All Stories

  1. New grounded immittance simulators employing a single CFCC
  2. Sinusoidal oscillator Synthesis using Third Generation Current Conveyors
  3. From Editor-in-Chief's Desk
  4. From Editor-in-Chief's Desk
  5. Sinusoidal Oscillator Realizations Using Modern Electronic Circuit Building Blocks
  6. Sinusoidal Oscillators and Waveform Generators using Modern Electronic Circuit Building Blocks
  7. Basic Sinusoidal Oscillators and Waveform Generators Using IC Building Blocks
  8. Switched-Capacitor, Switched-Current, and MOSFET-C Sinusoidal Oscillators
  9. Non-sinusoidal Waveform Generators and Multivibrators Using OTAs
  10. Single-Element-Controlled and Other Varieties of Op-Amp Sinusoidal Oscillators
  11. Generation of Equivalent Oscillators Using Various Network Transformations
  12. Various Performance Measures, Figures of Merit, and Amplitude Stabilization/Control of Oscillators
  13. Waveform Generators Using Current Conveyors and CFOAs
  14. Current-Controlled Sinusoidal Oscillators Using Current-Controllable Building Blocks
  15. Sinusoidal Oscillators Using Current Conveyors
  16. Electronically Controllable OTA-C and Gm-C Sinusoidal Oscillators
  17. Current Directions of Research and Concluding Remarks
  18. Realization of Sinusoidal Oscillators Using Current Feedback Op-Amps
  19. Nonsinusoidal Waveform Generators/Relaxation Oscillators Using Other Building Blocks
  20. Bipolar and CMOS Translinear, Log-Domain, and Square-Root Domain Sinusoidal Oscillators
  21. Simple Simulated Inductor, Low-Pass/Band-Pass Filter and Sinusoidal Oscillator Using OTRA
  22. From Editor-in-Chief's Desk
  23. New canonic lossy inductor using a single CDBA and its application
  24. From the Editor-in-Chief's Desk
  25. Current Conveyors
  26. New Squaring and Square-rooting Circuits Using Cdba
  27. Varieties of Current Conveyors
  28. CMOS Implementations of Current Conveyors
  29. Nonlinear Applications of CCs
  30. Realization of Sinusoidal Oscillators Using CCs
  31. Second Generation Controlled Current Conveyors (CCCII) and Their Applications
  32. Second Generation Applications of Other Types of Current Conveyors in Realizing Synthetic Impedances
  33. First, Second and Higher Order Filter Design Using Current Conveyors
  34. The Evolution and the History of Current Conveyors
  35. Sinusoidal Oscillator Realizations Using Other Types of Current Conveyors
  36. Hardware Implementations of CCs Using Off-the-Shelf ICs
  37. Integratable Bipolar CC Architectures and Commercially Available IC CCs
  38. Other Building Blocks Having MTC or CC at Front-end and Their Applications
  39. Recent Advances and Future Directions of Research
  40. Analog Filter Design Revisited: Circuit Configurations Using Newer Varieties of CCs
  41. Second Generation Miscellaneous Linear/Nonlinear Applications of Various Types of Current Conveyors
  42. From the Editor-in-Chief's Desk
  43. New Multiplier/Divider Using a Single Cdba
  44. From the Editor-in-Chief's Desk
  45. Generation of equivalent OTA-C Oscillators
  46. Simulation of a Floating Inductance: A New Two-CFOA-Based Configuration
  47. From the Editor-in-Chief’s Desk
  48. Realization of SRCOs: another new application of DDAs
  49. A new universal biquad filter using differential difference amplifiers and its practical realization
  50. Current Feedback Operational Amplifiers and Their Applications
  51. Synthesis of Sinusoidal Oscillators Using CFOAs
  52. Introduction
  53. Realization of Other Building Blocks Using CFOAs
  54. Miscellaneous Linear and Nonlinear Applications of CFOAs
  55. Design of Filters Using CFOAs
  56. From the Editor-in-Chief’s Desk
  57. New Voltage Mode Universal Filters Using Only Two CDBAs
  58. New OTRA-Based Generalized Impedance Simulator
  59. CFOAs: Merits, Demerits, Basic Circuits and Available Varieties
  60. Simulation of Inductors and Other Types of Impedances Using CFOAs
  61. Advances in the Design of Bipolar/CMOS CFOAs and Future Directions of Research on CFOAs
  62. Synthesis of Electronically-Controllable Signal Processing/Signal Generation Circuits Using Modern Active Building Blocks
  63. Synthesis of Analog Circuits Using Only Voltage and Current Followers as Active Elements
  64. ON THE TRANSFORMATION OF GROUNDED INDUCTORS TO FLOATING INDUCTORS USING OFA AND FCCII
  65. From the Editor-in-Chief’s Desk
  66. New lossy/loss-less synthetic floating inductance configuration realized with only two CFOAs
  67. Nullors, Their Bipolar and CMOS Implementations and Applications in Analog Circuit Synthesis and Design
  68. Current-Feedback Op-Amps, Their Applications, Bipolar/CMOS Implementations and Their Variants
  69. Configuration for realising a current-mode universal filter and dual-mode quadrature single resistor controlled oscillator
  70. Synthesis of New Single CFOA-Based VCOs Incorporating the Voltage Summing Property of Analog Multipliers
  71. OTRA-based Grounded-FDNR and Grounded-Inductance Simulators and Their Applications
