Hardware Reference
In-Depth Information
35. Soliman AM (1998) Generalized voltage and current conveyors: practical realizations using
CCII. IEICE Trans Fundament Electron Commun Comput Sci E81-A:973-975
36. Alami M (1999) Second generation current conveyors with enhanced input resistance. Int J
Electron 86:405-412
37. Awad IA (1999) Inverting second generation current conveyors: the missing building blocks,
CMOS realizations and applications. Int J Electron 86:413-432
38. Ridley R (2000) Current mode or voltage mode? Switching Power Mag 5:4-9
39. Schmid H (2000) Approximating the universal active element. IEEE Trans Circ Syst-II
47:1160-1169
40. Biolek D, Vrba K, Cajka J, Dostal T (2000) General three-port current conveyor: a useful tool
for network design. J Electr Eng 51:36-39
41. El-Adawy AA, Soliman AM, Elwan HO (2000) A novel fully differential current conveyor and
applications for analog VLSI. IEEE Trans Circ Syst-II 47:306-313
42. Becvar D, Vrba K, Zeman V, Musil V (2000) Novel universal active block: a universal current
conveyor. ISCAS 3:471-474
43. Beevao D, Vrba K (2000) Novel generations of inverting current conveyor using universal
current conveyor. Electron J Eng Tech 3:4
44. Gilbert B (2001) Analog at milepost 2000: a personal perspective. Proc IEEE 89:289-304
45. Takagi S (2001) Analog circuit designs in the last decade and their trends toward the 21st
century. IEICE Trans Fundament E84-A:68-79
46. Gupta SS, Senani R (2001) Comment on
'
CMOS differential difference current conveyors and
their applications
. IEE Proc Circ Devices Syst 148:335-336
47. Arbel AF (2002) Review of research on ASP by the author. IEEE Circ Syst-II 49:599-611
48. Mangelsdorf CW (2002) The changing face of analog IC design. IEICE Trans Fundament
E85-A:282-285
49. Sato T, Wada K, Takagi S, Fujii N (2002) Extension of current conveyor concepts and its
applications. IEICE Trans Fundament E85-A:414-421
50. Kuntman H, Cicekoglu O, Ozoguz S (2002) A modified third generation current conveyor, its
characterization and applications. Frequenz 56:47-54
51. Zeki A, Toker A (2003) The dual-X current conveyor (DXCCII): a new active device for
tunable continuous-time filters. Int J Electron 89:913-923
52. Schmid H (2003) Why
'
Current Mode
does not guarantee good performance. Analog Integr
'
'
Circ Sig Process 35:79-90
53. Alzaher HA, Elwan H, Ismail M (2003) A CMOS fully balanced second-generation current
conveyors. IEEE Trans Circ Syst-II 50:278-287
54. Biolek D, Gubek T, Brno UFV (2004) New circuit elements for current-mode signal
processing. Elektrorevue 28:12
55. Vidal E, Alarcon E, Gilbert B (2004) Up-to-date bibliography of current-mode design. Analog
Integr Circ Sig Process 38:245-262
56. Cajka J, Dostal T, Vrba K (2004) General view on current conveyors. Int J Circ Theor Appl
32:133-138
57. Gilbert B (2004) Current mode, voltage mode or free mode? A few sage suggestions. Analog
Integr Circ Sig Process 38:83-101
58. Cajka J, Vrba K (2004) The voltage conveyor may have in fact found its way into circuit
theory. Int J Electron Commun 58:244-248
59. Gift SJG (2005) The operational conveyor and its application in an accurate current amplifier
with gain-independent bandwidth. Int J Electron 92:33-47
60. Soliman AM (2008) The inverting second generation current conveyors as universal building
blocks. Int J Electron Commun 62:114-121
61. Biolek D, Senani R, Biolkova V, Kolka Z (2008) Active elements for analog signal processing:
classification, review, and new proposals. Radioengineering 17:15-32
62. Horng JW, Hou CL, Chang CM (2008) Multi-input differential current conveyor, CMOS
realisation and application. IET Circ Devices Syst 2:469-475
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