TDA8547TS/N1,118 NXP Semiconductors, TDA8547TS/N1,118 Datasheet - Page 9

TDA8547TS/N1,118

Manufacturer Part Number

TDA8547TS/N1,118

Description

IC AMP AUDIO PWR 1.2W AB 20SSOP

Manufacturer

NXP Semiconductors

Type

Class ABr

Datasheet

1.TDA8547TSN1118.pdf (21 pages)

Specifications of TDA8547TS/N1,118

Output Type

2-Channel (Stereo)

Package / Case

20-SSOP

Max Output Power X Channels @ Load

1.2W x 2 @ 8 Ohm

Voltage - Supply

2.2 V ~ 18 V

Features

Depop, Mute, Short-Circuit and Thermal Protection, Standby

Mounting Type

Surface Mount

Product

Class-AB

Output Power

1.2 W

Available Set Gain

30 dB

Thd Plus Noise

0.15 %

Operating Supply Voltage

5 V

Supply Current

15 mA

Maximum Power Dissipation

1.1 W

Maximum Operating Temperature

+ 85 C

Mounting Style

SMD/SMT

Audio Load Resistance

8 Ohms

Input Bias Current (max)

0.5 uA

Input Signal Type

Differential or Single

Minimum Operating Temperature

- 40 C

Output Signal Type

Differential, Single

Supply Type

Single

Supply Voltage (max)

18 V

Supply Voltage (min)

2.2 V

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Lead Free Status / RoHS Status

Lead free / RoHS Compliant, Lead free / RoHS Compliant

Other names

568-2381-2
935260066118
TDA8547TSDK-T

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TEST AND APPLICATION INFORMATION

Test conditions

Because the application can be either Bridge-Tied Load

(BTL) or Single-Ended (SE), the curves of each

application are shown separately.

The thermal resistance = 110 K/W for the SSOP20; the

maximum sine wave power dissipation for T

is:

For T

Thermal Design Considerations

The ‘measured’ thermal resistance of the IC package is

highly dependent on the configuration and size of the

application board. Data may not be comparable between

different Semiconductor manufacturers because the

application boards and test methods are not (yet)

standardized. Also, the thermal performance of packages

for a specific application may be different than presented

here, because the configuration of the application boards

(copper area!) may be different. NXP Semiconductors

uses FR-4 type application boards with 1 oz copper

traces with solder coating.

The SSOP package has improved thermal conductivity

which reduces the thermal resistance. Using a practical

PCB layout (see Fig.24) with wider copper tracks to the

corner pins and just under the IC, the thermal resistance

from junction to ambient can be reduced to about 80 K/W.

For T

this PCB layout is:

Please note that this two channel IC is mentioned for

application with only one channel active. For that reason

the curves for worst case power dissipation are given for

the condition of only one of the both channels driven with

a 1 kHz sine wave signal.

BTL application

f = 1 kHz, R

22 Hz to 22 kHz.

The BTL application circuit is illustrated in Fig.4.

1998 Apr 01

150 60

--------------------- -

amb

2 × 0.7 W BTL audio amplifier with

output channel switching

110

150 25

--------------------- -

–

amb

= 25 °C if not specially mentioned, V

amb

110

–

= 60 °C the maximum total power dissipation is:

= 60 °C the maximum total power dissipation at

0.82 W

= 8 Ω, G

1.14 W

150 60

--------------------- -

–

= 20 dB, audio band-pass

1.12 W

amb

= 5 V,

= 25 °C

The quiescent current has been measured without any

load impedance and both channels driven. When one

channel is active the quiescent current will be halved.

The total harmonic distortion as a function of frequency

was measured using a low-pass filter of 80 kHz.

The value of capacitor C3 influences the behaviour of the

SVRR at low frequencies: increasing the value of C3

increases the performance of the SVRR.

The figure of the MODE voltage (V

the supply voltage shows three areas; operating, mute

and standby. It shows, that the DC-switching levels of the

mute and standby respectively depend on the supply

voltage level. The figure of the SELECT voltage (V

as a function of the supply voltage shows the voltage

levels for switching the channels in the active, mute or

standby mode.

SE application

f = 1 kHz, R

22 Hz to 22 kHz.

The SE application circuit is illustrated in Fig.16.

Increasing the value of electrolytic capacitor C3 will result

in a better channel separation. Because the positive

output is not designed for high output current (2 × I

low load impedance (≤16 Ω), the SE application with

output capacitors connected to ground is advised.

The capacitor value of C6/C7 in combination with the load

impedance determines the low frequency behaviour.

The THD as a function of frequency was measured using

a low-pass filter of 80 kHz. The value of capacitor C3

influences the behaviour of the SVRR at low frequencies:

increasing the value of C3 increases the performance of

the SVRR.

General remark

The frequency characteristic can be adapted by

connecting a small capacitor across the feedback

resistor. To improve the immunity to HF radiation in radio

circuit applications, a small capacitor can be connected in

parallel with the feedback resistor (56 kΩ); this creates a

low-pass filter.

amb

= 25 °C if not specially mentioned, V

= 4 Ω, G

= 20 dB, audio band-pass

MODE

TDA8547TS

Product specification

) as a function of

= 7.5 V,

SELECT

) at

)

TDA8547TS/N1,118 NXP Semiconductors, TDA8547TS/N1,118 Datasheet - Page 9

TDA8547TS/N1,118

Specifications of TDA8547TS/N1,118

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