Designing antennas and RF components for upper millimeter frequencies using advanced substrate technology

Abstract. When shifting towards high frequency range, integration in the RF-front end becomes crucial. The ongoing planning of 6G communications systems causes a need to explore the possibilities beyond current 5G systems. To address the compactness and smaller sizes of the RF circuit components, the Integrated Passive Devices (IPD) multilayer technology provides us one solution to this problem. There are options already being tested in terms of implementing on-chip components, especially Antenna-in-Package (AiP) designs with a variety of different substrates. Among these technologies, Low Temperature Co-Fired Ceramic (LTCC) can be seen as a choice offering the freedom of multiple metal layers. IPD can be used for providing AiP solutions, as well as passive components such as baluns, filters, and power dividers. The main target of this thesis is to explore the possibilities and limitations for high frequency designs offered by IPD technology developed by (VTT) Technical Research Centre of Finland. The technology has already been tested at 20 GHz, but the focus was to reach the D-band (110–170 GHz) frequency range and subsequently up to even G-band (220–330 GHz). The technology utilizes 3 metal layers and a high resistivity silicon substrate (a lossy material). Starting off with simple transmission line structures (microstrip lines, strip lines and coplanar waveguides), the designs up to 330 GHz, provided information on the possibilities offered by this technology. After that, different AiP options were simulated with frequencies ranging from D- band to G- band. In addition to single elements, also antenna arrays were studied. Additionally, bandpass filters were designed. The dielectric thickness and the width and thickness of 3 the metal layers play a pivotal role in defining the performance of all the RF components designed using this technology. Furthermore, the size and pitch of the RF probe pads used to excite the structures show an impact on the overall behavior of the transmission lines.Antennien ja RF-komponenttien suunnittelu ylemmille millimetritaajuuksille edistynyttä substraattitekniikkaa käyttäen. Tiivistelmä. Siirryttäessä korkeammille taajuuskaistoille RF-etupään integrointi on entistä tärkeämpää. Käynnissä oleva kuudennen sukupolven (6G) viestintäjärjestelmien suunnittelu edellyttää nykyisiä 5G-järjestelmiä edistyksellisempien teknologisten mahdollisuuksien tarkastelua. Entistä pienempien RF-piirikomponenttien toteuttaminen vaatii uusia teknisiä ratkaisuja, ja yksi mahdollisuus komponenttien pienentämiseen on käyttää integroituihin passiivirakenteisiin (Integrated Passive Devices, IPD) pohjautuvaa monikerrosteknologiaa. Eri vaihtoehtoja on jo testattu sirulle sijoitettavien komponenttien toteuttamiseen eri substraattimateriaaleilla, etenkin paketoitujen antenniratkaisujen (Antenna-in-Package, AiP) suunnittelemiseksi. Eräs vaihtoehto IPD:lle on matalan lämpötilan yhteissintrattava keraamiteknologia (Low Temperature Co-Fired Ceramic, LTCC), joka mahdollistaa useamman metallikerroksen hyödyntämisen suunniteltaessa AiP-rakenteita sekä muita passiivikomponentteja (kuten symmetrointimuuntajia, suodattimia sekä tehonjakajia). Tämän opinnäytetyön päätavoitteena on tarkastella Valtion teknillisen tutkimuskeskuksen (VTT:n) kehittämän IPD-teknologian mahdollisuuksia ja rajoitteita korkean taajuuden rakenteiden suunnitteluun. IPD-teknologiaa on tähän mennessä testattu 20 GHz:n taajuudelle asti, mutta tässä työssä tarkoituksena on tutkia teknologiaa 110–170 GHz:n taajuuksille (D-kaista) sekä myöhemmin aina 220–330 GHz:iin saakka (G-kaista). Teknologia hyödyntää kolmea metallikerrosta sekä häviöllistä korkean ominaisvastuksen piisubstraattia. Yksinkertaisten siirtojohtorakenteiden (mikroliuskajohto, liuskajohto, koplanaarijohto) suunnittelu aina 330 GHz:n taajuudelle asti antoi tietoa teknologian mahdollisuuksista, minkä jälkeen erilaisia AiP-rakenteita simuloitiin D- ja G-kaistoilla. Yksittäisten antennielementtien ohella tarkasteltiin antenniryhmiä. Työssä suunniteltiin myös kaistanpäästösuodattimia. Käytettävissä olevien metalli- ja substraattikerrosten paksuudella sekä niiden mahdollistamilla liuskanleveyksillä on keskeinen rooli IPD-teknologialla suunniteltujen komponenttien suorituskyvyn kannalta. Lisäksi RF-mittapäiden kontaktikohtien koko ja välimatka vaikuttavat siirtojohtojen ominaisuuksiin

