LME49811 Datasheet, PDF(12/18 Page) Intersil Corporation – High Fidelity 200 Volt Power Amplifier Input Stage with Shutdown

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LME49811 Datasheet, PDF (12/18 Pages) Intersil Corporation – High Fidelity 200 Volt Power Amplifier Input Stage with Shutdown

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With large values of RIN oscillations may be observed on the

outputs when the inputs are left floating. Decreasing the value

of RIN or not letting the inputs float will remove the oscillations.

If the value of RIN is decreased then the value of CIN will need

to increase in order to maintain the same -3dB frequency re-

sponse.

COMPENSATION CAPACITOR

The compensation capacitor (CC) is one of the most critical

external components in value, placement and type. The ca-

pacitor should be placed close to the LME49811 and a silver

mica type will give good performance. The value of the ca-

pacitor will affect slew rate and stability. The highest slew rate

is possible while also maintaining stability through out the

power and frequency range of operation results in the best

audio performance. The value shown in Figure 1 should be

considered a starting value with optimization done on the

bench and in listening testing.

SUPPLY BYPASSING

The LME49811 has excellent power supply rejection and

does not require a regulated supply. However, to eliminate

possible oscillations all op amps and power op amps should

have their supply leads bypassed with low-inductance capac-

itors having short leads and located close to the package

terminals. Inadequate power supply bypassing will manifest

itself by a low frequency oscillation known as âmotorboatingâ

or by high frequency instabilities. These instabilities can be

eliminated through multiple bypassing utilizing a large elec-

trolytic capacitor (10Î¼F or larger) which is used to absorb low

frequency variations and a small ceramic capacitor (0.1Î¼F) to

prevent any high frequency feedback through the power sup-

ply lines. If adequate bypassing is not provided the current in

the supply leads which is a rectified component of the load

current may be fed back into internal circuitry. This signal

causes low distortion at high frequencies requiring that the

supplies be bypassed at the package terminals with an elec-

trolytic capacitor of 470Î¼F or more.

OUTPUT STAGE USING BIPOLAR TRANSISTORS

With a properly designed output stage and supply voltage of

Â±100V, an output power up to 500W can be generated at

0.05% THD+N into an 8â¦ speaker load. With an output cur-

rent of several amperes, the output transistors need substan-

tial base current drive because power transistors usually have

quite low current gainâtypical hfe of 50 or so. To increase the

current gain, audio amplifiers commonly use Darlington style

devices or additional driver stages. Power transistors should

be mounted together with the VBE multiplier transistor on the

same heat sink to avoid thermal run away. Please see the

section Biasing Technique and Avoiding Thermal Run-

away for additional information.

BIASING TECHNIQUES AND AVOIDING THERMAL

RUNAWAY

A class AB amplifier has some amount of distortion called

Crossover distortion. To effectively minimize the crossover

distortion from the output, a VBE multiplier may be used in-

stead of two biasing diodes. A VBE multiplier normally consists

of a bipolar transistor (QMULT, see Figure 1) and two resistors

(RB1 and RB2, see Figure 1). A trim pot can also be added in

series with RB1 for optional bias adjustment. A properly de-

signed output stage, combine with a VBE multiplier, can elim-

inate the trim pot and virtually eliminate crossover distortion.

The VCE voltage of QMULT (also called BIAS of the output

stage) can be set by following formula:

VBIAS = VBE(1+RB2/RB1) (V)

(6)

When using a bipolar output stage with the LME49811 (as in

Figure 1), the designer must beware of thermal runaway.

Thermal runaway is a result of the temperature dependence

of VBE (an inherent property of the transistor). As temperature

increases, VBE decreases. In practice, current flowing through

a bipolar transistor heats up the transistor, which lowers the

VBE. This in turn increases the current gain, and the cycle re-

peats. If the system is not designed properly this positive

feedback mechanism can destroy the bipolar transistors used

in the output stage. One of the recommended methods of

preventing thermal runaway is to use the same heat sink on

the bipolar output stage transistor together with VBE multiplier

transistor. When the VBE multiplier transistor is mounted to the

same heat sink as the bipolar output stage transistors, it tem-

perature will track that of the output transistors. Its VBE is

dependent upon temperature as well, and so it will draw more

current as the output transistors heat up, reducing the bias

voltage to compensate. This will limit the base current into the

output transistors, which counteracts thermal runaway. An-

other widely popular method of preventing thermal runaway

is to use low value emitter degeneration resistors (RE1 and

RE2). As current increases, the voltage at the emitter also in-

creases, which decreases the voltage across the base and

emitter. This mechanism helps to limit the current and coun-

teracts thermal runaway.

LAYOUT CONSIDERATION AND AVOIDING GROUND

LOOPS

A proper layout is virtually essential for a high performance

audio amplifier. It is very important to return the load ground,

supply grounds of output transistors, and the low level (feed-

back and input) grounds to the circuit board common ground

point through separate paths. When ground is routed in this

fashion, it is called a star ground or a single point ground. It

is advisable to keep the supply decoupling capacitors of

0.1Î¼F close as possible to LME49811 to reduce the effects of

PCB trace resistance and inductance. Following the general

rules will optimize the PCB layout and avoid ground loops

problems:

a) Make use of symmetrical placement of components.

b) Make high current traces, such as output path traces, as

wide as possible to accommodate output stage current re-

quirement.

c) To reduce the PCB trace resistance and inductance, same

ground returns paths should be as short as possible. If pos-

sible, make the output traces short and equal in length.

d) To reduce the PCB trace resistance and inductance,

ground returns paths should be as short as possible.

e) If possible, star ground or a single point ground should be

observed. Advanced planning before starting the PCB can

improve audio performance.

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