- Empowers designers to "attack" the multi-standard environment in a parallel way rather than serially;
- Enables readers to cope efficiently with the large amount of information provided in wireless standards, through manual analysis to find the optimal design path even from the embryonic state of the project;
- Demonstrates the fundamental choice designers have to make regarding the optimal channel selection for filtering in the analog domain and how much will remain to be filtered in the digital domain.
Dr. Silvian Spiridon (B.Sc.–2003, M.Sc.–2004 and Ph.D.–2011) is Principal Scientist with Broadcom Ltd. in Irvine, CA, USA. He is the project leader responsible for the design and development of wireline transceivers, high speed mixed-signal and RF circuits for cable applications. Dr. Spiridon is also a Senior Member with IEEE. His main research interest is focused on the development of a standard independent design methodology for wireless transceivers.
This book introduces a new intuitive design methodology for the optimal design path for next-generation software defined radio front-ends (SDRXs). The methodology described empowers designers to "attack" the multi-standard environment in a parallel way rather than serially, providing a critical tool for any design methodology targeting 5G circuits and systems. Throughout the book the SDRX design follows the key wireless standards of the moment (i.e., GSM, WCDMA, LTE, Bluetooth, WLAN), since a receiver compatible with these standards is the most likely candidate for the first design iteration in a 5G deployment. The author explains the fundamental choice the designer has to make regarding the optimal channel selection: how much of the blockers/interferers will be filtered in the analog domain and how much will remain to be filtered in the digital domain. The system-level analysis the author describes entails the direct sampling architecture is treated as a particular case of mixer-based direct conversion architecture. This allows readers give a power consumption budget to determine how much filtering is required on the receive path, by considering the ADC performance characteristics and the corresponding blocker diagram.
Overview of Wireless Communication in theInternet Age.- Defining the optimal architecture.- From High Level StandardRequirements to Circuit Level Electrical Specifications: A Standard IndependentApproach.- Optimal Filter Partitioning.- Smart Gain Partitioning for Noise –Linearity Trade-Off Optimization.- SDRXElectrical Specifications.- A System Level Perspective of Modern Receiver Building Blocks.- Conclusions and Future Developers.
This book introduces a new intuitive design methodology for the optimal design path for next-generation software defined radio front-ends (SDRXs). The methodology described empowers designers to "attack" the multi-standard environment in a parallel way rather than serially, providing a critical tool for any design methodology targeting 5G circuits and systems. Throughout the book the SDRX design follows the key wireless standards of the moment (i.e., GSM, WCDMA, LTE, Bluetooth, WLAN), since a receiver compatible with these standards is the most likely candidate for the first design iteration in a 5G deployment. The author explains the fundamental choice the designer has to make regarding the optimal channel selection: how much of the blockers/interferers will be filtered in the analog domain and how much will remain to be filtered in the digital domain. The system-level analysis the author describes entails the direct sampling architecture is treated as a particular case of mixer-based direct conversion architecture. This allows readers give a power consumption budget to determine how much filtering is required on the receive path, by considering the ADC performance characteristics and the corresponding blocker diagram.
Overview of Wireless Communication in theInternet Age.- Defining the optimal architecture.- From High Level StandardRequirements to Circuit Level Electrical Specifications: A Standard IndependentApproach.- Optimal Filter Partitioning.- Smart Gain Partitioning for Noise -Linearity Trade-Off Optimization.- SDRXElectrical Specifications.- A System Level Perspective of Modern Receiver Building Blocks.- Conclusions and Future Developers.
Dr. Silvian Spiridon (B.Sc.-2003, M.Sc.-2004 and Ph.D.-2011) is Principal Scientist with Broadcom Ltd. in Irvine, CA, USA. He is the project leader responsible for the design and development of wireline transceivers, high speed mixed-signal and RF circuits for cable applications. Dr. Spiridon is also a Senior Member with IEEE. His main research interest is focused on the development of a standard independent design methodology for wireless transceivers.
Über den Autor
Dr. Silvian Spiridon (B.Sc.-2003, M.Sc.-2004 and Ph.D.-2011) is Principal Scientist with Broadcom Ltd. in Irvine, CA, USA. He is the project leader responsible for the design and development of wireline transceivers, high speed mixed-signal and RF circuits for cable applications. Dr. Spiridon is also a Senior Member with IEEE. His main research interest is focused on the development of a standard independent design methodology for wireless transceivers.
Inhaltsverzeichnis
Overview of Wireless Communication in the
Internet Age.- Defining the optimal architecture.- From High Level Standard
Requirements to Circuit Level Electrical Specifications: A Standard Independent
Approach.- Optimal Filter Partitioning.- Smart Gain Partitioning for Noise -
Linearity Trade-Off Optimization.- SDRX
Electrical Specifications.- A System Level Perspective of Modern Receiver Building Blocks.- Conclusions and Future Developers.
Klappentext
This book introduces a new intuitive design methodology for the optimal design path for next-generation software defined radio front-ends (SDRXs). The methodology described empowers designers to "attack" the multi-standard environment in a parallel way rather than serially, providing a critical tool for any design methodology targeting 5G circuits and systems. Throughout the book the SDRX design follows the key wireless standards of the moment (i.e., GSM, WCDMA, LTE, Bluetooth, WLAN), since a receiver compatible with these standards is the most likely candidate for the first design iteration in a 5G deployment. The author explains the fundamental choice the designer has to make regarding the optimal channel selection: how much of the blockers/interferers will be filtered in the analog domain and how much will remain to be filtered in the digital domain. The system-level analysis the author describes entails the direct sampling architecture is treated as a particular case of mixer-based direct conversion architecture. This allows readers give a power consumption budget to determine how much filtering is required on the receive path, by considering the ADC performance characteristics and the corresponding blocker diagram.
Empowers designers to "attack" the multi-standard environment in a parallel way rather than serially;
Enables readers to cope efficiently with the large amount of information provided in wireless standards, through manual analysis to find the optimal design path even from the embryonic state of the project;
Demonstrates the fundamental choice designers have to make regarding the optimal channel selection for filtering in the analog domain and how much will remain to be filtered in the digital domain.
Includes supplementary material: sn.pub/extras