Reduction in human interaction with magnetic resonant coupling WPT systems with grounded loop

Wireless power transfer (WPT) systems have attracted considerable attention in relation to providing a reliable and convenient power supply. Among the challenges in this area are maintaining the performance of the WPT system with the presence of a human body and minimizing the induced physical quantities in the human body. This study proposes a magnetic resonant coupling WPT (MRC-WPT) system that utilizes a resonator with a grounded loop to mitigate its interaction with a human body and achieve a high-efficiency power transfer at a short range. Our proposed system is based on a grounded loop to reduce the leakage of the electric field, resulting in less interaction with the human body. As a result, a transmission efficiency higher than 70% is achieved at a transmission distance of approximately 25 cm. Under the maximum-efficiency conditions of the WPT system, the use of a resonator with a grounded loop reduces the induced electric field, the peak spatial-average specific absorption rate (psSAR), and the whole-body averaged SAR by 43.6%, 69.7%, and 65.6%, respectively. The maximum permissible input power values for the proposed WPT systems are 40 and 33.5 kW, as prescribed in the International Commission of Non-Ionizing Radiation Protection (ICNIRP) guidelines to comply with the limits for local and whole-body average SAR

Decoupled and Descattered Monopole MIMO Antenna Array with Orthogonal Radiation Patterns

This chapter introduces a novel design concept to reduce mutual coupling among closely-spaced antenna elements of a MIMO array. This design concept significantly reduces the complexity of traditional/existing design approaches such as metamaterials, defected ground plane structures, soft electromagnetic surfaces, parasitic elements, matching and decoupling networks using a simple, yet a novel design alternative. The approach is based on a planar single decoupling element, consisting of a rectangular metallic ring resonator printed on one face of an ungrounded substrate. The decoupling structure surrounds a two-element vertical monopole antenna array fed by a coplanar waveguide structure. The design is shown both by simulations and measurements to reduce the mutual coupling by at least 20 dB, maintain the impedance bandwidth over which S11, is less than −10 dB, and reduce the envelope correlation coefficient to below 0.001. The boresight of the far-field radiation patterns of the two vertical monopole wire antennas operating at 2.4 GHz and separated by 8 mm (λo/16), where λo is the free-space wavelength at 2.45 GHz, is shown to be orthogonal and inclined by 45° with respect to the horizontal (azimuthal) plane while maintaining the shape of the isolated single antenna element

A Review: Circuit Theory of Microstrip Antennas for Dual-, Multi-, and Ultra-Widebands

In this chapter, a review has been presented on dual-band, multiband, and ultra-wideband (UWB). This review has been classified according to antenna feeding and loading of antennas using slots and notch and coplanar structure. Thereafter a comparison of dual-band, multiband, and ultra-wideband antenna has been presented. The basic geometry of patch antenna has been present along with its equivalent circuit diagram. It has been observed that patch antenna geometry for ultra-wideband is difficult to achieve with normal structure. Ultra-wideband antennas are achieved with two or more techniques; mostly UWB antennas are achieved from coplaner structures

Application of embedded frequency selective surfaces for structural health monitoring

