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Erschienen in:
The Evolution and the History of Current Conveyors Kapitel lesen Erstes Kapitel lesen

2015 | OriginalPaper | Buchkapitel

6. First, Second and Higher Order Filter Design Using Current Conveyors

verfasst von : Raj Senani, D. R. Bhaskar, A. K. Singh

Erschienen in: Current Conveyors

Verlag: Springer International Publishing

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Abstract

A number of first order, second-order and higher-order active filter configurations, chosen from the vast literature available on this topic, using classical types of CCI and/or CCII, have been discussed and their salient features have been highlighted.

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Vorheriges Kapitel Basic Analog Circuit Building Blocks Using CCs and Application of CCs in Impedance Synthesis
Nächstes Kapitel Realization of Sinusoidal Oscillators Using CCs
Fußnoten
1
Note that this is nothing but the so-called ‘Inverting Current Conveyor’ (ICCII) as later re-introduced by Awad and Soliman; see Sect. 10.2.9 of Chap. 10.
 
Literatur
1.
Higashimura M, Fukui Y (1988) Realization of all-pass networks using a current conveyor. Int J Electron 65:249–250
2.
Higashimura M, Fukui Y (1990) Realization of current mode all-pass networks using a current conveyor. IEEE Trans Circ Syst 37:660–661
3.
Cicekoglu O, Kuntman H, Berk S (1999) All-pass filters using a single current conveyor. Int J Electron 86:947–955
4.
Khan IA, Maheshwari S (2000) Simple first order all-pass section using a single CCII. Int J Electron 87:303–306
5.
Chong CP, Smith KC (1986) Biquadratic filter sections employing a single current conveyor. Electron Lett 22:1162–1164
6.
Metin B, Yuce E, Cicekoglu O (2007) A novel dual output universal filter topology using a single current conveyor. Electr Eng 89:563–567
7.
Toumazou C, Lidgey FJ (1986) Universal active filter using current conveyors. Electron Lett 22:662–664
8.
Higashimura M, Fukui Y (1996) Universal filter using plus-type CCIIs. Electron Lett 32:810–811
9.
Senani R, Singh VK (1995) KHN equivalent biquad using current conveyors. Electron Lett 31:626–628
10.
Horng JW, Hou CL, Chang CM, Chou HP, Lin CT (2006) High input impedance voltage mode universal biquadratic filter with one input and five outputs using current conveyors. Circ Syst Sig Process 25:767–777MATHMathSciNet
11.
Chen HP (2010) Single CCII-based voltage mode universal filter. Analog Integr Circ Sig Process 62:259–262
12.
Horng JW (2004) Voltage-mode universal biquadratic filters using CCIIs. IEICE Trans Fundament 87:406–409
13.
Chang CM, Tu SH (1999) Universal voltage-mode filter with four inputs and one output using two CCII+ s. Int J Electron 86:305–309
14.
Liu SI, Lee JL (1997) Voltage mode universal filters using two current conveyors. Int J Electron 82:145–149
15.
Horng JW, Lee MH, Cheng HC, Chang CW (1997) New CCII based voltage mode universal biquadratic filter. Int J Electron 82:151–155
16.
Horng JW, Tsai CC, Lee MH (1996) Novel universal voltage mode biquad filter with three inputs and one output using only two current conveyors. Int J Electron 80:543–546
17.
Chang CM (1997) Multifunction biquadratic filters using current conveyors. IEEE Trans Circ Syst-II 44:956–958
18.
Ozoguz S, Gunes EO (1996) Universal filter with three input using CCII+. Electron Lett 32:2134–2135
19.
Chang C, Lee MS (1994) Universal voltage mode filter with three inputs and one output using three current conveyors and one voltage follower. Electron Lett 30:2112–2113MathSciNet
20.
Chang CM, Lee MS (1995) Comment: universal voltage mode filter with three inputs and one output using three current conveyors and one voltage follower. Electron Lett 31:353
21.
Horng JW (2004) High input impedance voltage mode universal biquadratic filters with three input using plus-type CCIIs. Int J Electron 91:465–475
22.
Ozoguz S, Acar C (1997) Universal current-mode filter with reduced number of active and passive components. Electron Lett 33:948–949
23.
Abuelma’atti MT, Shabra AM (1996) A novel current conveyor-based universal current-mode filter. Microelectron J 27:471–475
24.
