Author: Md Naimul Hasan Publisher: ISBN: 9780355460957 Category : Languages : en Pages :
Book Description
Modern wireless communication standards support numerous frequency bands. A dedicated surface acoustic wave (SAW) filter is assigned to each single band to isolate the desired frequency bands. As a result, multiple SAW filters are necessary to cover different frequency bands which clearly increases cost and form factor. There is a strong demand towards complete integrated solutions to reduce the cost and form-factor of wireless devices. However, it is quite challenging to build integrated high-performance bandpass filters. The inherent losses associated with on-chip inductors lead to filters having relatively high insertion losses, limited dynamic range and low out-of-band rejection. For this reason, nowadays, most wireless systems utilize individual off-chip filters rather than fully integrated bandpass filters. A cellular radio receiver is required to recover a weak desired signal in presence of other in-band and out-of-band interfering signals (blockers). These interfering signals near the desired signal need to be suppressed. To that end, a band selection filter is used to provide attenuation for out-of-band signals, and a subsequent baseband lowpass channel select filters provide channel selection. Existing filters providing channel selection directly at RF for cellular applications does not have adequate rejection in the stopband to full LTE requirements. In this thesis, several techniques based on N-path filters have been proposed to handle large out-of-band blockers. The ultimate rejection of classical N-path fillter is limited due to non-zero switch resistance. A cascaded configuration of bandpass (BP) and bandstop (BS) filter is utilized to create notches on both sides of the passband where the center frequency of bandstop filters are shifted by using feed-forward and feedback g[subscript m] cell. The filter is tunable from 0.2 GHz to 1.8 GHz. The proposed tunable filter has 48.3 dB rejection at 20 MHz offsetand has 58.8 dB rejection at 45 MHz offset from the center frequency. The simulated stop-band rejection of the filter is 71.2 dB. However, it is diffcult to create nearby notches without affecting the passband response of the later. To overcome the above diffculty, a new architecture is presented based on two-path signal cancellation technique to create notches close to the passband to handle large blockers. The filter consists of a tunable BPF in parallel with tunable BS filters. Due to the subtraction of BP and BS filters two notches can be created. This combination ensures the correct amplitude and phase relationships across a wide tuning range to create adjustable TZs without sacrificing the gain of the passband. This paper presents in detail the design considerations and guidelines, as well as analysis of the filter performance in the presence of non-idealities such as parasitics and imperfect clock signal shape. The proposed filter is implemented with high-Q N-path lter blocks in a 65-nm CMOS process. The passband of the filter is tunable from 0.1 GHz to 1.4 GHz with a 3-dB bandwidth of 9.8-10.2 MHz, a gain of 21.5-24 dB, a noise figure of 3-4.2 dB, and a total power consumption of 50-73 mW. TZs are created on both sides of the passband with a minimal offset of 25 MHz and are tunable across a 20 MHz range with up to 60 dB rejection. The measured blocker 1-dB compression point is 8 dBm and the out-of-band IIP3 is 23 dBm. The reported filter provides a promising on-chip filtering solution for multi-standard, multi-frequency software-dened radio applications with improved interference mitigation capabilities. Various on-chip techniques to handle out-of-band blockers have been proposed recently. Although these approaches are suitable for suppressing a single frequency blocker, the created single-frequency notch is not effective in presence of wideband blockers which is becoming more prevalent with the development in high-speed wireless communications. A tunable active bandpass filter with bandwidth-adjustable notches close to the passband for wideband blocker suppression with high attenuation is designed and fabricated. The proposed filter is composed of a 3-pole N-path bandstop filter in cascade with an Npath bandpass filter, where the center frequency of the bandpass filter is offset from the bandstop filters. With proper tuning of the coupling capacitors in the bandstop filter, three adjacent notches can be created which provides a larger suppression bandwidth. An implementation of the filter in 65-nm CMOS exhibits a passband tunable between 0.1-1.1 GHz, with a 3-dB bandwidth of 12.4-14.2 MHz, a gain of 9.5-10.3 dB, a noise figure of 4.3-5.8 dB, and a total power consumption of 40-64.3mW. The blocker 1-dB compression point is 6.5 dBm and the out-of-band IIP3 is 18.4 dBm.
