LM4830N National Semiconductor, LM4830N Datasheet - Page 9

LM4830N

Manufacturer Part Number

LM4830N

Description

IC AMP AUDIO PWR 2W MONO 24DIP

Manufacturer

National Semiconductor

Type

Class ABr

Datasheet

1.LM4830M.pdf (13 pages)

Specifications of LM4830N

Output Type

1-Channel (Mono) with Mono Headphones

Max Output Power X Channels @ Load

2W x 1 @ 4 Ohm; 100mW x 1 @ 32 Ohm

Voltage - Supply

2.7 V ~ 5.5 V

Features

Microphone, Shutdown, Thermal Protection, Volume Control

Mounting Type

Through Hole

Package / Case

24-DIP (0.600", 15.24mm)

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Other names

*LM4830N

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Application Information

POWER AMPLIFIER HANDSFREE MODE

As shown in Figure 1 , amplifier A1 can be used in one of two

modes, bridged output or single-ended output. This IC was

intended to be used in systems requiring both internal

speaker drive and external mono-headphone drive capabil-

ity. Headphones generally have a much higher impedance

than that of speakers since headphones don’t require as

much output power. This also allows headphones to be

driven single-endedly. Shown in Figure 1 , the output can be

automatically switched from bridged speaker drive to

single-ended headphone drive using a control pin in the

headphone jack that is tied to the Headset (HS) pin, pin 3.

When the voltage at the HS pin input changes from 0V to 5V,

ance. This allows the permanently connected internal

speaker of the system to be disabled when a headphone is

plugged into the headphone jack. Output V

headphone single-endedly through the output coupling cap,

be amplified. Since C

must be big enough to allow frequencies down to 20 Hz to be

amplified. The following equation should be used for proper

component selection.

As usual, the output drive limitations are the maximum sup-

ply voltage swing, current drive capability, and power dissi-

pation. In bridged-output drive mode, the power amplifier will

drive 4

ever, trying to put a sinewave through the amplifier at the

worst case power dissipation point could cause the amplifier

to go into thermal shutdown.

In single-ended drive mode, the amplifier is intended to drive

limitations of voltage swing and current drive capability. The

result of driving lower impedance loads single-endedly is

lower achievable output power.

Headset and Shutdown Pin Table

X — “Don’t Care” NA — Not Applicable

POWER DISSIPATION

Power dissipation is a major concern when using any power

amplifier and must be thoroughly understood to ensure a

successful design. Equation 2 states the maximum power

dissipation point for a bridged amplifier operating at a given

supply voltage and driving a specified output load.

Although the LM4830 has three amplifiers in the package,

the bridged amplifier produces the majority of the power dis-

sipation because it supplies the largest amount of output

power. If each of the amplifiers in the LM4830 were of the

same power level, each of their power dissipations would

need to be taken into account. However, this is not the case

and the bridged power amplifier is the only major power dis-

sipation contributor.

HS Pin

. C

High

Low

of the bridged amplifier output is put into high imped-

headphones. It will drive lower impedances with the

should be chosen to allow the full audio bandwidth to

= 1/(2 (20 Hz)(R

or 8

SD Pin

High

Low

with normal music signals over time. How-

DMAX

and R

= 4(V

All Outputs On

1/2 A1 On

Whole IC Off

IC Operation

)) where 16

On Only)

create a high-pass filter, C

)

/(2

)

then drives the

Microphone

MIC1 On

MIC2 On

600

(1)

(2)

Even with the large internal power dissipation created by the

bridged amplifier, the LM4830 does not require heatsinking

over a large range of ambient temperatures. Using Equation

2, assuming a 5V power supply and a 8 load, the maximum

power dissipation point is 633 mW.

For the LM4830 surface mount package,

of the system surroundings, Equation 3 can be used to find

the maximum internal power dissipation supported by the IC

packaging. If the result of Equation 2 is greater than that of

Equation 3, then either the supply voltage must be de-

creased, the load impedance increased, or the ambient tem-

perature reduced. For the typical application of a 5V power

supply, with a bridged 8

perature possible without violating the maximum junction

temperature is approximately 100˚C provided that device op-

eration is around the maximum power dissipation point. The

average power dissipation caused by typical music material

played at a reasonable level is generally lower than the

maximum power dissipation point. Refer to the Typical Per-

formance Characteristics curves for power dissipation in-

formation for lower output powers.

POWER SUPPLY BYPASSING

As with any power amplifier, proper supply bypassing is criti-

cal for low noise performance and high power supply rejec-

tion. The capacitor location on both the half-supply bypass

and power supply pins should be as close to the device as

possible. The effect of a larger half-supply bypass capacitor

is improved low frequency PSRR due to increased

half-supply stability. Typical applications employ a 5V regula-

tor with 10 µF and a 0.1 µF bypass capacitors which aid in

supply stability, but do not eliminate the need for bypassing

the supply nodes of the LM4830. The selection of bypass ca-

pacitors, especially C

frequency PSRR, system cost, and size constraints.

GROUNDING

In order to achieve the best possible performance, there are

certain grounding techniques that should be followed. All in-

put reference grounds should be tied with their respective

source grounds and brought back to the power supply

ground separately from the output load ground returns.

Those input grounds should also be tied in with the

half-supply bypass ground, pin 16. As an example, the AC in-

put ground reference for the power amplifier, A1, is V

7. This ground should be tied as close as possible to the By-

pass ground (pin 16), as shown in Figure 1 . In order to tie in

the signal source ground, the audio jack ground on V

should also be tied to the Bypass ground.

As stated above, the ground returns for the output loads

should be brought back to the supply ground individually.

This will keep large signal currents on those ground lines

from interfering with the stable AC input ground references.

In addition, the signal ground reference for the preamp, A2,

(the ground end of capacitor C

the mic inputs’ signal ground reference from the microphone.

LAYOUT ISSUES

As stated in the Grounding section, placement of ground re-

turn lines is imperative in maintaining the highest level of

system performance. It is not only important to route the cor-

rect ground return lines together, but also equally important

to be aware of where those ground return lines are routed in

conjunction with each other. As an example, the output load

JMAX

= 150˚C. Depending on the ambient temperature, T

DMAX

, is thus dependent upon desired low

= (T

load, the maximum ambient tem-

JMAX

) should be tied together with

− T

= 79˚C/W and

www.national.com

IN+

, pin

IN−

(3)

LM4830N National Semiconductor, LM4830N Datasheet - Page 9

LM4830N

Specifications of LM4830N

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