  72. New analogue inverse filters realised with current feedback op-amps
  73. SYNTHESIS OF LINEAR VCOs: THE STATE-VARIABLE APPROACH
  74. A NEW ELECTRONICALLY-TUNABLE ACTIVE-ONLY UNIVERSAL BIQUAD
  75. Electronically-Controlled Current-mode second order Sinusoidal Oscillators Using MO-OTAs and Grounded Capacitors
  76. A State Variable Method for the Realization of Universal Current-Mode Biquads
  77. Systematic realisation of quadrature oscillators using current differencing buffered amplifiers
  78. Linear sinusoidal VCOs: new configurations using current-feedback-op-amps
  79. Two Simple Analog Multiplier Based Linear VCOs Using a Single Current Feedback Op-Amp
  80. New grounded simulated inductance circuit using a single PFTFN
  81. Inverse active filters employing CFOAs
  82. New voltage controlled oscillators using CFOAs
  83. ELECTRONICALLY-CONTROLLABLE FLOATING INDUCTOR USING OPERATIONAL MIRRORED AMPLIFIER
  84. Comment: Practical voltage/current-controlled grounded resistor with dynamic range extension
  85. CFOA based oscillators generating sinusoidal current signals
  86. New CFOA-Based Single-Element-Controlled Sinusoidal Oscillators
  87. Improved grounded-capacitor SRCO using only a single PFTFN
  88. New Universal Biquads Employing CFOAs
  89. New voltage-model/current-mode universal biquad filter using unity-gain cells
  90. A systematic realization of current mode universal biquad filters
  91. New universal filter using only current followers as active elements
  92. New Dual-mode Biquads Using OTAs
  93. New Single-Resistance-Controlled Oscillator Configurations Using Unity-Gain Cells
  94. Two new canonic single-CFOA oscillators with single resistor controls
  95. DUAL FUNCTION CAPABILITY OF RECENTLY PROPOSED FOUR-CURRENT-CONVEYOR-BASED VM BIQUAD
  96. Novel mixed-mode universal biquad configuration
  97. CFOA-based state-variable biquad and its high-frequency compensation
  98. Explicit-current-output sinusoidal oscillators employing only a single current-feedback op-amp
  99. Grounded-capacitor SRCOs using a single differential difference complementary current feedback amplifier
  100. Tunable Current-Mode Universal 220 Frequenz 59 (2005) 9-10 Biquads employing only three MOCCs and all grounded passive elements: Additional New Realizations
  101. New OTA-C universal current-mode/trans-admittance biquads
  102. On the Realization of Universal Current Mode Biquads Using a Single CFOA
  103. A New Floating Current-Controlled Positive Resistance Using Mixed Translinear Cells
  104. Universal current mode biquad using a single CFOA
  105. New single resistance controlled oscillators employing a reduced number of unity-gain cells
  106. Novel sinusoidal oscillators using only unity-gain voltage followers and current followers
  107. Novel electronically controllable current-mode universal biquad filter
  108. New Tunable SIMO-Type Current Mode Universal Biquad Using only three MOCCs and all Grounded Passive Elements
  109. Realisation of Current-Mode SRCOs using All Grounded Passive Elements
  110. Multifunction CM/VM Biquads Realized with a Single CFOA and Grounded Capacitors
  111. A NEW FOUR-CC-BASED CONFIGURATION FOR REALIZING A VOLTAGE-MODE BIQUAD FILTER
  112. A New Universal Current-mode Biquad Filter
  113. Active-R design using CFOA-poles: new resonators, filters, and oscillators
  114. Comment: CMOS differential difference current conveyors and their applications
  115. Novel SRCOs using first generation current conveyor
  116. Grounded-capacitor current-mode SRCO: Novel application of DVCCC
  117. Low-Component-Count, High Frequency Resonators and their Applications, using Op-Amp Compensation Poles
  118. Realization of a Class of Analog Signal Processing / Signal Generation Circuits: Novel Configurations Using Current Feedback Op-Amps
  119. Implementation of Chua's chaotic circuit using current feedback op-amps
  120. Low-component-count active-only imittances and their application in realising simple multifunction biquads
  121. State variable synthesis of single-resistance-controlled grounded capacitor oscillators using only two CFOAs: additional new realisations
  122. State variable synthesis of single resistance controlled grounded capacitor oscillators using only two CFOAs
  123. Universal Voltage-Mode/Current-Mode Biquad Filter Realised with Current Feedback Op-Amps
  124. New macromodels of a switch for SPICE applications
  125. Synthesis of single-resistance-controlled oscillators using CFOAs: simple state-variable approach
  126. A Simple Approach of Deriving Single-Input-Multiple-Output Current- Mode Biquad Filters
  127. New active-R sinusoidal VCOs with linear tuning laws
  128. Alternative modification of the classical GIC structure
  129. Comment: Synthesis of canonic single-resistance-controlled-oscillators using a single current-feedback-amplifier
  130. Novel single-resistance-controlled-oscillator configuration using current feedback amplifiers
