Hardware Reference
In-Depth Information
95. Abuelma
atti MT (2000) Comment on active simulation of grounded inductors with CCII+ s
and grounded passive elements. Int J Electron 87:177-181
96. Cicekoglu O (2000) Reply to comment on
'
Active simulation of grounded inductors with
'
. Int J Electron 87(2):183-184
97. Wang HY, Lee CT (2000) Systematic synthesis of R-L and C-D immittances using single
CCIII. Int J Electron 87(3):293-301
98. Fabre A, Saaid O (2000) Phase compensation of ideal inductances based second-generation
current conveyors. Analog Integr Circ Sig Syst 24:153-162
99. Gift SGJ (2001) An enhanced current-mode instrumentation amplifier. IEEE Trans Instrum
Meas 50:85-88
100. Tomita Y, Agu M (2001) A multi-port D-R mutator using CCIIs with current followers. Int J
Electron 88:31-39
101. Ferri G, Guerrini N (2001) High-valued passive elements simulation using low-voltage
low-power current conveyors for fully integrated applications. IEEE Trans Circ Syst-II
48:405-408
102. Cicekoglu O, Toker A, Kuntman H (2001) Universal immittance function simulators using
current conveyors. Comput Electr Eng 27:227-238
103. Minaei S, Cicekoglu O, Kuntman H, Turkoz S (2002) Electronically tunable, active only
floating inductance simulation. Int J Electron 89:905-912
104. Ferri G, Guerrini NC, Diqual M (2003) CCII-based floating inductance simulator with
compensated series resistance. Electron Lett 39:22
105. Arslan E, Cam U, Cicekoglu MO (2003) Novel lossless grounded inductance simulators
employing only a single first generation current conveyors. Frequenz 57:204-206
106. Khan IA, Zaidi MH (2003) A novel ideal floating inductor using translinear conveyors.
Active Passive Electron Comput 26:87-89
107. Gift SJG (2004) New simulated inductor using operational conveyors. Int J Electron
91:477-483
108. Pal K (2004) Floating inductance and FDNR using positive polarity current conveyors.
Active Passive Electron Comput 27:81-83
109. Anand Mohan PV (2005) Floating capacitance simulation using current conveyors. J Circ
Syst Comput 14:123-128
110. Abuelma
CCII+ s and grounded passive elements
'
atti MT, Al-Shahrani SM, Al-Absi MK (2005) Simulation of a mutually coupled
circuit using plus-type CCIIs. Int J Electron 92:49-54
111. Ghallab YH, Badawy W, Kaler VIS, Maundy BJ (2005) A novel current-mode instrumenta-
tion amplifier based on operational floating current conveyor. IEEE Trans Instrum Meas
54:1941-1949
112. Galanis C, Haritantis I (1996) International conference on electronics, circuits and systems
1:65-68
113. Yuce E, Cicekoglu O, Minaei S (2006) Novel floating inductance and FDNR simulators
employing CCII+ s. J Circ Syst Comput 15:75-81
114. Yuce E, Minaei S, Cicekoglu O (2006) Limitations of the simulated inductors based on a
single current conveyors. IEEE Trans Circ Syst-I 53:2860-2867
115. Metin B, Cicekoglu O (2006) A novel floating lossy inductance realization topology with
NICs using current conveyors. IEEE Trans Circ Syst-II 53:483-486
116. Yuce E, Cicekoglu O (2006) The effects of non-idealities and current limitations on the
simulated inductances employing current conveyors. Analog Integr Circ Sig Process
46:103-110
117. Fakhfakh M, Loulou M, Tlelo-Cuautle E (2007) Synthesis of CCIIs and design of simulated
CCII-based floating inductance. IEEE international conference on electronics, circuits and
systems, Marrakech, pp 379-382
118. Yuce E, Cicekoglu O, Minaei S (2006) CCII-based grounded to floating immittance converter
and a floating inductance simulator. Analog Integr Circ Sig Process 46:287-291
119. Yuce E (2006) On the realization of the floating simulators using only grounded passive
components. Analog Integr Circ Sig Process 49:161-166
'
Search WWH ::
Custom Search