This thesis proposes the use of Frequency Selective Surfaces (FSSs) as an embedded structural health monitoring (SHM) sensor. FSSs are periodic arrays of conductive elements that filter certain frequencies of incident electromagnetic radiation. The behavior of this filter is heavily dependent on the geometry of the FSS and local environment. Therefore, by monitoring how this filtering response changes when the geometric or environmental changes take place, information about those changes may be determined. In previous works, FSS-based sensing has shown promise for sensing normal strain (a stretching or compressing geometrical deformation). This concept is extended in this thesis by investigating the potential of FSSs for sensing shear strain (a twisting deformation) and detection of delamination/disbond (defined as an air gap that develops due a separation between layered dielectrics, and herein referred to as delamination) in layered structures. For normal strain and delamination sensing, monitoring of the FSS\u27s resonant frequency is shown to be a reliable indicator for each phenomena, as verified by full-wave simulation and measurement. For shear strain, simulation results indicate that an FSS may cross-polarize incident radiation when under shear strain. Additionally, FSS was applied as a normal and shear strain sensor within a steel-tube reinforced concrete column, where it was found to provide reliable normal strain detection (as compared to traditional strain sensors), but was not able to detect shear strain. Lastly, in order to improve the design procedure by reducing computation time, an algorithm was developed that rapidly approximates the response of an FSS to delamination through use of conformal mapping and existing frequency response calculations --Abstract, page iii

Terahertz antenna design for future wireless communication

A Terahertz (THz) antenna with a size of a few micrometres cannot be accomplished by just reducing the extent of a traditional metallic antenna down to a couple of micrometres. This approach has several downsides. For example, the low mobility of electrons in nanoscale metallic structures would result in high channel attenuation. Thus, using traditional micrometre metallic antennas for THz wireless communication becomes unfeasible. The THz band refers to the electromagnetic spectrum between the microwave and infrared frequency bands, which is colloquially referred to as the band gap due to the lack of materials and technological advancements. As opposed to their visible-spectrum features, metals such as gold and silver, which typically exhibit surface plasmon polaritons (SPPs), have completely different THz physical properties. 2D materials, which typically refer to single-layer materials, have been the focal point of researchers since the advent of graphene. 2D materials, for example, graphene, perovskite, and MoS2 (TMDs), provide a ground-breaking stage to control the propagation, modulation, and detection of THz waves. Moreover, 2D materials can enable the propagation of SPP waves in the THz band. These materials offer a promise of a future technological revolution. Combined with other profound advantages in lightweight, mechanical flexibility, and environmental friendliness, 2D materials can be used to fabricate low-cost wearable devices. This study also reported CH3NH3PbI3 perovskite as a promising material for THz antennas for wearable applications. CH3NH3PbI3 has a high charge carrier mobility and diffusion length, indicating that this material is a potential candidate for antenna design. The attractive feature about perovskite, graphene and other 2D materials is the ultra-high specific surface areas that enable their energy band structures to be sensitive to external basing. In the literature, scientists have tested a wide range of nano-antenna designs using modelling and simulation approaches. Nano-antenna fabrication and measurement using 2D materials is still the missing piece in the THz band. The design, fabrication, and measurement of THz antennas based on 2D materials for wearable wireless communication is the primary goal of this PhD study, including designing, fabrication, and measurement. In this study, we have designed, fabricated, and measured five different designs using different materials in the THz band, which will pave the way for enabling future THz short-range wireless communication

Design and Modelling of Wireless Power Transfer and Energy Harvesting Systems

The escalation of the Internet-of-Everything topicality has motivated an increased interest in both academia and industry research for efficient solutions enabling self-sustained smart operations. From the maintenance point of view, indeed, battery-less strategies represent the most valuable way for distributed zero-power standalone electronics. With this purpose, different scavenging techniques are being adopted, gathering energy from different sources such as mechanical, solar, thermal and electromagnetic waves. Due to the wide spread of wireless communication systems, the latter technology has recently benefited a renewed interest. This Ph.D. research activity has been focused on the investigation of new efficient solutions for radiofrequency energy harvesting and wireless power transmission techniques, aiming at improving the state of the art, by also taking into account the imperative necessity of eco-friendly materials for the development of green electronics. The combination of radiofrequency energy harvesting and ultra-wideband techniques is also proposed as possible candidate for future RFID systems. These functionalities are integrated in a novel, compact and low-profile tag, whose details are provided thoroughly from both electromagnetic and nonlinear circuit viewpoints. Results validation is provided through experimental characterization. Compatibility with the environment is assured by implementation with recyclable material. This concept is then extended with the investigation of more elaborated energy scavenging architectures, including rectenna arrays. Finally, a near-field wireless power transmission system is presented on low-cost materials, therefore suitable for possible mass-market deployment

Realistic frequency coded chipless RFID: physically modulated tags and refectarray readers

