Lecture 6-1

Frequency Responses and Active Filter Circuits

• Compensation capacitors and parasitic capacitors will influence the frequency response

• Capacitors are also purposely added to create certain functions; e.g. integrators

• The most common use of energy storage elements in opamp circuits is for filtering

• Inductors are not as often used as capacitors because they are much bulkier and more difficult to integrate on an IC

• The order of the filter depends on the number of energy storage elements that are used

Lecture 6-2

Ideal Filters

H jω( )Vout jω( )Vin jω( )

----------------------= Vout jω( )Vin jω( )

A

0ωH

Pass Stop

ω

|H(jω)|

A

0ωL

Stop Pass

ω

|H(jω)|

A

0ωL

Stop Pass

ω

|H(jω)|

Stop

ωH

A

0ωL

Pass Stop

ω

|H(jω)|

Pass

ωH

Lecture 6-3

Ideal Filters

A

0

ωH ω

|H(jω)|

• We know that a first order filter will not look like an ideal model:

• Higher order filters will attempt to have sharper transitions at the cut-off frequencies, but sometimes at the expense of increased ripple

A

0

ωH ω

|H(jω)|

Lecture 6-4

First-Order Low Pass Filter

• Design for a 3dB cut-off frequency of 3000π (radians/second), a dc gain of 2, and an input impedance of at least 100kΩ

C

R1

vin

vout

R2

Lecture 6-5

First-Order Low Pass Filter

530pF

100k

vin

vout

200k

• Will the frequency dependence of the open loop gain present a problem for this circuit using a 741 opamp?

frequency

e-1 e0 e1 e2 e3 e4 e5 e6 e7

-100dB

0dB

100 dB

200dB

DB(VMOUT/VMIN)

Lecture 6-6

First-Order Low Pass Filter

• SPICE results for magnitude using 741 opamp model

frequencye0 e1 e2 e3 e4 e5

-40

-30

-20

-10

0

10

DB(VMOUT/VMIN)

Lecture 6-7

First-Order Low Pass Filter

• SPICE results for phase using 741 opamp model

frequencye0 e1 e2 e3 e4 e5

80

100

120

140

160

180

PH(VMOUT/VMIN)

Lecture 6-8

First-Order High Pass Filter

• Calculate a transfer function to approximate the cut-off frequency

10kΩ

vin

vout

40kΩ

0.0159µF

Lecture 6-9

First-Order High Pass Filter

10kΩ

vin

vout

40kΩ

0.0159µF

• What is the high frequency gain for this circuit?

Lecture 6-10

First-Order High Pass Filter

• SPICE results for magnitude using 741 opamp model

frequencye0 e1 e2 e3 e4 e5

-50

-40

-30

-20

-10

0

10

20

DB(VMOUT/VMIN)

Lecture 6-11

First-Order High Pass Filter

• Note that the low-pass nature of the opamp makes this high-pass filter a band-pass filter when using a 741-type opamp

frequencye0 e1 e2 e3 e4 e5 e6 e7

-50

-40

-30

-20

-10

0

10

20e0

DB(VMOUT/VMIN)

Lecture 6-12

First-Order High-Pass Filter

• SPICE results for phase using 741 opamp model

• Why the discontinuity?

frequencye0 e1 e2 e3 e4 e5

-200

0.0

200

PH(VMOUT/VMIN)

Lecture 6-13

Band Pass Filter

• Design for a mid-band frequency gain of 5 (volts/volt), and fL=500Hz and fH=5kHz.

R1

vin

vout

R2

C1

C2

Lecture 6-14

Band-Pass Filter

R1

vin

vout

R2

C1

C2

Lecture 6-15

Band Pass Filter

• SPICE results for magnitude using 741 opamp model

frequencye0 e1 e2 e3 e4 e5 e6

-50

-40

-30

-20

-10

0

10

20

DB(VMOUT/VMIN)

Lecture 6-16

Band-Pass Filter

• SPICE results for phase using 741 opamp model

frequencye0 e1 e2 e3 e4 e5 e6

-200

0.0

200

PH(VMOUT/VMIN)

Lecture 6-17

Noninverting Opamp

• Most of the circuits that we’ve seen so far can also be designed in a non-inverting configuration too

R2

R1

Vin

Vo

Lecture 6-18

Other Noninverting Configurations

• But sometimes they are a bit trickier to solve

• What is the transfer function of this circuit? How is it best evaluated?

R4

R3

VoR1

R2

V1

V2

Lecture 6-19

Second-Order Low Pass Filter

• Design for a 3dB cut-off frequency of 3000π (radians/second), a dc gain of 2, and an input impedance of 100kΩ

+ SINVIN C2

1214E-12F+

-

R2100E3Ω

R1100E3Ω

+ -

-15VVC8

+ 15VVC9

741

+

-

C1927E-12F+ -

RA100E3Ω

RB100E3Ω

Suggested configurationand element values from a book

Lecture 6-20

Second-Order Low Pass Filter

• SPICE results for magnitude using 741 opamp model

• Input impedance “magnitude” as a function of frequency

frequencye2 e3 e4 e5 e6 e7

90

100

110

K

VMIN/IMIN

Lecture 6-21

Second-Order Low Pass Filter

• Input impedance “phase” as a function of frequency

frequencye2 e3 e4 e5 e6 e7

-90

-80

-70

-60

-50

-40

-30

-20

-10

0

PH(VMIN/IMIN)

Lecture 6-22

Second-Order Low Pass Filter

• SPICE results for magnitude using 741 opamp model

• Fall-off is sharper for higher frequencies, but 3dB point is at 5.6kHz

frequencye0 e1 e2 e3 e4 e5 e6

-70

-60

-50

-40

-30

-20

-10

0

10

DB(VMOUT)

Lecture 6-23

Second-Order Low Pass Filter

• 3dB cut-off frequency is slightly off from 1.5kHz target

• What parameters do we change to lower it 3dB slightly?

+ SINVIN C2

1214E-12F+

-

R2100E3Ω

R1100E3Ω

+ --15VVC8

+ 15VVC9

741+

-

C1927E-12F+ -

RA100E3Ω

RB100E3Ω

Lecture 6-24

Second-Order Low Pass Filter

• Design for a 3dB cut-off frequency of 3000π (radians/second), a dc gain of 2, and an input impedance of 100kΩ using values determined by pole analysis

+ SINVIN C2

1960E-12F+

-

R2100E3Ω

R1100E3Ω

+ -

-15VVC8

+ 15VVC9

741

+

-

C1900E-12F+ -

RA100E3Ω

RB100E3Ω

Lecture 6-25

Second-Order Low Pass Filter

frequencye0 e1 e2 e3 e4 e5 e6

-80

-70

-60

-50

-40

-30

-20

-10

0

10

DB(VMOUT)

3dB is now at 1.5kHz