| About the authors |
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xvii | |
| Preface |
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xxi | |
| Acknowledgement |
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xxiii | |
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1 Gyrators, integrated inductors and simulated inductors |
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1 | (26) |
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1 | (1) |
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1 | (1) |
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1.2 Basic one-port circuit elements |
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2 | (1) |
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1.3 Basic two-port circuit elements |
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3 | (5) |
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3 | (1) |
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4 | (2) |
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1.3.3 The two-port impedance converters and inverters |
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6 | (2) |
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1.4 The pathological elements |
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8 | (2) |
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1.5 Multi-terminal gyrator |
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10 | (2) |
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1.6 Multiport inverters/converters |
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12 | (1) |
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1.7 Commercially available inductors and Coilcraft |
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12 | (1) |
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1.8 Basic difficulties in micro-miniaturization of inductors |
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13 | (2) |
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1.9 Integrated inductors and transformers on the chip |
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15 | (1) |
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16 | (1) |
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1.11 Use of ANSYS and COMSOL for the analysis of inductor designs |
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17 | (1) |
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1.12 The need for simulated inductors |
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17 | (1) |
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18 | (9) |
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19 | (8) |
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2 Gyrators and simulated inductors using op-amps |
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27 | (72) |
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27 | (1) |
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27 | (1) |
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28 | (3) |
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2.3 Op-amp gyrators and related circuits |
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31 | (13) |
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31 | (1) |
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32 | (1) |
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2.3.3 Generalized impedance converters (GIC)/gyrators |
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33 | (3) |
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2.3.4 Two-op-amp resistively variable capacitance simulators |
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36 | (4) |
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2.3.5 Two-op-amp lossless inductance simulator |
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40 | (1) |
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2.3.6 Tripathi-Patranabis lossless grounded inductor |
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41 | (1) |
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2.3.7 Lossless GI using summer/subtractor circuits |
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42 | (1) |
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2.3.8 Two modified forms of the GIC and their applications |
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42 | (2) |
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2.4 Single-op-amp lossless inductance simulators |
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44 | (4) |
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2.4.1 Orchard-Will son gyrator |
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44 | (1) |
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2.4.2 Schmidt-Lee circuit |
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45 | (1) |
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46 | (1) |
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2.4.4 Horn-Moschytz circuit |
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47 | (1) |
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2.5 Economic inductance simulators and resonators |
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48 | (11) |
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2.5.1 Ford-Girling circuit |
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48 | (1) |
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49 | (1) |
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2.5.3 Berndt-Dutta Roy circuit |
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49 | (2) |
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51 | (1) |
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51 | (1) |
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2.5.6 The parallel/series RL inductors derived by Rao-Venkateswaran |
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52 | (1) |
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2.5.7 Ahmed-Dutta Roy technique of deriving grounded-capacitor lossy GI |
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53 | (2) |
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2.5.8 Senani-Tiwari circuit |
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55 | (1) |
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2.5.9 Soliman-Awad tunable active inductor |
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56 | (1) |
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2.5.10 Nagarajan-Dutta Roy-Choudhary circuit |
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57 | (1) |
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2.5.11 Senani's single-resistance-tunable GIs |
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58 | (1) |
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2.6 Lossless floating impedance simulators using four op-amps |
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59 | (3) |
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2.6.1 Riordan's method of creating a lossless FI |
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59 | (1) |
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2.6.2 GIC method of simulating FI |
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60 | (1) |
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2.6.3 Tripathi-Patranabis FI |
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61 | (1) |
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2.6.4 Mutator-simulated floating inductors |
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62 | (1) |
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2.7 The multi-port immittance converters/inverters and multi-port gyrators |
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62 | (1) |
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2.8 Three-op-amp-based floating immittance simulators |
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62 | (6) |
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2.8.1 Three-op-amp-single-capacitor FIs based on GlC-type networks |
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63 | (2) |