In letzter Zeit hat die chiplose RFID Technologie enorme Aufmerksamkeit im besonders kostenbewussten Markt für Objektidentifikation erregt. Allerdings befindet sich der aktuelle Stand der Technik auf einem konzeptionellen Niveau und leidet noch unter einer Menge Einschränkungen, die eine sofortige Verwendung der Technologie noch verhindern. Grundsätzlich lässt sich ein chiploses RFID System in drei Teile unterteilen, dem RFID Lesegerät, den verwendeten Antennen und dem RFID Tag. Der Beitrag der vorliegenden Dissertation zur Überwindung der erwähnten Einschränkungen liegt in innovativen physikalisch modulierenden RFID Tags und in der Weiterentwicklung des Antennensystems des RFID Lesegerätes. Dabei werden besonders die drei im Folgenden beschriebenen Aspekte betrachtet. Der erste Aspekt beschäftigt sich mit physikalisch linear modulierten RFID Tags. Dabei werden die RFID Tags mit einem Ultra Breitband (engl. ultra wideband, UWB) Signal bestrahlt und die auf dem RFID Tag aufgebrachten Resonatoren modulieren die Frequenz des Signals physikalisch. Dabei werden dem UWB Signal resonante Notches und/oder Peaks aufmoduliert, die sich in der Frequenzantwort des von der effektiven Rückstrahlfläche (engl. radar cross section, RCS) zurückgestrahlten Signals befindet. Hierfür sind vier innovative physikalisch modulierende RFID Tags, mit dem Ziel einer effektiveren Kodierung und maximalen Kodierungstiefe bei gleichbleibender Frequenzauslastung und RFID Tag Größe, entwickelt worden. Der erste RFID Tag besteht aus ineinander verschachtelten Ringresonatoren, wobei jeder Resonator ein Notch, also ein Bit, erzeugt. Der zweite RFID Tag arbeitet auf zwei unterschiedlichen Polarisationsebenen für empfangene und rückgestrahlte Signale. Dadurch kann die Streustrahlung der Umgebung leichter herausgefiltert werden. Beide Strukturen sind skalierbar, druckbar und kompakt. Als drittes wird ein neuartiger Notchbreiten modulierender (engl. notch width modulation, NWM) RFID Tag eingeführt. Dabei ist die ID des RFID Tags nicht nur über die Notchlage im Frequenzbereich sondern auch über die Notchbreite definiert. Die Notchbreite stellt also eine zusätzliche Dimension bereit, die die Freiheitsgrade (engl. degree of Freedom, DoF) für Kodierung und Modulation erhöhen, was wiederum die kodier Effektivität und Codetiefe verbessert. Als letztes wird ein neuartiger On Off-Notch/Peak (OONP) und Notch/Peak-Position (N/P-P) modulierender RFID Tag eingeführt. Die Idee dahinter ist, sowohl das kopolarisierte als auch das kreuzpolarisierte Rückstrahl Signal eines mit einer linear-polarisierten Welle angeregten RFID Tags auszunutzen. Dies bittet ein weiteres Kriterium um sowohl kodier Effektivität als auch Codetiefe des chiplosen RFID Systems weiter zu verbessern. Gleichzeitig verbessert die kreuzpolarisierte Antwort auch wieder die Detektion des RFID Tags in einer realen Umgebung. Alle vorgeschlagenen RFID Tags und Modulationsschemata sind mit elektromagnetischen (EM) Simulationen und in einer realen Testumgebung überprüft worden. Der zweite Aspekt dieser Arbeit schlägt Reflect-Array Antennen (RA) für das RFID Lesegerät mit dem Ziel vor, die Lesereichweite zu erhöhen und die Reflektionen an der Umgebung zu minimieren. Das RA bietet dabei im Vergleich zu herkömmlichen Phased-Array-Antennen eine Menge weiterer Eigenschaften. Das RA ist einfach zu integrieren, von geringem Gewicht, hat eine sehr geometrische Anordnung und ist preiswert, um nur einige zu nennen. Insgesamt wurden drei neuartige RA Aufbauten entwickelt. Als erstes wurde eine logarithmisch periodische Antenne (engl. log periodic antenna array, LPDA) als Primärstrahler für die entworfene RA Oberfläche genutzt. Der Prototype arbeitet bei 5.8GHz und erreicht eine Bandbreite von 300MHz. Außerdem ist der erzeugte Antennenstrahl viermal schmaler als der Primärstrahl und erreicht somit einen um 6dB höheren Antennengewinn bei einem Nebenkeulenpegel (engl. side lobe level, SSL) von −10dB. Für den zweiten Prototypen wird ein selbstentwickelter Hornstrahler mit konstanter Phase als Primärstrahler für die RA Oberfläche verwendet. Durch diese Anordnung wird ein UWB RA realisiert, mit dem mehrere Bits gleichzeitig ausgelesen werden können. Die Antenne arbeitet zwischen 4 − 6GHz und erreicht einen Öffnungswinkel (engl. half power beam