Senani R (1996) A simple approach of deriving single input multiple output current mode biquad filters. Frequenz 50:124–127
25.
Senani R (1992) New current-mode biquad filter. Int J Electron 73:735–742
26.
Chang CM (1993) Universal active current filter with single input and three outputs using CCIIs. Electron Lett 29:1932–1933
27.
Chang CM (1993) Novel universal current-mode filter with single input and three outputs using only five current conveyors. Electron Lett 29:2005–2007
28.
Sun Y, Fidler JK (1994) Versatile active biquad based on second generation current conveyors. Int J Electron 76:91–98
29.
Senani R (1985) Novel higher order active filter design using current conveyors. Electron Lett 21:1055–1057
30.
Ozcan S, Cicekoglu O, Kuntman H (2003) Multi-input single output filter with reduced number of passive elements employing single current conveyor. Comput Electr Eng 29:45–53
31.
Abuelma’atti MT, Tasadduq NA (1999) A novel three inputs and one outputs universal current mode filter using plus type CCIIs. Microelectron J 30:287–292
32.
Abuelma’atti MT, Al-Zaher HA (1998) Novel current conveyor based universal current mode biquad filter with three inputs and one output. Active Passive Elec Comp 20:235–240
33.
Chang CM (1997) Universal active current filter with three inputs and one output using plus type CCIIs. Electron Lett 33:1207–1208
34.
Chang CM, Chien CC, Wang HY (1994) Universal active current filter with three input using current conveyors Part 2. Int J Electron 76:87–89
35.
Kuntman H, Cicekoglu O, Ozcan S (2002) Realization of current mode third order Butterworth filters employing equal valued passive elements and unity gain buffers. Analog Integr Circ Sig Process 30:253–256
36.
Hwang YS, Chen JJ, Li JP (2007) New current mode all pole and elliptic filters employing current conveyors. Electr Eng 89:457–459
37.
Liu SI, Tsao HW, Wu J, Lin TK (1990) MOSFET capacitor filters using unity gain CMOS current conveyors. Electron Lett 26:1430–1431
38.
Senani R (1987) Network transformations for incorporating nonideal simulated immittances in the design of active filters and oscillators. IEE Proc 134:158–166
39.
Hwang YS, Liu SI, Wu DS, Wu YP (1995) Linear transformation all-pole filters based on current conveyors. Int J Electron 79:439–445
40.
Anday F, Gunes O (1992) Realization of nth-order transfer functions using current conveyors. Int J Circ Theor Appl 20:693–696
41.
Soliman AM (1972) Active RC realization of current transfer function using voltage generalized-immittance converters. Int J Electron 33:273–280
42.
Soliman AM (1973) Inductorless realization of an all-pass transistor function using the current conveyor. IEEE Trans Circ Theory 20:80–81
43.
Soliman AM (1973) Another realization of an all-pass or a notch filter using a current conveyor. Int J Electron 35:135–136
44.
Aronhime P (1974) Transfer-function synthesis using a current conveyor. IEEE Trans Circ Syst 21:312–313
45.
Gopal K (1974) Comment on ‘Inductorless realization of an All pass transfer function using the current conveyor’. IEEE Trans Circ Syst 21:704–705
46.
Naimpally SV (1975) Comments on “Transfer-function synthesis using a current conveyor”. IEEE Trans Circ Syst 22:960
47.
Soliman AM (1977) Two novel active RC canonic band pass networks using the current conveyor. Int J Electron 42:49–54
48.
Nandi R (1978) Equal valued earthed-capacitor realisation of a third-order low pass Butterworth characteristic using current conveyors. Electron Lett 14:699–700
49.
Stephenson FW, Davies JD (1979) Simplified design procedures for a third-order system using current conveyors. Electron Lett 15:215–216
50.
Davies JD, Stephenson FW (1980) Sensitivity optimization of active filters containing current conveyors and controlled sources. Int J Electron 48:283–289
51.
Rathore TS (1980) Active complementary networks. IEEE Trans Circ Syst 27:1278–1279
52.
Pal K (1981) Realization of current conveyor all-pass networks. Int J Electron 50:165–168
53.
Higashimura M, Ishida M, Hara M, Fukui Y (1988) Realization of biquadratic transfer function using single current conveyor. Trans IEICE J71-A: 228–234
54.
