Clamping circuits|Dept of ECE| ANITS

ANIL NEERUKONDA INSTITUTE OF TECHNOLOGY & SCIENCES(A)
Department of Electronics and Communication Engineering
ECE 216 Electronic circuits and Analysis-I
➢Academic year : 2020-21
➢Class & Section : 2/4 ECE-C
➢Name of the Faculty : Mr.D.Anil Prasad
ANIL PRASAD DADI/DEPT OF ECE/ANITS

Non Linear Wave shaping circuits
Clamping circuits

Clamping circuits
• The circuit which is used to add DC level as per requirement in
the output of the AC signal.
• The clamper circuit is also called as DC restorer or DC inserter

Clamping circuits
Types of Clamping circuits:
1. Positive clamper
2. Negative clamper

-Vm
Positive Clamper circuit
Positive
clamper
t0
Vm
V0
t0
Vm
2 Vm
Vi
V0=Vi +Vm

Negative Clamper circuit
Negative
clamper
t0
Vm
-Vm
V0
t0
Vm
2 Vm
Vi
V0=Vi -Vm
-Vm
-2 Vm

Analysis of Positive clamper circuit
using
ideal diode model

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
RL
VC=0
-
+
-
V0Vi
VC(0
-)=0=VC(0+) Capacitor is initially uncharged
+
-
Vi

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
RL
VC=0
-
+
-
V0Vi
0<t<T/4
VC(0
Diode is reverse biased

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
RL
C
-
+
-
V0Vi
𝑉𝑐
𝑇
4
−
= 𝑉𝑐
𝑇
4
+
=0V
τ=RthC=RLC
RLC>>T, Time period of input signal
0<t<T/4

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
0<t<T/4
RL
VC=0
-
+
-
V0Vi
V0=Vi

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
T/4<t<T/2
RL
VC=0
-
+
-
V0Vi
+
-
Vi
𝑉𝑐
𝑇
4
−
= 𝑉𝑐
𝑇
4
+
=0V

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
RL
VC=0
-
+
-
V0Vi
T/4<t<T/2 Diode is reverse biased

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
RL
C
-
+
-
V0Vi
𝑉𝑐
𝑇
2
−
= 𝑉𝑐
𝑇
2
+
=0V
τ=RthC=RLC
T/4<t<T/2

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
T/4<t<T/2
RL
VC=0
-
+
-
V0Vi
V0=Vi

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
T/2<t<3T/4
RL
VC=0
-
+
-
V0Vi
+
-
Vi
𝑉𝑐
𝑇
2
−
= 𝑉𝑐
𝑇
2
+
=0V

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
T/2<t<3T/4
RL
-
+
-
V0Vi
i
VC
+-
τ=RthC=0
VC= -Vi 𝑉𝑐
3𝑇
4
−
= 𝑉𝑐
3𝑇
4
+
=+Vm
Diode is forward biased

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
T/2<t<3T/4
RL
-
+
-
V0Vi
i
VC
+-
V0=0

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
3T/4<t<T
RL
-
+
-
V0Vi
VC
+-
𝑉𝑐
3𝑇
4
−
= 𝑉𝑐
3𝑇
4
+
=+Vm
V0=VD=VC+Vi VD =Vm+Vi
+
-
VD
Let Vm=10V
10-9.9
10-9.8
….

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
tT
3𝑇
4
3T/4<t<T
RL
-
+
-
V0Vi
Vm
+-
V0=Vm+Vi ANIL PRASAD DADI/DEPT OF ECE/ANITS
2Vm
𝑇
4
𝑇
2
T
τ=RthC=RLC

Problem #1(Assume ideal diode)

Analysis of Negative clamper circuit
using
ideal diode model

Vi
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
0<t<T/4
VC(0
+
RL
VC=0
-
+
-
Vi
+
-

RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
0<t<T/4
VC(0
+
RL
-
+
-
Vi
-VC+
i

-
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
0<t<T/4
+
RL
VC
-
+
-
Vi
i
+
τ=RthC=0
𝑉𝑐
𝑇
4
−
= 𝑉𝑐
𝑇
4
+
=+Vm
VC= Vi

-
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
0<t<T/4
+
RL
VC
-
+
-
Vi
i
+V0=0