width, HPBW) von 15° bei 19dBi Antennengewinn und −10dB SLL. Im Zusammenspiel mit den physikalisch modulierenden RFID Tags konnte mit diesem UWB RA eine Lesereichweite von 1m erzielt werden, was nach meinem Kenntnisstand die größte bisher für ein chiploses frequenzkodiertes (engl. frequency coded, FC) RFID System erreichte Lesereichweite in einer realen Innenraum Umgebung darstellt. Weiter wird eine dual polarisierte RA Antenne mit geringem Kreuzpolarisations Pegel vorgestellt. Es wird vorgeschlagen diese Antenne mit den ko-/kreuzpolarisierten RFID Tags zu verwenden. Als letztes wird eine RA Antenne mit elektronischer Strahlsteuerung eingeführt, die die Stabilität des Lesevorgangs weiter erhöht und eine präzise Ortung der chiplosen RFID Tags ermöglicht. Dazu wird eine Zelle vorgeschlagen, die mit Hilfe einer Varaktordiode in der Lage ist, für einzelne Frequenzen die Phase des reflektierten Signals elektronisch zu steuern. Ein Scanbereich von ±50° kann damit abgedeckt werden. Als dritter Aspekt werden nicht-lineare physikalisch modulierende RFID Tags vorgeschlagen. Hier ist der Kerngedanke, dass der RFID Tag seine ID mit einer anderen Frequenz zurückstrahlt als die mit der er selber angestrahlt wird. Durch dieses nichtlineare Verhalten wird die Umgebungsstrahlung komplett ausgeblendet, die sonst unumgänglichen Kalibrierungsmessungen werden überflüssig, das Problem der Verstimmung durch das RFID Tag Material wird umgangen und die Abdeckung wird erhöht. Die Nicht-Linearität wird durch eine einzige in die Struktur des RFID Tags integrierte Diode erzeugt. Zunächst werden RFID Tags vorgeschlagen, die mit Nichtlinearitäten zweiter Ordnung arbeiten. Für diese Kategorie werden drei unterschiedliche RFID Tags entworfen. Als Erstes ein Einzelton harmonischer RFID Radar Tag. In dieser Klasse strahlt das RFID Lesegerät einige spezifische Grundtöne aus, die schmalbandige Empfangsan-tenne des RFID Tags ist auf einen Grundton abgestimmt, den sie an die Diode weiterleitet. Die hier generierte zweite Harmonische wird von der entsprechend konfigurierten Sendeantenne der RFID Tags zurückgestrahlt. Dabei gilt, je schmaler der Bandbassfilter, desto mehr Frequenzen können zur Kodierung genutzt werden. Um die Codekapazität zu erhöhen werden als nächsten Mehrfrequenzabfragen vorgestellt. Dazu werden am RFID Lesegerät nacheinander, um keine Mischprodukte entstehen zu lassen, vordefinierte Frequenzen durchlaufen. Auf dem RFID Tag können jetzt mehrere ID Bits wieder durch die unterschiedlichen Frequenzen der jeweiligen zweiten Harmonischen erzeugt werden (engl. Notch Position Modulation, NPM). Anschließend werden festdefinierte Frequenzpaare zum Auslesen der ID verwendet. Die Diode mischt beide Frequenzen und antwortet nur auf der Mischfrequenz eines der Frequenzpaare. In einer weiteren Kategorie werden die Intermodulationseigenschaften der dritten Ordnung ausgenutzt, mit dem Vorteil, dass nur ein relativ geringer Frequenzbereich benötigt wird. Hierbei wir der RFID Tag mit zwei benachbarten Frequenzen bestrahlt und die zurückgestrahlte Intermodulationsfrequenz stellt die ID des RFID Tags dar. Schließlich wird die Kodierung über die Phaseninformation vorgestellt. Zusätzlich zur Existenz oder Fehlen eines Peaks oder Notches wird der dazuge- hörige relative Phasenzustand zur Kodierung herangezogen. Alle vorgestellten RFID Tags und ihre Modulation werden an Hand von Harmonische-Balance-Analyse, EM Simulationen und Messungen in einer realen Testumgebung überprüft. Zum Schluss lässt sich sagen, die einzigartigen Eigenschaften, die in der vorliegenden Dissertation betrachtet werden, bringen wesentliche Verbesserungen für den Einsatz von chiplosen RFID Systemen.Recently, the chipless Radio Frequency Identification (RFID) technology has attracted tremendous attention in the market of item identification where the cost is the main concern. However, up to date the technology is at the conceptual level and suffers from a lot of imitations that hinder the technology deployment. The chipless RFID system comprises three major parts which are the reader circuit, the interrogation antennas, and the chipless tags. The contributions of this dissertation are to overcome the challenges that impede the deployment of the chipless RFID system from the perspective of innovating physically