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2.8.2 FI realizations using three op-amps along with a grounded capacitor |
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65 | (1) |
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2.8.3 Senani's single-resistance-controllable lossless FI |
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66 | (1) |
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2.8.4 Patranabis-Paul capacitance floatation circuit |
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67 | (1) |
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2.9 Lossless FIs using only two op-amps |
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68 | (2) |
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2.9.1 The-Yanagisawa circuit |
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68 | (1) |
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2.9.2 Sudo-Teramoto circuit |
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69 | (1) |
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2.10 Economic op-amp-based lossless/lossy FIs |
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70 | (4) |
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2.10.1 The cascade back-to-back approach to FI realization |
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71 | (1) |
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2.10.2 Parallel back-to-back approach to FI realization |
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72 | (1) |
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73 | (1) |
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2.11 The active-/? simulation of grounded/floating impedances and resonators |
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74 | (2) |
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2.12 Switched-capacitor simulated inductors |
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76 | (4) |
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2.13 FI realization using four-terminal floating nullors (FTFNs) |
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80 | (4) |
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2.14 Non-ideal behaviour of simulated impedances due to finite GBP of the op-amps used |
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84 | (1) |
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84 | (15) |
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86 | (13) |
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3 The operational transconductance amplifier based gyrators and impedance simulators |
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99 | (48) |
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99 | (1) |
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3.1 The OTAs and their advantages in analog circuit design |
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99 | (1) |
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100 | (2) |
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3.3 OTA-C gyrators, inductors and related impedances |
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102 | (8) |
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3.4 07A-RC impedance converters/inverters |
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110 | (2) |
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3.5 Other OTA-based lossless/lossy inductors and FDNRs |
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112 | (3) |
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3.6 Synthetic impedances using OTAs and op-amps |
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115 | (8) |
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3.7 OTA-based capacitance multipliers |
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123 | (3) |
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3.8 Inductor and FDNC simulators using OTAs and unity gain adders/subtractors |
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126 | (2) |
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3.9 Active-only simulators using op-amps and OTAs |
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128 | (5) |
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3.10 Electronically controllable resistors using OTAs |
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133 | (5) |
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3.11 Simulation of mutually coupled circuits and transformers |
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138 | (1) |
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3.12 Multi-port gyrators using OTAs: retrospection |
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138 | (2) |
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140 | (7) |
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141 | (6) |
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4 Synthetic impedances using current conveyors and their variants |
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147 | (102) |
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147 | (1) |
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147 | (2) |
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4.2 Realization of grounded and floating negative impedances |
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149 | (2) |
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4.3 Realization of synthetic grounded inductors, FDNRs and related elements |
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151 | (5) |
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4.3.1 Grounded inductance simulation using CCs |
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151 | (1) |
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4.3.2 Single-CCII-based active gyrators |
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152 | (1) |
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4.3.3 Single CCII-based grounded impedance simulators |
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153 | (3) |
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4.4 Synthetic floating impedances without component-matching requirements |
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156 | (25) |
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4.4.1 The first ever CC-based FI simulators without requiring any component matching |
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156 | (9) |
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4.4.2 Two other single-CC-based FIs without component matching |
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165 | (1) |
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4.4.3 GPIC/GPII/three-port gyrator configurations using CCs |
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166 | (4) |
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4.4.4 Additional three-CC-based floating inductor/FDNR simulators |
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170 | (2) |
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4.4.5 Floating impedance realization using two DOCCs |
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172 | (1) |
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4.4.6 Floating impedances using CCIIs and op-amps/OTAs |
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173 | (3) |
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4.4.7 Economical floating impedance circuits synthesized using the `CCll-nullor' equivalence |
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176 | (3) |
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4.4.8 Realization of mutually coupled circuits |
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179 | (2) |
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4.5 Impedance simulation using CCCII |
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181 | (12) |
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4.5.1 Current-controlled positive/negative resistance realization |
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184 | (3) |
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4.5.2 Electronically tunable grounded/floating impedances |