VD
-
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
T/4<t<T/2
+
RL
VC
-
+
-
Vi
+𝑉𝑐
𝑇
4
−
= 𝑉𝑐
𝑇
4
+
=+Vm
VD= -VC+Vi
+
-
V0
Let Vm=10V
-10+9.9
-10+9.8
….
VD= -Vm+Vi

-
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
T/4<t<T/2
+
RL
Vm
-
+
-
Vi
+
V0
V0= Vi - Vm
𝑇
4
τ=RthC=RLC

using
diode equivalent resistance
model

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
RL
VC=0
-
+
-
V0Vi
0<t<T/4
Rr
Diode is in Reverse bias

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
RL
-
+
-
V0Vi
0<t<T/4
Rr
𝑉𝑐
𝑇
4
−
= 𝑉𝑐
𝑇
4
+
=0V
τ=RthC=(Rr||RL)C
τ=RLC

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
0<t<T/4
RL
-
+
-
V0Vi
V0=Vi
Rr

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
T/4<t<T/2
RL
-
+
-
V0Vi
+
-
Vi
𝑉𝑐
𝑇
4
−
= 𝑉𝑐
𝑇
4
+
=0V

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
RL
-
+
-
V0Vi
T/4<t<T/2
Rr
Diode is in Reverse bias

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
RL
-
+
-
V0Vi
T/4<t<T/2
Rr
𝑉𝑐
𝑇
2
−
= 𝑉𝑐
𝑇
2
+
=0V
τ=RthC=(Rr||RL)C τ=RLC

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
T/4<t<T/2
RL
-
+
-
V0Vi
V0=Vi
Rr

Rf
+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
T/2<t<3T/4
RL
-
+
-
V0Vi
i
VC
+-

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
T/2<t<3T/4
RL
-
+
-
V0Vi
i
VC
+-
VC= -Vi 𝑉𝑐
3𝑇
4
−
= 𝑉𝑐
3𝑇
4
+
=+Vm
Rf
RfC<<T, Time period of input signal
τ=RthC=(Rf||RL)C=RfC

+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
T/2<t<3T/4
RL
-
+
-
V0Vi
i
VC
+-
V0 ≈ 0
Rf

+
RL
C
+
-
+
-
V0Vi
3T/4<t<T
RL
-
+
-
V0Vi
Vm
+-
V0=Vm+Vi ANIL PRASAD DADI/DEPT OF ECE/ANITS
Rr
Vi(t)
tT
3𝑇
4
2Vm
𝑇
4
𝑇
2
T

using
diode equivalent resistance
model

Vi
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
VC(0
+
RL
VC=0
-
+
-
Vi
+
-

RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
0<t<T/4
VC(0
+
RL
-
+
-
Vi
RfDiode is forward biased

-
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
0<t<T/4
+
RL
VC
-
+
-
Vi
i
+
𝑉𝑐
𝑇
4
−
= 𝑉𝑐
𝑇
4
+
=+VmVC= Vi
Rf
τ=RthC=(Rf||RL)C=RfC
RfC<<T, Time period of input signal

-
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
0<t<T/4
+
RL
VC
-
+
-
Vi
i
+V0 ≈ 0
Rf

VD
-
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
T/4<t<T/2
+
RL
VC
-
+
-
Vi
+𝑉𝑐
𝑇
4
−
= 𝑉𝑐
𝑇
4
+
=+Vm
VD= -VC+Vi
+
-
V0
Let Vm=10V
-10+9.9
-10+9.8
….
VD= -Vm+Vi

-
RL
C
+
-
+
-
V0Vi
T/4<t<T/2
+
RL
Vm
-
+
-
Vi
+
V0
V0= Vi - Vm
Rr
Diode is reversed biased
Vi(t)
t𝑇
2
T𝑇
4
𝑇
4
3𝑇
4
-2Vm

using
Constant voltage drop model

-
+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
RL
VC=0
-
+
-
V0Vi
VC(0
+
Vi
Vγ

-
+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
0<t<T/4
RL
VC=0
-
+
-
V0Vi
VC(0
+
Vi
VγDiode is reverse biased

