Wearable and Neuronic Antennas for Medical and Wireless Applications. Группа авторов
Читать онлайн.| Название | Wearable and Neuronic Antennas for Medical and Wireless Applications |
|---|---|
| Автор произведения | Группа авторов |
| Жанр | Техническая литература |
| Серия | |
| Издательство | Техническая литература |
| Год выпуска | 0 |
| isbn | 9781119792567 |
14 10 A Rectangular Microstrip Patch Antenna with Defected Ground for UWB Application 10.1 Introduction 10.2 Antenna Design 10.3 Simulation Results 10.4 Conclusion References
15 11 Waveform Optimization in Multi-Carrier Communications for 5G Technology 11.1 Introduction 11.2 Related Literature Review 11.3 System Model: OFDM System 11.4 POPS: A Popular Existing Method for OFDM Waveform Optimization 11.5 Proposed Method for the Waveform Optimization in OFDM Systems 11.6 Results and Discussion 11.7 Summary References
16 12 Wearable Antennas for Biomedical Applications 12.1 Introduction 12.2 Need of Wearable Antennas 12.3 Design Considerations for Wearable Antenna 12.4 Materials for Wearable Antenna 12.5 Fabrication Methods for Wearable Antenna 12.6 Measurements for Wearable Antenna 12.7 Frequency Bands for Wearable Antenna 12.8 Applications of Wearable Antenna in Biomedical 12.9 Conclusion References
17 13 Received Power Based Jammer Localization Using Unscented Kalman Filtering 13.1 Introduction 13.2 Related Work 13.3 System Model 13.4 Simulation and Results 13.5 Summary References
18 Index
List of Tables
1 Chapter 1Table 1.1 Performance comparison of SVM based FBMC equalizers.
2 Chapter 2Table 2.1 Performance summary of the discussed low noise amplifiers.
3 Chapter 3Table 3.1 Denotes meaning of variable. Source: Created by the authors.Table 3.2 Variable and meaning in the proposed algorithm. Source: Created by aut...Table 3.3 Shows image formed after epochs through our DCGAN architecture. Source...Table 3.4 Accuracy of CNN architecture. Source: Created by author.
4 Chapter 4Table 4.1 Design parameter of proposed antenna.
5 Chapter 5Table 5.1 Power density and efficiency of different sources.Table 5.2 Different RF sources.Table 5.3 SPICE parameter of Schottky Diodes [27, 28, 30].
6 Chapter 6Table 6.1 Notations.Table 6.2 The schemes for RF EH NOMA-MEC with a multi-antenna user.Table 6.3 Typical values of the parameters in the simulation.
7 Chapter 7Table 7.1 CNTFET design parameters for this analysis.Table 7.2 Comparative analysis of performance for proposed SRAM memory cell stru...Table 7.3 Comparative analysis of leakage current.Table 7.4 Static Noise Margin for proposed SRAM cells.Table 7.5 Stability metrics analysis of proposed SRAM cells using N-curve.
8 Chapter 8Table 8.1 Comparison of SARs on different part of human body.
9 Chapter 9Table 9.1 Specifications of antenna.
10 Chapter 10Table 10.1 Parameters of the proposed antenna.Table 10.2 Comparison of different antennas.
11 Chapter 12Table 12.1 Wearable antenna design step.Table 12.2 Recently developed textile materials for wearable antennas.Table 12.4 “Frequency bands used by antennas for in-body, on-body and external m...Table 12.3 Recently developed non textile materials for wearable antennas.
List of Illustrations
1 Chapter 1Figure 1.1 FBMC-OQAM transmission system.Figure 1.2 FBMC-OQAM reception system.Figure 1.3 BER performance comparison of different equalizers in FBMC system.
2 Chapter 2Figure 2.1 Amplitude and frequency band of bio signal [2].Figure 2.2 ECG signal characteristics [6].Figure 2.3 Common mode voltages rejection by eliminating the ground electrode [1...Figure 2.4 Typical configuration of a wearable ECG monitoring system [12].Figure 2.5 Fully differential capacitive coupled feedback amplifier [19].Figure 2.6 Typical telescopic cascode amplifier [39].Figure 2.7 Complementary input closed loop amplifier.Figure 2.8 Fully differential current reuse OTA [41].Figure 2.9 Fully reconfigurable OTA using floating gate transistors [42].Figure 2.10 Low noise OTA using quasi floating gate (QFG) transistors in the out...Figure 2.11 Low noise low power OTA [46].Figure 2.12 Cross coupled load current reuse OTA [47].Figure 2.13 Fully differential stacked OTA [48].
3 Chapter 3Figure 3.1 Architecture of GAN.Figure 3.2 Basic constituent layer of CNN.Figure 3.3 Weight vector initialization.Figure 3.4 Pooling window.Figure 3.5 Discriminator architecture.Figure 3.6 Generator architecture.Figure 3.7 Accuracy curve for CNN model. Source: Created by authors.Figure 3.8 Loss curve of CNN architecture. Source: Created by authors.
4 Chapter 4Figure 4.1 The block diagram of WBAN.Figure 4.2 The three tiers involved in WBAN and its medical needs. Source: https...Figure 4.3 Patient monitoring using on body a wireless body area network (WBAN)....Figure 4.4 Application of In body WBAN in the various areas of medical and non-m...Figure 4.5 Wireless body area networks.Figure 4.6 (a) Transmitter of wireless body area networks. (b) Receiver of wirel...Figure 4.7 (a) Front side of proposed antenna. (b) Back side of proposed antenna...Figure 4.8 (a) and (b): Effect of variation of radius of via on return loss and ...Figure 4.9 (a) and (b): Effect of variation of length of feed on return loss and...Figure 4.10 (a) and (b): Effect of defected ground structure on the return loss ...Figure 4.11 (a) and (b): Return loss and gain of proposed antenna.Figure 4.12 3D plot of the proposed antenna.
5 Chapter 5Figure 5.1 RF energy harvesting system.Figure 5.2 Antenna electrical model representation.Figure 5.3 L, pi, T type matching circuits.Figure 5.4 L & pi type