Tek H, Anday F (1989) Voltage transfer function synthesis using current conveyors. Electron Lett 25:1552–1553
55.
Roberts GW, Sedra AS (1989) All current-mode frequency selective circuits. Electron Lett 25:759–761
56.
Fabre A, Martin F, Hanafi M (1990) Current mode all pass/notch and band pass filters with reduced sensitivities. Electron Lett 26:1495–1496
57.
Aronhime P, Nelson D, Adams C (1990) Applications of a first-generation current conveyor in current-mode circuits. Electron Lett 26:1456–1457
58.
Liu SI, Tsao HW, Wu J (1990) Cascadable current-mode single CCII biquads. Electron Lett 26:2005–2006
59.
Sagbas M, Koksal M (2007) Voltage-mode three-input single-output multifunction filters employing minimum number of components. Frequenz 61:87–93
60.
Aronhime P, Dinwiddie A (1991) Biquadratic current-mode filters using a single CCI. Int J Electron 70:1063–1071
61.
Higashimura M (1991) Current-mode transfer function using CC IIs with grounded passive elements. IEICE Trans 74:1017–1019
62.
Chang CM (1991) Current mode all pass/notch and band pass filter using single CCII. Electron Lett 27:1812–1813
63.
Higashimura M (1991) Realization of voltage-mode biquads using CCIIs. Electron Lett 27:1345–1346
64.
Liu SI, Tsao HW (1991) New configurations for single CCII biquads. Int J Electron 70:609–622
65.
Liu SI, Tsao HW, Wu J (1991) CCII-based continuous-time filters with reduced gain-bandwidth sensitivity. IEE Proc Pt-G 138:210–216
66.
Chang CM, Chen PC (1991) Realization of current-mode transfer function using second-generation current conveyors. Int J Electron 71:809–815
67.
Alami M, Fabre A (1991) Insensitive current-mode band pass filter implemented from two current conveyors. Electron Lett 27:897–899
68.
Chang CM (1991) Universal active current filters using single second-generation current conveyor. Electron Lett 27:1614–1417
69.
Liu SI, Tsao HW (1991) The single CCII biquads with high-input impedance. IEEE Trans Circ Syst 38:456–461
70.
Liu SI, Kuo JH, Tsay JH (1992) New CCII-based current-mode biquadratic filters. Int J Electron 72:243–252
71.
Fabre A, Houle JL (1992) Voltage-mode and current-mode Sallen-Key implementation based on translinear conveyors. IEE Proc Pt-G 139:491–497
72.
Hou CL, Wu YP (1992) New methods of synthesizing transfer functions by applying CCIIs. Int J Electron 72:119–128
73.
Higashimura M (1992) A novel configuration for voltage-mode biquads using a single current conveyor. Microelectron J 23:359–362
74.
Chang CM, Chien CC, Wang HY (1993) Universal active current filters using single second-generation current conveyor. Electron Lett 29:1159–1160
75.
Chang CM (1993) Current-mode low pass, band pass and high pass biquads using two CCIIs. Electron Lett 29:2020–2021
76.
Abuelma’atti MT (1993) New current-mode-active filters employing current conveyors. Int J Circ Theor Appl 21:93–99
77.
Svoboda JA (1994) Comparison of RC op-amp and RC current conveyor filters. Int J Electron 76:615–626
78.
Soliman AM (1994) Kerwin-Huelsman-Newcomb circuit using current conveyors. Electron Lett 30:2019–2020
79.
Fabre A, Dayoub F, Duruisseau L, Kamoun M (1994) High input impedance insensitive second-order filters implemented from current conveyors. IEEE Trans Circ Syst-I 41:918–921
80.
Wu DS, Hwang YS, Liu SI, Wu YP (1994) New multifunction filter using an inverting CCII and a voltage follower. Electron Lett 30:551–552
81.
Nandi R (1994) Insensitive current mode realization of third-order Butterworth characteristic using current conveyors. IEEE Trans Circ Syst-I 41:925–927
82.
Gunes EO, Anday F (1995) Realization of nth-order voltage transfer function using CCII+. Electron Lett 31:1022–1023
83.
Soliman AM (1995) Current conveyors steer universal filter novel arrangement delivers low pass, band pass, and high pass response, inverting and non-inverting. IEEE Circ Devices Mag 11:45–46
84.
Anandamohan PV (1995) New current mode biquad on Friend-Deliyannis active RC biquad. IEEE Trans Circ Syst-II 42:225–228
85.
Abuelma’atti MT, Quddus A (1995) Programmable current-conveyor-based voltage mode filters with single input and five outputs. Active Passive Electron Comp 18:273–278
86.
