and are distributed in a wide area or located in
inaccessible places. Besides, the growing implications of energy costs and carbon footprints, the
need to adopt inexpensive, green energy harvesting strategies are of paramount importance for the
long-term conservation of the environment and the global economy. [2]
The uses of the Wireless Power Transmission (WPT) allow the overcoming of these
problems. The rectification of microwave signals to DC power has been proposed and researched
in the context of high-power beaming since the 1950s [3]. It has been proposed for helicopter