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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 matching circuits output voltage.Figure 5.5 (a) L & pi type Matching Circuits S11 at 2.45 GHz (b) L & pi type Mat...Figure 5.6 Rectifier input impedance.Figure 5.7 Schottky diode non-linear model [26].Figure 5.8 Complete Energy harvester with one stage Dickson multiplier.Figure 5.9 (a) real impedance variation at different frequencies, (b) imaginary ...Figure 5.10 (a) Real impedance variation at different load values at 50 MHz; (b)...Figure 5.10 (c) Real impedance variation at different load values at 100 MHz; (d...Figure 5.10 (e) Real impedance variation at different load values at 930 MHz; (f...Figure 5.10 (g) Real impedance variation at 2.45 GHz for different loads; (h) Im...

6 Chapter 6Figure 6.1 System model for RF EH NOMA MEC network.Figure 6.2 Time flowchart of the considered RF EH NOMA MEC network.Figure 6.3 Impacts of the time switching ratio on SCP of different schemes.Figure 6.4 Impacts of the power allocation coefficient on SCP of different schem...Figure 6.5 The convergence of optimization algorithms.Figure 6.6 SCP comparison of different methods with/without optimal algorithms.

7 Chapter 7Figure 7.1 Schematic of 6T based CNTFET SRAM memory cell.Figure 7.2 Schematic of 7T CNTFET based SRAM memory cell.Figure 7.3 Structure of 8T CNTFET based SRAM cell.Figure 7.4 Schematic of 9T based CNTFET SRAM memory cell.Figure 7.5 Schematic of 10T CNTFET SRAM cell.Figure 7.6 Simulation results of 6T, 7T and 9T based CNTFET SRAM memory cell.Figure 7.7 Simulated transient response of 8T based CNTFET SRAM cell.Figure 7.8 Simulation results of 10T CNTFET based SRAM cell.Figure 7.9 Average power consumption versus chiral vector.Figure 7.10 Average power consumption versus channel length.Figure 7.11 Average power consumption versus supply voltage.Figure 7.12 Average power consumption versus temperature.Figure 7.13 Leakage power versus channel length.Figure 7.14 Leakage power v/s chiral vector.Figure 7.15 Leakage power versus supply voltage.Figure 7.16 Delay versus supply voltage.Figure 7.17 Butterfly curve for CNTFET SRAM cell in hold mode.Figure 7.18 Butterfly curve for SRAM in read mode.Figure 7.19 Butterfly curve for SRAM in write mode.Figure 7.20 HSNM variations with supply voltage.Figure 7.21 RSNM variations with power supply.Figure 7.22 WSNM variations with power supply.Figure 7.23 N-curve for proposed 6T SRAM cell.Figure 7.24 SVNM variations with power supply.Figure 7.25 SINM variations with power supply.Figure 7.26 WTV variations with supply voltage.Figure 7.27 WTI variations with supply voltage.

8 Chapter 8Figure 8.1 Proposed antenna structure.Figure 8.2 On-body [green dotted line] and free space [blue line] reflection coe...Figure 8.3 Reflection coefficient during bending at 2.4 GHz ISM band.Figure 8.4 Reflection coefficient during bending at 5.8 GHz ISM band.Figure 8.5 (a) Surface current distributions at 2.4 GHz.Figure 8.5 (b) Surface current distributions at 5.8 GHz.Figure 8.6 (a) Specific absorption rate of antenna placed on forearm at frequenc...Figure 8.6 (b) Specific absorption rate of antenna placed on upper arm at freque...Figure 8.6 (c) Specific absorption rate of antenna placed on thigh at frequency ...Figure 8.6 (d) Specific absorption rate of antenna placed on chest at frequency ...

9 Chapter 9Figure 9.1 The proposed antenna designed in HFSS simulation software.Figure 9.2 Edge mount coaxial connector for feeding, (a) without shorting pins a...Figure 9.3 Fabrication of antenna using LPKF pro tool.Figure 9.4 The equivalent circuit approach of antenna (notch-enabled).Figure 9.5 The equivalent circuit of patch antenna using notch.Figure 9.6 the equivalent circuit of shorting pin enabled antenna withslot.Figure 9.7 Plot of return loss vs frequency of designed antenna.Figure 9.8 Measured, simulated plot of return loss versus frequency of antenna.Figure 9.9 The plot of simulated E-plane, H-plane of radiation of antenna.Figure 9.10 Plot of measured E/H-plane radiation pattern of antenna.

10 Chapter 10Figure 10.1 Main antenna geometry.Figure 10.2 (a) Uppersight, and (b) lowestsight.Figure 10.3 S-parameter (No notching).Figure 10.4 S-parameter for different slots dimension.Figure 10.5 VSWR.Figure 10.6 3-D radiation patterns.

11 Chapter 11Figure 11.1 OFDM transmitter and receiver systems.Figure 11.2 POPS philosophy of the waveforms. Optimization by the maximization o...Figure 11.3 Validation of derived analytical outage probabilities via simulation...Figure 11.4 Outage probability performance of the proposed method.

12 Chapter 12Figure 12.1 Body centric communication [4].Figure 12.2 S11 for the “implanted antenna inside the head of the male anatomica...Figure 12.3 Distinct techniques for flexible antennas: (a) PET substrate and sil...Figure 12.4 Embroidery machine [65].Figure 12.5 Prototype of embroidered UWB antenna with electro conductive polyest...Figure 12.6 “E-Caption: smart and sustainable coat. (a) Design of the coat and (...Figure 12.7 (a) Fabrication flow chart (b) specialized DMP 2831 printer.Figure 12.8 (a) Fabrication process (b) UWB antenna printed on substrate by etch...Figure 12.9 Photograph of the fabricated antenna prototype and of the measuremen...Figure 12.10 Various wearable devices placed on different locations on human bod...

13 Chapter 13Figure 13.1 Representation of the comparison between the original trajectory, UK...Figure 13.2 X position error.Figure 13.3 Y position error.

Wearable and Neuronic Antennas for Medical and Wireless Applications

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