Liu SI, Chen JJ, Hwang YS (1995) New current mode biquad filters using current followers. IEEE Trans Circ Syst-I 42:380–383
87.
Fabre A, Alami M (1995) Universal current mode biquad implemented from two second generation current conveyors. IEEE Trans Circ Syst-I 42:383–385
88.
Celma S, Sabadell J, Martinez P (1995) Universal filter using unity-gain cells. Electron Lett 31(21):1817–1818
89.
Acar C, Ozoguz S (1996) High-order voltage transfer function synthesis using CCII+ based unity gain current amplifiers. Electron Lett 32:2030–2031
90.
Acar C (1996) Nth-order all pass voltage transfer function synthesis using CCII+ s: signal-flow graph approach. Electron Lett 32:727–729
91.
Acar C (1996) Nth-order low pass voltage transfer function synthesis using CCII+ s: signal-flow graph approach. Electron Lett 32:159–160
92.
Soliman AM (1996) New inverting-non-inverting band pass and low pass biquad circuit using current conveyors. Int J Electron 81:577–583
93.
Vrba K, Cajka J, Zeman V (1996) RC-active N-th order low pass filter. J Electr Eng 47:257–259
94.
Nakai K, Yamamoto G, Nakamura T (1996) A configuration of state variable biquad filters using current conveyors. IEICE Trans Fundament E-79:639–641
95.
Abuelma’atti MT, Quddus A (1996) Programmable voltage-mode multifunction filter using two current conveyors and one operational transconductance amplifier. Active Passive Electron Comp 19:133–138
96.
Nandi R (1996) Precise insensitive current-mode third-order low pass Butterworth characteristics. IEE Proc Circ Devices Syst 143:223–224MATH
97.
Abuelma’atti MT, Al- Qahtani MA (1996) Current mode universal filters using unity-gain cells. Electron Lett 32:1077–1078
98.
Celma S, Martinez PA, Sabadell J (1996) A transformation method for equivalent infinite-gain Op-amp to unity-gain CCII networks. IEEE Trans Circ Syst-I 43:61–63
99.
Acar C, Kuntman HK (1996) Limitations on input signal level in current-mode active-RC filters using CCIIs. Electron Lett 32:1461–1462
100.
Soliman AM (1996) Comment on ‘The single CC II biquads with high-input impedance’. IEEE Trans Circ Syst-I 43(1):65
101.
Fabre A, Amrani H, Saaid O (1996) Current-mode band-pass filters with Q-magnification. IEEE Trans Circ Syst-II 43:839–842
102.
Cajka J, Lindovsky D (1997) Universal RC-active networks using CCII+. J Electr Eng 48:98–100
103.
Soliman AM (1997) Theorems relating to port interchange in current mode CCII circuits. Int J Electron 82:585–604
104.
Acar C (1997) On the realization of current-mode filters using second-generation current conveyors. Int J Circ Theor Appl 25:229–233
105.
Zhang X, Kambayashi N, Shinada Y (1997) A realization of active current-mode resonator with complex coefficients using CCIIs. IEICE Trans Fundament 2:413–415
106.
Lata ZJ, Aronhime PB (1997) Cascadable current-mode biquads. Analog Integr Circ Sig Process 13:275–284
107.
Cajka J, Dostal T, Vrba K (1997) Realization of Nth-order voltage transfer function using current conveyors CCII. Radioengineering 6:22–25
108.
Vrba K, Cajka J (1997) High-order one–port elements for low pass filter realization. J Electr Eng 48:31–34
109.
Soliman AM (1997) Generation of current conveyor-based all-pass filter from op-amp based circuits. IEEE Trans Circ Syst-II 44:324–330
110.
Cajka J, Vrba K, Lindovsky D (1997) Network function synthesis using current conveyors. J Electr Eng 48:209–211
111.
Hou CL, Wu JS (1997) Universal cascadable current-mode biquad using only four CCIIs. Int J Electron 82:125–129
112.
Gunes ECEO, Anday F (1997) Realization of voltage and current-mode transfer functions using unity-gain cells. Int J Electron 83:209–213
113.
Papazoglou CA, Karybakas CA (1997) Noninteracting electronically tunable CCII-based current mode biquadratic filters. IEE Proc Circ Devices Syst 144:178–184
114.
Abuelma’atti MT, Farooqui AA (1998) Universal current-conveyors-based current-mode filters with single input and three outputs. Active Passive Electron Comp 20:195–200
115.
Abuelma’atti MT (1998) Programmable current-mode universal active filters employing current conveyors. Active Passive Electron Comp 21:221–230
116.
Cabeza R, Carlosena A (1998) A cautionary note on stability of current conveyor based circuits. Int J Circ Theor Appl 26:215–218