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187 | (5) |
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4.5.3 Electronically tunable synthetic transformer |
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192 | (1) |
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4.6 Immittance simulation using different variants of current conveyors |
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193 | (26) |
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4.6.1 Lossless FI realization employing only two DOCCs and three passive components |
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194 | (1) |
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4.6.2 DVCC-based floating inductance/FDNR realization |
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194 | (1) |
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4.6.3 CCIII-simulated inductors |
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195 | (1) |
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4.6.4 Single-DVCC-based grounded RL and CD immittance simulators |
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196 | (1) |
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4.6.5 DXCCII-based electronically controllable gyrator/inductor |
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197 | (1) |
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4.6.6 Grounded inductor realized with modified inverting CCII |
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198 | (1) |
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4.6.7 Synthetic floating immittances realized with DOCCII |
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199 | (1) |
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4.6.8 Another FI with improved low-frequency performance realized with only two DOCCIIs |
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200 | (1) |
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4.6.9 Floating impedance simulator realized with a DOCCII and an OTA |
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201 | (1) |
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4.6.10 Lossless FI realization employing a DOCCCII and grounded capacitor |
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202 | (1) |
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4.6.11 AN FI employing only a single DODDCC and three passive elements |
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203 | (1) |
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4.6.12 External resistorless FI realization using DXCCII |
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203 | (1) |
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4.6.13 Electronically tunable MOSFET-C FDNR using a DXCCII |
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204 | (1) |
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4.6.14 Grounded inductance simulation using a DXCCII |
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205 | (1) |
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4.6.15 FI realization using only two DVCCs/DVCCCs |
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206 | (3) |
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4.6.16 FDCCII-based lossless grounded inductor employing three grounded passive elements |
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209 | (2) |
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4.6.17 DXCCII-based grounded inductance simulators |
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211 | (2) |
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4.6.18 Grounded-capacitor-based floating capacitance multiplier using CCDDCCs |
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213 | (2) |
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4.6.19 Single-DODDCC-based grounded lossy inductance simulators employing a grounded capacitor |
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215 | (1) |
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4.6.20 DCCII-based grounded inductance simulator |
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216 | (1) |
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4.6.21 Miscellaneous FI simulators using ICCII, DVCC and FDVCC elements |
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217 | (2) |
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4.7 Higher order filter design using nonideal simulated impedances |
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219 | (3) |
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222 | (27) |
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223 | (26) |
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5 Current feedback-op-amp-based synthetic impedances |
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249 | (46) |
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249 | (1) |
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249 | (2) |
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251 | (2) |
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5.3 Systematic synthesis of gyrators/grounded inductance simulators |
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253 | (2) |
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5.4 Lossless FI simulators using CFOAs |
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255 | (8) |
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5.5 Grounded/floating generalized positive impedance converters/inverters (GPIC/GPII) and generalized negative impedance converters/inverters (GNIC/GNII) |
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263 | (6) |
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5.6 Economic simulation of lossy grounded inductors |
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269 | (2) |
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5.7 Low-component-count lossy FI simulation |
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271 | (2) |
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5.8 Single resistance-controllable single CFOA simulators |
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273 | (6) |
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5.9 Inductors and resonators using CFOA poles |
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279 | (3) |
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5.10 GI/FI simulators using modified CFOAs |
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282 | (8) |
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290 | (5) |
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290 | (5) |
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6 Applications of FTFN/OFA and OMAs in impedance synthesis |
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295 | (40) |
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295 | (1) |
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295 | (1) |
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6.2 An overview of nullors, FTFN/OFA and OMAs |
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296 | (9) |
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6.3 Generation of FTFN-based floating immittances |
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305 | (7) |
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6.3.1 Realization of floating generalized impedance converters/inverters |
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306 | (2) |
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6.3.2 Generation of lossless FI circuits using a single FTFN |
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308 | (2) |
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6.3.3 Single-resistance-tunable lossy FI simulation using only a single FTFN |
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310 | (2) |
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6.4 Operational mirrored amplifiers (OMA)-based simulators |
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312 | (11) |
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6.4.1 OMA-based floating GIC |
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312 | (2) |
