iPhoneAlle anzeigen
iPhone 11iPhone 11 ProiPhone 11 Pro MaxiPhone 12iPhone 12 ProiPhone 12 Pro MaxiPhone 12 miniiPhone 13iPhone 13 ProiPhone 13 Pro MaxiPhone 13 miniiPhone 14iPhone 14 PlusiPhone 14 ProiPhone 14 Pro MaxiPhone 15iPhone 15 PlusiPhone 15 ProiPhone 15 Pro MaxiPhone 16iPhone 16 PlusiPhone 16 ProiPhone 16 Pro MaxiPhone 16eiPhone 8iPhone 8 PlusiPhone SE 2020iPhone SE 2022iPhone XiPhone XRiPhone XSiPhone XS Max
Galaxy A-SerieAlle anzeigen
Galaxy A12Galaxy A13Galaxy A13 5GGalaxy A14Galaxy A15Galaxy A16Galaxy A17 5GGalaxy A20eGalaxy A21Galaxy A22Galaxy A23Galaxy A24Galaxy A25Galaxy A26 5GGalaxy A32Galaxy A33Galaxy A34Galaxy A35Galaxy A36 5GGalaxy A40Galaxy A41Galaxy A42Galaxy A50Galaxy A51Galaxy A52Galaxy A53Galaxy A54Galaxy A55Galaxy A56 5GGalaxy A70Galaxy A71Galaxy A72
Redmi SeriesAlle anzeigen
Redmi 10Redmi 13CRedmi 15 5GRedmi Note 10Redmi Note 10 ProRedmi Note 11Redmi Note 11 ProRedmi Note 11 Pro Plus 5GRedmi Note 11sRedmi Note 12Redmi Note 12 5GRedmi Note 12 ProRedmi Note 12 Pro 5GRedmi Note 12 Pro PlusRedmi Note 13Redmi Note 13 5GRedmi Note 13 ProRedmi Note 13 Pro PlusRedmi Note 14Redmi Note 14 Pro PlusRedmi Note 8Redmi Note 8 ProRedmi Note 9Redmi Note 9 Pro
- Startseite
Bücher Englische Bücher Wissen & Bildung Naturwissenschaft, Medizin, Informatik, Technik Technik Elektronik, Elektro- und Nachrichtentechnik Generalized Frequency Division Multiplexing in Cognitive Radio
-89 %*
Handgeprüfte Gebrauchtware
Bis zu 50 % günstiger als neu
Der Umwelt zuliebe
Generalized Frequency Division Multiplexing in Cognitive Radio
Rohit Datta (Unbekannter Einband, Englisch)
★★★★★
☆☆☆☆☆ Keine Bewertungen vorhanden
Optischer Zustand
Exzellenter Zustand Keine oder nur minimale Gebrauchsspuren vorhanden Ohne Knicke, Markierungen Bestens als Geschenk geeignet
Beschreibung
In today’s scenario, radio spectrum is becoming scarce, and the intelligent use of the available spectrum by cognitive radio (CR) has become an important aspect of research in wireless communication. To cope with this huge demand for spectrum, regulatory bodies (such as FCC in the USA, BNetzA in Germany, and Ofcom in the UK) have recently opened up licensed spectrum for secondary unlicensed… access. Unlicensed access in licensed bands should not create interference to incumbent users, and hence, new physical layer (PHY) designs and waveforms are being researched, which can fill in the TV white spaces (TVWS) in an opportunistic manner. One of the strict specifications for CR physical layer modulation design is that the opportunistic signal should have extremely low out-of-band radiation, so that incumbent signals are not disturbed, and co-existence is assured. Moreover, to cope with spectrum fragmentation, the receiver should be able to aggregate several TV white spaces (TVWS) by a single wide band signal. Hence, innovative waveform design with a new multicarrier modulation capable of interference mitigation has emerged as a very important topic of research.
The multiband Generalized Frequency Division Multiplexing (GFDM) is a new idea for designing a multicarrier PHY. GFDM is block based multicarrier transmission scheme derived from filter bank approach where the transmit data of each block is distributed in time and frequency and each subcarrier is pulse shaped with an adjustable pulse shaping filter. GFDM is well suited for cognitive radio, as the choice of pulse shaping filters makes the out-of-band leakage extremely small. Compared to OFDM, which has rectangular pulse shaping, GFDM with a choice of transmit pulse shaping, causes lesser interference to the adjacent incumbent frequency bands.