117.
Soliman AM (1998) Current conveyor filters: classification and review. Microelectron J 29:133–149
118.
Soliman AM (1998) Generation of CCII and CFOA filters from passive RLC filters. Int J Electron 85:293–312
119.
Horng JW (1999) Inverting and/or non-inverting biquad circuit using second-generation current conveyors. Int J Electron 86:297–303
120.
Karybakas CA, Papazoglou CA (1999) Low-sensitive CCII-based biquadratic filters offering electronic frequency shifting. IEEE Trans Circ Syst-II 46:527–539
121.
Cicekoglu O (1999) Comments on ‘Multifunction biquadratic filters using current conveyors’. IEEE Trans Circ Syst-II 46:658–659
122.
Bhaskar DR, Sharma VK, Monis M, Rizvi SMI (1999) New current-mode universal biquad filter. Microelectron J 30:837–839
123.
Toker A, Ozoguz S (2000) Insensitive current-mode universal filter using dual output current conveyors. Int J Electron 87:667–674
124.
Abuelma’atti MT, Tasadduq NA (2000) Current-mode low pass, band pass and high pass filter using CCII+ s. Frequenz 54:162–164
125.
Toker A, Cicekoglu O, Ozcan S, Kuntman H (2001) High-output-impedance transadmittance-type continuous-time multifunction filter with minimum active elements. Int J Electron 88:1085–1091
126.
Horng JW (2003) High input impedance voltage-mode universal biquadratic filter using two OTAs and one CCII. Int J Electron 90:185–191
127.
Saraswat R, Pal K, Rana S (2003) Novel grounded capacitor all-pass and notch filters using current conveyors and differential amplifier. Active Passive Electron Comp 26:167–170
128.
Aksoy M, Ozcan S, Cicekoglu O, Kuntman H (2003) High output impedance current-mode third-order Butterworth filter topologies employing unity gain voltage buffers and equal-valued passive components. Int J Electron 90:589–598
129.
Pal K, Rana S (2004) Some new first-order all-pass realizations using CCII. Active Passive Electron Comp 27:91–94
130.
Horng JW, Tang HW, Wen YH (2005) Voltage-mode high input impedance inverting and/or non-inverting high pass, band pass and low pass filers using three CCIIs. J Active Passive Electron Devices 1:145–158
131.
Hayat M, Kumar U (2005) Novel variable current gain active filter using current conveyors. J Active Passive Electron Devices 1:91–96
132.
Kumar P, Pal K (2005) Variable Q all-pass, notch and band-pass filters using single CCUU. Frequenz 59:9–10
133.
Pandey N, Paul SK, Bhattacharyya A, Jain SB (2006) A new mixed mode biquad using reduced number of active and passive elements. IEICE Electron Express 6:115–121
134.
Minaei S, Goknar IC, Cicekoglu O (2006) A new differential configuration suitable for realization of high CMRR all-pass/notch filters. Electr Eng 88:317–326
135.
Kumar P, Pal K (2006) High input impedance band pass, all pass and notch filters using two CCIIs. HAIT J Sci Eng A 3:2–13
136.
Khan IQ, Khan MR, Afzal N (2006) Digitally programmable multifunctional current mode filter using CCIIs. J Active Passive Electron Devices 1:213–220
137.
Dostal T, Axman V (2007) Biquads based on single negative impedance converter implemented by classical current conveyor. Radioengineering 16:96–102
138.
Kumar P, Pal K, Rana S (2008) High input impedance universal biquadratic filters using current conveyors. J Active Passive Electron Devices 3:17–27
139.
Kumar P, Pal K (2008) Universal biquadratic filter using a single current conveyor. J Active Passive Electron Devices 3:7–16
140.
Yuce E, Minaei S (2008) Signal limitations of the current-mode filters employing current conveyors. Int J Electron Commun (AEU) 62:193–198
141.
Soliman AM (2009) Current mode universal filters with grounded passive elements filters with grounded passive elements and using single outputs current conveyors. J Active Passive Electron Devices 4:55–62
142.
Soliman AM (1998) Equal-R, Equal-C current mode Butterworth lowpass filters. IEICE Trans Fundament 2:340–342
143.
Weng RM, Lai JR, Lee MH (2000) New universal biquad filters using only two unity-gain cells. Int J Electron 87:57–61
144.
Metin B, Pal K, Cicekoglu O (2012) A new approach for high-input impedance in voltage mode filters using first-generation current conveyor in place of second-generation current conveyor. Int J Electron 99:131–139