modulated tags and developing the reader antenna system. In particular, the system is considered in three novel aspects. The first aspect is the linear physically modulated tags where the tag is interrogated by Ultra Wideband (UWB) signal and the tag inscribed metallic resonators are physically modulating the interrogation frequencies. Therefore, the UWB waveform is modulated in the form of resonant notches, and/or peaks that are inherently embedded in the tag backscattered Radar Cross Section (RCS) frequency response. In this regard, four innovative physically modulated tags are developed aiming at enhancing the coding efficiency, maximizing the coding capacity, conserving the operating frequency range and preserving the tag size. The first tag is based on nested circular ring resonators where each resonator codifies a tag coding notch. Terefore, the tag structure is scalable, printable and compact size. Moreover, a novel encoding methodology is employed to preserve the notch width and position while coding. The second developed tag is a depolarizing one where the polarization isolation between the reader interrogation signal and the tag response is utilized to minimize the environmental clutter reflections. Furthermore, the tag is scalable, printable, and compact size in the credit card format. Thirdly, a novel Notch Width Modulation (NWM) tag is introduced where the tag-ID is not only based on the notch position but also on the notch width. Hence, the notch width configures a further dimension to increase the Degree of Freedom (DoF) for coding and modulation. Therefore, the notch width and position are modulated simultaneously aiming at enhancing the coding efficiency and capacity. Lastly, a novel On Off Notch/Peak (OO-N/P) and Notch/Peak-Position (N/P-P) modulation tag is introduced. The tag basic idea is to exploit both the co-polarized and cross polarized backscattered signals from a tag excited with a linear polarized wave. Consequently, the tag signature is encoded into Notch/Peak (N/P) format in two orthogonal planes. Thus, the Co/Cross-polarizing N/P modulation scheme presents a novel criterion for enhancing the coding efficiency and capacity of the chipless RFID systems. Moreover, the cross-polarized response enhances the tag detection in a realistic environment. The proposed tags and their associated physical modulation schemes are validated using Electro Magnetic (EM) simulations and real-world testbed measurements. In the second aspect, the Reflectarray (RA) antenna is proposed to be utilized in the reader side aiming at increasing the reading range, minimizing the environmental reflections, and acquiring a lot of novel capabilities that can not be provided by the conventional antenna arrays. The spatial feeding RA antenna is easily integrated with the RF circuits, lightweight, conformal geometry, and low cost. Hence, in this concern, three different novel designs are developed. The first design utilizes the Log Periodic Array (LPDA) antenna to feed the developed RA surface. This introduced prototype operates at 5.8GHz and achieves 300MHz bandwidth. Moreover, the RA antenna radiation beam is 4 times narrower than the feeder beam and thus 6dB higher in gain with −10dB Side Lobe Level (SLL). The second developed prototype uses a constant phase center horn antenna to feed the RA surface. Thus, an UWB RA antenna enabling multiple bits accommodation is designed. This antenna operates from 4GHz to 6GHz with 15° Half Power Beam Width (HPBW), 19dBi gain, and −10dB SLL. Furthermore, this developed UWB RA antenna is successfully integrated with the physically modulated tags and a reading range of 1m is achieved. To the best of my knowledge, this is the highest reading range achieved in the Frequency Coded (FC) chipless RFID systems, considering real-world indoor environment and software defined radio reader. After that, dual-polarized RA antenna with low cross-polarization level is presented. This RA antenna is proposed to be utilized with the Co/Cross-polarizing tags. Finally, a successful implementation of an electronic beam steering RA antenna is introduced. This novel beam steering RA antenna system enhances the reading robustness and can precisely locate the chipless tags. In this concern, a novel unit cell that is able to