Hardware Reference
In-Depth Information
41. Nandi S, Jana PB, Nandi R (1984) Novel floating ideal tunable FDNR simulation using
current conveyors. IEEE Trans Circ Syst 31:402-403
42. Abdalla YAN (1985) Comment on Novel floating ideal tunable FDNR simulation using
current conveyors. IEEE Trans Circ Syst 32:303
43. Toumazou C, Lidgey FJ (1985) Floating-impedance convertors using current conveyors.
Electron Lett 21:640-642
44. Wilson B (1985) Floating FDNR employing a new CCII-conveyor implementation. Electron
Lett 21:996-997
45. Senani R (1985) Novel higher-order active filter design using current conveyors. Electron
Lett 21:1055-1057
46. Von Grunigen DC, Ramseier D, Moschytz GS (1986) Simulation of floating impedances for
low-frequency active filter design. Proc IEEE 74:366-367
47. Senani R (1986) On the realization of floating active elements. IEEE Trans Circ Syst
33:323-324
48. Higashimura M, Fukui Y (1986) Novel lossless tunable floating FDNR simulation using two
current conveyors and a buffer. Electron Lett 22:938-939
49. Senani R (1987) Network transformations for incorporating nonideal simulated immittances
in the design of active filters and oscillators. IEE Proc 134:158-166
50. Nandi R (1987) Precise realisation of an insensitive floating negative admittance convertor.
Electron Lett 23:775-777
51. Nandi R (1987) Novel floating negative immittance convertor. IEE Proc 134:236-238
52. Higashimura M, Fukui Y (1987) Novel method for realising lossless floating immittance
using current conveyors. Electron Lett 23:498-499
53. Higashimura M, Fukui Y (1987) Realization of floating immittance using three current
conveyors. IEICE Trans JPN J70-A:1203-1204
54. Higashimura M, Fukui Y (1987) New lossless tunable floating FDNR simulation using two
current conveyors and an INIC. Electron Lett 23:529-531
55. Surakampontorn W, Thitimajshima P (1988) Integrable electronically tunable current con-
veyors. IEE Proc 135:71-77
56. Senani R (1988) Floating immittance realisation: Nullor approach. Electron Lett 24:403-405
57. Higashimura M, Fukui Y (1988) Type 1 mutator using current conveyor and its application to
immittance simulation. Int J Electron 64:377-383
58. Ishida M, Okazaki Y, Fukui Y, Ebisutani K (1988) Realization of immittance function using
current conveyors. Trans IEICE J71-A:1205-1207
59. Higashimura M, Fukui Y (1988) Realization of impedance function using current conveyors.
Int J Electron 65:223-231
60. Senani R (1989) Three op-amp floating immittance simulators: a retrospection. IEEE Trans
Circ Syst 36:1463-1465
61. Singh V (1989) An implementation of CCII-current conveyor, with application. IEEE Trans
Circ Syst 36:1250-1251
62. Higashimura M, Fukui Y (1989) Simulation of lossless floating inductance using two current
conveyors and an operational transconductance amplifier. Int J Electron 66:633-638
63. Himura A, Fukui Y, Ishida M, Higashimura M (1989) Immittance function simulator using a
single current conveyor. IEICE Trans E72:1279-1284
64. Kumar U, Shukla SK (1989) The implementation and applications of current conveyors.
Microelectron J 20:25-46
65. Himura A, Fukui Y, Ishida M, Higashimura M (1989) Immittance function simulator using a
single current conveyor. Trans IEICE 72:1279-1284
66. Toumazou C, Lidgey FJ (1989) Novel current-mode instrumentation amplifier. Electron Lett
25:228-230
67. Wilson B (1989) Universal conveyor instrumentation amplifier. Electron Lett 25:470-471
68. Wilson B (1990) Recent developments in current conveyors and current-mode circuits. IEE
Proc 137:63-77
Search WWH ::




Custom Search