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6.4.2 A floating GIC using OMA |
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314 | (1) |
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6.4.3 Floating impedance realization using a dual OMA |
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315 | (2) |
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6.4.4 Three OMA-based floating impedance simulators |
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317 | (3) |
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6.4.5 OMA-based FI using op-amp pole |
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320 | (2) |
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6.4.6 OMA-based FI with extended frequency range |
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322 | (1) |
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6.5 Operational floating amplifiers and their use in floating gyrator and FI realization |
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323 | (4) |
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6.5.1 The OFA-based floating gyrator |
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324 | (1) |
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6.5.2 The DD-OFA and its use in FI synthesis |
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325 | (2) |
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327 | (8) |
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328 | (7) |
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7 Realization of voltage-controlled impedances |
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335 | (32) |
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335 | (1) |
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335 | (2) |
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7.2 Grounded VCZ realization using op-amps |
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337 | (14) |
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7.2.1 Nay-Budak voltage-controlled resistors with extended dynamic range |
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337 | (2) |
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7.2.2 Senani-Bhaskar VCZ configurations |
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339 | (3) |
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7.2.3 Leuciuc-Goras VCZ configurations based upon GIC |
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342 | (3) |
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7.2.4 Three-op-amp-based VCZ structure by Senani-Bhaskar |
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345 | (1) |
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7.2.5 Senani's universal VCZ structure with only two op-amps |
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346 | (2) |
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7.2.6 Ndjountche configuration using MOS resistive circuit |
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348 | (1) |
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7.2.7 Economical VCZ configurations |
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349 | (2) |
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7.3 Grounded VCZ configurations using CFOAs |
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351 | (1) |
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7.4 VCZ configurations using current conveyors |
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352 | (1) |
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352 | (3) |
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7.6 The floating/grounded voltage-controlled GIC/GIIs using CFOAs |
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355 | (2) |
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7.7 Floating VC-negative-impedance realization using OMAs |
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357 | (2) |
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7.8 Floating/grounded VCZ structures using CFOAs and analogue multipliers |
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359 | (4) |
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363 | (4) |
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364 | (3) |
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8 Impedance synthesis using modern active building blocks |
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367 | (56) |
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367 | (1) |
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367 | (1) |
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8.2 An overview of modem electronic circuit building blocks |
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368 | (1) |
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8.3 Grounded impedance and floating impedance synthesis using modern building blocks |
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368 | (46) |
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8.3.1 Unity gain VF/CF-based circuits |
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368 | (6) |
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8.3.2 OTRA-based circuits |
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374 | (1) |
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375 | (5) |
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8.3.4 Translinear operational current amplifier |
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380 | (1) |
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8.3.5 CDTA-based circuits |
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380 | (2) |
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8.3.6 CDBA-based circuits |
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382 | (3) |
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8.3.7 CFTA-based circuits |
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385 | (3) |
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8.3.8 VDTA-based impedance simulators |
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388 | (4) |
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8.3.9 CCTA-based circuits |
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392 | (4) |
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8.3.10 VDBA-based circuits |
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396 | (3) |
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8.3.11 VD-DIBA-based circuit |
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399 | (3) |
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8.3.12 CFCC-based circuits |
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402 | (4) |
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8.3.13 Inductance simulation using OTA-CO A |
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406 | (1) |
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8.3.14 FDNR realization using capacitive gyrators |
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406 | (2) |
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8.3.15 Lossless grounded inductance simulator using VDCC |
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408 | (1) |
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8.3.16 Inductance simulation using VDIBA |
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408 | (2) |
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8.3.17 General floating immittance simulator using CBTA |
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410 | (2) |
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8.3.18 Simulation of inductor using current differential amplifiers (CDA) |
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412 | (1) |
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8.3.19 GI/FI using other miscellaneous active elements |
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412 | (2) |
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414 | (9) |
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415 | (8) |
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9 Transistor-level realization of electronically controllable grounded and floating resistors |