Author: Nihar Athreyas Publisher: ISBN: Category : Electric filters, Passive Languages : en Pages : 99
Book Description
The advent of new standards in wireless communication like the Long Term Evolution (LTE) has resulted in a need for newer and better design of receivers for wireless communication systems, the first step of which is to design a tunable integrated filter on the receiver front end. In this work we propose a new design for a passive tunable integrated Roofing filter for LTE bands. The role of the Roofing filter is to protect the rest of the circuitry from overloading and distortions caused due to large out-of-band signals. This filter protects the rest of the circuitry and hence it gets the name Roofing filter. The Roofing filter is present on the receiver front-end. The filter has a low insertion loss and a high return loss at the input. The bandwidth of the Roofing filter is around 200MHz at the highest values. The filter uses off-chip inductors. The filter has a continuous center frequency tuning range of 2GHz from 0.7GHz to 2.7GHz, which is the allocated frequency range for LTE bands. This continuous tuning is achieved by the use of MOSFET based varactors. The filter is a narrowband filter. The design is implemented in TSMC 65nm CMOS technology.
Author: IEEE Staff Publisher: ISBN: 9781665430821 Category : Languages : en Pages :
Book Description
RFIC is the premier IC Conference focused on the latest developments in RF Microwave, and Millimeter Wave Integrated Circuit Technology and Innovation
Author: Vladimir Kopta Publisher: CRC Press ISBN: 1000794490 Category : Technology & Engineering Languages : en Pages : 224
Book Description
Over the past two decades we have witnessed the increasing popularity of the internet of things. The vision of billions of connected objects, able to interact with their environment, is the key driver directing the development of future communication devices. Today, power consumption as well as the cost and size of radios remain some of the key obstacles towards fulfilling this vision. Ultra-Low Power FM-UWB Transceivers for IoT presents the latest developments in the field of low power wireless communication. It promotes the FM-UWB modulation scheme as a candidate for short range communication in different IoT scenarios. The FM-UWB has the potential to provide exactly what is missing today. This spread spectrum technique enables significant reduction in transceiver complexity, making it smaller, cheaper and more energy efficient than most alternative options. The book provides an overview of both circuit-level and architectural techniques used in low power radio design, with a comprehensive study of state-of-the-art examples. It summarizes key theoretical aspects of FM-UWB with a glimpse at potential future research directions. Finally, it gives an insight into a full FM-UWB transceiver design, from system level specifications down to transistor level design, demonstrating the modern power reduction circuit techniques. Ultra-Low Power FM-UWB Transceivers for IoT is a perfect text and reference for engineers working in RF IC design and wireless communication, as well as academic staff and graduate students engaged in low power communication systems research.
Author: Ali M. Niknejad Publisher: Springer Science & Business Media ISBN: 0387765611 Category : Technology & Engineering Languages : en Pages : 313
Book Description
This book compiles and presents the research results from the past five years in mm-wave Silicon circuits. This area has received a great deal of interest from the research community including several university and research groups. The book covers device modeling, circuit building blocks, phased array systems, and antennas and packaging. It focuses on the techniques that uniquely take advantage of the scale and integration offered by silicon based technologies.
Author: Ville Saari Publisher: Springer Science & Business Media ISBN: 1461433657 Category : Technology & Engineering Languages : en Pages : 207
Book Description
This book presents a new filter design approach and concentrates on the circuit techniques that can be utilized when designing continuous-time low-pass filters in modern ultra-deep-submicron CMOS technologies for integrated wideband radio receivers. Coverage includes system-level issues related to the design and implementation of a complete single-chip radio receiver and related to the design and implementation of a filter circuit as a part of a complete single-chip radio receiver. Presents a new filter design approach, emphasizing low-voltage circuit solutions that can be implemented in modern, ultra-deep-submicron CMOS technologies;Includes filter circuit implementations designed as a part of a single-chip radio receiver in modern 1.2V 0.13um and 65nm CMOS;Describes design and implementation of a continuous-time low-pass filter for a multicarrier WCDMA base-station;Emphasizes system-level considerations throughout.
Author: Yichuang Sun Publisher: IET ISBN: 0852969767 Category : Technology & Engineering Languages : en Pages : 258
Book Description
Sun (communication electronics, U. of Hertfordshire, UK), this volume's editor, also contributed a chapter on the architectures and design of OTA/gm-C filters. The other papers describe on-chip automatic tuning of filters, analog adaptive filters, low voltage techniques for switched-current filters, log domain filters, the MOSFET-C technique and active filters using integrated inductors. The contributors teach electrical engineering in the US, the UK, Thailand, and Canada. Annotation copyrighted by Book News, Inc., Portland, OR
Author: Md Naimul Hasan
Author: Nihar Athreyas
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Author: 
Author: IEEE Staff
Author: Vladimir Kopta
Author: 
Author: Ali M. Niknejad
Author: Ville Saari
Author: Yichuang Sun