electronically control the reflected phase at different discrete frequencies utilizing a single varactor diode is proposed. Therefore, a scanning range of ±50° is achieved. Moreover, the steered beams are 4 times narrower than the feeder beam and thus 4 times higher in gain. In the third aspect, the nonlinear physically modulated tags are proposed. The core functionality relies on interrogating the tag with a prescribed set and format of frequencies in a time regulated technique while the tag replies with its unique ID at other frequencies. Therefore, the nonlinearity is exploited to completely isolate the environmental clutter reflections, get rid of the necessary reference calibration measurements, overcome the detuning caused by the tagged item materials, and increase the coverage. These objectives are attained by exploiting the nonlinearity generated from a single unbiased diode integrated with the tag structure. The first proposed tag category relies on exploiting the second order nonlinear terms. Therefore, in this regard, three novel tags are introduced. The first class is the single tone harmonic radar tags. In this class, the reader scans the available tags by sending specific fundamental tones. Then, the tag receiving antenna is tuned at only one of these fundamentals which is maximally conveyed to the nonlinear device for generating the corresponding harmonics. Consequently, the tag transmitting antenna is tuned at the second harmonic which is retransmitted back towards the reader representing the tag-ID. Thus, the narrower is the band-pass filter provided by the tag receiving antenna or integrated into it, the more the frequencies that can be utilized for coding. After that, the multi-tone interrogation is proposed to increase the coding capacity. Hence, the tag is interrogated with a prescribed set of fundamentals that are swept over the time to avoid the generation of the mixing products in the reader and tag as well. The tag in turn which is completely planar based on the Coplanar Waveguide (CPW) technology implements a Notch Position Modulation (NPM) scheme in the second harmonics of these fundamental tones. Therefore, the notches that are existing in the second harmonic response symbolize the tag-ID. Afterward, the simultaneous multi-tone interrogation is explored. In this concern, a set of distinct frequency pairs are used to interrogate the nonlinear tags. As a consequence, these tones are mixed through the nonlinear device. Consequently, the tag transmitting antenna figures out only one of these mixed products. The second proposed tag category relies on exploiting the inter-modulation communication principle which exhibits a small frequency span. Therefore, the tag is illuminated by two co-located frequencies and respond at an inter-modulated frequency which is retransmitted by the tag transmitting antenna representing the tag-ID. Finally, the phase encoding capability is proposed. Therefore, not only the existence or the non-existence of a harmonic notch or peak used in coding the tag-ID but also the corresponding relative phase states can be considered. The introduced tags and their associated physical modulation schemes are verified using harmonic balance analysis, EM simulations and realistic testbed measurements. Lastly, the unique features which are considered in the dissertation bring a significant enhancement to the deployment of the chipless RFID system

Marshall Space Flight Center Electromagnetic Compatibility Design and Interference Control (MEDIC) handbook

The purpose of the MEDIC Handbook is to provide practical and helpful information in the design of electrical equipment for electromagnetic compatibility (EMS). Included is the definition of electromagnetic interference (EMI) terms and units as well as an explanation of the basic EMI interactions. An overview of typical NASA EMI test requirements and associated test setups is given. General design techniques to minimize the risk of EMI and EMI suppression techniques at the board and equipment interface levels are presented. The Handbook contains specific EMI test compliance design techniques and retrofit fixes for noncompliant equipment. Also presented are special tests that are useful in the design process or in instances of specification noncompliance