-
+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
RL
VC=0
-
+
-
V0Vi
+
Vi
Vγ
𝑉𝑐
𝑇
4
−
= 𝑉𝑐
𝑇
4
+
=0V
τ=RthC=RLC
0<t<T/4

-
+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
RL
VC=0
-
+
-
V0Vi
+
Vi
Vγ
0<t<T/4 V0=Vi

-
+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
T/4<t<T/2
RL
VC=0
-
+
-
V0Vi
𝑉𝑐
𝑇
4
−
= 𝑉𝑐
𝑇
4
+
=0V
Vγ
+
Vi

-
+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
T/4<t<T/2
RL
VC=0
-
+
-
V0Vi
Vγ
+
Vi

-
+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
T/4<t<T/2
RL
VC=0
-
+
-
V0Vi
Vγ
+
Vi
𝑉𝑐
𝑇
2
−
= 𝑉𝑐
𝑇
2
+
=0V
τ=RthC=RLC

-
+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
T/4<t<T/2
RL
VC=0
-
+
-
V0Vi
Vγ
+
Vi
V0=Vi

-
+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
RL
VC=0
-
+
-
V0Vi
Vγ
+
Vi
T/2<t<3T/4 𝑉𝑐
𝑇
2
−
= 𝑉𝑐
𝑇
2
+
=0V

-
+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
RL
VC
-
+
-
V0Vi
Vγ
+
Vi
T/2<t<3T/4
τ=RthC=0
VC +Vi +Vγ=0
𝑉𝑐
3𝑇
4
−
= 𝑉𝑐
3𝑇
4
+
= Vm -Vγ
-
i
Diode is in forward bias for Vi>- Vγ
VC =-(Vi +Vγ)

-
+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
RL
VC
-
+
-
V0Vi
Vγ
+
Vi
T/2<t<3T/4
-
i
V0= -Vγ

Vγ
+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
3T/4<t<T
RL
-
+
-
V0Vi
VC
+-
𝑉𝑐
3𝑇
4
−
= 𝑉𝑐
3𝑇
4
+
= Vm -Vγ VC+Vi+Vγ-VD=0
VD=VC+ Vγ +Vi Let Vm=10V
+
-
VD
10-9.9
10-9.8
….
VD= Vm -Vγ + Vγ +Vi
VD= Vm +Vi

Vγ
+
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t
𝑇
2
T𝑇
4
3𝑇
4
3T/4<t<T
RL
-
+
-
V0Vi
Vm -Vγ
+-
V0=VC+Vi V0= Vm -Vγ +Vi
2Vm- Vγ
τ=RthC=RLC

using
Constant voltage drop model

-
Vi
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
VC(0
+
RL
VC=0
-
+
-
Vi
+
Vγ

Vγ
-
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
0<t<T/4
VC(0
+
RL
VC=0
-
+
-
Vi
+
Diode is forward biased for Vi> Vγ

VC
Vγ
-
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
+
RL
-
+
-
Vi
0<t<T/4 τ=RthC=0
𝑉𝑐
𝑇
4
−
= 𝑉𝑐
𝑇
4
+
=Vm –Vγ
VC-Vi +Vγ=0 VC=Vi –Vγ

VC
Vγ
-
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
+
RL
-
+
-
Vi
0<t<T/4 V0=Vγ

-
VD
-
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t𝑇
2
T𝑇
4
3𝑇
4
T/4<t<T/2
+
RL
VC
-
+
-
Vi
+𝑉𝑐
𝑇
4
−
= 𝑉𝑐
𝑇
4
+
= Vm –Vγ
-VC+Vi –Vγ-VD=0
+
V0
Let Vm=10V
VγVD =-VC –Vγ +Vi -10+9.9
-10+9.8
….VD =-Vm +Vγ–Vγ +Vi
VD =-Vm +Vi

-
RL
C
+
-
+
-
Vi(t)
0
V0Vi
t
𝑇
2
T
3𝑇
4
T/4<t<T/2
+
RL
VC
-
+
-
Vi
+
V0
Vγ
V0= Vi - VC
V0= Vi - Vm +Vγ
𝑇
4
-2Vm+Vγ
τ=RthC=RLC

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Clamping circuits|Dept of ECE| ANITS

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