  131. Macromodeling ideal switches for SPICE
  132. Floating GNIC/GNII configuration realised with only a single OMA
  133. Universal linear voltage-controlled-impedance configuration
  134. KHN-equivalent biquad using current conveyors
  135. Realisation of linear voltage-controlled resistance in floating form
  136. Minimal realisations of a class of operational-mirrored-amplifier-based floating impedances
  137. Class of floating, generalised, positive/negative immittance convertors/inverters realised with operational mirrored amplifiers
  138. Versatile voltage-controlled impedance configuration
  139. On equivalent forms of single op-amp sinusoidal RC oscillators
  140. Systematic derivation of all possible canonic OTA-C sinusoidal oscillators
  141. A class of three-OTA-two-capacitor oscillators with non-interacting controls
  142. Simple sinusoidal oscillator using opamp compensation poles
  143. New current-conveyor-based single-resistance-controlled/voltage-controlled oscillator employing grounded capacitors
  144. New current-mode biquad filter
  145. Erratum: Single element-controlled sinusoidal oscillator employing single current conveyor IC
  146. Single-element-controlled sinusoidal oscillator employing single current conveyor IC
  147. A simple configuration for realizing voltage-controlled impedances
  148. Erratum: Systematic generation of OTA-C sinusoidal oscillators
  149. Some Simple Techniques of Generating OTA-C Sinusoidal Oscillators
  150. Realization of voltage-controlled impedances
  151. Single op-amp sinusoidal oscillators suitable for generation of very low frequencies
  152. Realisation of Linear Circuits Using IC Op-Amps: Some Appraisals
  153. New multifunction active filter configuration employing current conveyors
  154. Systematic generation of OTA-C sinusoidal oscillators
  155. Linearly tunable Wien bridge oscillator realised with operational transconductance amplifiers
  156. New electronically tunable OTA-C sinusoidal oscillator
  157. Erratum: Linearly tunable Wien bridge oscillator realised with operational transconductance amplifiers
  158. Three op amp floating immittance simulators: a retrospection
  159. Analysis, Synthesis and Design of New Types of RC-Active Sinusoidal Oscillators (Part I)
  160. Floating immittance realisation: nullor approach
  161. Analysis, Synthesis and Design of New Types of RC-Active Sinusoidal Oscillators (Part II)
  162. Simple approach for generating active-compensated building blocks
  163. On the transformation of RC-active oscillators
  164. Generation of new two-amplifier synthetic floating inductors
  165. A novel application of four-terminal floating nullors
  166. Network transformations for incorporating nonideal simulated immittances in the design of active filters and oscillators
  167. Network Transformation for Active-RC Realisation of RLM-Immittances
  168. New Types of Sinewave Oscillators
  169. New Rc-Active oscillator configuration employing unity-gain amplifiers
  170. Novel higher-order active filter design using current conveyors
  171. Erratum: Novel application of generalised current conveyor
  172. Novel application of generalised current conveyor
  173. Floating ideal FDNR using only two current conveyors
  174. On the synthesis of a class of immittances and filters using grounded capacitors
  175. Comments on "New canonic active RC realizations of grounded and floating inductors"
  176. Novel lossless synthetic floating inductor employing a grounded capacitor
  177. Erratum: Novel lossless synthetic floating inductor employing a grounded capacitor
  178. New Single-Capacitor Simulations of Floating Inductors
  179. Book Reviews
  180. Linear resistance-to-frequency conversion employing integrated circuit operational amplifiers
  181. Canonic Synthetic Floating-Inductance Circuits Employing Only a Single Component-Matching Condition
  182. Comments on: ‘Floating ideal inductor with one d.v.c.c.s.’ and ‘Novel capacitor flotation scheme’
  183. Reply: Novel sinusoidal oscillator employing grounded capacitors
  184. Novel sinusoidal oscillator employing grounded capacitors
  185. Novel active RC realisations of tunable floating inductors
  186. Novel circuit implementation of current conveyors using an o.a. and an o.t.a
  187. New tunable synthetic floating inductors
  188. New canonic single-resistance-controlled sinusoidal oscillator using a single current conveyor
  189. New canonic sinusoidal oscillator with independent frequency control through a single grounded resistor
  190. Novel active RC circuit for floating-inductor simulation
  191. Reply: Active simulation of inductors using current conveyor
  192. Some observations concerning the methods of filter/oscillator realization using the concept of FDNR
  193. New canonic active RC realizations of grounded and floating inductors
  194. Active simulation of inductors using current conveyor
  195. Realisation of single-resistance-controlled lossless floating inductance