tda2500 Tripath Technology Inc., tda2500 Datasheet - Page 13

tda2500

Manufacturer Part Number

tda2500

Description

Stereo Class-t Digital Audio Amplifier Driver Using Digital Power Processing Dpp

Manufacturer

Tripath Technology Inc.

Datasheet

1.TDA2500.pdf (29 pages)

Current page: 13 of 29
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The MOSFET drivers in the TDA2500 are operated from voltages obtained from VN12 and LO1COM for

the low-side driver, and bootstrap voltage (internally generated) and HO1COM for the high-side driver.

VN12 must be a regulated 12V above VNN.

N-Channel MOSFETs are used for both the top and bottom of the half bridge. The gate resistors, R

used to control MOSFET slew rate and thereby minimize voltage overshoots. If used, gate diodes, D

reduce the MOSFET turn-off time, thus resucing cross conduction and idle supply current.

C IRCU IT BOARD LA YOU T

The TDA2500 is a power (high current) amplifier that operates at relatively high switching frequencies.

The output of the amplifier switches between VPP and VNN at high speeds while driving large currents.

This high-frequency digital signal is passed through an LC low-pass filter to recover the amplified audio

signal. Since the amplifier must drive the inductive LC output filter and speaker loads, the amplifier

outputs can be pulled above the supply voltage and below ground by the energy in the output inductance.

To avoid subjecting the TDA2500 and external mosfets to potentially damaging voltage stress, it is critical

to have a good printed circuit board layout. It is recommended that Tripath’s layout and application circuit

be used for all applications and only be deviated from after careful analysis of the effects of any changes.

Please refer to the TDA2500 evaluation board document, RB-TDA2500, available on the Tripath website,

at www.tripath.com.

The following components are important to place near either their associated TDA2500 or output

MOSFET pins. The recommendations are ranked in order of layout importance, either for proper device

operation or performance considerations.

Some components are not sensitive to location but are very sensitive to layout and trace routing.

The impedance of the output node (the connection between the top side MOSFET source to

bottom side MOSFET drain) must be minimized. Reducing the parasitic trace inductance is the

most effective way of limiting output node ringing. A flat, bar conductor, in parallel with the PCB

output node trace, is quite effective at minimizing the inductance thereby reducing output

transients due to the switching architecture.

The capacitors, C

serve to reduce spikes and modulation of the power supply rails. Please note that both mosfet

half-bridges must be decoupled separately. In addition, the voltage rating for C

least 400V as this capacitor is exposed to the full supply range, VPP-VNN.

The output diodes, D

Please note that the proper connection of these is “Drain to Drain” and “Source to Source” as

shown in the Application/Test Circuit.

useless due to PCB trace inductance.

The gate resistors, R

possible. In addition, the trace length from the pins LOx/HOx to the gate resistor should be

minimized. To reduce the loop area, a parallel trace from LOxCOM/HOxCOM should be

routed directly to the respective MOSFET source lead.

the output switching frequency by delaying the feedback signals. In addition, the value of C

different for channel 1 and channel 2 to keep the average switching frequency difference

greater than 40kHz. This minimizes in-band audio noise. Locate these capacitors as close to

their respective TDA2500 pin as possible.

The routing of the sense resistors, R

from the respective TDA2500 pin to the sense resistor lead without interruption. If additional

removes very high frequency components from the amplifier feedback signals and lowers

HBR,

provide high frequency bypassing of the amplifier power supplies and will

, should be located as close to the output MOSFET gates leads as

, are used to minimize overshoots/undershoots on the output node.

, must be Kelvin connected. This implies a direct trace

Improper routing of these diodes will render them

T r i p a t h T e c h n o l o g y , I n c . - T e c h n i c a l I n f o r m a t i o n

TDA2500 – KL/ Rev. 0.9/05.05

HBR

should be at

, are

tda2500 Tripath Technology Inc., tda2500 Datasheet - Page 13

tda2500

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