OP279_15 Datasheet, PDF(13/16 Page) Analog Devices – Rail-to-Rail High Output Current Operational Amplifiers

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OP279_15 Datasheet, PDF (13/16 Pages) Analog Devices – Rail-to-Rail High Output Current Operational Amplifiers

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OP179/OP279

Band-pass Configurations

The MFB band-pass filter using an OP179/OP279 section is

shown in Figure 17. This filter provides reasonably stable medium

Q designs for frequencies of up to a few kHz. For best pre-

dictability and stability, operation should be restricted to

applications where the OP179/OP279 has an open-loop gain

in excess of 2Q2 at the filter center frequency.

26.4kâ

(264kâ)

1.4kâ

(1.33kâ)

0.1â®F

OUT

0.1â®F

R = R3

530kâ GIVEN:

Q, F, AND AO (PASSBAND GAIN)

ALPHA = 1/Q, H = AO/Q

PICK A STD C1 VALUE, THEN:

U1B

OP279

C2 = C1

R1 = 1/(H*(2*PI*F*C1))

R2 = 1/(((2*Q) âH)*(2*PI*F*C1))

R3 = Q/(PI*F*C1)

0.1â®F

EXAMPLE: 60Hz, Q = 10,

AO = 10 (OR 1)

AO = 1 FOR '( )' VALUES

Figure 17. Two-Pole, Band-pass Multiple Feedback Filters

Given the band-pass design parameters for Q, F, and pass band

gain AO, the design process is begun by picking a standard value

for C1. Then C2 and resistors R1-R3 are selected as per the

relationships noted. This filter is subject to a wide range of

component values by nature. Practical designs should attempt

to restrict resistances to a 1 kâ¦ to 1 Mâ¦ range, with capacitor

values of 1 ÂµF or less. When needed, dc bias current compensa-

tion is provided by Zb, where R is equal to R3.

Two-Way Loudspeaker Crossover Networks

Active filters are useful in loudspeaker crossover networks for

reasons of small size, relative freedom from parasitic effects,

and the ease of controlling low/high channel drive, plus the con-

trolled driver damping provided by a dedicated amplifier. Both

Sallen-Key (SK) VCVS and multiple-feedback (MFB) filter

architectures are useful in implementing active crossover

networks (see Reference 4, page 14), and the circuit shown in

Figure 18 is a two-way active crossover that combines the advan-

tages of both filter topologies. This active crossover exhibits less

than 0.01% THD+N at output levels of 1 V rms using general

purpose unity gain HP/LP stages. In this two-way example, the

LO signal is a dc-500 Hz LP woofer output, and the HI signal is

the HP (> 500 Hz) tweeter output. U1B forms an MFB LP

section at 500 Hz, while U1A provides an SK HP section, cov-

ering frequencies â¥ 500 Hz.

This crossover network is a Linkwitz-Riley type (see Reference 5,

page 14), with a damping factor or Î± of 2 (also referred to as

âButterworth squaredâ). A hallmark of the Linkwitz-Riley type

of filter is the fact that the summed magnitude response is flat

across the pass band. A necessary condition for this to happen

is the relative signal polarity of the HI output must be inverted

with respect to the LOW outputs. If only SK filter sections were

used, this requires that the connections to one speaker be reversed

on installation. Alternately, with one inverting stage used in the

LO channel, this accomplishes the same effect. In the circuit as

shown, stage U1B is the MFB LP filter, which provides the

necessary polarity inversion. Like the SK sections, it is config-

ured for unity gain and an Î± of 2. The cutoff frequency is 500 Hz,

which complements the SK HP section of U4.

VIN

+VS

TO U1

âVS

0.01â®F

31.6kâ

0.01â®F

31.6kâ

+VS

U1A

3 OP279

âVS

15.8kâ

0.01â®F

0.02â®F

0.1â®F

+5V

100â®F/25V

COM

100â®F/25V

â5V

U1B

OP279

49.9â

500Hz AND UP

49.9â

DC â 500Hz

Figure 18. Two-Way Active Crossover Networks

In the filter sections, component values have been selected for

good balance between reasonable physical/electrical size, and

lowest noise and distortion. DC offset errors can be minimized

by using dc compensation in the feedback and bias paths, ac

bypassed with capacitors for low noise. Also, since the network

input is reactive, it should driven from a directly coupled low

impedance source at VIN.

Figure 19 shows this filter architecture adapted for single-supply

operation from a 5 V dc source, along the lines discussed

previously.

VIN

RIN

100kâ

0.01â®F

CIN

10â®F

31.6kâ

+VS

100kâ

31.6kâ

0.01â®F

31.6kâ

+VS

U1A

3 OP279

49.9â

10â®F

500Hz

AND UP

100kâ

31.6kâ

15.8kâ

0.02â®F

10â®F

0.01â®F

49.9â

10â®F

DC â

500Hz

100kâ

U1B

OP279

+VS

TO U1

0.1â®F

+5V

100â®F/25V

COM

Figure 19. A Single-Supply, Two-Way Active Crossover

REV. G

â13â

▷