The thesis introduces the concept of GFDM and extends it towards cognitive radio applications. The basic GFDM transceiver chain is described in detail along with all its intricacies. The thesis analyses the adjacent channel leakage ratio of GFDM and compares them with traditional OFDM and other new waveforms like filter bank multi-carrier (FBMC) and interference avoidance partition frequency technique (IAPFT). The thesis studies the effects of different pulse shaping filters, like raised cosine and root raised cosine filters, to out of band leakage, and also, to the bit error rate performance. The thesis studies the adjacent channel leakage ratio (ACLR) of GFDM and introduces the concept of cancellation carrier insertion to GFDM. This method reduces the out of band leakage to match that of FBMC.
In a cognitive radio application, sensing the opportunistic signal is extremely important. Towards this, the thesis studies the sensing performance of GFDM. Along with theoretical analysis, simulation methods are explained and numerical studies have been performed. The thesis also introduces the idea of sensing opportunistic signals with GFDM sharper filters with a significant gain in performance.
Along with sensing, feature detection of an opportunistic signal is also an interesting and invigorating study. The thesis details the study of cyclostationary properties of GFDM and identifies new correlative properties in the GFDM signals which give rise to additional cyclostationary peaks in the cyclostationary autocorrelation function. The thesis uses these additional peaks of correlative informations to improve the detection performance of a GFDM signal compared to OFDM.
The concept of GFDM data block and flexible pulse shaping filters to reduce the ACLR, however, introduces severe non-orthogonality between the subcarriers. This in-turn produces self interference which degrades the bit error rate (BER) performance of the GFDM system. The thesis implements a successive interference cancellation scheme which cancels out the self interference and matches the GFDM performance to theoretical studies and that of OFDM. The thesis also describes an experimental testbed for GFDM as a cognitive radio waveform in a 4G LTE cellular whitespace. The GFDM waveform is transmitted with SIGNALION SDR testbed, and interference to the legacy LTE signal is calculated. Apart from which, a sensor, which proves the spectral efficiency of sharper GFDM waveform compared to traditional OFDM, has also been implemented. The prototype implementation proves the validity of GFDM as a suitable candidate for CR access beyond doubt.
As a major outcome, the results clearly indicate the suitability of GFDM as an opportunistic waveform for application in fragmented TVWS cognitive radio environments. The thesis studies the applicability of GFDM in cognitive radio not only in respect to its out of band leakage but also to its robust sensing performance. The new results of low ACLR in GFDM and improved sensing performance for GFDM makes it very suitable for CR applications. Additional correlative properties found in its cyclostationary autocorrelative functions improves its detection performance and also hints at ease of synchronization of GFDM in this direction. The results from the thesis highlights the overall applicability and suitability of GFDM as a next generation flexible waveform for cognitive radio application in fragmented spectrum scenarios. neu 59,00 € -89 %*
5,99 €
zzgl.
zzgl.
Handgeprüfte Gebrauchtware
Bis zu 50 % günstiger als neu
Der Umwelt zuliebe
* Spare 89 % gegenüber Neuware
Der Streichpreis bezieht sich auf den festgelegten Preis für Neuware.
Technische Daten
Erscheinungsdatum
28.11.2014
Sprache
Englisch
EAN
9783938860809
Herausgeber
Jörg Vogt Verlag
Sonderedition
Nein
Autor
Rohit Datta
Seitenanzahl
134
Auflage
1
Einbandart
Unbekannter Einband
Schlagwörter
Mobilfunk, FDMA, Generalized Frequency Division Multiplexing, Cognitive Radio
Thema-Inhalt
TJ - Elektronik, Nachrichtentechnik
Höhe
210 mm
Breite
14.8 cm
-.-
★★★★★
☆☆☆☆☆ Leider noch keine Bewertungen
Leider noch keine Bewertungen
Sicher bei rebuy kaufen
Schreib die erste Bewertung für dieses Produkt!
Wenn du eine Bewertung für dieses Produkt schreibst, hilfst du allen Kund:innen, die noch überlegen, ob sie das Produkt kaufen wollen. Vielen Dank, dass du mitmachst!
Sicher bei rebuy kaufen