145.
Hwang YS, Hung PT, Chen W, Liu SI (2002) CCII-based linear transformation elliptic filters. Int J Electron 89:123–133
146.
Ozoguz S, Toker A, Cicekoglu O (1998) High output impedance current mode multifunction filter with minimum number of active and reduced number of passive elements. Electron Lett 34:1807–1809
147.
Soliman AM (2008) Current mode universal filters using current conveyors: classification and review. Circ Syst Sig Process 27:405–427MathSciNet
148.
Soliman AM (2008) History and progress of the Tow-Thomas Bi-quadratic filter. Part I. Generation and op-amp realizations. J Circ Syst Comput 17:33–54
149.
Soliman AM (2008) History and progress of the Tow-Thomas biquadratic filter Part II: OTRA, CCII, and DVCC realizations. J Circ Syst Comput 17:797–826
150.
Soliman AM (2008) History and progress of the Kerwin-Huelsman Newcomb filter: generation and op-amp realizations. J Circ Syst Comput 17:637–658
151.
Metin B, Toker A, Terzioglu H, Cicekoglu O (2003) A new all-pass section for high performance signal processing with a single CCII-. Frequenz 57:11–12
152.
Singh VK, Senani R (1990) New multifunction active filter configuration employing current. Electron Lett 26:1814–1815
153.
Higashimura M, Fukui Y (1988) Realization of all-pass and notch filter using a single current conveyor. Int J Electron 65:823–828
154.
Hou CL, Wu YP, Liu SI (1991) New configuration for single-CCII first order and biquadratic current-mode filters. Int J Electron 71:637–644
155.
Khan IA, Zaid MH (2000) Multifunctional translinear-C current mode filter. Int J Electron 87:1047–1051
156.
Horng JW (2005) Current conveyors based all pass filters and quadrature oscillators employing grounded capacitors and resistors. Comput Electr Eng 31:81–92MATH
157.
Senani R (1994) Two ICs make biquad filter. Circuit ideas, electronics and wireless world. Reed Business Publishing Ltd. UK, p 922
158.
Fabre A, Alam M (1993) Insensitive current mode notch filter implemented form translinear conveyors. Int J Electron 74:735–739
159.
Roberts GW, Sedra AS (1992) A general class of current amplifier-based biquadratic filter circuits. IEEE Trans Circ Syst-I 39:257–263MATH
160.
Hassan TM, Mahmoud SA (2009) Fully-programmable universal filer with independent gain –ω0-Q control based on new digitally programmable CMOS CCII. J Circ Syst Comput 18:875–897
161.
Cicekoglu O, Ozcan S, Kuntman H (1999) Insensitive multifunction filter implemented with current conveyors and only grounded passive elements. Frequenz 53:158–160
162.
Ozoguz S, Toker A, Cicekoglu O (1999) New current mode universal filters using only four (CCII+)s. Microelectron J 30:255–258
163.
Horng JW, Lay JR, Chang CW, Lee MH (1997) High input impedance voltage mode multifunction filters using plus-type CCIIs. Electron Lett 33:472–473
164.
Svoboda JA (1994) Transfer function synthesis using current conveyors. Int J Electron 76:611–614
165.
Horng JW, Hou CL, Chang CM, Chung WY, Liu HL, Lin CT (2006) High output impedance current-mode first order all pass networks with four grounded components and two CCIIs. Int J Electron 93:613–621
166.
Horng JW (2010) Voltage/current mode universal biquadratic filter using single CCII+. Indian J Pure Appl Phys 48:149–756
167.
Kerwin W, Huelsman L, Newcomb R (1967) State variable synthesis for insensitive integrated circuit transfer functions. IEEE J Solid State Circ 2:87–92
168.
Thomas L (1971) The biquad Part-I – some practical design considerations. IEEE Trans Circ Theor 18:350–357
169.
Tow J (1969) A step by step active filter design. IEEE Spectrum 6:64–68
170.
Akerberg D, Mossberg K (1974) A versatile active RC building block with inherent compensation for the finite bandwidth of the amplifier. IEEE Trans Circ Syst 21:75–78
Metadaten
Titel
First, Second and Higher Order Filter Design Using Current Conveyors
verfasst von
Raj Senani
D. R. Bhaskar
A. K. Singh
Copyright-Jahr
2015
Buch
Current Conveyors

Print ISBN: 978-3-319-08683-5

Electronic ISBN: 978-3-319-08684-2

Copyright-Jahr: 2015

DOI
https://doi.org/10.1007/978-3-319-08684-2_6

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