TDA7454 Datasheet, PDF(8/13 Page) STMicroelectronics – 4 x 35W HIGH EFFICIENCY QUAD BRIDGE CAR RADIO AMPLIFIER

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TDA7454 Datasheet, PDF (8/13 Pages) STMicroelectronics – 4 x 35W HIGH EFFICIENCY QUAD BRIDGE CAR RADIO AMPLIFIER

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TDA7454

OPERATING PRINCIPLE.

Thanks to its unique operating principle, the

TDA7454 obtains a substantial reduction of power

dissipation from traditional class-AB amplifiers

without being affected by the massive radiation

effects and complex circuitry normally associated

with class-D solutions.

Its is composed of 8 amplifier blocks, making up

4 bridge-equivalent channels. Half of this struc-

ture is drafted in fig 15. These blocks continu-

ously change their connections during every sin-

gle signal event, according to the instantaneous

power demand. This means that at low volumes

(output power steadily lower than 2.5 W) the

TDA7454 acts as a Single Ended amplifier, condi-

tion where block âCâ remains disabled and the

block âDâ behaves like a buffer, which, by furnish-

ing the correct DC biasing (half-Vcc) to each pair

of speakers, eliminate the needs of otherwise re-

quired output-decoupling capacitors. At the same

time, SW1 keeps closed. thus ensuring a com-

mon biasing point for L-R front / L-R rear speak-

ers couples. As a result, the equivalent circuit be-

comes that of fig. 16.

The internal switches (SW1) are high-speed, dis-

sipation-free power MOS types, whose realization

has been made possible by the ST- exclusive By-

polar-CMOS-DMOS mixed technology process

(BCD). From fig. 16 it can be observed that âAâ

and âBâ amplifiers work in phase opposition. Sup-

posing their output have the same signal (equal

shape/amplitude), the current sourced by âBâ will

be entirely sunk by âAâ, while no current will flow

into âDâ, causing no power dissipation in the lat-

ter.

âAâ and âBâ are practically configured as a bridge

whose load is constituted by Ra + Rb (= 8 Ohm, if

4 Ohm speakers are used), with considerable ad-

vantages in terms of power dissipation. Designat-

ing âAâ and âBâ for the reproduction of either

FRONT or REAR sections of the same channel

(LEFT or RIGHT), keeping the fader in centre po-

sition (same amplitude for FRONT and REAR

sections) and using the same speakers, as it hap-

pens during most of the time, will transpose this

best-case dissipation condition into practical ap-

plications.

To fully take advantage of the TDA7454âs low-dis-

sipation feature, it is then especially important to

adopt some criteria in the channels assignment,

using the schematic of fig. 1 as a reference.

When the power demand increases to more than

2.5 W, all the blocks will operate as amplifiers,

SW1 is opened, leading to the seemingly conven-

tional bridge configuration of fig. 17.

The efficiency enhancement is based upon the

concept that the average output power during the

reproduction of normal music/speech programs

will stand anywhere between 10 % and 15 % of

the rated power (@ THD= 10 %) that the amplifier

can deliver. This holds true even at high volumes

and frequent clipping occurrence.

Applied to the TDA7454 (rated power= 25 W),

this will result into an average output level of 2.5

- 3 W in sine-wave operation, region where the

dissipated power is about 50 % less than that of a

traditional amplifier of equivalent power class (see

TDA7454 vs. CLASS-AB characteristics, fig. 18).

Equally favourable is the case shown by fig. 19,

when gaussian-distributed signal amplitudes,

which best simulates the amplifierâs real working

conditions, are used.

APPLICATION HINTS (ref. to the circuit of fig. 1)

STAND-BY and MUTING (pins 4 & 22)

Both STAND-BY and MUTING pins are CMOS-

compatible. The current sunk by each of them is

about 1 ÂµA. For pop prevention it is essential that

during TURN ON/OFF sequences the muting be

preventively inserted before making stand-by

transitions. But, if for any reason, either muting or

stand-by are not used, they have to be connected

to Vcc through a 100 Kohm (minimum) resis-

tance.

The R-C networks values in fig. 1 (R1-C6 and R2-

C7) are meant to be the minimum-necessary for

obtaining the lowest pop levels possible. Any re-

ductions (especially for R2-C7) will inevitably im-

pair this parameter.

SVR (pin 10)

The duty of the SVR capacitor (C5) is double: as-

suring adequate supply-ripple rejection and con-

trolling turn ON/OFF operations. Its indicated

value (100 uF) is the minimum-recommended to

correctly serve both the purposes.

INPUTS (pins 11-12-13-14)

The inputs are internally biased at half-Vcc level.

The typical input impedance is 15 KOhm, which

implies using Cin (C1-C2-C3-C4) = 220 nF for ob-

taining a theoretical minimum-reproducible fre-

quency of 48 Hz (-3 dB). In any case, Cin val-

ues can be enlarged if a lower frequency bound

is desired, but, at any Cin enlargement must cor-

respond a proportional increase of Csvr (C5), to

safeguard the on/off pop aspect.

The following table indicates the right values to be

used for Cin and Csvr, whose operating voltage

can be 10 V.

LOW FREQUENCY

ROLL-OFF (-3dB)

Cin (ÂµF)

0.22

0.47

0.68

Csvr (ÂµF)

100

220

330

470

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