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423 | (50) |
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423 | (1) |
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423 | (1) |
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9.2 BJT-based translinear current-controlled resistors |
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424 | (15) |
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9.2.1 Current-controllable grounded/floating resistors |
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424 | (2) |
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9.2.2 A translinear current-controlled floating resistor due to Barthelemy and Fabre |
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426 | (2) |
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9.2.3 A translinear current-controllable floating negative resistor |
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428 | (2) |
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9.2.4 Translinear floating current-controlled positive resistance due to Senani, Singh and Singh |
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430 | (3) |
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9.2.5 A circuit to realize current-controllable floating positive/negative resistance |
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433 | (1) |
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9.2.6 A low transistor count current-controlled grounded/floating, positive/negative resistor due to Arslanalp, Yuce and Tola |
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434 | (3) |
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9.2.7 Current-controlled-resistor based upon a new eight-transistor mixed-translinear cell (MTC) |
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437 | (1) |
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9.2.8 Electronically tunable active resistance circuits based upon differential amplifiers |
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438 | (1) |
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9.3 CMOS linear voltage/current-controlled grounded/floating resistors |
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439 | (24) |
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9.3.1 A two-MOSFET-based linear voltage-controlled resistor devised by Han and Park |
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440 | (1) |
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9.3.2 Some general techniques of realizing linear MOS-resistive circuits |
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441 | (3) |
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9.3.3 The two MOSFET transresistor due to Wang |
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444 | (1) |
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9.3.4 Banu-Tsividis linear voltage-controlled floating linear resistor |
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445 | (1) |
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9.3.5 Linear transconductor due to Park and Schaumann |
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445 | (2) |
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9.3.6 Linear floating VCR due to Nagaraj |
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447 | (1) |
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9.3.7 Wilson and Chan grounded VCR |
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448 | (1) |
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9.3.8 Wang's grounded linear VCR |
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449 | (1) |
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9.3.9 Positive/negative linear grounded VCRs due to Wang |
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450 | (2) |
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9.3.10 Positive/negative linear grounded VCRs and voltage-controlled gyrator using NICs |
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452 | (2) |
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9.3.11 Floating linear resistor proposed by Elwan, Mahmoud and Soliman |
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454 | (9) |
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463 | (10) |
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464 | (9) |
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10 Bipolar and CMOS active inductors and transformers |
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473 | (32) |
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473 | (1) |
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473 | (1) |
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10.2 BJT-based gyrators and inductance simulators |
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474 | (6) |
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10.2.1 The early attempts of devising transistor-based gyrators/simulated inductors |
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474 | (1) |
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10.2.2 A two-transistor semiconductor FI simulator due to Takahashi, Hamada, Watanabe and Miyata |
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475 | (1) |
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10.2.3 A direct-coupled fully integratable gyrator due to Chua and Newcomb |
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476 | (1) |
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10.2.4 The integrated gyrator due to Haykim, Kramer, Shewchun and Treleaven |
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476 | (1) |
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10.2.5 Synthesis of three transistor gyrators |
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477 | (1) |
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10.2.6 The translinear floating inductance simulator |
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478 | (2) |
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10.3 CMOS active inductors |
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480 | (12) |
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10.3.1 CMOS inductor proposed by Uyanik and Tarim |
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480 | (1) |
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10.3.2 CMOS grounded inductor proposed by Reja, Filanovsky and Moez |
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481 | (2) |
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10.3.3 Constant-g active inductor proposed by Tang, Yuan and Law |
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483 | (1) |
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10.3.4 CMOS active inductors due to Krishnamurthy, El-Sankary and El-Masry |
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484 | (2) |
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10.3.5 CMOS high-g active grounded inductor due to Li, Wang and Gong |
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486 | (1) |
|
10.3.6 Tunable CMOS inductor using MOSFETs |
|
|
487 | (2) |
|
10.3.7 CMOS inductor proposed by Sato and Ito |
|
|
489 | (3) |
|
10.4 CMOS active transformers |
|
|
492 | (3) |
|
|
|
495 | (10) |
|
|
|
496 | (9) |
|
11 Recent developments and concluding remarks |
|
|
505 | (32) |
|
|
|
505 | (1) |
|
|
|
505 | (1) |
|
|
|
505 | (7) |
|
11.3 Recent developments on inductance simulation and related impedances |
|
|
512 | (19) |
|
11.3.1 Evolution of single-active-element-based floating impedance configurations |
|
|
512 | (7) |
|
11.3.2 Floating impedance configurations having electronic tunability and temperature-insensitivity |
|
|
519 | (2) |
|
11.3.3 Impact of the circuits and techniques of impedance simulation on the area of memristive circuits |
|
|
521 | (6) |
|
11.3.4 Impact of the circuit techniques of impedance simulation on the area of fractional-order circuits |
|
|
527 | (4) |
|
|
|
531 | (1) |
|
|
|
531 | (6) |
|
|
|
532 | (5) |
| Further reading |
|
537 | (6) |
| Index |
|
543 | |
